Systems Biology of Mitosis



Dissertation
to receive the degree Dr. rer. nat from the
Friedrich-Schiller-University Jena
by


Bashar Ibrahim 

Born on August 28, 1976 in Mosul 


Examiners: 

1. PD Dr. Peter Dittrich (Jena Centre for Bioinformatics & FSU Jena) 
2. Prof. Dr. Stephan Diekmann (Fritz-Lipmann-Institute Jena) 
3. Dr. Andrea Musacchio (European Institute of Oncology) 
Oral examination : July 30, 2008 
Public defence : September 15, 2008 


Systems Biologie der Mitose



Dissertation zur Erlangung des akademischen Grades doctor rerum 
naturalium (Dr. rer. nat.) vorgelegt dem Rat der Fakultat fur 
Mathematik und Informatik der Friedrich-Schiller-Universitat Jena 
von 

Bashar Ibrahim 

geboren am 28.08.1976 in Mosul 


Gedruckt mit Unterstutzung des Deutschen Akademischen Austauschdienstes


Gutachter: 

1. PD Dr. Peter Dittrich (Jenaer Centrum fur Bioinformatik & FSU Jena) 
2. Prof. Dr. Stephan Diekmann (Fritz-Lipmann-Institut Jena) 
3. Dr. Andrea Musacchio (Europaisch Institut fur Onkologie) 
Tag der letzten Prufung des Rigorosums: 30. Juli 2008 
Tag der oentlichen Verteidigung: 15. September 2008 


To the loving memory of my Father, 
who passed away on March 14th, 2005. 
I've no words to describe him. 

I am so proud of his gentle, beautiful ways.
I did see his love. He presented me with it, and it lled my
heart with loyalty and dignity.


I dedicate this work to him, to honor these lial remem
brances.


... And to my Mother. 
Her support, encouragement, and constant love have sustained me throughout my entire life. 


Acknowledgements 

I am deeply indebted to the German Academic Exchange Service 
(DAAD) for providing me with a high-quality research opportunity to 

carry out my PhD research in Germany. 

I would like to express my gratitude to my advisor, Peter Dittrich, 
whose research expertise, comprehensive understanding of our work, 
and patience, added considerable knowledge to my graduate experience. 
I am most thankful, and indebted to him in all possible ways. 

Stephan Diekmann made crucial contributions in the context of this 

thesis. He became a virtual co-adviser of my research, and provided 

us with critical knowledge on all the biological aspects of this work. 

I am grateful to Eberhard Schmitt for his important and very much 
welcomed contributions on many mathematical aspects of this work. 

I would also like to thank Clemens Beckstein for his unconditional 

support to our work. 

My sincere thanks also go to Rodulf Goren
o and Martin Hermann, 
who initially supported my research, and to Mrs. Margret Steuernagel 
and Mrs. Birgit Klaes (DAAD), who took care of many important 
aspects related to my wonderful experience in Germany. 

I would like to express my profound gratitude to my friends, Mariana 

Gil and Rodrigo De Marco; their extraordinary love and support were 

of immeasurable value to me. 

I feel a deep sense of gratitude to my family who formed part of my 
vision and taught me the good things that really matter in life. The 
happy memory of my father still provides a persistent inspiration for 


my journey in this life. I am grateful for my beloved brothers for 
rendering me the sense and the value of brotherhood. I am glad to be 
one of them. 

Finally, it is my belief that quite a number of people contributed to 
and supported my work in many dierent ways. It would virtually be 
impossible to refer to all of them, and to emphasize their roles and 
specic contributions. They will, I think forgive me if I name only 
the two whose contribution proved most far-reaching and decisive: 
Thorsten Lenser and Heiko Lochas. 


Abstract 

In mitosis, `surveillance control mechanisms’ regulate transitions across 
the several stages of cell division. The so called `Mitotic-Spindle-
Assembly-Checkpoint (MSAC)’ and `Exit-From-Mitosis (EFM)’ are 
examples of such mechanisms. MSAC ensures the correct segregation 
of chromosomes by preventing cell-cycle progression until all chromosomes have made proper bipolar attachments to the mitotic spindle 
through their kinetochores. EFM ensures that each of the two daughter 
nuclei receives one copy of each chromosome. Both mechanisms are 
seemingly regulated by the so called `Anaphase-Promoting-Complex 
(APC)', bound, in turn, to either `Cdc20’ or `Cdh1', which are associated regulatory proteins. APC remains inactive during metaphase. 
In the transition from metaphase to anaphase, and only after all 
chromosomes are attached, a newly formed `APC:Cdc20’ complex 
mediates the ubiquitination and degradation of the protein `Securin'; 
this leads, in turn, to the activation of the protein `Separase', the 
dissolution of the so called `Cohesin Complex', and, eventually, to 
chromatid separation. `APC:Cdc20’ also mediates the initial phase of 
`Cyclin B’ proteolysis. In the transition from anaphase to telophase, 
APC:Cdh1 completely ubiquitinates `Cyclin B', thus inactivating a protein called `CyclinB:Cdk1-Mitotic-Kinase’ and triggering the exit from 
mitosis. Both MSAC and EFM prevent chromosome miss-segregation 
and aneuploidy, and their failure eventually leads to cell death; both 
mechanisms have been implicated in cancer. Our understanding of 
mitotic regulatory mechanisms has signicantly improved in recent 
years. Yet, MSAC and EFM remain poorly understood. Hence, we 
beneted from in-silico modeling and simulation approaches embedded in a cross-disciplinary framework, typically referred to as Systems 


Biology, in order to contribute to a deeper understanding of these 
mitotic regulatory mechanisms. We rst focused on the question how 
`Cdc20’ availability is controlled prior to the attachments of all chromosomes; or, in other words, how `APC:Cdc20’ formation is eventually 
prevented. It had been proposed that Cdc20 remains fully sequestered 
until the last chromosome is attached. By using a Systems Biology 
approach to this question, we built-up and tested predictions from 
a series of dynamic models fed with empirical data (Ibrahim et al., 
2008b,c). According to our results, cells are unable to completely 
sequester Cdc20 until the last chromosome is attached. Next, we 
asked whether a complex called `MCC’ might be able to fully prevent 

`APC:Cdc20’ formation by binding APC, thereby sequestering it fully, 
prior to the attachment of all chromosomes. To tackle this question, 
we built-up a combined in-silico model fed with empirical data on 
APC levels prior to chromosome attachment (Ibrahim et al., 2008a). 
Our results then showed that MCC can fully sequester APC prior to 
chromosome attachment. This would eventually prevent `APC:Cdc20’ 
activity. From the later results, one still needs to ask how a complex 
like `MCC:APC’ would fall apart after chromosome attachment. In 
order to address this question, we constructed two equally suitable 
model variants, called the \Dissociation” and \Convey” models, and 
validated them by means of mutation experiments (Ibrahim et al., 
2008a). Moreover, we also developed and tested the robustness of a 
qualitative model of MSAC (Ibrahim et al., 2007). Finally, we incorporated an adapted `EFM-model’ involving `APC:Cdh1’ activity into an 
integrative model involving APC:Ccd20 activity, thereby addressing 
simultaneously the functioning of both transition control mechanisms, 
MSAC and EFM. 


Deutsche Zusammenfassung 

¨ 

Die Ubergange zwischen den einzelnen Phasen der Mitose werden 
durch `surveillance control mechanisms’ reguliert. Zwei Beispiele hierfur sind der `Mitotic-Spindle-Assembly-Checkpoint (MSAC)’ und 
der `Exit-From-Mitosis (EFM)'. MSAC sichert die korrekte Teilung 
der Chromosomen, indem der Fortschritt des Zellzyklus angehalten 
wird, bis alle Chromosomen durch ihre Kinetochore fest mit dem mitotischen Spindelapparat verbunden sind. EFM stellt sicher, dass jeder 
der beiden Zellkerne nach der Teilung 

uber genau eine Kopie eines 

jeden Chromosomes verfugt. 
Beide Mechanismen werden anscheinend durch den `Anaphase-
Promoting-Complex (APC)’ reguliert, welcher wiederum an die 
regulativen Proteine `Cdc20’ und `Cdh1’ gebunden ist. APC bleibt 

¨ 

inaktiv wahrend der Metaphase. Beim Ubergang von der Metaphase 
zur Anaphase, nachdem alle Chromosomen an den Spindelapparat 
gekoppelt sind, katalysiert der neu geformte `APC:Cdc20’ Komplex 
die Ubiquitination und Degradierung des Proteins `Securin'; dies 
wiederum fuhrt zur Aktivierung des Proteins `Separase', zur Au
osung 
des `Cohesin Komplexes’ und zur Trennung der Chromatide. 

`APC:Cdc20’ katalysiert auch die Fruhphase der Proteolyse des `Cy
¨ 

clin B'. Beim Ubergang von Anaphase zu Telophase wird `Cyclin B’ 
komplett durch APC:Cdh1 ubiquitiniert, was zur Inaktivierung des Proteins `CyclinB:Cdk1-Mitotic-Kinase’ und schlielich zum Austritt aus 
der Mitose fuhrt. Sowohl MSAC als auch EFM verhindern fehlerhafte 
Chromosomenteilung und Aneuploidie, ihr Versagen fuhrt zum Zelltod. 
Beide Mechanismen sind mit der Entstehung von Krebserkrankungen 
in Verbindung gebracht worden. 

In den letzten Jahren hat sich unser Verstandnis der regulativen Mechanismen in der Mitose drastisch verbessert, aber MSAC und EFM sind 
weiterhin schlecht verstanden. In silico Modellierungs-und Simulationsansatze -eingebettet in die interdisziplinare Systembiologie -konnen 


uns helfen, ein tieferes Verstandnis dieser regulativen Mechanismen zu 
erreichen. 
Wir haben uns zuerst auf die Frage konzentriert, wie die Verfugbarkeit 
von `Cdc20’ vor dem Andocken der Chromosomen kontrolliert wird, 
oder in anderen Worten, wie die Bildung von `APC:Cdc20’ verhindert wird. Ein bestehender Vorschlag besagt, dass Cdc20 vollstandig 
festgehalten wird bis das letzte Chromosom angedockt ist. In einem 
systembiologischen Zugang zu dieser Fragestellung haben wir eine 
Reihe von dynamischen Modellen erstellt, basierend auf empirischen 
Daten (Ibrahim et al., 2008b,c), um Vorhersagen zu erstellen und zu 
testen. Unsere Ergebnisse implizieren, dass Zellen Cdc20 nicht komplett bis zum Andocken des letzten Chromosomes festhalten konnen. 

Als nachstes fragten wir, ob der sogenannte `MCC’ Komplex in der 
Lage sein konnte, die Bildung von `APC:Cdc20’ vor dem Andocken 
aller Chromosome vollstandig zu verhindern, indem er APC bindet und 
festhalt. Um diese Frage zu attackieren, haben wir ein kombiniertes 
in silico Model erstellt und mit empirischen Daten 

uber APC Levels 
vor dem Andocken der Chromosomen gefuttert (Ibrahim et al., 2008a). 
Unsere Ergebnisse zeigen, dass MCC APC vollstanding festhalten 
kann, was die Aktivitat von `APC:Cdc20’ verhindern wurde. 
Aufbauend auf diesem Resultat stellt sich nun die Frage, wie der 
`MCC:APC’ Komplex nach dem Andocken der Chromosome auseinanderfallt. Um diese Frage zu addressieren, haben wir zwei Modellvarianten erstellt -die sogenannten \Dissociation” und \Convey” Modelle 
-und diese mit Hilfe von Mutationsexperimenten validiert (Ibrahim 
et al., 2008a). Daruber hinaus haben wir ein qualitatives Modell von 
MSAC erstellt und dessen Robustheit untersucht (Ibrahim et al., 2007). 
Zum Abschluss haben wir ein `EFM’ Modell, welches `APC:Cdh1’ 
Aktivitat mitbeachtet, in ein integratives Modell inklusive APC:Cdc20 
eingefugt. Das entstandene Modell enthalt nun gleichzeitig die Funktion von MSAC und EFM, der beiden Mechanismen der Transitionskontrolle. 


Contents 

1 Orientation, Motivation and Aim of the study 1 

1.1 Why to use a Systems Biology Approach to Mitosis Transition 
Controls? ............................... 2 

1.2 Background, Specic Problems, and Results . . . . . . . . . . . . 6 

1.3 This thesis is based on the following publications . . . . . . . . . 9 

2 Mitosis Transition Controls 11 

2.1 CellDivision.............................. 12


2.2 Mitosis................................. 14


2.3 CheckpointsinCellCycleRegulation . . . . . . . . . . . . . . . . 19 

2.4 AnaphaseInitiationControl ..................... 21


2.4.1 The Mitotic Spindle Assembly Checkpoint (MSAC) .... 21 

2.4.2 Experimental Studies on the MSAC ............. 23


2.4.3 Recent Models of the MSAC ................. 42


2.5 MitoticExitcontrol.......................... 43


2.5.1 Exit From Mitosis (EFM) Mechanism . . . . . . . . . . . 43 

2.5.2 Analysis of the Recent Experimental Studies of the EFM . 43 

2.5.3 RecentModelsoftheEFM.................. 46


2.6 ConcludingRemarks ......................... 47


Entering to Anaphase ... 51 

3 Modeling Mad2 Function in Sequestering Cdc20 51 

3.1 Summary ............................... 52


xiii 


CONTENTS


3.2 Introduction .............................. 52


3.3 Methods: Denition and Simulation of the Models . . . . . . . . . 53 

3.4 BiochemicalBasisoftheModels ................... 54


3.5 TheExchangeModel ......................... 55


3.6 TheTemplateModel ......................... 59


3.7 VariationsoftheTemplatemodel .................. 64


3.7.1 AmplicationEects ..................... 64


3.7.2 InhibitionEects ....................... 67


3.7.3 Amplication plus Inhibition Eects . . . . . . . . . . . . 68 

3.8 Discussion............................... 68


3.9 Conclusion............................... 72


4 Modeling MCC assembly 73 

4.1 Summary ............................... 74


4.2 Molecular biological basis of MCC models . . . . . . . . . . . . . 74 

4.3 MathematicalmodelingoftheMCC. . . . . . . . . . . . . . . . . 76 

4.4 DynamicsofdierentMCCmodels . . . . . . . . . . . . . . . . . 77 

4.4.1 Kinetochore dependent MCC model (KDM) . . . . . . . . 77 

4.4.2 Kinetochore independent MCC model (KIM) . . . . . . . . 83 

4.4.3 Amplicationeects ..................... 85


4.4.4 p31comet contributions..................... 86


4.4.5 MaximumsequesteringofCdc20. . . . . . . . . . . . . . . 88 

4.5 DiscussionandConclusions ..................... 96


5 Modeling APC Control 99 

5.1 Summary ............................... 100


5.2 Biochemicalbackground ....................... 100


5.2.1 Mad2TemplateModel .................... 101


5.2.2 MCCAssembly ........................ 101


5.2.3 APCInhibition ........................ 102


5.2.4 ControlbyAttachment .................... 103


5.2.5 ChemicalReactionScheme.................. 104


5.2.6 Mathematical Treatment and Simulation . . . . . . . . . . 105 

5.3 Results................................. 107


xiv 


CONTENTS


5.3.1 MSACModelBehavior .................... 109


5.3.2 Model Validation by Mutation Experiments . . . . . . . . 115 

5.4 Discussion............................... 119


6 Robustness and Stochasticity Eect 125 

6.1 Summary ............................... 126


6.2 Introduction .............................. 126


6.3 TheModelanditsSimulation .................... 127


6.4 Results................................. 133


6.5 DiscussionandConclusion ...................... 134


Mitosis Consolidation ... 143 

7 Integrative Model of Mitosis Transition Control Mechanisms 143 

7.1 Summary ............................... 144


7.2 Biochemical Background of the Integrative Model . . . . . . . . . 146 

7.3 Simulation ............................... 148


7.3.1 Optimization ......................... 149


7.3.2 ModelBehavior ........................ 153


7.4 ModelValidation ........................... 155


7.5 ConcludingRemarks ......................... 158


8 Conclusion 163 

A Modeling and Simulation for Systems Biology 167 

A.1 Prologue................................ 167


A.2 NetworkModels............................ 173


A.3 Algebraic Models (Discrete/State Time) . . . . . . . . . . . . . . 174 

A.3.1 Theory of Chemical Organizations . . . . . . . . . . . . . . 174 

A.3.2 PetriNets ........................... 176


A.4 TimeDynamicalModels ....................... 177


A.4.1 Deterministic versus Stochastic (Probabilistic) Models . . 177 

A.4.2 Multi-ScaleModels ...................... 180


A.5 SpaceDynamicalModels ....................... 182


xv 


CONTENTS


A.6 Methods ................................ 182


B Template-like models 185 

B.1 ODEsoftheExchangemodel .................... 185


B.2 ODEsoftheTemplatemodel .................... 186


B.3 ODEs of the Template model with the Amplication eects . . . . 186 

B.4 ODEsofofp31eectsontheTemplatemodel . . . . . . . . . . . 187 

B.5 ODEs of of p31 eects on the Template model with amplication 188 

B.6 Materials, Methods, and Optimization . . . . . . . . . . . . . . . 188 

C MCC formation models 191 

C.1 MCC\kinetochoredependentmodel” ................ 191


C.2 Amplicationeects ......................... 192


C.3 p31comet contribution ......................... 193


C.4 Fitnessfunction ............................ 193


D The Dissociation and the Convey Model 195 

D.1 ODEs of the MSAC model Dissociation variant . . . . . . . . . . . 196 

D.2 ODEs of the MSACmodelConveyvariant . . . . . . . . . . . . . 197 

D.3 Optimization ............................. 198


E The Integrative Model of MSAC and EFM Mechanisms 199 

E.1 ODEs of the integrative model of MSAC (Dissociation variant) and 
EFM.................................. 200 

E.2 ODEs of the integrative model of MSAC ( Convey variant ) and 
EFM ............................... 201 

References 203 

¨ 

Uber den Autor 235 

About the Author 241 

xvi



\Mathematics, rightly viewed, possesses not only truth, but 
supreme beauty -a beauty cold and austere, like that of 
sculpture". Bertrand Russell (1872 -1970) 

\Biologists must constantly keep in mind that what they see 
was not designed, but rather evolved". 

Francis Crick, What Mad Pursuit, 1990, p.138. 

Chapter 1 

Orientation, Motivation and Aim of 
the study 

Contents 

1.1 Why to use a Systems Biology Approach to Mitosis 
TransitionControls?.................... 2 
1.2 Background, Specic Problems, and Results . . . . . 6 
1.3 This thesis is based on the following publications . . 9 
1



1. ORIENTATION, MOTIVATION AND AIM OF THE STUDY
1.1 Why to use a Systems Biology Approach to Mitosis Transition Controls? 
The renowned theoretical and applied mathematician Norbert Wiener stated 
that living organisms can be thought of as systems governed by feedback and 
regulatory mechanisms, which are, in turn, plausible of being understood (Wiener, 
1948). The study of both complexity (Holland, 1995) and control theory (von 
Bertalany, 1968) now receives increasing attention by scientists following the so 
called \Systems Biology” approach to research. Some refer to Systems Biology 
as an emergent eld that \studies cells as spatiotemporal networks of interacting 
molecules using an integrative approach of theory (mathematics, physics, engineering), experimental biology (genetics, molecular biology, physiology), and 
quantitative network-wide analytical measurement (analytical biochemistry, imaging) (Bruggeman, 2007).” Systems Biology therefore deals with modeling and 
simulation, and involves concepts from mathematics, computer science, physics, 
biochemistry, and engineering. 

Living systems are undoubtedly complex. They exhibit organizational principles, 
chemical uniqueness, variability, genetic programs, and historical nature, properties 
embedded in the concepts of pleiotropy and polygeny (Mayr, 1982). It follows 
that only systems, or subsystems, that show their own dynamics, but not their 
isolated, constitutive elements, can be thought of as the subject matter of functional 
biology (Nunez and Marco, 2007). We need to examine the structure and dynamics 
of biological functions, rather than the characteristics of the isolated parts of a cell 
or organism. In the context of cell biology, this may have a major impact on the 
future of biological and medical research (Kitano, 2002b,a). There is a need which 
drives Systems Biology. It relies on an increasing knowledge on a cell's constitutive 
elements, accompanied by a simultaneous lack of comparable knowledge on the 
ensuing interactions and organizing principles that govern them. Computer science 
already proved fruitful in biology, and it now appears as increasingly dicult to 
study complex cellular functions without the help of computational, modeling 
approaches. 

2 


1.1 Why to use a Systems Biology Approach to Mitosis Transition 
Controls? 
Mitosis can be thought of as a nely regulated and exceedingly complex process. 
During the process of cell division, a cell's chromosomes are eventually distributed 
between two daughter nuclei. Molecular biologists typically characterize the 
activity, aggregation and interactions of tens of cellular elements involved in mitosis, 
although the relation between such interacting elements and their respective 
environment remains still elusive. Predictions, therefore, are not straightforward. 
There is a need for a system-level understating of the regulatory mechanisms 
involved in mitosis. This might be of major relevance for medical research, as 
well as for a better understating of other cellular processes. We shall refer to our 
work as to \Systems Biology of Mitosis". Our focus is on human cells, and we 
benet from modeling and simulation approaches embedded in a cross-disciplinary 
framework, in order to contribute to a deeper understanding of mitotic regulatory 
mechanisms. Below there is a list of items that may help in illustrating what we 
can gain from a Systems Biology approach to mitosis. 

Identifying a System's Structure: Understanding the functioning of a biochemical network demands identifying its underlying pathways. One can 
obtain knowledge about the several elements involved in the mechanisms 
controlling mitosis, as well as information on their -isolated-interactions. Yet, 
one also needs to ask whether and how these elements and interactions are 
topologically organized. This would eventually allow understanding a system's 
functional structure by means of accessible network models. Analyzing these 
networks would lead, in turn, to the development of new, testable hypotheses. 
(e.g., Appendix A, Section A.2) 

Capturing a System's Behavior: Modeling and simulation approaches allow 
qualitative as well as quantitative analyzes of a system's behaviour. They 
permit to capture not only the dynamics of an evolving system, but also its 
specic state at any given time on the basis of kinetic data. To this end, one 
uses deterministic (ODEs), stochastic (particle simulation), or even mixed 
(SDEs) modeling approaches. (See Chapters 3-7) 

Evaluating a System's Intrinsic Properties: A Systems Biology approach 
to mitosis allows predictions based on stability and sensitivity analyzes. It 
also allows capturing the eects of noise, bifurcations, and chaotic attractors. 

3



1. ORIENTATION, MOTIVATION AND AIM OF THE STUDY
Chapter 6 helps in illustrating the relevance of these intrinsic properties in 
the context of a qualitative model of anaphase initiation. 

Capturing a System's Signalling Pathways: The functioning of the transition 
control mechanisms depends upon regulating signals; a Systems Biology 
account of such signals would eventually lead to a deeper understanding of 
the entire process of mitosis. (e.g., Chapter 5). 

3D-Modeling: A Systems Biology approach to mitosis allows evaluating specic eects of a three-dimensional `environment’ on those interactions occurring 
among the several elements of a network. The term `environment’ here refers 
to variations arising from diusion eects, the movements of microtubules, 
changes in the cell volume, localization and binding specicities, etc. This is 
important because the functioning of the several networks controlling mitosis 
in
uences the cellular space, and vice versa; there is a cross-talk between a 
given environment and the functional processes embedded in it (Figure 1.1). 
To tackle the eects of such a phenomenon, one benets from partial dierential equations (PDEs), cellular automate, or even mixed approaches like 
stochastic partial dierential equations (SPDEs). By means of such tools, rich 
dynamics and powerful predictions are within reach. 

Mutual Benets Across Disciplines: Systems Biology demands a fusion of 
concepts from several disciplines, thereby integrating dierent computational 
instruments into a general computational infrastructure. In the present context, 
new concepts arise from well-established and tested results from mathematics, 
computer science, molecular biology, and biochemistry. It is sometimes dicult 
to handle data arising from such an inter-disciplinary approach. As a by-
product of the present work, a software tool, called \Mitosis Arena", is being 
developed to help in visualizing and interpreting the 
ood of data related 
to mitosis transitions control mechanisms (Figure 1.1). Such a tool would 
eventually be integrated and communicated via SBML (Systems Biology 
Markup Language). 

A cross-talk between theoretical and empirical accounts of mitosis: Biological research can sometimes be the subject of ontological reductionism; 

4 


1.1 Why to use a Systems Biology Approach to Mitosis Transition 
Controls? 
Systems Biology aims to counterbalance such a tendency. We suggest that a 
Systems Biology approach to mitosis would prove fruitful in proposing testable 
hypotheses, simply because it gives off useful predictions based on the countless interactions among the various cellular elements whose behaviors cannot 
simultaneously be addressed in the laboratory. (See, for example, Chapter 5) 

Mitosis of a three-movement.
cellular space includingMitosis Network ModelsSimulation of network dynamicsDeterministic (ODEs), 
Stochastic (SDEs), orPetri Net
Figure 1.1: Schematic diagram of the simulation environment. The new tool called 
Mitosis Arena will allow to load a network model (SBML) describing the biochemical reaction mechanism. The simulation includes the three-dimensional movement of the chromosomes, which in
uences the bio-chemical dynamics through a 
changing topology and which in turn is in
uenced by the state of the bio-chemical 
network species. This tool is necessary, because understanding the network controlling mitosis requires also to consider a changing cellular space whose topological 
change is in
uenced by the biochemical network, and vice versa where the spatial 
structure in
uences the dynamics of the biochemical system. 

5



1. ORIENTATION, MOTIVATION AND AIM OF THE STUDY
1.2 Background, Specic Problems, and Results 
In the present context, our emphasize is on two dierent, still connected mitosis transition control mechanisms, namely, the Mitotic Spindle Assembly 
Checkpoint (MSAC) and Exit From Mitosis (EFM). MSAC ensures the correct 
segregation of chromosomes by restraining cell-cycle progression from entering 
anaphase until all chromosomes have made proper bipolar attachments to the 
mitotic spindle. MSAC thus ensures the delity of chromosome segregation; its 
failure leads to aneuploidy (Kim and Kao, 2005; Steuerwald, 2005), for example, 
and might contribute to cancer (Compton, 2006; Gupta et al., 2003). In principle, 
MSAC controls the activity of a complex of proteins called \Anaphase Promoting 
Complex", or APC, during the transition from metaphase to anaphase, when 
chromosomes are not yet attached. MSAC becomes inactive once all chromosomes 
are attached. At this time, APC interacts with its co-activator, a protein called 
\Cell Division Cycle", or Cdc20. The active, ensuing complex \APC:Cdc20” has 
two functions. First, it activates a protein called \Separase", involved in breakingup the so called \Cohesion ring", which eventually leads to the separation of the 
sister chromatids. Second, APC:Cdc20 is involved in the partial degradation of 

\Cyclin B", the mitotic cyclin. Mitosis then progresses, and becomes the subject 
of the second transition control mechanism, the Exit From Mitosis mechanism. 
Generally speaking, EFM ensures that each of the two daughter nuclei receives 
one copy of each chromosome. Its main role is to guarantee a full degradation of 
Cyclin B via the activity of the complex \APC:Cdh1", formed by APC and its 
second co-activator, a protein called Cdh1. After the full degradation of Cyclin B, 
the process of cell division progresses into cytokinesis. 

Both MSAC and EFM are complex mechanisms involving numerous interacting 
elements. They are the subject of complex dynamics, in addition. Therefore 
their functional and topological structures remain still poorly understood. At 
present, no model provides a satisfactory account of how MSAC actually works. 
In contrast, there are several models describing how EFM works, all them based 
on data from yeast. These two mechanisms have not yet been integrated into a 

6



1.2 Background, Specic Problems, and Results
single model. Here we aim to contribute towards an integrative model explaining 
both MSAC and EFM in human cells. 

We rst focused on the question how the availability of Cdc20 is controlled prior to 
the attachments of all chromosomes. In other words, how APC:Cdc20 formation is 
eventually prevented. It has been proposed that Cdc20 remains fully sequestered 
until the last chromosome is attached. The rst candidate thought to fully 
sequester Cdc20 appeared to be a MSAC -protein called \Mad2"(e.g., Luo et al., 
2002; Sironi et al., 2001a). Two basic models, called \Exchange” (Luo et al., 2004) 
and \Template” (DeAntoni et al., 2005a), have been developed on the basis of such 
hypothesis. By using a Systems Biology approach to this question, we built-up a 
series of dynamic models, fed them with empirical data, and tested predictions 
from both the Template and the Exchange models. Our results indicate that 
Mad2 is not sucient to fully sequester Cdc20, and that only the Template model 
appears to be partially consistent with our simulations (See Chapter 3). It has also 
been proposed that a second protein, called \BubR1", can sequester Cdc20 prior 
to the attachment of all chromosomes (e.g., Bolanos-Garcia et al., 2005; Davenport 
et al., 2006). BubR1 binds Cdc20 within two seemingly dierent contexts. In 
the rst context, it forms an isolated complex with Cdc20, whereas in the second 
it is part of a larger complex of proteins (BubR1, Cdc20, Mad2, Bub3) called 
\Mitotic Checkpoint Complex", or MCC. We incorporated both contexts in two 
dierent models, and found that Cdc20 can be fully sequestered by BubR1 neither 
in the rst nor in the second context. Moreover, it has been postulated that MCC 
formation can be either Kinetochore-independent (KIM) or Kinetochore-dependent 
(KDM) ( Musacchio and Salmon, 2007; for details, see Chapter 4). We found that 
only the Kinetochore-dependent model can -partially-account for the availability 
of Cdc20 both before and after the attachment of all chromosomes. Next, we asked 
whether MCC might be able to fully prevent APC:Cdc20 formation by binding 
APC, thereby sequestering it fully, prior to the attachment of all chromosomes. To 
tackle this question, we built-up an in-silico model that combines the Template 
model, the MCC-Kinetochore-dependent formation model, and empirical data 
on APC levels prior to chromosome attachment. Our results show that MCC 
can fully sequester APC prior to chromosome attachment, thereby preventing 

7



1. ORIENTATION, MOTIVATION AND AIM OF THE STUDY
APC:Cdc20 activity. If this was the case in nature, one would also need to ask 
how such a complex as the MCC:APC complex would fall apart after chromosome 
attachment. Hence, we built-up two equally suitable model variants addressing 
this issue, called \Dissociation” and the \Convey” models, and validated them by 
means of mutation experiments (see Chapter 5). Moreover, we also developed a 
qualitative model of MSAC , and tested its robustness (see Chapter 6). Finally, 
we incorporated an adapted EFM model that involves the activity of APC:Cdh1 
into an integrative model that also involves the activity of APC:Ccd20. Hence, we 
addressed simultaneously the functioning of both transition control mechanisms, 
MSAC and EFM. This integrative model is presented in Chapter 7. 

Important questions still remain open. For example, how the checkpoint remains 
active until all kinetochores are attached? Answering this kind of questions, 
however, demands understanding how the mitosis transition control mechanisms 
work in three dimensions. For such an understanding to be achieved, new tools 
are needed. Therefore, we are currently developing a software tool called \Mitosis 
Arena", in order to test network models of mitosis within a 3-D framework. 
\Mitosis Arena” will be available to the scientic community, so that alternative 
models could easily be studied within a dynamical 3-D environment (Figure 1.1). 
It has been designed in accordance with standard languages (i.e., SBML), and 

would eventually be combined with other Systems Biology software tools. 

8



1.3 This thesis is based on the following publications
1.3 This thesis is based on the following publications 
Peer-reviewed articles in international journals 

. Ibrahim, B., Dittrich, P., Diekmann, S., Schmitt, E. Mad2 binding is not 
sucient for complete Cdc20 sequestering (an in-silico study). BioPhy Chem. 
Journal, 134, 93-100., 2008. 
. Ibrahim, B., Schmitt, E., Dittrich, D., Diekmann, D. In-silico study of 
kinetochore control, amplication, and inhibition eects in MCC assembly. 
BioSystems Journal, 2008. (In press) 
. Ibrahim, B., Diekmann, S., Schmitt, E., Dittrich, P. In-silico Modeling of the 
Mitotic Spindle Assembly Checkpoint. PLoS ONE Journal, 3(2): e1555, 2008. 
. Ibrahim, B, Dittrich, P., Diekmann, S., Schmitt, E. Stochastic eects in a 
compartmental model for mitotic checkpoint regulation. Journal of Integrative 
Bioinformatics, 4(3):66, 2007. 
Peer-reviewed articles in proceedings 

. Rohn, H., Ibrahim, B., Lenser, T., Hinze, T., Dittrich., Enhancing Parameter 
Estimation of Biochemical Networks by Exponentially Scaled Search Steps. 
In: E. Marchiori and J. H. Moore (Eds.), Proceedings of the Sixth European 
Conference on Evolutionary Computation, Machine Learning and Data Mining 
in Bioinformatics (EvoBIO), Napoli, LNCS 4973, pp. 177-187, Springer Verlag, 
2008. 
. Lenser, T., Hinze, T., Ibrahim, B., Dittrich, P., Towards evolutionary network 
reconstruction tools for systems biology. In: E. Marchiori, J.H. Moore, J.C. Rajapakse (Eds.), Proceedings of the Fifth European Conference on Evolutionary 
Computation, Machine Learning and Data Mining in Bioinformatics (EvoBIO), 
Valencia, LNCS 4447, pp 132-142, Springer Verlag, 2007. 
9



1. ORIENTATION, MOTIVATION AND AIM OF THE STUDY
10



\It is the weight, not numbers of experiments that is 
to be regarded". Isaac Newton (1642-1727) 

\Biology will tell you a lot of things, but there are 

many that it can not explain and you need to look at 

physics instead". Walter Gilbert(1932-) 

Chapter 2 
Mitosis Transition Controls 

Contents 

2.1 CellDivision ........................ 12


2.2 Mitosis............................ 14


2.3 Checkpoints in Cell Cycle Regulation . . . . . . . . . 19 

2.4 AnaphaseInitiationControl ............... 21


2.4.1 The Mitotic Spindle Assembly Checkpoint (MSAC) .. 21 

2.4.2 Experimental Studies on the MSAC .......... 23


2.4.3 Recent Models of the MSAC .............. 42


2.5 MitoticExitcontrol .................... 43


2.5.1 Exit From Mitosis (EFM) Mechanism . . . . . . . . . 43 

2.5.2 Analysis of the Recent Experimental Studies of the EFM 43 

2.5.3 RecentModelsoftheEFM ............... 46


2.6 ConcludingRemarks ................... 47


11



2. MITOSIS TRANSITION CONTROLS
2.1 Cell Division 
Cell1 division is accomplished by means of two dierent processes in eukaryotes: 
mitosis2 and meiosis3 . During mitosis, a somatic cell (and also eukaryotic unicellular organisms) divides to produce two genetically identical cells. In contrast, 
during meiosis, a sex cell undergoes two stages of cell division resulting in four 
haploid cells (gametes) each of which has only a single complement of chromosomes. 
In this thesis we will focus on transition control mechanisms of mitosis. 

In an elaborate series of events known as \cell cycle", chromosomes4;5 are replicated 
and then, together with other components, distributed into the two daughter cells. 
The cell cycle is composed of ve distinct phases: G1 (Gap 1), S (Synthesis)-phase, 
G2 (Gap 2) (which are collectively called interphase), Mitosis and Cytokinesis 
(which are collectively called M-phase) (see Figure 2.1). During interphase, the 
rate of biosynthetic activity is high. During G1 various proteins are synthesised 
that are required in S-phase, for example those needed for DNA replication. G1's 
duration is highly variable; in humans it can take between 6-12 h. Most cells in 
G1 become committed to either continued division or exit from the cell cycle. A 
cell may pause for an extended period in G1 or may even enter in a non-dividing 
state called G0. In S-phase the DNA is replicated so that at the end of this 
phase the genome is duplicated from 2n to 4n. In human's cells, the S-phase lasts 
6-8 h. The cell then enters into G2. Now proteins are synthesised which are for 
example involved in the production of microtubules required during mitosis. In 
humans G2 lasts 3-4h. Finally, after G2, the cell enters into M-phase, during 
which chromosomes are segregated into the two daughter cells. This process last 

1Robert Hooke (1635 1703), an English polymath, was the rst person to coined the 
term \cell” to describe the basic unit of life, after viewing slices of cork through a microscope in 
about 1663. 

2Mitosis has been rst identied by the anatomist Walther Flemming (1882). 

3Meiosis has been rst identied by the German embryologist Oscar Hertwig (1875). 

4Chromosomes are organized structures of DNA and proteins. A chromosome contains 
a single continuous piece of DNA, which contains many genes, regulatory elements and other 
nucleotide sequences. Chromosomes also contain DNA-bound proteins, which serve to package 
the DNA and control its functions. 

5Karl Wilhelm von Ngeli (1817 1891), a Swiss botanist, he discovered what would later 
become known as chromosomes. 

12 


2.1 Cell Division
Figure 2.1: Cell cycle phases in eukaryotic cells. Interphase consisting of G1, S, 
and G2 -phases, is followed by M-phase, consists of mitosis (or could be meiosis) 
and cytokinesis. G0 refers to a pause period or an extended periods in G1 or 
even inter nondividing state. The time course is an example for the human cell 
cycle. G1, occurs before S-phase, whereas G2 occurs before M-phase. The DNA 
is 2n in both G0 and G1, and 4n in both G2 and M -phases. n is the number of 
DNA strands The gure also depict cell cycle checkpoints. In interphase, G1/S 
is the rst checkpoint, followed by G2/M. In M-phase, the mitosis checkpoint “ 
metaphase-to-anaphase transition checkpoint". 

approximately 1 h in human cells. Chromosome segregation of newly replicated 
sister chromatids1 into daughter cells is a critical and central event. It ensures 
that both of the newly divided cells receive a full complement of chromosomes. If 
this event is not properly completed, the newly divided cells will probably lack 
essential genes resulting in cellular malfunction. 

From a technical point of view, cells behave like an oscillator. In mitosis, two new 
daughter cells are created from the mother cell. In G1, these daughter cells grow 
until they reach a mass which allows them to enter a new round of duplication. 
This new round begins with entry into the S-phase. Once genome duplication is 

1Sister chromatids are identical copies of a chromosome. In other words, sister chromatids 
contain the same genes 

13 


2. MITOSIS TRANSITION CONTROLS
completed, the cell prepares for division in G2. In mitosis, when a checkpoint has 
checked the correct state of the cell, the cell nally dives and creates new daughter 
cells. During this oscillation, the cell runs through kinetically very dierent states: 
static or semi-static, dynamic, intermediate and steady-states. When modeling 
the mitotic transition control, all input and output signals across these cell cycle 
phases must be incorporated as precisely as possible (see Appendix A). In doing 
this, the work can benet from a deterministic and stochastic modeling base for 
biochemical reaction networks. 

This work focuses on the mechanisms controlling human mitosis. The goal is to 
understand how chromosomes segregation is controlled by the mitotic checkpoint. 
Since the proteins carrying out these mechanisms were already identied in 
experimental laboratories, this work intends to tackle how these proteins interact 
with each other and which are the rules for their combined function. Ultimately, 
we intend to simulate empirical knowledge and formulate straight forward, useful 
predictions to be experimentally tested in the future. The goal is to determine 
the essential features of mitotic control of the meta-to anaphase transition. 

2.2 Mitosis 
The German anatomist Walther Flemming1(1882), a pioneer of mitosis research, 
was one of the rst scientists to give a detailed description of the numerous events 
during cell division in animals and named the division of somatic cells \mitosis". 
He originally minted the term \mitosis” from the Greek word for thread, re
ecting 
the shape of mitotic chromosomes. Mitosis is the most dramatic period of the cell 
cycle, involving a major reorganization of virtually all cell components. Although 
many of the details of mitosis vary among dierent organisms, the fundamental 
processes that ensure the faithful segregation of sister chromatids are conserved 
in all eukaryotes. These basic events of mitosis include chromosome condensation, 

1Walther Flemming: (1843-1905) a founder of the science of cytogenetics (the study of 
the cell's hereditary material, the chromosomes). He was the rst to observe and describe 
systematically the behaviour of chromosomes in the cell nucleus during normal cell division 
(mitosis). 

14 


2.2 Mitosis
formation of the mitotic spindle, and attachment of chromosomes to the spindle 
microtubules1 . Sister chromatids then separate from each other and move to 
opposite poles of the spindle, followed by the formation of daughter nuclei (see 
Figure 2.3). 

Mitosis is simply described as having four stages: prophase, metaphase, anaphase, 2 
and telophase3; these stages follow one to another as a continuous process without 
interruption. The entire four-stage division process in human cells lasts about one 
hour in average. 

Prophase During prophase the chromosomes become condensed and key proteins 
bind the kinetochores4 preparing for spindle5 attachment. Centrioles6 begin 
moving to opposite ends of the cell and bers extend from the centrosomes. The 
nuclear membrane dissolves. Proteins link the multi-protein kinetochore complex 
at the centromeres with the microtubules and the chromosomes move to the 
equatorial plate. Sometimes, this stage is classied in two sub-stages, Prophase 
and late Prophase or Prometaphase (see Figure 2.3). 

1Microtubule: Eukaryotic cells rely on self assembling array of microtubules (MTs) known 
as the spindle to eect chromosome segregation. MTs emanate from microtubule organizing 
centers (MTOCs) and form attachments with the cell cortex and with anti-parallel MTs from 
the opposite pole. Moreover, MTs attach to the chromosomes by binding to the kinetochore. A 
microtubule is a polymer of globular tubulin subunits, which are arranged in a cylindrical tube 
measuring about 25 nm in diameter (see Figure 2.2) 

2Prophase, metaphase and anaphase were rst coined by Eduard Strasburger in 1884. 

3Telophase was rst introduced by Martin Heidenhain in 1894 

4The kinetochore is a large A multiprotein structure, positioned at the central constriction 
of each chromosome, contains two regions: an inner kinetochore, which is tightly associated 
with the centromere DNA; and an outer kinetochore, which interacts with microtubules (see 
Figures 2.2 and 2.8). Kinetochores consist of more than 45 dierent proteins. Many of these 
proteins are conserved throughout eukaryote species (see Figure 2.8). 
The centromere is a single site on the chromosome that is responsible for assembling the kineto
chore, which mediates chromosome attachment to the microtubule spindle and all chromosome 
movements. 

5Spindle is a network of protein bers that forms in the cytoplasm of a cell during cell 
division. The spindle grows forth from the centrosomes and attaches to the chromosomes after 
the latter have been replicated, and the nuclear membrane dissolves. Once attached, the spindle 
bers contract, pulling the replicate chromosomes apart to opposite poles of the dividing cell. It 
often referred to as the mitotic spindle during mitosis and the meiotic spindle during meiosis. 

6Centrioles are cylindrical structures, found in eukaryotic, that are composed of groupings 
of microtubules arranged in pattern. They help to organize the assembly of microtubules during 
cell division. 

15 


2. MITOSIS TRANSITION CONTROLS
Figure 2.2: Organization of the kinetochore. A complex structure that species 
the attachments between the chromosomes and microtubules of the spindle and 
is thus essential for accurate chromosome segregation. The left hand side refers 
to the sister chromatids. The right hand side refers to the kinetochore structure. 
The eukaryotic kinetochore consists of an inner, gap, and outer regions. The blue 
stained material are the microtubules that form the mitotic spindle. The Navajo 
White color refers to the centromere 

16



2.2 Mitosis
Figure 2.3: Depiction of the distinct stages of mitosis. Interphase is divided 
into G1-, S-and G2-phase, followed by M-phase, which is divided into mitosis 
and cytokinesis. Mitosis is simply described as having four stages: prophase, 
metaphase, anaphase, and telophase; the stages follow one another as a continuous 
process without interruption or pause. 

Metaphase In this stage, chromosomes are attached to microtubule spindles via 
their kinetochores followed by alignment on the metaphase plate half way between 
the two spindle poles. This state is controlled by the mitotic checkpoint. Once all 
the chromosomes are aligned, mitosis can progress into the next stage. 

Anaphase The paired chromosomes separate at the kinetochores and move to 
opposite sides of the cell. Motion results from a combination of kinetochore 
movement along the spindle microtubules and through the physical interaction of 
polar microtubules. 

Telophase After successful segregation of the chromosomes, chromatids arrive 
at opposite poles of the cell and new membranes are formed around the daughter 
nuclei. The chromosomes disperse and are no longer visible under the light 
microscope. The spindle bers disperse and partitioning of the cell begins. 

17



2. MITOSIS TRANSITION CONTROLS
Cytokinesis It is the nal phase, the cell cytoplasm of the mother cell is physically 
divided in two daughter cells. Cytokinesis was one of the rst cell cycle events 
observed by cell biological techniques (see Figure 2.3). 

Two essential transition control mechanisms, namely, `initiation of anaphase” and 
\exit from mitosis", govern mitosis. In the following sections, these mechanisms 

are described. 

18



2.3 Checkpoints in Cell Cycle Regulation
2.3 Checkpoints in Cell Cycle Regulation 
Checkpoints are surveillance control mechanisms that monitor the progression of 
the cell cycle, so that in the case of malfunction the cell cycle can be arrested 
at a given stage by specic signals. The central components of the cell cycle 
control system are a family of enzymes called cyclin-dependent kinases (Cdks). 
Like others protein kinases, Cdks catalyze the covalent attachment of phosphate 
groups derived from ATP to protein substrates. This phosphorylation results 
in changes in the substrate's enzymatic activity or its interaction with other 
element species. A cyclin-dependent kinase is activated by association with a 
cyclin forming a cyclin-dependent kinase complex. Dierent types of cyclins are 
produced at dierent cell cycle phases. Cyclins and CDKs determine a cell's 
progress through the cell cycle (see Table 2.1). Malfunctions of any control during 
cell division might lead to serous diseases (see section 2.4.2). In order to avoid 
any failure, the cell veries that proper conditions are satised at crucial steps in 
the division process. In general, cell cycle progression is governed by three major 
checkpoints (Figure 2.1). 

. The rst checkpoint control occurs in G1-phase, and is called the G1/S 
checkpoint. It checks the cell size, nutritional, status DNA/cellular damage 
mating status and growth factor availability. In case of damage during G1, it 
will delay the onset of S-phase and DNA replication. 
. The second checkpoint control occurs in G2-phase, and is called the G2/M 
checkpoint. It monitors the completion of DNA replication and assures 
accurate transmission of genetic material and the completion of mitosis. 
. The third checkpoint is the metaphase-to-anaphase transition control (mitotic, 
or chromosome segregation, or division control) named the Mitotic Spindle 
Assembly Checkpoint (MSAC)(in order to dierentiate it from the Meiosis 
checkpoint). The MSAC functions to ensure faithful chromosome segregation 
by delaying cell division until all chromosomes are correctly oriented on the 
mitotic spindle. It is an important element of mitosis transition control and 
thus, is a main focus of this thesis. 
19 


2. MITOSIS TRANSITION CONTROLS
The Major Cyclins and Cdks


Homo sapiens Saccharomyces cerevisiae 
Cyclin:Cdk Cyclin Cdk partner Cyclin Cdk partner 
complex 
G1-Cdk Cyclin D* Cdk4, Cdk6 Cln3 Cdk1* 
G1/S-Cdk Cyclin E Cdk2 Cln1, 2 Cdk1 
S-Cdk Cyclin A Cdk2 Clb5, 6 Cdk1 
M-Cdk Cyclin B Cdk1* Clb1, 2, 3,4 Cdk1 

Table 2.1: The major cyclins and Cdks for progression through the cell cycle in 
Homo sapiens and Budding Yeast. There are three D cyclins in mammals (cyclins 
D1, D2, and D3), The original name of Cdk1 was Cdc2 in both Homo sapiens 
and ssion yeast, and Cdc28 in budding yeast. For S. pombe, the major cyclins 
are; Puc1, Cig2, Cdc13, and Puc1 for G1/S, S, M, and G1 -phases respectively. 
This table has been taken and modied from (Alberts et al., 2002). The bold line 
denotes mitosis cyclin, which is of our interest. 

The following focusses on the human MSAC mechanism. 

20



2.4 Anaphase Initiation Control
2.4 Anaphase Initiation Control 
2.4.1 The Mitotic Spindle Assembly Checkpoint (MSAC) 
Chromosomes segregation of newly replicated sister chromatids into daughter 
cells during anaphase is a critical event of mitosis. MSAC ensures the correct 
segregation of chromosomes by restraining cell cycle progression from entering 
anaphase until all chromosomes have made proper bipolar attachments to the 
mitotic spindle and are aligned at the metaphase plate (for review see Musacchio and Salmon, 2007). Incorrect chromosome segregation may lead to cell 
death (Weaver and Cleveland, 2005; Heald, 2006) and aging (Baker et al., 2004), 
may also generate aneuploidy (Kim and Kao, 2005; Steuerwald, 2005; Mondal 
and Roychoudhury, 2003). Since deviation from euploidy is seen in 70-80% of 
all types of human cancers, errors in DNA segregation might facilitate tumorigenesis (Iwanaga et al., 2002; Kops et al., 2005b; Michel et al., 2004; Sotillo 
et al., 2007) and possibly contribute to cancer (Compton, 2006; Gupta et al., 
2003; Mondal et al., 2007a) Thus, the MSAC mechanism guards the delity of 
chromosome segregation. Figure 2.4 illustrates how the MSAC mechanism seems 
to works. In early metaphase, those chromosomes not attached to the spindle, 
generate a signal that inhibits the transition from metaphase to anaphase. Once 
all kinetochores achieve bipolar attachment to the spindle's microtubules (in 
late metaphase) the MSAC is switched off and anaphase ensues. The Anaphase 
Promoting Complex (APC) is the target of the MSAC. It becomes active only 
after the attachment of the last kinetochore. Cdc20 is the co-activator of APC at 
the metaphase to anaphase transition. APC:Cdc20 mediated ubiquitination leads 
to activation of the separase, which cleaves the cohesins that maintain the linkage 
between sister chromatids (Peters, 2002), leading to sister chromatid separation 
and anaphase onset. Ubiquitination and degradation of cyclin B inactivates Cdk1, 
thereby permitting exit from mitosis (Nasmyth, 1993; Taylor, 1999). 

21



2. MITOSIS TRANSITION CONTROLS
Figure 2.4: The MSAC , is the major cell cycle control mechanism in mitosis. 
It delays the transition from metaphase to anaphase until all chromosomes are 
correctly aligned at the metaphase spindle equator. In early metaphase, the chromosomes are not attached to the spindle of microtubules, while in late metaphase 
most chromosomes are attached. Once all kinetochores are attached, anaphase 
initiation is rapid. The subscript n denotes the number of chromosomes (e.g. 
n = 46 for human) 

22



2.4 Anaphase Initiation Control
2.4.2 Experimental Studies on the MSAC 
MSAC is a complex mechanism the elucidation of which is of high importance for 
cell biology and medical research. The following section summarizes recent progress 
toward the understanding of the functions of the MSAC , as well as the mechanisms 
by which it activates the APC/C, and its regulation by phosphorylation and by 
association with its binding proteins. 

Core Components of the MSAC 

The core proteins involved in MSAC (Minshull et al., 1994) include MAD (\Mitotic 
Arrest Decient"; Mad1, Mad2, and Mad3 (in humans: BubR1)) (Li and Murray, 1991) and BUB (\Budding Uninhibited by Benzimidazole"; Bub1, and 
Bub3) (Hoyt et al., 1991), all of which are conserved among eukaryotes. A detailed 
list of the characteristics and proposed functions of the MSAC core proteins in 
dierent organisms is shown in Table 2.2. 

23



24


Structural 
domain 
and 
Functions 
of 
the 
Core 
MSAC 
Species 

S.c
. 
S.p
. 
H
. 
sapien
s 
Structural
Featur
e 
Function
s 
i
n 
M 
SA
C 
Reference
s 
Mad
1 
Mad
1 
Mad
1 
~ 
71
8 
residue
. 
coiled-coi
l 
Bin
d 
t
o 
Mad
2 
an
d 
recruit
s 
i
t 
t
o 
unattache
d 
kinetochor
e 
Phosphorylate
d 
b
y 
Mps
1 
an
d 
Bub
1 
i
n 
vitr
o 
Essentia
l 
fo
r 
generatio
n 
th
e 
Cdc20:Mad
2 
comple
x 
(Hardwic
k 
an
d 
Murray
, 
1995;
Che
n 
e
t 
al.
, 
1998
, 
1999a
; 
Chun
an
Chen
2002;
Hardwic
k 
an
d 
Murray
, 
1995;
Hardwic
k 
e
t 
al.
, 
1996
; 
Siron
e
al.
2002
2001b;
Brad
y 
an
d 
Hardwick
, 
2000;
Millban
d 
an
d 
Hardwick
, 
2002;
Mad
2 
Mad
2 
Mad
2 
~ 
20
5 
residue
. 
Horm
a 
domai
n 
Bind
s 
Cdc2
0 
an
d 
inhibit
s 
APC:Cdc2
0 
activit
y 
Bind
s 
t
o 
Mad
1 
(Che
n 
e
t 
al.
, 
1998
, 
1999a
; 
Yu
2006;
Sudaki
n 
e
t 
al.
, 
2001
; 
L
i 
e
t 
al.
1997b;
Podda
r 
e
t 
al.
, 
2005
; 
Zhan
g 
an
Lees
2001a;
Fang
, 
2002
; 
Aravin
d 
an
d 
Koonin
1998).
Mad
3 
Mad
3 
BubR
1 
~ 
105
2 
residue
. GLEB
S 
moti
f 
Serine/
threonin
e 
kinas
e 
Bin
d 
t
o 
Bub
3 
constitutively
. 
Bind
s 
t
o 
CENP-
E 
Bind
s 
Cdc2
0 
yeast Mad
3 
lack
s 
th
e 
kinase domai
n 
(Bharadwa
j 
an
d 
Yu
, 
2004;
Ma
o 
e
t 
al.
, 
2003
, 
2005
; 
Che
e
al.
1998
1999a;
Davenpor
t 
e
t 
al.
, 
2006;
Wan
g 
e
t 
al.
, 
2001
; 
Fraschin
e
al.
2001;
Millban
d 
an
d 
Hardwick
, 
2002).
Bub
1 
Bub
1 
Bub
1 
~ 
108
0 
residue
. 
GLEB
S 
moti
f 
Serine/
threonin
e 
kinas
e 
Phosphorylat
e 
Mad
1 
i
n 
vitr
o 
Require
s 
fo
r 
localizatio
n 
o
f 
Bub
3 
an
d 
BubR
1 
(Musacchi
o 
an
d 
Hardwick
, 
2002
Abrie
e
al.
2001;
Yamaguch
i 
e
t 
al.
, 
2003
; 
Stuck
e
al.
2002;
Gillet
t 
e
t 
al.
, 
2004
; 
Wan
g 
e
t 
al.
2001;
Brad
y 
an
d 
Hardwick
, 
2000
; 
Palframa
e
al.
2006;
Taylo
r 
e
t 
al.
, 
2001
; 
Che
n 
e
t 
al.
1999a;
Hardwic
k 
e
t 
al.
, 
1996).
Bub
3 
Bub
3 
Bub
3 
~ 
32
7 
residue
. 
Seve
n 
WD4
0 
repeat
s 
Bind
s 
t
o 
BubR
1 
(Taylo
r 
e
t 
al.
, 
2004
; 
Wan
g 
e
al.
2001;
Sharp-Bake
r 
an
d 
Chen
, 
2001;
Sudakin e
t 
al.
, 
2001)
. 

Table 
2.2: 
M 
SA
C 
Cor
e 
components
: 
Domai
n 
structure
s 
an
d 
function
s 
i
n 
dieren
t 
eukaryoti
c 
organism
s 
(S.c.
, 
Saccharomyce
cerevisiae
S.p.
, 
Schizosaccharomyce
s 
pombe
; 
an
d 
H
. 
sapiens
, 
Hom
o 
sapiens)
, 
(reviewe
d 
i
n 
Zho
u 
e
t 
al
. 
(2003)
; 
Cha
n 
an
d 
Ye
(2003)
Hoy
(2001))



2.4 Anaphase Initiation Control
Cdc20 

The molecular understanding of the cell cycle began when Lee Hartwell and 
coworkers isolated Cell Division Cycle 20 homolog (Cdc20) mutants of S. cerevisiae 
that, despite continued cell growth, failed to execute or complete key cell-cycle 
events, such as DNA replication or mitosis (Hartwell et al., 1970). 

Among the original Hartwell mutant collection were the Cdc20 mutants that 
arrest cell division in mitosis and fail to initiate anaphase and chromosome 
segregation (Hartwell et al., 1973). Cdc20 is a highly conserved WD40-repeat 
protein (Prinz et al., 1998; P
eger and Kirschner, 2000a). Orthologs of Cdc20 
were then discovered in various organisms (see Tables 2.3), including mammals 
and Drosophila (Weinstein et al., 1994; Dawson et al., 1995). In Drosophila, the 
Cdc20 ortholog, Fizzy, was shown to be required for the degradation of mitotic 
cyclins A and B (Dawson et al., 1995). However, the biochemical functions of 
Cdc20 remained obscure until the discovery of the Anaphase Promoting Complex/Cyclosome (King et al., 1995; Sudakin et al., 1995). (for review see Yu, 2007). 
Two main species, Mad2 and BubR1, can bind and sequester Cdc20. 

APC 

The downstream target of the MSAC is the Anaphase Promoting Complex/ 
Cyclosome (APC/C or APC; an E3 ubiquitin ligase). APC is a multisubunit 
enzyme conserved from yeasts to humans, which is rst identied independently 
by King et al. (1995) and Sudakin et al. (1995). The APC is composed of at least 
thirteen dierent subunits (see Table 2.3) which form two sub-complexes joined 
by the Apc1 subunit (see Figure 2.5). They remain tightly associated throughout 
the cell cycle. 

APC activity is also strictly dependent on one of several co-activator proteins (see 
Table 2.3) that associate with APC during specic periods of the cell cycle. The 
best studied of these are Cdc20 and Cdh1, which are encoded by all known 
eukaryotic genomes. Additional meiosis-specic APC co-activators have been 
identied in yeasts and Drosophila. 

25 


2. MITOSIS TRANSITION CONTROLS
Figure 2.5: The APC subunits, The APC is composed of two sub-complexes joined 
by Apc1. This gure has been re-drown and modied from Peters (2006). 

APC activity at metaphase-to-anaphase transition depends on the co-activator 
Cdc20. At the exit from mitosis, its activity depends on the co-activator Cdh1. 
Note that all APC co-activators contain a C-terminal WD40 domain1 that is 
predicted to fold into a propeller-like structure, and that is now believed to 
recognize APC substrates by interacting with specic recognition elements in 
these substrates, called D2-(Glotzer et al., 1991), and KEN3-boxes (P
eger and 
Kirschner, 2000b). Both Cdc20 and Cdh1 can recognize APC substrates that 
contain the D-box, but Cdh1 can also interact with a second motif, the KEN-box, 
thereby broadening the substrate specicity of the APC (Buschhorn and Peters, 
2006; P
eger et al., 2001; Eytan et al., 2006; Yamano et al., 2004; P
eger and 
Kirschner, 2000a; Burton and Solomon, 2007; Chang et al., 2004). 

The APC becomes active as APC:Cdc20 at the onset of anaphase just after 
MSAC is silenced. The APC:Cdc20 has two main functions: 

. First, it catalyzes the ubiquitination of Securin which binds and inhibits the 
protease Separase (May and Hardwick, 2006). Subsequently, the Separase 
cleaves the cohesin subunit Scc1, which breaks the Cohesin ring (species details 
1WD40 domain: A propeller-shaped protein domain that is composed of sequence repeats 
that are 40-amino-acid residues long and contain tryptophan (W) and aspartate (D) residues 
in conserved positions. In most cases, seven WD40 repeats fold into a seven-bladed propeller 
structure. 

2Destruction-box: A sequence element (consensus RXXLXXXN) that was rst discovered 
in the N terminus of mitotic cyclins that is required for their destruction. D-boxes can be 
recognized by APC:Cdc20 and by APC:Cdh1f. Where x is any amino acid 

3KEN-boxes: A sequence element (consensus KEN) that is present in many APC substrates. 
KEN-boxes are preferentially, but not exclusively, recognized by APC:Cdh1. 

26 


2.4 Anaphase Initiation Control
are summarized in Table 2.3 and Table 2.4). 

. Second, APC:Cdc20 is responsible for the rst phase of Cyclin B proteolysis 
that occurs when cellular levels of the Cyclin B are high. Then the activated 
APC:Cdh1 mediates the second phase of Cyclin B destruction and triggers 
mitotic exit (Tan et al., 2005; Yeong et al., 2000). 
27



28


APC 
subunits 
and 
co-activators 
in 
diff 
erent 
organisms


S.c
. 
Mass
(kDa
) 
D.m
. 
H
. 
sapien
s 
C.e
. 
S.p
. 
A.n
. 
Structural
Featur
Function
Cor
e 
subunits
Apc
1 
Apc
2 
Cdc27/Apc
3 
Apc
4 
Apc
5 
Cdc16/Apc
6 
-
Cdc23/Apc
8 
Apc
9 
Doc1/Apc1
0 
Apc1
1 
Cdc26
Apc13/Swm
1 
Mnd
2 
196
96
85
73
77
94
-
70
30
26
19
14
19
4
3 
CG9198/
Shattered
CG3060/
Morula
cdc27/Mako
s 
CG4350
CG10850/lda
cdc16
-
CG2508
-
CG11419
Lmg
(Lemming)
-
-
-
Apc1/Tsg2
4 
Apc
2 
Cdc27/Apc
3 
Apc
4 
Apc
5 
Cdc16/Apc
6 
Apc
7 
Cdc23/Apc
8 
-
DOC1/Apc1
0 
Apc1
1 
Cdc26
Swm1/Apc1
3 
-
Mat-2
K06H7.6
Mat-1
Emb-3
0 
M163.4
Emb-2
7 
-
Mat-3
-
F15H10.3
F35G12.9
-
-
-
Cut4
SPBP23A10.04
Nuc2
Cut20/Lid1
Apc5,spac959,09
C 
Cut9
-
Cdc23/Apc
8 
-
Apc1
0 
Apc11
, 
SPAC343.0
3 
Hcn1
-
-
Bime
-
Bima
-
-
Bimh
-
-
-
-
-
-
-
-
Rpn1/2
homology
Cullin
homology
TPRs
WD4
0 
repeat
TPRs
TPRs
TPRs
TPRs
-
Do
c 
domai
Ring-H2nge
-
-
-
-
-
binding
Apc1
Doc1
Cdh
bindin
-
-
-
-
-
-
Substrate
recognition
E
recruitment
E
activit
-
-
Ama
inhibition
Co-activators
Cdc20
Cdh1/Hct1
Ama
1 
68
64
6
6 
Fizzy
Fizzy-related
-
Cdc20/
P 
5
5 
CD
C 
Cdh
1 
A,B,C,
D 
-
-
FZR-1
-
Slp1
Srw1/Ste9
Mfr
1 
-
-
-
WD4
0 
repeat
WD4
0 
repeat
WD4
0 
repeat
Meta-to-anaphase
Mitosi
exi
Meiosi


Table 
2.3: 
APC
: 
Subunits
, 
Domai
n 
structure
s 
an
d 
function
s 
(se
e 
(Peters
, 
2006
, 
2002
; 
Passmore, 2004a
; 
Zacharia
e
al.
1998b
Dube
e
t 
al.
, 
2005
; 
Thornto
n 
e
t 
al.
, 
2006
; 
Harpe
r 
e
t 
al.
, 
2002
; 
Mello
y 
an
d 
Holloway
, 
2004
; 
yon
g 
Huan
g 
an
d 
Ra
, 
2002
; 
Kin
e
al.
1995
Sudakin
e
t 
al.
, 
1995
; 
Blo
w 
an
d 
Tanaka
, 
2005))
. 
S.c.
, 
Saccharomyce
s 
cerevisiae
; 
D.m.
, 
Drosophil
a 
melanogaster; H
. 
sapiens
Hom
sapiens
C.e.,
Caenorhabditi
s 
elegans
; 
S.p.
, 
Schizosaccharomyce
s 
pombe
; 
an
d 
A.n.
, 
Aspergillu
s 
nidulans)
. 


29


APC 
targets 
in 
dierent 
organisms


S.c. 
S.p. 
H. 
sapiens 
Functions 
Feature 
References 
Pds1 
Cut2 
Securin/ 
PTTG 
Binds 
and 
inhibits 
separase. 
M 
SAC 
activation 
prevents 
its 
ubiquitination 
by 
APC:Cdc20.
(Yu, 
2002; 
Peters, 
2002;
May 
and 
Hardwick, 
2006; 
Luo 
et 
al.
2000a;
Fang, 
2002; 
Palframan 
et 
al.
2006).
Esp1 
Cut1 
Separase 
Degradation 
of 
securin 
releases 
separase 
to 
cleave 
cohesin 
and 
allow 
chromosomes 
to 
segregate. 
(Uhlmann 
et 
al.
, 
1999;
May 
and 
Hardwick, 
2006; 
Yu, 
2002;
Yanagida, 
2000)
. 
Clb2 
Cdc13 
Cyclin 
B 
M 
SAC 
prevents mitotic 
exit 
by 
inhibitin 
APC-mediated 
ubiquitination 
of 
cyclin 
B.
(Hagan 
et 
al.
, 
1988;
Nasmyth, 
1993; 
Taylor, 
1999).

Table 
2.4: 
APC: 
Subunits, 
Domain 
structures 
and 
functions. 
S.c.
, 
Saccharomyces 
cerevisiae; 
S.p.
, 
Schizosaccharomycespombe; 
and 
H. 
sapiens, 
Homo 
sapiens 


2. MITOSIS TRANSITION CONTROLS
Mad2 Function in Sequestering Cdc20 

Mad1 forms a tight 2:2 complex with Mad2 (Sironi et al., 2001b, 2002). The binding 
of Mad2 to Mad1 triggers a conformational change of Mad2, in a similar way as 
does Cdc20 binding. Mad2 binds to Mad1 and Cdc20 in the same pocket with 
similar anities (Luo et al., 2002; Yu, 2006). Mad2 can adopt two conformations: 
O-Mad2 and C-Mad2 (for \Open” and \Closed” respectively), which dier in 
the structure of its 50 residue C-terminal segment (Luo et al., 2002; Luo and Yu, 
2005). The O-Mad2 is the physiological state of cytosolic Mad2 in the absence 
of Mad1 or Cdc20 (Luo et al., 2004; DeAntoni et al., 2005a). O-Mad2 refolds to 
C-Mad2 when bound to kinetochore receptor Mad1 or APC activator Cdc20 (Luo 
et al., 2002, 2000a). p31comet is a negative regulator of the spindle checkpoint. It 
prevents further Mad2 turnover on Mad1 and neutralizes the inhibitory activity 
of Cdc20-bound Mad2, leading to activation of the APC followed by degradation 
of Securin and Cyclin B (Habu et al., 2002; Xia et al., 2004; Mapelli et al., 2006). 

Recently, intensive studies led to an improved understanding of Mad2 -Cdc20 
binding. Accordingly, two alternative mechanistic models were proposed: the 
\Exchange” (Luo et al., 2004) and the \Template” model (DeAntoni et al., 2005a; reviewed by Lenart and Peters, 2006; Nasmyth, 2005; Hardwick, 2005; Hagan and 

Sorger, 2005). 

. In the Exchange model (see Figure 2.6), Mad1 recruits O-Mad2 at the kinetochore and transforms its conformation from O-Mad2 to C-Mad2. Then, C-Mad2 
dissociates from Mad1 and binds Cdc20. This model was criticized because it 
is unable to explain additional experimental data (DeAntoni et al., 2005a,b; 
Vink et al., 2006; Mapelli et al., 2006) and assumes that Mad1 competes with 
Cdc20 for Mad2 binding. 
. According to the alternative Mad2 Template model (see Figure 2.6), Mad1 and 
C-Mad2 form a stable 2:2 complex at unattached kinetochores (DeAntoni et al., 
2005a). This quadromer complex then, binds additional molecules of O-Mad2 
through formation of conformational heterodimers between the C-Mad2 subunit 
of the Mad1:C-Mad2 complex and O-Mad2. Upon Mad1:C-Mad2 binding, OMad2 adopts an intermediate conformation (O-Mad2*) that can quickly and 
30



2.4 Anaphase Initiation Control
Figure 2.6: Schematic drawing of the Mad2 Template and the Mad2 Exchange 
models. The Template model (upper part of the gure) assumes that Mad1 
and C-Mad2 form a stable core complex at unattached kinetochores. This core 
then binds additional molecules of O-Mad2 through formation of conformational 
heterodimers between the C-Mad2 subunit of the Mad1:C-Mad2 complex and 
O-Mad2. Cdc20 binding to this complex leads to the conversion of O-Mad2 to 
C-Mad2 resulting in the formation of Cdc20:C-Mad2, which in turn is assumed 
then to dissociate off Mad1:C-Mad2. Upon Mad1:C-Mad2 binding, O-Mad2 
adopts an intermediate conformation (O-Mad2*) that can quickly and eciently 
bind Cdc20 and switch to the C-conformation. The Exchange (lower part of the 
gure) assumes that Mad1 recruits open Mad2 (O-Mad2) at the kinetochore and 
transforms its conformation from O-Mad2 to closed Mad2 (C-Mad2). C-Mad2 
then dissociates from Mad1 and binds Cdc20. 

31



2. MITOSIS TRANSITION CONTROLS
eciently bind Cdc20 and switch to the C-conformation. The binding of Cdc20 
to this complex leads to the conversion of O-Mad2 to C-Mad2, resulting in the 
formation of C-Mad2:Cdc20 which then dissociates from Mad1:C-Mad2 (Fang, 
2002). The Template model describes Mad2:Cdc20 complexation, which is the 
seeding reaction of MCC (M itotic C heckpoint C omplex) formation. 

There are still open questions related to the role of Mad2 that are critical to 
understanding the MSAC mechanism. These questions will be discussed in the 
conclusion section of this chapter as well as in chapter 3. In the following section, 
MCC formation will be analyzed. 

MCC Formation 

The highly conserved proteins Mad2 and BubR1 are essential for Cdc20 binding. 
They form the Mitotic Checkpoint Complex (MCC). In HeLa1 cells, MCC contains 
Mad2, Bub3, BubR1 and Cdc20 in apparently equal stoichiometries (Sudakin 
et al., 2001). A similar complex was identied in budding (Hardwick et al., 2000) 
and ssion (Millband and Hardwick, 2002) yeasts and in Xenopus (Chung and 
Chen, 2003). 

Bub3 associates with BubR1 (Taylor et al., 1998a; Sudakin et al., 2001). This 
interaction is constitutive and is required for the localization of BubR1 to the kinetochores during mitosis. In prometaphase, CENP-E activates the kinase activity 
of BubR1 at unattached kinetochores. It is unclear whether BubR1 activation is 
required for MSAC function (Chen, 2002a; Mao et al., 2003). The kinase activity 
of BubR1 might not be required in the MCC, however, it might control other 
aspects of kinetochore signaling or chromosome alignment (Ditcheld et al., 2003; 
Lampson and Kapoor, 2005) (reviewed by Musacchio and Salmon, 2007). BubR1 
activity is switched off upon microtubule attachment (Mao et al., 2005; Braunstein 
et al., 2007). BubR1 cannot bind Mad2 directly (Fang, 2002). Moreover, BubR1 
does not form a ternary complex with Mad2 and Cdc20. Two Cdc20 binding sites 

1HeLa cell: cancerous cell belonging to a strain continuously cultured since its isolation in 
1951 from a patient suering from uterine cervical carcinoma. The designation HeLa is derived 
from the name of the patient (Henrietta Lacks (August 18, 1920 October 4, 1951)). HeLa cells 
have been widely used in laboratory studies. 

32 


2.4 Anaphase Initiation Control
were identied on BubR1 (Bolanos-Garcia et al., 2005; Davenport et al., 2006). 
Binding of the N-terminal region of BubR1 to Cdc20 requires prior binding of 
Mad2 to Cdc20 (Davenport et al., 2006). The other site (between residues 490 and 
560) can bind Cdc20 tightly regardless of Mad2 being bound to Cdc20 (Davenport 
et al., 2006). Thus, BubR1 can form a ternary complex with Bub3 and Cdc20 
which however has no inhibitory activity at the APC (unpublished data by Sudakin 
et al., 2001). In addition, in vivo inhibition of Cdc20 for mitotic function is a 
two-step process in which prior binding of Mad2 to Cdc20 is required to make 
Cdc20 sensitive for BubR1 binding (Davenport et al., 2006). 

Localization of all MSAC proteins at unattached kinetochores in mitosis provides a 
catalytic platform and contributes to MCC formation. The MCC is also detectable 
in normal metaphase-arrested cells in which the MSAC is inactive. This indicates 
that MCC formation does not require checkpoint activation (Poddar et al., 2005). 
Moreover, the MCC is also detectable in checkpoint defective cells (Poddar et al., 
2005; Fraschini et al., 2001). A detailed study (Meraldi et al., 2004) proposes 
that cytosolic Mad2-BubR1 is essential to restrain anaphase onset early in mitosis 
when kinetochores are still assembling. These arguments support the idea that the 
MCC (and its sub-complexes) might form in a kinetochore-independent manner (for 
review see Musacchio and Salmon, 2007). 

The MCC binds to and inhibits the APC and is believed to be essential for 
MSAC function (Musacchio and Salmon, 2007). However, MCC inhibits only 
the mitotic and not the interphase APC (Pinsky and Biggins, 2005). The 
interaction between APC and MCC is quite labile in the absence of unattached 
kinetochores (Sudakin et al., 2001). How the MCC inhibits APC activity is poorly 
understood (Musacchio and Salmon, 2007). The MCC might bind to the APC as a 
pseudo-substrate due to a KEN-box motif in BubR1. This indicates that the MCC 
needs to disassemble from the APC at metaphase to elicit anaphase (Morrow et al., 
2005; Fang, 2002). Bub1 and Aurora-B kinase contribute directly to the formation 
of a complex of the MCC with the APC (Morrow et al., 2005). Unattached 
kinetochores might sensitize the APC to inhibition by the MCC (Sudakin et al., 
2001; Chan et al., 2005; Doncic et al., 2005; Sear and Howard, 2006). 

33 


2. MITOSIS TRANSITION CONTROLS
In addition to kinetochore attachment, tension is important for MSAC inactivation 
(Nicklas et al., 1995; Nicklas, 1997). For example, if both sister kinetochores attach 
to microtubules from the same pole, not enough tension is generated and microtubule kinetochore attachment is destabilized to correct the problem (Musacchio 
and Salmon, 2007). This destabilization depends on Aurora-B kinase (Hauf et al., 
2003; Pinsky and Biggins, 2005; Tanaka et al., 2002; Lampson et al., 2004). For 

sub-complex details see Table2.5. 

34



35


MSAC 
Complexes

Complex
nam
e 
Complex
element
s 
Function
s 
Reference
s 
Mad1:C-Mad
2 
Mad1
, 
C-Mad
2 
conversio
n 
o
f 
O-Mad
2 
int
o 
close
d 
Mad
2 
boun
d 
t
o 
Cdc20
. 
(Siron
i 
e
t 
al.
, 
2001b
, 
2002;
DeAnton
i 
e
t 
al.
, 
2005a).
Cdc20:C-Mad
2 
Cdc20
, 
C-Mad
2 
Sequeste
r 
Cdc2
0 
an
d 
contribut
e 
t
o 
MC
C 
formatio
n 
(Lu
o 
e
t 
al.
, 
2002
; 
Yu
, 
2006;
DeAnton
i 
e
t 
al.
, 
2005a
; 
Lu
e
al.
2004).
Bub3:BubR
1 
Bub3
, 
BubR
1 
Contribute
s 
t
o 
MC
C 
formatio
n 
Sequeste
r 
Cdc2
0 
(Sudaki
n 
e
t 
al.
, 
2001
; 
Taylo
e
al.
1998a
2004;
Taylo
r 
e
t 
al.
, 
2004
; 
Davenpor
e
al.
2006).
Bub3:BubR1:Cdc2
0 
Bub3, BubR1
, 
Cdc2
0 
Partiall
y 
sequeste
r 
Cdc2
0 
(Sudaki
n 
e
t 
al.
, 
2001).
MC
C 
Cdc20, C-Mad2
, 
Bub3
, 
BubR1
, 
Bind
s 
an
d 
inhibit
s 
AP
C 
(Sudaki
n 
e
t 
al.
, 
2001
; 
Hardwic
e
al.
2000;
Millban
d 
an
d 
Hardwick
, 
2002
Chun
an
Chen
2003).
MCC:AP
C 
MCC
, 
AP
C 
Kee
p 
inhibitin
g 
o
f 
AP
C 
(Sudaki
n 
e
t 
al.
, 
2001
; 
Fan
e
al.
1998a;
Shanno
n 
e
t 
al.
, 
2002
; 
Tan
e
al.
2001;
Hardwic
k 
e
t 
al.
, 
2000
; 
Fraschin
e
al.
2001;
Podda
r 
e
t 
al.
, 
2005
; 
Acquaviv
e
al.
2004;
Morro
w 
e
t 
al.
, 
2005
; 
D'Angiolell
e
al.
2003).
RZ
Z 
Rod
, 
Zw10
, 
Zwilc
h 
Localize
d 
dyneindynacti
n 
complex
, 
an
d 
Mad1Mad2 complex
. 
(Karess
, 
2005
; 
Ma
y 
an
d 
Hardwick
2006;
Bu
n 
e
t 
al.
, 
2007
; 
Saer
e
al.
2000a;
Saer
y 
e
t 
al.
, 
2000b
; 
Cha
e
al.
2000;
William
s 
e
t 
al.
, 
2003
; 
Karess
2005;
Schole
y 
e
t 
al.
, 
2003
; 
Ra
ff 
e
al.
2002;
Kop
s 
e
t 
al.
, 
2005a
; 
Wan
g 
e
al.
2004a)
APC:Cdc2
0 
APC
, 
Cdc2
0 
Anaphas
e 
initiation
, 
cycli
n 
B 
rs
t 
phas
e 
destructio
n 
Mor
e 
detail
s 
i
n 
Table2.
4 
(Yu
, 
2002
; 
Peters
, 
2002;
Shirayam
a 
e
t 
al.
, 
1999
; 
Ta
e
al.
2005;
D'Amour
s 
an
d 
Amon
, 
2004).
APC:Cdh
1 
APC
, 
Cdh
1 
complet
e 
destructio
n 
o
f 
Cycli
n 
B
, 
inactivate
s 
APC:Cdc2
0 
(P
ege
r 
an
d 
Kirschner
, 
2000a
Prin
e
al.
1998).
(fo
r 
detail
s 
se
e 
Section.2.9)

Table 
2.5: 
M 
SA
C 
Complexe
s 


2. MITOSIS TRANSITION CONTROLS
Additional Components of the MSAC 

In addition to the four MCC proteins, the MSAC also involves several other 
proteins that also are involved in essential aspects of this mechanism. Among 
these additional components are Aurora-B and the \Multipolar spindle-1” protein (Mps1). These components are required for MSAC signal amplication and 
MCC formation (see Table 2.6). Moreover, several other proteins have recently 
been identied in higher eukaryotes that are also involved in carrying out essential 
aspects of the MSAC mechanism e.g., localization or biochemical signaling: \Rough 
Deal” (Rod) (May and Hardwick, 2006; Bun et al., 2007), ZW10 (Zeste White 
10) (Saery et al., 2000a,b; Chan et al., 2000; Scholey et al., 2003; Raff et al., 
2002), Zwilch (Williams et al., 2003; Karess, 2005) , Zwint-1 (Kops et al., 2005a; 
Wang et al., 2004a) the RZZ complex (Karess, 2005), CENP-E (\Centromere 
associate Protein E", a member of the kinesin superfamily), and protein kinases 
like \Mitogen Activated Protein Kinase” (MAPK), CDK1, and cyclin-B. 

Several core checkpoint proteins are recruited to unattached kinetochores in 
prometaphase including Mad1 (Campbell et al., 2001; Chung and Chen, 2002), 
Mad2 (Fang et al., 1998a; Lampson and Kapoor, 2005), BubR1 (Morrow et al., 
2005; Homan et al., 2001), Bub1 (Taylor et al., 1998a; Chen, 2002b), Bub3 (Taylor 
et al., 1998a; Howell et al., 2004), and Mps1 (Stucke et al., 2004, 2002) (Figure 2.7). Obviously, the kinetochores serve as a platform for complex formation (cf. 
Figure 2.8). The Cdc20:Mad2 and Mad1:Mad2 complexes form in the absence of 
other proteins in vitro (BubR1 or Bub3 are dispensable) (Chung and Chen, 2002; 
Hwang et al., 1998; Martin-Lluesma et al., 2002; Luo et al., 2002; Fraschini et al., 
2001). Upon microtubule attachment, many of these proteins deplete from the 
kinetochores (see for example Lampson and Kapoor, 2005; Wassmann et al., 2003; 
Shannon et al., 2002). 

36



37


Structural 
domain 
and 
Functions 
of 
the 
additional 
MSAC 
Species 

S.c
. 
S.p
. 
H
. 
sapien
s 
Structural
Featur
e 
Function
s 
i
n 
M 
SA
C 
Reference
s 
Mps
1 
Mph
1 
Mps
1 
(hMps1
) 
Dual-specicit
y 
kinas
e 
Rol
e 
i
n 
recruitmen
t 
o
f 
checkpoin
t 
protein
s 
t
o 
kinetochore
s 
(Mad1/2
) 
Require
s 
fo
r 
spindl
e 
pol
e 
Require
s 
fo
r 
centrosom
e 
replicatio
n 
(Stuck
e 
e
t 
al.
, 
2002
, 
2004;
Abrie
u 
e
t 
al.
, 
2001
; 
Homa
e
al.
2001;
Howel
l 
e
t 
al.
, 
2004
; 
Fis
e
al.
2004;
Fis
k 
an
d 
Winey
, 
2004
, 
2001;
Li
u 
e
t 
al.
, 
2003
; 
Tan
g 
e
al.
2004;
Vignero
n 
e
t 
al.
, 
2004).
Ipl
1 
Ark
1 
Auror
a 
B 
Serine/threonine
kinas
e 
Importan
t 
fo
r 
MC
C 
bin
d 
APC
propose
d 
t
o 
sens
e 
tensio
n 
a
t 
kinetochore
s 
Ensure
s 
bipola
r 
orientatio
n 
(Morro
w 
e
t 
al.
, 
2005
; 
Li
e
al.
2006;
Duca
t 
an
d 
Zheng
, 
2004;
Steuerwald
, 
2005
; 
Cheesema
e
al.
2002;
Biggin
s 
an
d 
Murray
, 
2001;
Murata-Hor
i 
an
d 
l
i 
Wang
2002).
Bub
2 
Cdc1
6 
TBC
1 
(tre-
2 
Bub2
, 
cdc16
) 
GA
P 
(GTPas
e activating-protein
) 
coiled-coi
l 
Regulate
s 
mitoti
c 
exi
t 
networ
k 
i
n 
S
. 
cerevisiae
. 
Essentia
l 
fo
r 
cytokinesi
s 
in S
. 
pombe
. 
(H
u 
an
d 
Elledge
, 
2002;
Skla
n 
e
t 
al.
, 
2007;
Martin
u 
e
t 
al.
, 
2004;
Fraschin
i 
e
t 
al.
, 
2001;
Geymona
t 
e
t 
al.
, 
2003
; 
Pereir
e
al.
2002).
--CENP-
E 
~ 
266
3 
residues
. 
Kinesin-lik
e 
plu
s 
end-directed
moto
r 
Interacts wit
h 
BubR
1 
an
d 
microtubules
Essentia
l 
fo
r 
the stabl
e 
bi-oriente
d 
attachment
s 
o
f 
chromosom
e 
t
o 
th
e 
MT
s 
(Ya
o 
e
t 
al.
, 
2000;
Zecevi
c 
e
t 
al.
, 
1998;
Cha
n 
e
t 
al.
, 
1998
, 
1999;
Neuman
n 
e
t 
al.
, 
2006;
Garcia-Sae
z 
e
t 
al.
, 
2004.
Ma
o 
e
t 
al.
, 
2003
, 
2005;
Vignero
n 
e
t 
al.
, 
2004
; 
Morro
e
al.
2005).

Table 
2.6: 
M 
SA
C 
additiona
l 
components
: 
Domai
n 
structure
s 
an
d 
function
s 
i
n 
dieren
t 
eukaryoti
c 
organism
(S.c.
Saccharomyces
cerevisiae
; 
S.p.
, 
Schizosaccharomyce
s 
pombe
; 
an
d 
H
. 
sapiens
, 
Hom
o 
sapiens)
. 


2. MITOSIS TRANSITION CONTROLS
Figure 2.7: A hierarchical network of localization pathways. This gure has been 
re-drown modied from Liu et al. (2006), new species has been added like, Spindly, 
Bub3, and Dynein. 

Biochemical Signaling 

UbcH10 increases both, Cdc20 ubiquitination and the dissociation of Cdc20 
from Mad2 and APC Reddy et al. (2007). Conversely, depletion of UbcH10 
from HeLa cells decreases APC-mediated ubiquitination of Cdc20, stabilizes the 
Mad2-Cdc20 interaction, and delays anaphase initiation (Reddy et al., 2007). In 
an accompanying study, Stegmeier et al. (2007) have identied the ubiquitinspecic protease USP44 as a spindle checkpoint component through an RNA 
interference (RNAi) screen. Human cells depleted for USP44 by RNAi do not 
undergo mitotic arrest in the presence of spindle poisons. The checkpoint bypass 
of USP44 RNAi cells depends on APC, although Mad2 and BubR1 are localized 
normally in the kinetochores. Thus, in APC inhibition, USP44 acts downstream 
of Mad2 in APC inhibition. Furthermore, USP44 antagonizes APC-mediated 
ubiquitination of Cdc20 in vivo. Recombinant USP44 directly deubiquitinates 
Cdc20 in vitro. This study indicates that USP44 reduces Cdc20 autoubiquitination 
and protects the Cdc20:Mad2 checkpoint complexes from disassembly. Gris 

38



2.4 Anaphase Initiation Control
Figure 2.8: Structural features in the regulation of mitotic progression from 
metaphase to anaphase dening the model relations. The left part of the gure 
(unattached case) has been re-drown modied from Musacchio and Salmon (2007) 
and new species like Spindly and Dynein have been integrated. Before the 
attachment most species recruited to the kinetochore. The right hand port of 

the gure presented the kinetochore after attachment to the spindle microtubule. 
After the attachment, many species deplete from the kinetochore. 

39



2. MITOSIS TRANSITION CONTROLS
et al. (2007) have recently identied a new protein, called \Spindly". After the 
depletion of Spindly, dynein cannot target to kinetochores, and, as a result, cells 
arrest in metaphase with high levels of kinetochore-bound Mad2 and RZZ. They 
also identied a human homologue of Spindly that serves a similar function that 
accumulates on unattached kinetochores and is required for silencing the MSAC . 

p31comet (formerly CMT2) is a negative regulator of the spindle checkpoint. It 
prevents further Mad2 turnover on Mad1 and neutralizes the inhibitory activity 
of Cdc20-bound Mad2, leading to activation of APC (Habu et al., 2002; Xia et al., 
2004; Mapelli et al., 2006). For details see Table 2.7. 

40



41


MSAC 
Signaling 
Species

Species 
Name 
(s) 
Functions 
in 
M 
SAC 
References 
UBE2C 
or 
UbcH10 
ubiquitin-conjugatingenzyme E2C 
dissociation 
of 
Cdc20 
from 
Mad2. 
(Reddy 
et 
al.
, 
2007; 
Townsley 
et 
al.
1997;
Hershko 
et 
al.
, 
1994; 
Aristarkhov 
et 
al.
1996;
Yu 
et 
al.
, 
1996; 
Seufert 
and 
Jentsch, 
1990).
USP44 
Ubiquitin 
speci
c 
protease 
44 
reduces 
Cdc20 
autoubiquitination 
and 
protects 
the 
Cdc20 
and 
Mad2complex 
from 
disassembly.
(Stegmeier 
et 
al.
, 
2007).
Dynein 
Dynein 
Remove 
Mad1:C-Mad2 
from 
KTs 
(Howell 
et 
al.
, 
2001; 
Starr 
et 
al.
1998;
Gri
s 
et 
al.
, 
2007).
Spindly 
Spindly 
Localized Dynein 
(Gri
s 
et 
al.
, 
2007).
p31 
comet 
p31 
comet 
It 
prevents 
further 
Mad2 
turnover 
on 
Mad1 and neutralizes 
the 
inhibitoryactivity 
of 
Cdc20-bound Mad2(Habu 
et 
al.
, 
2002; 
Xia 
et 
al.
2004;
Mapelli 
et 
al.
, 
2006; 
Yang 
et 
al.
2007).

Table 
2.7: 
M 
SAC 
Signaling Species 


2. MITOSIS TRANSITION CONTROLS
2.4.3 Recent Models of the MSAC 
For the cell cycle in general there exists already a large number of models, ranging 
from relative simple, low-dimensional models (Tyson, 1991; Goldbeter, 1991) to 
complex models taking into account a large number of molecular species (Chen 
et al., 2004). 

Because most experimental studies of the spindle checkpoint are recent, the 
MSAC has not yet been modeled in a detailed molecular level. Doncic et al. 
(2005) compared several mechanisms that could account for the inhibition of the 
APCCdc20 complex in yeast. They noticed that the design of the MSAC network 
is limited by physical constrains imposed by realistic diusion constants and 
the relevant spatial and temporal dimensions in the yeast cell. By designing a 
simplied model of radial symmetry, they observed that amplifying the signal 
through the release of a diusible inhibitory complex can describe the checkpoint 
function. Nevertheless, their model does not fully take into account the molecular 

complexity. A similar approach was presented by Sear and Howard (2006). They 
investigated two mechanisms for MSAC in metazoan cells: 

. one involves free diusion and sequestration of cell cycle regulators requiring a 
two-stage signal amplication cascade. 
. The second mechanism involves spatial gradients of a short-lived inhibitory 
signal that propagates by diusion and primarily by active transport along 
spindle microtubules. 
Both mechanisms might act in parallel. Mathematical modeling of cell cycle 
control in budding yeast was analyzed in more details by Chen et al. (2004), 
however, this work is not focused on the MSAC. A model for the exit from 
mitosis (Ciliberto et al., 2005) describes the control of the checkpoint, however 
it not considers BubR1 (Mad3 in yeast) and the in
uence of spatial distribution 
and diusion. 

42



2.5 Mitotic Exit control
2.5 Mitotic Exit control 
The second critical control mechanism during mitosis is a complex regulatory 
mechanism (called Exit From Mitosis (EFM)) that allows cells to leave mitosis. 

2.5.1 Exit From Mitosis (EFM) Mechanism 
As described above, the APC plays an important role in the ubiquitination and 
destruction of both securin and cyclin B. The kinase activity of a cyclinB:Cdk1 
complex promotes mitosis, whereas the destruction of the cyclin partner and loss 
of kinase activity is required for EFM (Su et al., 1998). 

APC:Cdc20 is responsible for the rst phase of Cyclin B proteolysis that occurs 
when cellular levels of the Cyclin B are high. Since MSAC is activated, Cdh1 
is phosphorylated by Cdks and thereby kept inactive. After anaphase initiation (MSAC inactivate), Cdh1 is dephosphorylated and thus, it is able to bind and 
activate the APC (Kramer et al., 2000; Zachariae et al., 1998a). APC:Cdh1 then 
ubiquitinates Cdc20 and thereby inactivates APC:Cdc20 (P
eger and Kirschner, 
2000a; Prinz et al., 1998). More precisely, APC:Cdh1 is activated once the degradation of cyclin B has been initiated by APC:Cdc20 (see Figure 2.9). The second 
phase of Cyclin B destruction is mediated by APC:Cdh1 which then trigger the 
exit from mitosis (Tan et al., 2005; Yeong et al., 2000; Bosl and Li, 2005; Morgan, 
1999; King et al., 1996; Alexandru et al., 1999). 

2.5.2 Analysis of the Recent Experimental Studies of the EFM 
In all eukaryotes, EFM occurs through the inactivation of the Cdk1 in complex 
with mitotic cyclin. This complex is called Cdk1:cyclin B or Cdc28:Clb2 in 
budding yeast (Bloom and Cross, 2007). Two main events must occur before a 
cell is able to leave mitosis: 

. The separation of sister chromatids 
. The destruction of Cyclin B. 
43 


2. MITOSIS TRANSITION CONTROLS
Figure 2.9: Activation of APC by Cdc20 and Cdh1 during mitosis. MSAC is 
activated at kinetochores that are not (or not fully) attached with microtubules. 
It inhibits the capability of APC:Cdc20 to ubiquitylate securin and cyclin B and 
thereby prevent anaphase. Once, all kinetochores are attached to microtubules, 
APC:Cdc20 is responsible for activates Separase and the rst phase of Cyclin B 
proteolysis that occurs when cellular levels of the Cyclin B are high. Thereby 
Cdh1 is dephosphorylated (activated) and thus able to bind and activate the 
APC:Cdch1. Activated APC:Cdh1 then mediates the second phase of Cyclin B 
destruction and triggers EFM. The upper part of this gure explain the expected 
behavior of APC activity (with both Cdc20 and Cdh1)and cyclin B in mitosis. 
Then, an abstract reaction scheme explain active APC functions. The lower part 
of the gure explain the corresponding transition event of mitosis. 

44 


2.5 Mitotic Exit control
These late mitotic events are tightly regulated to occur only after the onset of 
anaphase (MSAC inactivated) and prior to cytokinesis (Wolfe et al., 2006; Nasmyth 
et al., 2000). Several proteins and protein complexes are involved in these tasks; 
APC, Cdc20, Cdc14, Cdh1, Cdc15, Net1, Tem, Cyclin B complex, securin, separase 
and the cohesin complex. Some of these players are not observed in humans (e.g. 
Net1). 

During anaphase, the phosphatase Cdc14 is activated. It dephosphorylates several 
targets of mitotic Cdk and promotes mitotic exit (D'Amours and Amon, 2004). 
Separase plays an essential role in Cdc141 activation (Queralt et al., 2006; Sullivan and Uhlmann, 2003). Cdc14 dephosphorylates (and thereby activates) a 
second APC co-activator called Cdh12 that promotes completion of cyclin destruction (Prinz et al., 1998). In higher eukaryotes, it has been shown that a 
homolog of Cdc14 can dephosphorylate Cdh1 in vitro (Bembenek and Yu, 2001b). 
Cdh1 dephosphorylation activates APC and forms the APC:Cdh1 complex, allowing cells to progressively accumulate mitotic cyclin Clb2 (in human Cyclin 
B) (Zachariae et al., 1998b; Yeong et al., 2000; Zachariae et al., 1998a; Huang 
et al., 2001). Then, APC:Cdh1 ubiquitinates Cdc20, and completely degrades 
Cyclin B. Additionally, APC:Cdh1 ubiquitinates other species, like Bub1 that are 
not required for EFM (Qi and Yu, 2007). 

The mechanism of the activation of APC:Cdh1 and EFM is well characterized 
in budding yeast (Morgan, 1999). Mutations of a set of yeast genes, such as 
Tem1, Lte1, Cdc14, and Cdc15 stabilize mitotic cyclin Clb2p and cause late 
anaphase arrest, indicating that they are required for the EFM (Morgan, 1999; 
Jaspersen et al., 1998; Shou et al., 1999; Visintin et al., 1999). During most 
part of the cell cycle, Cdc14 is sequestered in the nucleolus due to its association 
with the regulatory subunit Net1 (also called C1) (Shou et al., 1999; Visintin 
et al., 1999). The release of Cdc14 from the nucleolus and its accumulation in 

1hCdc14A is the human homologue of Cdc14 (Lanzetti et al., 2007; Krasinska et al., 2007; 
Vazquez-Novelle et al., 2005). hCdc14A protein is 64% identical to yeast Cdc14 (Li et al., 1997a). 

2hCdc14A was shown to dephosphorylate Cdh1 and reconstitute active APC:hCdh1 in 
vitro (Bembenek and Yu, 2001a). Additionally, human Cdc14 phosphorylates Cdc25 in vitro (Es
teban et al., 2006). The later has important roles in other cell cycle phases. 

45 


2. MITOSIS TRANSITION CONTROLS
the nucleus (and partially in the cytoplasm) during anaphase is thought to be 

important for activating APC:Cdh1 (Shirayama et al., 1999). 

2.5.3 Recent Models of the EFM 
Bela Novak and colleagues have proposed several models for EFM in budding 
yeast. Queralt et al. (2006) presented a new mathematical model for EFM focused 
only on the cell cycle transition from a stable state of high Cdk activity in mitosis, 
via anaphase and mitotic exit, to a stable state of low Cdk activity in G1. This 
transition corresponds to the window of the cell cycle that was analyzed by 
experiments in which cells arrested in metaphase because of Cdc20-deprivation, 
are able to enter in anaphase by re-addition of Cdc20 or by over-expression of 
separase. They described a wiring diagram of EFM and developed a quantitative 
model based on nonlinear dierential equations. The model was analyzed by 
numerical simulations. The kinetic parameters were chosen to t the experimental 
observations. 

Toth et al. (2007) present a two dimensional model for the EFM in budding yeast. 
They use phase-plane analysis, which reveals two underlying bistable switches 
in the regulatory network. One bistable switch is caused by mutual activation 
(positive feedback) between Cdc14 activating MEN and Cdc14 itself. The mitosisinducing Cdk1 activity inhibits the activation of this positive feedback loop and 
thereby controlling this switch. The other irreversible switch is generated by a 
double-negative feedback (mutual antagonism) between mitosis inducing Cdk1 
activity and its degradation machinery (APC:Cdh1). The Cdc14 phosphatase 
helps turning this switch in favor of APC:Cdh1. Both of these bistable switches 
have characteristic thresholds, the rst one for Cdk1 activity, and other for Cdc14 
activity. The same authors show that the physiological behaviors of certain cell 

cycle mutants are suggestive for those Cdk1 and Cdc14 thresholds. 

We built an integrative mathematical model for MSAC and EFM mechanism 

(M. Palm, 2008). Our model overlaps with the model developed by Toth et al. 
(2007).And will be introduced in detail in Chapter 7. 
46 


2.6 Concluding Remarks
2.6 Concluding Remarks 
Our focus in this chapter was on identifying open questions related to two dierent, 
still connected mitosis transition control mechanisms, namely, the Mitotic Spindle 
Assembly Checkpoint (MSAC) and Exit From Mitosis (EFM) mechanisms. 
These mechanisms involve a rather large number of biochemical species of elements, together with their corresponding interactions. Since of these elements 
serve multiple functions, in addition. Empirical data have proved fruitful in the 
understanding of these mechanisms, in the context of mitosis, a fact well documented by an increasing number of open questions. Yet, such data are typically 
limited by the complexity of such mechanisms. 

The following are examples of open questions that are of most importance in this 
context. We know that both Mad2 and BubR1 sequester Cdc20, but how do these 
three elements interact? The Template model seems to explain some empirical 
data more accurately than the Exchange model does, but the question why this 
is so remains elusive. Is there any amplication phenomenon in the template 
model? MCC is formed in dierent organisms, but is MCC formation kinetochore 
dependent or independent? Moreover, MCC inhibits APC, but how? How an 
MCC:APC complex falls apart after attachments? How biochemical signals as 
p31comet and dynein actually work? How can we ponder the roles of localizations 
and diusion in the context of MSAC ? Eventually, how does MSAC operate 
throughout the entire process of mitosis? These questions, as examples, relate to 
the MSAC mechanism, and comparable questions can be made in relation to the 
EFM mechanism. 

We propose that theoretical accounts of mitosis transition controls based on modeling, simulation, and cross-disciplinary research (In-Silico) will be of signicant 
help for better understanding of such a complex phenomenon as mitosis. This 
might well be an eye-opening trip a cross disciplines, a perspective belonging to 
the so called new science of Systems Biology. We shall refer to our work as to 
\Systems Biology of Mitosis". In the next chapter, we will introduce modeling 
approaches and classications for systems biology. Some details and basic concepts 

will be presented for non modelers. 

47 


2. MITOSIS TRANSITION CONTROLS
48



Entering to Anaphase


49



\Music is the pleasure the human mind experiences from 
counting without being aware that it is counting". 

Gottfried Leibniz (1646 1716) 

\Mathematics is the handwriting on the human consciousness 
of the very Spirit of Life itself". 

Claude Bragdon (1866-1946) 

Chapter 3 

Modeling Mad2 Function in 
Sequestering Cdc20 

Contents 

3.1 Summary .......................... 52


3.2 Introduction ........................ 52


3.3 Methods: Denition and Simulation of the Models . 53 

3.4 BiochemicalBasisoftheModels ............ 54


3.5 TheExchangeModel ................... 55


3.6 TheTemplateModel ................... 59


3.7 Variations of the Template model. . . . . . . . . . . . 64 

3.7.1 AmplicationEects................... 64


3.7.2 InhibitionEects ..................... 67


3.7.3 Amplication plus Inhibition Eects . . . . . . . . . . 68 

3.8 Discussion.......................... 68


3.9 Conclusion ......................... 72


51



3. MODELING MAD2 FUNCTION IN SEQUESTERING CDC20 
3.1 Summary 
For successful mitosis, metaphase has to be arrested until all centromeres are 
properly attached. The onset of anaphase, which is initiated by activating the 
APC, is controlled by the spindle assembly checkpoint MSAC . Mad2, which 
is a constitutive member of the MSAC , is supposed to inhibit the activity of 
the APC by sequestering away its co-activator Cdc20. Mad1 recruits Mad2 to 
unattached kinetochores and is compulsory for the establishment of the Mad2 
and Cdc20 complexes. Recently, based on results from in vivo and in vitro 
studies, two biochemical models were proposed: the Template and the Exchange 
model. Here, we derive a mathematical description to compare the dynamical 
behavior of the two models. Our simulation analysis supports the Template 
model. Using experimentally determined values for the model parameters, the 
Cdc20 concentration is reduced down to only about half. Thus, although the 
Template model displays good metaphase-to-anaphase switching behavior, it 
is not able to completely describe MSAC regulation. This situation is neither 
improved by amplication nor by p31comet inhibition. We speculate that either 
additional reaction partners are required for total inhibition of Cdc20 or an 
extended mechanism has to be introduced for MSAC regulation. 

3.2 Introduction 
To address the question, how Cdc20 concentration relates to anaphase onset and 
how it is regulated, we investigated the role of Mad1 in eliciting the formation of the 
Cdc20:Mad2 complex on the basis of two biochemical models, the exchange (Luo 
et al., 2004) and the template (DeAntoni et al., 2005a) model. To this end, we 
derived the reaction equations from the description in (Luo et al., 2004; DeAntoni 
et al., 2005a). Using standard principles of chemistry and thermodynamics, we 
converted the reaction equations into non-linear ordinary dierential equations 
for the concentrations of the reactants. To simulate their dynamics in the course 
of time, the dierential equations were integrated for dierent values of the 
kinetic constants involved. To nd a behavior in concordance with experimental 

52



3.3 Methods: Denition and Simulation of the Models
results, we employed a minimization procedure. The purpose of this chapter is 
threefold. First, we show how to derive a mathematical model for the biochemically 
described Exchange and Template models. Then, as the main purpose, we 
compare the two models by mathematical simulations and show that the Exchange 
model is not able to realistically describe the metaphase-to-anaphase transition. 
Though the Template model in principle can show correct switching behavior 
for this transition, it is not able to sequester away Cdc20 completely whenever 
physiologically realistic kinetic constants are used. Therefore, in a third step, 
we investigate six further extensions of the Template model, based on recently 
described biochemical amplication and inhibition eects, especially considering 
the role of p31comet . As total inhibition of Cdc20 activity during metaphase is 
the basis of most models for metaphase-to-anaphase transition (Ibrahim et al., 
2007; Toth et al., 2007; Queralt et al., 2006), it is an important question, whether 
Mad2 is able to fully Cdc20 sequester (inhibition) or additional reaction partners 
are required or an extended MSAC regulation mechanism has to be introduced? 

3.3 Methods: Denition and Simulation of the 
Models 
For each model, we describe brie
y the basic biochemical pathways and experimental ndings. These experimental foundations are turned into chemical 
reaction equations. In some cases, reactions depend on the attachment of the 
microtubules to the kinetochore, which is described by a switching parameter 

u: before attachment, we set u = 1; and after attachment, u = 0. Formation 
of the Mad1:C-Mad2:OMad2* complex in the classical Template model is an 
example for this dependence (see Eq. (3.6)). The corresponding kinetic parameter 
T is therefore multiplied by u. Biochemically, the switching parameter u may 
represent the function of dynein, which after microtubule attachment removes the 
Mad1:C-Mad2 2:2 complex from the kinetochore site. 
The reaction equations are converted into non-linear ordinary dierential equations 
(ODEs) using the mass action kinetics (c.f. Appendix B B.1-B.5). Starting from 

53



3. MODELING MAD2 FUNCTION IN SEQUESTERING CDC20 
initial concentrations for all reaction partners taken from literature (cf. Table 3.1), 
the ODEs are integrated until steady state is reached before attachment (using 
u = 1). After switching u to 0, the equations are again integrated, until steady 
state is reached. The minimum concentration of Cdc20 before attachment and the 
recovery after attachment (level of Cdc20 increase and recovery time) are criteria 
to compare the models. As far as documented in the literature, experimental 
values are used for the kinetic constants. In all other cases, we select representative 
values for each parameter (cf. Table 3.1) exemplifying its whole physiologically 
possible range. The resulting concentration curves show the in
uence of the kinetic 
parameter on the behavior of the model. It can be clearly seen that the variation 
of the curves depends in a continuous manner on the variation of the parameters. 
Their in
uence on the behavior of the models is described in detail in the respective 
sections. In a more global approach, we t optimal values to the model parameters 
by minimizing a Cdc20 concentration objective functional describing a minimal 
Cdc20 concentration before and a maximal concentration after switching (see 
Appendix B B.6). Minimization was performed by statistical approaches by 
selecting randomly starting values within the whole range of parameters. For the 
Cdc20 concentration functional, a minimal solution is in general not unique, as can 
be seen from the graphs with the example parameter settings. On the other hand, 
due to the continuous behavior of the system in dependence of the parameters, in 
some cases parameters tend to an asymptotic, often physiologically unrealistic, 
value. In other cases, the velocity of Cdc20 recovery after switching can help to 
dene a possible parameter set. The details are explained in the respective model 
sections. 

3.4 Biochemical Basis of the Models 
The biochemical basis of the models are the binding kinetics of Mad1, Mad2, and 
Cdc20. Mad1 forms a tight 2:2 complex with Mad2 (Sironi et al., 2001a). Binding 
of Mad2 to Mad1 triggers a conformational change of Mad2, in a similar way as 
does Cdc20 binding: Mad2 binds to Mad1 and Cdc20 in the same pocket with 
similar anities (Luo et al., 2002). Mad2 can adopt two conformations, O-Mad2 

54



3.5 The Exchange Model
and C-Mad2, diering in the structure of its 50 residue C-terminal segment (Luo 
et al., 2002). The O-Mad2 is the physiological state of cytosolic Mad2 in the 
absence of Mad1 or Cdc20 (Luo et al., 2004). O-Mad2 refolds to C-Mad2 when 
bound to the kinetochore receptor Mad1 or the APC activator Cdc20 (Luo et al., 
2004). Upon microtubule attachment, Mad1 (Campbell et al., 2001) remains 
detectable at kinetochores whereas Mad2 (Lampson and Kapoor, 2005) depletes 
from the kinetochores. 

3.5 The Exchange Model 
In order to explain the formation of the Mad1:Cdc20 complex, Luo et al. (2004) 
suggested the Mad2 Exchange model, based on a series of in vitro and in vivo 
experiments. It assumes that Mad1 recruits open Mad2 (O-Mad2) at the kinetochore and transforms its conformation from open Mad2 (O-Mad2) to closed Mad2 
(C-Mad2). C-Mad2 then dissociates away from Mad1 and binds Cdc20. This 
model portrays Mad1 as a catalyst of the structural transition of O-Mad2 into 
C-Mad2. The reaction rules governing the Exchange model are (cf. Figure 3.1): 

k1

O-Mad2 . C-Mad2 (3.1)

..--. 

k..

..1 

E :u 

Mad1 + O-Mad2 ). Mad1:C-Mad2 (3.2)

---

k

..2 
k3

Mad1:C-Mad2 . C-Mad2 + Mad1 (3.3)

..--. 

k..

..3 

kE

C-Mad2 + Cdc20 ....... Cdc20:C-Mad2 (3.4) 

E

Cdc20:C-Mad2 ....... Cdc20 + O-Mad2 (3.5) 

which lead to the set of time dependent nonlinear ODEs listed in Appendix B B.1, 
Eqs. (B.1)-(B.6). 

55



3. MODELING MAD2 FUNCTION IN SEQUESTERING CDC20
Figure 3.1: Schematic reaction network of the Exchange model. In the Exchange 
model (Luo et al., 2004), it is assumed that Mad1 recruits open Mad2 (O-Mad2) 
at the kinetochore and transforms its conformation from O-Mad2 to closed Mad2 
(C-Mad2). C-Mad2 then dissociates from Mad1 and binds Cdc20. This model 
portrays Mad1 as a catalyst of the structural transition of O-Mad2 into C-Mad2. 
Already this purely biochemical description gave rise to several criticisms (Lenart 
and Peters, 2006; Hardwick, 2005). Especially the question remained, why and 
how Mad2 rst binds (as O-Mad2) to Mad1, but then dissociates off (as C

Mad2) (DeAntoni et al., 2005b). 

56



3.5 The Exchange Model
The only parameter dependent on the kinetochore attachment status is E which 
therefore is multiplied by the switching parameter u. The reaction scheme contains 
the background reaction for O-Mad2 conversion to C-Mad2 (Eq. (3.1)) with very 
low rates k1 and k..1 (Luo et al., 2004). For E, k..2, k3, and k..3 we used 
quantitative experimental data from (Luo et al., 2004) (see Table 3.1). The 
remaining two parameters kE and E were varied within a realistic range (Luo 
et al., 2004; DeAntoni et al., 2005a; Fang, 2002): kE between 105M..1 s..1and 
109M..1 s..1and E between 3 * 10..5s..1and 10..2s..1 . When analyzing this set of 
ODEs, we found that only for very small E (3 * 10..5s..1) the initial Cdc20 
concentration is clearly reduced to about half the initial value (Figure 3.2a) while 
for the higher values of E (10..2s..1) the Cdc20 concentration hardly changed 
(Figure 3.2d). Our data indicate that the switching of u from 1 to 0 has little 
in
uence on Cdc20 concentration, smaller E (Figure 3.2 a) showing slightly larger 
eects than larger E (Figure 3.2 d). A large in
uence of u on Cdc20 concentration, 
however, is required for checkpoint function. While the MSAC is activated, the 
concentration of Cdc20 should be low, and should switch to large values when the 
kinetochores are attached. The Exchange model does not describe this behavior. 

57



3. MODELING MAD2 FUNCTION IN SEQUESTERING CDC20
ab
01234x 10500.511.52x 10-7Time[Cdc20]
h= 3*10-5kE 
105106107108109
01234x 10500.511.52x 10-7Time[Cdc20]
h= 5*10-4kE 
105106107108109
cd


01234x 10500.511.52x 10-7Time[Cdc20]
h= 10-3kE 
105106107108109
01234x 10500.511.52x 10-7Time[Cdc20]
h= 10-2kE 
105106107108109
Figure 3.2: The dynamical behavior of the Exchange model with dierent values of 
k4 and E. Color lines represent dierent values of k4, which is without in
uence 
on the model behavior, as all line coincide. Switching of u from 0 to 1at time 

58



3.6 The Template Model
3.6 The Template Model 
In the Exchange model it remained unclear, how Mad2 rst binds to Mad1 and 
then dissociates off by just adopting another conformation. In an experimental 
study, (DeAntoni et al., 2005a) provided information about the detailed reaction 
mechanism, which was nally condensed into the Mad2 Template model. It 
assumes that Mad1 and C-Mad2 form a stable core complex at unattached 
kinetochores (DeAntoni et al., 2005a). This core then binds additional molecules 
of O-Mad2 through formation of conformational heterodimers between the CMad2 subunit of the Mad1:C-Mad2 complex and O-Mad2. Cdc20 binding to 
this complex leads to the conversion of O-Mad2 to C-Mad2 resulting in the 
formation of Cdc20:C-Mad2, which in turn is assumed then to dissociate off 
Mad1:C-Mad2 (Fang, 2002). Upon Mad1:C-Mad2 binding, O-Mad2 adopts an 
intermediate conformation (O-Mad2*) that can quickly and eciently bind Cdc20 
and switch to the C-conformation (see Figure 3.3). The reaction rules covering 
the Template model are (cf. Appendix B B.2 for ODEs): 

Mad1:C-Mad2 + O-Mad2 . 
T :u 
. Mad1:C-Mad2:O-Mad2* (3.6)

..---..

T 
Mad1:C-Mad2:O-Mad2 * + Cdc20 

T :u 
Cdc20:C-Mad2 + Mad1:C-Mad2

-..... 

(3.7) 
T

Cdc20:C-Mad2 ....... O-Mad2 + Cdc20 (3.8) 

The kinetic constants T , T , and 
T depend on the attachment state of the 
kinetochore and are thus multiplied by the variable u. We used quantitative 
data from FRAP experiments for T and T (Vink et al., 2006). The remaining 
two parameters 
T and T were varied widely within realistic frames (Luo et al., 
2004; DeAntoni et al., 2005a; Fang, 2002): T between 5 * 10..4s..1and 10..1s..1 , 
and 
T between 105M..1 s..1and 109M..1 s..1(c.f. Table 3.1). Characteristic Cdc20 
concentration curves were obtained as displayed in 3.4. 

59 


3. MODELING MAD2 FUNCTION IN SEQUESTERING CDC20
Figure 3.3: Schematic reaction network of the Template model. In a subsequent 
sophisticated experimental investigation, (DeAntoni et al., 2005a) could precise the 
reaction mechanism further and developed the biochemical Template model. Here, 
it is assumed that Mad1 and C-Mad2 form a stable core complex at unattached 
kinetochores. This core then binds additional molecules of O-Mad2 through 
formation of conformational heterodimers between the C-Mad2 subunit of the 
Mad1:C-Mad2 complex and O-Mad2. Cdc20 binding to this complex leads to the 
conversion of O-Mad2 to C-Mad2 resulting in the formation of Cdc20:C-Mad2, 
which in turn is assumed then to dissociate off Mad1:C-Mad2 (Fang, 2002). But 
even with this rened description, many questions remained open (Mapelli et al., 
2006; Nezi et al., 2006), and a decision for one of the models to be more realistic 
could not be met Vink et al. (2006). 

60



3.6 The Template Model
For T values smaller than 10..1s..1, we observed a clear dependence of the Cdc20 
concentration on the switching parameter u with the eect being larger for larger 

T . In early mitosis (u = 1), for T values in the order of 10..3s..1(clearly smaller 
than 10..2s..1) and 
T values larger than 106M..1 s..1, the Template model sequesters 
about half of the Cdc20 concentration (Figure 3.4) in quantitative agreement with 
experimental ndings (Luo et al., 2004; Fang, 2002). However, within this frame 
of realistic parameter variations, Cdc20 is never completely inhibited as would be 
required for checkpoint function. T determines the rate of Cdc20 concentration 
recovery after u is switched to zero: small T values of about 10..3s..1display slow 
recovery while values of 10..2s..1and above show fast recovery (Figure 3.4). 

Already Fang (2002) increased the Mad2 level 100fold (to 22.5 M) to gain 
maximal Cdc20 inhibition. In our Template model simulation, an 8fold increase 
of free Mad2 concentration showed complete Cdc20 disappearance for small T 
(< 10..1s..1) and large 
T (> 106M..1 s..1) (see Figure 3.5). In addition, the rate 
of Cdc20 recovery becomes fast for larger values of T . However, this Mad2 
concentration is far above experimentally observed values (Fang, 2002). 

61



3. MODELING MAD2 FUNCTION IN SEQUESTERING CDC20
ab
0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 5*10-4
g 
105106107108109
0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 10-3
g 
105106107108109
cd


0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 10-2
g 
105106107108109
0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 10-1
g 
105106107108109
Figure 3.4: The dynamical behavior of the Template model with dierent values 
of 
T and T . Figures a, b, c, and d for physiological data (see text), for increase 
Mad2 see Figure 3.5. Switching of u from 0 to 1 at time 2000 s 

62



3.6 The Template Model
ab
0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 5*10-4
g 
105106107108109
0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 10-3
g 
105106107108109
cd


0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 10-2
g 
105106107108109
0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 10-1
g 
105106107108109
Figure 3.5: The dynamical behavior of the Template model with dierent values 
of 
T and T . Figures a, b, c, and d for 8folds increase of free Mad2. Switching of 
u from 0 to 1 at time 2000 s 

63



3. MODELING MAD2 FUNCTION IN SEQUESTERING CDC20 
3.7 Variations of the Template model 
In the Template model, for realistic parameter ranges, Cdc20 inhibition is not 
as high as anticipated. We therefore modied the model according to recent 
experimental results. 

3.7.1 Amplication Eects 
DeAntoni et al. (2005a) hypothesized that in analogy to the reactions in Eqs. (3.6) 
and (3.7) based on Mad1, Cdc20:C-Mad2 can also be formed by the reactions in 
Eqs. (3.9) and (3.10) below based on Cdc20. This additional pathway for the 
production of Cdc20:C-Mad2 results in a signal amplication for the MSAC since 
Cdc20:C-Mad2 now is produced not only at the location of Mad1 at the kinetochore 
but at a larger number of locations everywhere in the cell. To check the eect of 
this additional pathway, we added two reactions (3.9-3.10) to the Template model 
(see Figure 3.6 a, ODEs Appendix B B.3): 

Cdc20:C-Mad2 + O-Mad2 . 
k
k
..
4
4 - Cdc20:C-Mad2:O-Mad2 * (3.9)

..---. 

k5

Cdc20:C-Mad2:O-Mad2 * + Cdc20 - ..... 2 Cdc20:C-Mad2 (3.10) 

The Mad2 heterodimer formation at the Mad1 location is considered to be as fast 
as at Cdc20, so that k4 and k5 would be as large as T and 
T , respectively. For 
k4 and k5 both equal to 105M..1 s..1 , T = 10..3s..1and 
T in the range between 
105M..1 s..1and 109M..1 s..1 . Our calculations indicate that the switching parameter 
u has little to no eect on the Cdc20 concentration (Figure 3.7 b). Small k4 = 
k5 = 103M..1 s..1have vanishing in
uence on the model and roughly show the 
Template model behavior as observed before (Figure 3.7 a). Furthermore, using 
our tting procedure for optimal parameters, the values of k4 and k5 tend to zero: 
the amplication is discarded from the reaction scheme. 

64 


3.7 Variations of the Template model
a
b



Figure 3.6: Schematic reaction networks and localization: (a) the Template model 
with amplication, (b) the Template model with amplication controlled by 

p31comet 

. 

65 


3. MODELING MAD2 FUNCTION IN SEQUESTERING CDC20 
ab 

0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 10-3
g 
105106107108109cd
0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 10-3
g 
105106107108109
0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 10-3
g 
105106107108109ef
0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 10-3
g 
105106107108109
0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 10-3
g 
105106107108109
0500100015002000250030003500400000.511.52x 10-7Time[Cdc20]
h= 10-3
g 
105106107108109
Figure 3.7: The dynamical eects of the dierent amplication mechanisms in the 
Template model (time in s) : a and b represent the case, in which the amplication 
is uncontrolled (Eqs (B.12)-(B.17), Appendix B B.3). c and d: amplication 
controlled by the switching parameter u (Eqs (B.25)-(B.33), Appendix B B.5). e 
and f: e and f: controlled amplication, but now with p31comet . Left column (a, 
c, e): low amplication rate k4 = k5 = 103M..1 s..1 . Right column (b, d, f): high 
amplication rate k4 = k5 = 105M..1 s..1 . Numerical solution of the dierential 
equations in Appendix B B.3, B.4, and B.5. Color lines represent dierent values 
of 
T . 

66 


3.7 Variations of the Template model
The additional amplication reactions could contribute to the model behavior, 
in case the reaction Eq. (3.9) did not take place all the time, but instead would 
also be controlled by the switching parameter u (k4 replaced by k4:u). With the 
same parameter values as in the previous calculation (Figure 3.6 d), we obtained 
Cdc20 concentrations nearly independent from 
T : low Cdc20 concentrations 
were reached now also for small values of 
T (Figure 3.6 c). However, we have 
no experimental indication for such an in
uence of microtubule attachment to 
kinetochores on k4. 

3.7.2 Inhibition Eects 
Another way to vary the Template model is the introduction of the Mad2 ligand 
p31comet (formerly CMT2), which is a negative regulator of the spindle checkpoint. 
It prevents further Mad2 turnover on Mad1 and neutralizes the inhibitory activity 
of Cdc20-bound Mad2, leading to activation of APC followed by degradation of 
Securin and Cyclin B (Habu et al., 2002). Its negative eect on the MSAC is 
based on its competition with O-Mad2 for C-Mad2 binding (Habu et al., 2002; 
Xia et al., 2004). It forms triple complexes with C-Mad2 and either Mad1 or 
Cdc20 (Xia et al., 2004). If p31comet is activated at microtubule attachment to the 
kinetochores, it might be a cellular factor contributing to the checkpoint switching 
behavior. Therefore, we introduced an additional reaction 3.11 into the Template 
model reactions (3.6-3.8) describing the eect of p31comet (ODEs Appendix B B.4): 

T :v 

Mad1:C-Mad2 + p31 ). Mad1:C-Mad2:p31 (3.11)

- --

T 

The activation of p31comet is taken care of by the introduction of the switching 
parameter v which is equal to zero until the kinetochores are attached and switches 
to one afterwards. In fact, the function of the switching parameter u can be totally 
replaced by p31comet inhibition, as the p31comet system with u = 1 all the time 

67



3. MODELING MAD2 FUNCTION IN SEQUESTERING CDC20 
shows the same dynamic results as the unmodied Template model (Figure 3.4). 
Combining both eects (u and v switching) still show the same dynamics. 

3.7.3 Amplication plus Inhibition Eects 
Including both, amplication and p31comet inhibition, into the Template model, we 

obtain the chemical reaction scheme (see Figure 3.6 b), consisting of Eqs. (3.6-3.8), 
(3.9-3.10), and an additional equation (3.12), (ODEs Appendix B B.5): 

T :v 

Cdc20:C-Mad2 + p31 ). Cdc20:C-Mad2:p31 (3.12)

- --

T 

For u = 1 before and after attachment (all the time), the model behavior is 
not in
uenced before switching (v = 0). After switching (v = 1), for low T = 
103M..1 s..1, the new additional reaction mechanism is slightly less eective in 
Cdc20 recovery, whereas for high T = 105M..1 s..1, Cdc20 cannot recover since it 
is incorporated into the triple complex with C-Mad2 and p31comet . Combining u 
and v switching does not change the dynamics. 

3.8 Discussion 
The mitotic checkpoint proteins Mad1, Mad2 and Cdc20 play an essential role in 
cell cycle control by contributing to the regulation of the MSAC mechanism (DeAntoni et al., 2005a). Their interactions have been studied experimentally (e.g. (Luo 
et al., 2004; DeAntoni et al., 2005a; Fang, 2002)) resulting in two alternative 
models describing their behavior, the \Exchange model” (Luo et al., 2004) and 
the \Template model” (DeAntoni et al., 2005a). Recently, experimental data 
questioned the validity of the Exchange model while they supported the Template 
model (Mapelli et al., 2006; Nezi et al., 2006; Vink et al., 2006). Here, the two 
models were described by sets of chemical reactions, which were transformed into 

68



3.8 Discussion
Model Parameters


Parameters References


Species initial concentrations 

[Cdc20]= 2:2 * 10..7M (Tang et al., 2001; Fang, 2002; Howell et al., 2000a)
[Mad1]= 0:5 * 10..7M (Tang et al., 2001; Fang, 2002; Howell et al., 2000a)
[O-Mad2]= 1:5 * 10..7M (Tang et al., 2001; Fang, 2002; Howell et al., 2000a)
[C-Mad2]= 0:1875 * 10..7M (Tang et al., 2001; Fang, 2002; Howell et al., 2000a)
[Mad1:C-Mad2]= 0:5 * 10..7M (Tang et al., 2001; Fang, 2002; Howell et al., 2000a)
[p31comet ] = 10 * 10..7M (Xia et al., 2004; Mapelli et al., 2006)
Other species are zero


Template model 

T =5 * 105 M..1 s..1 (Vink et al., 2006) 
T = 0.2 s..1 (Vink et al., 2006) 
T =1:7 * 106 M..1 s..1 (Vink et al., 2006) 
T = 0.037 s..1 (Vink et al., 2006) 
k4 = 103 , 105 M..1 s..1 This study 
k..4 =0:03 s..1 This study 
k5 = 103 , 105 M..1 s..1 This study 

T = 105 , 106 , 107 , 108 , 109 M..1 s..1 This study 
T =5 * 10..4 , 10..3 , 10..2 , 10..1s..1 This study 

Exchange model 

k1 =3 * 10..5 s..1 (Luo et al., 2004) 
k..1=5:2 * 10..6 s..1 (Luo et al., 2004) 
E=4 * 103 M..1 s..1 (Luo et al., 2004) 
k..2=1:5 * 10..2 s..1 (Luo et al., 2004) 
k3 =2:8 * 10..4 s..1 (Luo et al., 2004) 
k..3=23 M..1 s..1 (Luo et al., 2004) 
kE =105 , 106 , 107 , 108 , 109M..1 s..1 This study 
E=3 * 10..5 , 5 * 10..4 , 10..3 , 10..2s..1 This study 

Table 3.1: Kinetic data. Species initial concentrations and parameters value for 
models. 

69 


3. MODELING MAD2 FUNCTION IN SEQUESTERING CDC20 
sets of nonlinear ordinary dierential equations (ODEs). The ODEs quantitatively display the dynamic behavior of the models. Where experimental results 
were available, parameters were chosen according to these data. The unknown 
systems parameters were optimized according to the known behavior of the Cdc20 
concentration at the metaphase to anaphase transition (Appendix B B.6). 

The Exchange model was suggested by Luo et al. (2004) in order to explain 
their experimental data. This model however had been criticized because it is 
unable to explain additional experimental data from other groups (Musacchio and 
Salmon, 2007; Mapelli et al., 2006; Nezi et al., 2006; Vink et al., 2006) and since 
it assumes that Mad1 competes with Cdc20 for Mad2 binding. We identied an 
additional weakness of the Exchange model: it is hardly able to show switching 
kinetics. This property is model inherent since those reactions involving Cdc20 
are kinetochore uncontrolled and are not in
uenced by microtubule attachment. 
Moreover, the steady state is reached very slowly (about 100 times slower than 
in the Template model). In addition, when applying experimentally determined 
parameter values, the Exchange model is not able to sequester Cdc20 suciently 
as would be required for MSAC regulation. Even a free parameter optimization 
did not result in a satisfying model switching behavior. 

In contrast, the behavior of the Mad2 Template model (DeAntoni et al., 2005a) is 
in accordance with experimental observations (Fang, 2002; Mapelli et al., 2006; 
Vink et al., 2006) and shows robust switching behavior. However, the Cdc20 
concentration is only reduced down to about half when experimentally determined 
values are used for the model parameters. This observation is in agreement with 
Fang (2002), and Luo et al. (2004) in HeLa cells. Complete sequestering of Cdc20 
is obtained for higher Mad2 concentrations, as observed by Fang (for a 100fold 
higher Mad2 concentration). When increasing the free Mad2 concentration 8fold 
in the Template model, we found complete reduction of Cdc20 concentration. 
However, there is no experimental indication for such a high Mad2 concentration 
in HeLa cells. Thus, although showing robust switching behavior when using 
experimentally determined parameter values, the Template model as listed is 
unable to result in complete inhibition of Cdc20. This conclusion is in agreement 
with statements of Fang (2002). Contributions from additional reaction partners 

70



3.8 Discussion
are required for complete Cdc20 sequestering. Such a reaction partner seems to be 
the checkpoint protein BubR1 which also binds Cdc20 (Fang, 2002; Sudakin et al., 
2001; Tang et al., 2001) and cooperates to form the mitotic checkpoint complex 
MCC (Sudakin et al., 2001). 

Mad2 heterodimers can bind to either Mad1 or Cdc20 (DeAntoni et al., 2005a,b). 
Thus, C-Mad2:Cdc20 complexes can be formed not only at Mad1 kinetochore 
sites but in the whole cell, amplifying complex formation. To investigate the 
amplication mechanism, we extended the Template model by the appropriate 
reactions. When the newly introduced reaction rates are small, these reactions 
do not contribute to the model behavior. If however the rates are high, there is 
hardly any Cdc20 recovery after switching since these amplication reactions are 
not in
uenced by mitotic progression. Thus, these additional reactions do not 
improve Template model behavior. 

The checkpoint inhibitor p31comet competes with O-Mad2 for C-Mad2 binding, 
thus preventing the binding of O-Mad2 to C-Mad2 (Mapelli et al., 2006; Habu 
et al., 2002; Ciliberto et al., 2005). It binds to the surface of C-Mad2 opposite to 
Mad1 and Cdc20 (Mapelli et al., 2006; Vink et al., 2006), forming triple complexes 
with these proteins. If p31comet is activated at metaphase to anaphase transition, 
our model calculations clearly show that p31comet is able to introduce switching 
behavior into the model and would be even able to replace the function of the 
switching parameter u: The Template model behavior is very similar when u is 
removed and p31comet reactions are added to the model. The situation is slightly 
dierent in the presence of the amplication reactions. Now, removing u and 
introducing the p31comet reactions, we found no improved Cdc20 recovery for small 
reactions rates T , however, strongly reduced recovery for large T rates. In order 
to distinguish between these two cases, additional experimental kinetic data are 
required for p31comet reactions. In general we observe that p31comet is not sucient 
for full MSAC regulation. This nding is particularly interesting, because it was 
shown in a very general model that amplication reactions might be necessary 
to promote the nal signal from the last attaching kinetochore for anaphase 
onset (Doncic et al., 2005; Sear and Howard, 2006). In (Doncic et al., 2005), 
p31comet is explicitly mentioned as a candidate for this information transmission. 

71



3. MODELING MAD2 FUNCTION IN SEQUESTERING CDC20 
The switching parameter u represents the function of dynein which after microtubule attachment removes the Mad1:C-Mad2 2:2 complex from the kinetochore 
site. It might also represent potential additional functions which contribute to 
switching behavior. When both, u and p31comet , are included in the reaction 
scheme, the general behavior of the system is not improved over those systems 
including only u or only p31comet . We observed an improvement however, when 
the reaction Eq. (3.9) becomes controlled by u. Now, before attachment, low 
concentrations for Cdc20 were observed even for low values of 
T , and after attachment Cdc20 recovers fast independent of 
T values, showing an considerably 
improved regulation behavior. However, we have no experimental indication for a 
mitotic control of reaction Eq. (3.9). 

3.9 Conclusion 
Taken together we conclude, that the presented Exchange model is not describing 
checkpoint function. The Template model is clearly superior and shows robust 
switching behavior. However, applying experimentally determined parameter 
values to this model, Cdc20 is not sequestered completely. Additional reaction 
partners would be required for total inhibition of free Cdc20. BubR1 would be 
a potential candidate for this function. Thus, as a next step (Chapter 4), MCC 
formation including BubR1 and Cdc20 will be included into the quantitative 
analysis. 

72



\The best model of a cat is another cat or, better, the cat itself". 

Norbert Wiener (1894 -1964) 

\One of the deepest functions of a living organisms is to 
look ahead... to produce future". 

Francois Jacob (1974 -) 

Chapter 4 
Modeling MCC assembly 

Contents 

4.1 Summary .......................... 74


4.2 Molecular biological basis of MCC models . . . . . . 74 

4.3 Mathematical modeling of the MCC . . . . . . . . . . 76 

4.4 Dynamics of dierent MCC models . . . . . . . . . . 77 

4.4.1 Kinetochore dependent MCC model (KDM) . . . . . . 77 

4.4.2 Kinetochore independent MCC model (KIM) . . . . . 83 

4.4.3 Amplicationeects ................... 85


4.4.4 p31comet contributions .................. 86


4.4.5 Maximum sequestering of Cdc20 . . . . . . . . . . . . 88 

4.5 DiscussionandConclusions ............... 96


73



4. MODELING MCC ASSEMBLY
4.1 Summary 
BubR1 binds Cdc20 within two seemingly dierent contexts. In the rst context, it forms an isolated complex with Cdc20, whereas in the second it is part 
of a larger complex of proteins (BubR1, Cdc20, Mad2, Bub3) called \Mitotic 
Checkpoint Complex", or MCC. We incorporated both contexts in two dierent 
models, and found that Cdc20 can be fully sequestered by BubR1 neither in the 
rst nor in the second context. Moreover, it has been postulated that MCC formation can be either Kinetochore-independent (KIM) or Kinetochore-dependent 
(KDM) (e.g., Musacchio and Salmon, 2007). We found that only the Kinetochoredependent model can -partially-account for the availability of Cdc20 both before 

and after the attachment of all chromosomes. 

We observed that for the models analyzed, eective MCC formation cannot be 
combined with complete Cdc20 sequestering. Instead, the MCC might bind and 
completely block the APC. The MSAC might function by an MCC:APC complex 
rearrangement. 

4.2 Molecular biological basis of MCC models 
Sudakin et al. (2001) analysed and described the MCC in HeLa cells. It contains 
Mad2, Bub3, BubR1 and Cdc20 in apparently equal stoichiometries. A similar 
complex was identied in budding (Hardwick et al., 2000) and ssion (Millband and 
Hardwick, 2002) yeasts and in Xenopus (Chung and Chen, 2003). Bub3 associates 
with BubR1 (Sudakin et al., 2001; Taylor et al., 2004, 1998a). This interaction 
is constitutive and is required for the localization of BubR1 to the kinetochores 
during mitosis. In prometaphase, CENP-E activates the kinase activity of BubR1 
at unattached kinetochores (Mao et al., 2003, 2005; Chan et al., 1998). It is 
unclear whether the BubR1 activation is required for MSAC function (Mao et al., 
2003; Chen, 2002b): the kinase activity of BubR1 might not be required in 
the MCC, however, it might control other aspects of kinetochore signaling or 
chromosome alignment (Ditcheld et al., 2003; Lampson and Kapoor, 2005) 

74



4.2 Molecular biological basis of MCC models
(reviewed in Musacchio and Salmon (2007)). BubR1 activity is switched off upon 
microtubule attachment (Mao et al., 2005; Braunstein et al., 2007). 

The binding properties of BubR1 are controverse. BubR1 cannot bind Mad2 
directly (Fang, 2002). Though it was reported that BubR1 does not form a ternary 
complex with Mad2 and Cdc20 (Bolanos-Garcia et al., 2005; Davenport et al., 
2006), for ssion and budding (Burton and Solomon, 2007; King et al., 2007) yeasts 
such complexes (with Mad3) were found when investigating the highly conserved 
KEN boxes. Two Cdc20 binding sites were identied on BubR1 (Bolanos-Garcia 
et al., 2005; Davenport et al., 2006): Binding of the N-terminal region of BubR1 
to Cdc20 requires prior binding of Mad2 to Cdc20 (Davenport et al., 2006). The 
other site (between residues 490 and 560) can bind Cdc20 tightly regardless of 
Mad2 being bound to Cdc20 (Davenport et al., 2006). Thus, BubR1 can form a 
ternary complex with Bub3 and Cdc20 which however has no inhibitory activity 
at the APC (unpublished data (Sudakin et al., 2001)). 

During prometaphase, Cdc20 and all MSAC proteins concentrate at unattached 
kinetochores (Cleveland et al., 2003; Maiato et al., 2004), like Mad1 (Campbell 
et al., 2001; Chung and Chen, 2002), Mad2 (Fang et al., 1998a; Lampson and 
Kapoor, 2005), BubR1 (Morrow et al., 2005; Homan et al., 2001), Bub1 (Taylor 
et al., 1998a; Chen, 2002b), Bub3 (Taylor et al., 1998a; Howell et al., 2004), and 
Mps1 (Stucke et al., 2004, 2002). Kinetochore localization of Cdc20 and of its 
binding partners in the MCC is dynamic. Localization of all MSAC proteins at 
unattached kinetochores in mitosis provides a catalytic platform and contributes 
to MCC formation (Kallio et al., 2002a; Howell et al., 2000b; Shah et al., 2004). 
The MCC is also detectable in normal metaphase-arrested cells in which the 
MSAC is inactive. This indicates that MCC formation does not require checkpoint activation (Poddar et al., 2005). Moreover, the MCC is also detectable in 
checkpoint defective cells (Poddar et al., 2005; Fraschini et al., 2001). A detailed 
study (Meraldi et al., 2004) proposes that cytosolic Mad2-BubR1 is essential to 
restrain anaphase onset early in mitosis when kinetochores are still assembling. 
These arguments support the idea that the MCC (and its subcomplexes) might 
form in a kinetochore-independent manner (for review see Musacchio and Salmon 
(2007)). We thus distinguish two dynamical models (see Figure 4.1): a kinetochore 

75



4. MODELING MCC ASSEMBLY
dependent model (KDM), and a kinetochore independent model (KIM). In the 
following, we dene the chemical reaction equations based on empirical results 
and analyse their properties. 

4.3 Mathematical modeling of the MCC 
We analyse dierent models for MCC function considering in particular the role 
of the attachment status of the kinetochore. For each model, we describe the 
reaction equations in the usual biochemical notation specifying kinetic constants 
and assuming mass action rules to derive the dierential equations for the concentrations as functions of time. Some of the reactions are independent of the 
kinetochore attachment status, others are mediated in some way by attachment or 
non-attachment, respectively. The most prominent equation will be the formation 
of the MCC complex 

kF

Cdc20:C-Mad2 + Bub3:BubR1 MCC

..-)*..

k..F 

which, in the \kinetochore dependent model” (KDM), proceeds only, when the 
kinetochore is unattached, whereas in the \kinetochore independent model” (KIM) 
it proceeds all the time independently of the attachment status. Therefore, in the 
KDM, we set kF := k4 · u, where u is a switching parameter, which is set to u =1 
as long as the kinetochore is unattached and switches to u = 0 when it attaches. 
The backward reaction with kinetic parameter k..F := k..4 proceeds all the time. 
In the KIM, on the contrary, we assume no dependency of the forward reaction on 
the attachment status and set kF := k4. In general, more than one equation will 
be aected by the kinetochore attachment status, and they will be all regulated by 

u. We do not consider down or upregulation by a certain percentage, in agreement 
with experimental ndings (Vink et al., 2006; Musacchio and Salmon, 2007). For 
regulation of reactions proceeding with attached kinetochores only, we use the 
factor v =1 - u, as is the case in the model with p31comet contribution. 
Biochemically, the switching parameter u represents the function of dynein, which 
after microtubule attachment removes the Mad1:C-Mad2 2:2 complex from the 

76



4.4 Dynamics of dierent MCC models
kinetochore site. It might also represent potential additional functions which 
contribute to switching behavior. 

From the reaction equations, ordinary dierential equations (ODEs) are derived 
using mass action kinetics. For a set of given initial concentrations for all reaction 
partners, the ODEs are integrated until steady state is reached before attachment 
(phase 1). Then u switches from 1 to 0 and the resulting set of equations is again 
integrated until steady state is reached (phase 2). For consistency and comparability of all models we use the same initial concentrations (c.f. Table 4.1). The actual 
values are chosen according to data from the literature. When only a certain 
range was known, we have used dierent starting values for our computations, but 
we did not nd qualitatively diering trajectories. The kinetic constants are also 
taken from literature as far as they are known (Table 5.2). For all other constants 
(k2,k3,k5,k7,k8, see Table 5.2), several computations with values representing the 
whole physiologically reasonable parameter range are compared. The trajectories 
are discussed in corresponding gures. They all show a continuous dependence 
of the parameters used. Criteria for comparison of the ability of the model to 
show acceptable switching behaviour are the level of MCC depletion and Cdc20 

increase and the recovery time after the metaphase to anaphase transition. 

4.4 Dynamics of dierent MCC models 
4.4.1 Kinetochore dependent MCC model (KDM) 
The Template model (DeAntoni et al., 2005a) for the Cdc20:C-Mad2 complex 
formation can be regarded as a seeding reaction to MCC assembly. In our recent 
mathematical description and simulation analysis of the Template model (Chapter 3), we found that for realistic Mad2 concentrations, Cdc20 cannot be se-
questered completely in the cell by Mad2 alone. In addition to binding to Mad2, 
Cdc20 also binds to BubR1 (Bolanos-Garcia et al., 2005; Davenport et al., 2006; 
Chen, 2002b; Fang, 2002) and it might be this protein which sequesters the 
remaining part of Cdc20. We therefore added to the reaction equations of the 

77



4. MODELING MCC ASSEMBLY
Figure 4.1: Schematic networks of MCC models. Black lines represent the 
kinetochore dependent (KDM) and the kinetochore independent (KIM) models. 
The KDM is obtained for u inside the green circles being = 1 for phase 1 before 
kinetochore attachment, and = 0 for phase 2 after attachment. In the KIM, in 
contrast, u inside the green circles is = 1 in both phases. The red lines represent 
the amplication reactions as dened in section 4.4.3. For biochemical details see 
text. 

78



4.4 Dynamics of dierent MCC models
Template model (Eqs. (4.1)-(4.3), Chapter 3) those reaction equations describing 

the interaction with BubR1. The reaction scheme is presented in Figure 4.1 and 

the reaction rules (4.1)-(4.6) are listed below. The BubR1 reaction equations 

(4.4) for MCC formation and (4.5) for complexation with Bub3 and Cdc20 were 
deduced from experimental work (Sudakin et al., 2001; Davenport et al., 2006; 
Fang, 2002). Reaction (4.6) and its low rate were mentioned by Musacchio and 
Salmon (2007) (see also Fang (2002); Davenport et al. (2006)). 
u 

Mad1:C-Mad2 + O-Mad2 . 
k1
*Mad1:C-Mad2:O-Mad2 * (4.1)

..--..

k..1 

u

Mad1:C-Mad2:O-Mad2 * + Cdc20 k2
Cdc20:C-Mad2 + Mad1:C-Mad2 (4.2)

- ... 

k3

Cdc20:C-Mad2 O-Mad2 + Cdc20 (4.3)

- ... 

u 

Cdc20:C-Mad2 + Bub3:BubR1 . 
k4
*MCC (4.4)

..--..

k..4 

u 

Cdc20 + Bub3:BubR1 . 
k5
*Bub3:BubR1:Cdc20 (4.5)

..--..

k..5 

k6

Cdc20 + O-Mad2 Cdc20:C-Mad2 (4.6)

- ... 

The corresponding dierential equations are listed in Appendix A, Eqs. (C.1)
(C.8). The rst two reactions (4.1) and (4.2) are kinetochore controlled and 
therefore the rates are multiplied by the switching parameter u. In the reaction 
scheme we assume that also the BubR1 forward reactions (4.4) and (4.5) are 
kinetochore dependent so that also rates k4 and k5 are multiplied by u. Most 
concentrations and rates of this reaction scheme were taken from literature (listed 
in Table 4.1 and Table 5.2). For k4 we chose a high rate of 107 M..1 s..1 similar to 
k1 and k2 since only for high values of k4 high amounts of MCC would be formed. 
Nevertheless, we analysed the consequences of lower values of k4 (see below). k5 
should be considerably smaller than k4 and was chosen to be 104 M..1 s..1 . Below, 
also the in
uence of larger values of k5 was studied. The backward reactions k..4 
and k..5 should be slow and in the range of the experimental values of k..1; we 
put k..4 =0:02 s..1 and k..5 =0:2s..1 (see Table 5.2). For these kinetic data, 
we calculated the time-dependent values of all species concentrations. Here we 

79



4. MODELING MCC ASSEMBLY
focus our discussion on the dynamics of the Cdc20 and MCC concentrations. In 
Figure 4.2, the Cdc20 concentration is plotted for three dierent values of k3 
and ve dierent values of k2. With increasing values of k3, we observed faster 
switching behavior. For k3 =0:01 s..1, switching is already considerably fast, 
consistent with the ndings for the Template model. k2 hardly in
uenced the 
Cdc20 concentration when being larger than 107 M..1 s..1 . For no parameter value 
combination of k2 and k3 could Cdc20 be sequestered completely. Instead, for low 
values of k3 and high values of k2, Cdc20 concentration was reduced to slightly 
more than half and other parameter value combinations reduced it even less. The 
MCC shows fast switching behavior in all cases considered (see Figure 4.2). 

In Figure 4.3a, we show the time course of the concentrations of all eight species 
in the model for the physiologically relevent parameters k2 = 107M..1 s..1 and 
k3 =0:01s..1 . It is interesting to note that [Bub3:BubR1] does not decay to zero 
to sequester more Cdc20 into MCC. There is also virtually no Bub3:BubR1:Cdc20 
formed. Instead, about 15% of the Bub3:BubR1 concentration remains freely 

oating in the cell plasma. Another interesting feature is exhibited by the 
Mad1, Mad2, and Cdc20 dynamics. As there is virtually no Mad1:C-Mad2:OMad2* formed, this complex shows its property as short living intermediate 
in the reactions (4.1) and (4.2), clearly catalysed by Mad1:C-Mad2, staying at 
constant concentration of 0:5 10..7 M and transforming O-Mad2 plus Cdc20 into 

· 

Cdc20:C-Mad2. Immediately after switching at 2000 s, the MCC releases at a 
fast rate Cdc20:C-Mad2, which rst increases, but shortly afterwards decays into 
its components. 

80



4.4 Dynamics of dierent MCC models
0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
a1) k3 = 0.001 s..1 a2) k3 = 0.001 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
b1) k3 = 0.01 s..1 b2) k3 = 0.01 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
c1) k3 = 0.1 s..1 c2) k3 = 0.1 s..1 

Figure 4.2: Kinetochore dependent MCC model (KDM). For three dierent 
k3..values, the time evolution within phase 1 before attachment (0-2000 s) and 
within phase 2 after attachment (2000-4000 s) of Cdc20 (a1-c1) and MCC (a2c2) are shown for ve dierent k2..values (colored lines). Solutions are nearly 
independent of k2 for k2 = 107 M..1 s..1 . Whereas switching behaviour for MCC 
is satisfactory for any k3, Cdc20 recovery time becomes short enough only for 
k3 = 0:01 s..1 . 

81 


4. MODELING MCC ASSEMBLY
0500100015002000250030003500400000.511.52x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20
a) Kinetochore dependent model (KDM)


0500100015002000250030003500400000.511.52x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20
b) Kinetochore independent model (KIM) 

Figure 4.3: Species concentrations for KDM (a) and KIM (b). For k2 = 107M..1 s..1 
and k3 =0:01s..1, the time evolution of all eight species in the MCC assembly 
models are shown before (phase 1, t =0 - 2000 s) and after attachment (phase 
2, t = 2000 - 4000 s). Bub3:BubR1 is noy totally used up to sequester Cdc20. 
Mad1:C-Mad2 shows its function as a catalyzer for Cdc20:C-Mad2 production. 
Time evolution is identical in KDM (a) and KIM (b) before t = 2000 s, but 
quantitatively and qualitatively ([Cdc20:C-Mad2]) dierent after that. Details see 
text. 

82 


4.4 Dynamics of dierent MCC models
4.4.2 Kinetochore independent MCC model (KIM) 
The line of biochemical reactions placing MCC formation under the control 
of the kinetochore are not clear (reviewed by Musacchio and Salmon (2007)). 
MCC formation might be kinetochore independent (Poddar et al., 2005; Fraschini 
et al., 2001; Meraldi et al., 2004). We therefore analysed a modied kinetochore 
independent model in which the reaction equations (4.4) and (4.5) are now replaced 
by u{independent equations (4.7) and (4.8) (see Figure 4.1): 

k4

Cdc20:C-Mad2 + Bub3:BubR1 )*- MCC (4.7)

..-

k..4 

k5

Cdc20 + Bub3:BubR1 )*- Bub3:BubR1:Cdc20 (4.8)

..-

k..5 

The resulting dierential equations are the same as in Appendix A, Eqs. (C.1)
(C.8), except for the kinetic constants k4 · u and k5 · u, which have to be replaced 
by k4 and k5, respectively. Using the same initial concentrations (Table 4.1) 
and rate values (Table 5.2) as above we calculated the time dependent model 
behavior. Of course, until kinetochore attachment, both, time dependence and 
concentrations are unchanged since u = 1. After attachment, however, we found 
very slow switching and Cdc20 and MCC concentration changes only for larger 
k3. Even for large k3, Cdc20 recovery and MCC depletion were not complete (see 
Figure 4.4). The quantitative failure of this reaction model indicates that the 

BubR1 reactions are kinetochore controlled. 

As already done for the KDM, we show the concentration over time curves for all 
eight species in the KIM for k2 = 107M..1 s..1 and k3 =0:01s..1 in Figure 4.3b. The 
characteristic features of the catalyzing reactions (4.1) and (4.2) involving Mad1 
remain the same, but there is a drastic qualitative change in the concentration 
dynamics of Cdc20:C-Mad2, which decreases immediately after switching, because 
without kinetochore control it still restores MCC (Eq. 4.7) besides decaying into 
its components (Eq. 4.3). There is thus not only a quantitative change resulting 
in a slower dynamics, but also a qualitative change in the time evolution of the 
trajectory of [Cdc20:C-Mad2]. 

83 


4. MODELING MCC ASSEMBLY
0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
a1) k3 = 0.001 s..1 a2) k3 = 0.001 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
b1) k3 = 0.01 s..1 b2) k3 = 0.01 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
c1) k3 = 0.1 s..1 c2) k3 = 0.1 s..1 

Figure 4.4: Kinetochore independent MCC model (KIM). Same representation as 
in Figure 4.2. Concentration curves in phase 1 before attachment (0-2000 s) are 
identical to those in Figure 4.2, whereas in phase 2 after attachment (2000-4000 
s) the parameter u (in the green circle in Figure 4.1) is still set to u = 1 (no 
kinetochore control). As a consequence, switching is very slow. Furthermore, 
Cdc20 recovery and MCC depletion levels are poor. 

84



4.4 Dynamics of dierent MCC models
4.4.3 Amplication eects 
DeAntoni et al. (2005a) hypothesized that in analogy to the reactions based on 
Mad1 (Eqs. (4.1) and (4.2)), Cdc20:C-Mad2 can also be formed by reactions 
catalyzed by O-Mad2 and Cdc20 in a two step mechanism as described by the two 
reaction equations (4.9) and (4.10). This additional pathway for the production of 
Cdc20:C-Mad2 results in a signal amplication for the MSAC since Cdc20:C-Mad2 
now is produced not only at the location of Mad1 at the kinetochore but at a 
larger number of locations everywhere in the cell. We checked the eect of this 
assumption by adding two additional reactions to the Template model, but we 
found no improvement of the Template model behavior (Chapter 3). Also here, 
we added the two reaction equations (4.9) and (4.10) to the KDM and analysed 
the in
uence of the amplication on the model (see Figure 4.1, red arrows). 

Cdc20:C-Mad2 + O-Mad2 . 
k7. Cdc20:C-Mad2:O-Mad2 * (4.9)

--

k..7 

Cdc20:C-Mad2:O-Mad2 * + Cdc20 k8 2 Cdc20:C-Mad2 (4.10)

- ... 

When calculating the time-dependent Cdc20 and MCC concentrations, we observed 
hardly any change for small values of k7 and k8 (see Figure 4.5, a1-a2) compared 
to the KDM (Figure 4.2, b1-b2). This result was expected since for small rates, 
reactions (4.9) and (4.10) do not contribute to the model behavior. When, however, 
the rates adopt values in the realistic range (k7 =k8 = 106 M..1 s..1, see Table 5.2), 
we observed only little Cdc20 recovery after kinetochore attachment (see Figure 4.5, 
b1-b2). This result is due to both reactions being independent of kinetochore 
control. The MCC concentration is hardly in
uenced by these reactions, since 
they do not contribute to MCC regulation. 

It might be speculated that also the amplication reactions might be somehow 
kinetochore dependent. When multiplying the rates k7 and k8 by a switching parameter u (controlled case), we observed the same model behaviour (see Figure 4.5, 
c1-c2 for fast amplication reaction). as for the KDM without amplication (Figure 4.2, b1-b2). For slow amplication reactions, the concentration curves (gures 

85



4. MODELING MCC ASSEMBLY
not shown) are virtually identical to those in the uncontrolled case (Figure 4.5, 
a1-a2). 

4.4.4 p31comet contributions 
The negative spindle checkpoint regulator p31comet is a Mad2 ligand. Its negative 
eect on the MSAC is based on its competition with O-Mad2 for C-Mad2 binding (Habu et al., 2002; Xia et al., 2004; Mapelli et al., 2006; Yu, 2006). It forms 
triple complexes with C-Mad2 and either Mad1 or Cdc20 (Xia et al., 2004; Vink 
et al., 2006; Mapelli et al., 2006). In our analysis of the Template model (Chapter 3), we added a reaction describing the eect of p31comet . We could show that, 
when p31comet is activated at microtubule attachment to the kinetochores, it can 
function as a cellular factor contributing to the checkpoint switching behavior: 
p31comet function can replace the switching parameter u. Here, we introduced the 
same p31comet reactions (4.17) and (4.18) to the KDM: 

Mad1:C-Mad2 + O-Mad2 
k1 Mad1:C-Mad2:O-Mad2 * (4.11)

)*..

..-

k..1 

k2

Mad1:C-Mad2:O-Mad2 * + Cdc20 -. Cdc20:C-Mad2 + Mad1:C-Mad2 (4.12) 

k3

Cdc20:C-Mad2 O-Mad2 + Cdc20 (4.13)

- ... 

u 

Cdc20:C-Mad2 + Bub3:BubR1 . 
k4
*MCC (4.14)

..--..

k..4 

u 

Cdc20 + Bub3:BubR1 . 
k5
*Bub3:BubR1:Cdc20 (4.15)

..--

k..5- 
k6

Cdc20 + O-Mad2 Cdc20:C-Mad2 (4.16)

- ... 

v

k7p


Mad1:C-Mad2 + p31 )*Mad1:C-Mad2:p31 (4.17)

- -..

k..7p 

v

k8p


Cdc20:C-Mad2 + p31 )*Cdc20:C-Mad2:p31 (4.18)

- -..

k..8p 

This corresponds to the dierential equations Eqs. (C.18)-(C.28) in Appendix 
C, where v =1 - u. Reaction equations (4.11) and (4.12) are now kinetochore 
uncontrolled (no multiplication of the rates by u). However, MCC formation (4.14) 

86



4.4 Dynamics of dierent MCC models
0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
a1) slow (k7 =k8 = 104 M..1s..1) a2) slow (k7 =k8 = 104 M..1s..1) 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
b1) fast (k7 =k8 = 106 M..1s..1) b2) fast (k7 =k8 = 106 M..1s..1) 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
c1) fast (k7 =k8 = 106 M..1s..1) c2) fast (k7 =k8 = 106 M..1s..1) 

Figure 4.5: Amplication eects. Here, k3 = 0.01. For slow (a1, a2) and fast (b1, 
b2, c1, c2) amplication reaction rates, the concentration curves for Cdc20 and 
MCC show fast switching behaviour in the uncontrolled (a1/2-b1/2) as well as in 
the controlled (c1-c2) case, where rates k7 and k8 are multiplied by u. Only for 
fast (k7 =k8 = 106 M..1 s..1) amplication reaction rates in the uncontrolled case, 
Cdc20 does not recover to the maximal level (b1). 

87



4. MODELING MCC ASSEMBLY
and the BubR1 reaction (4.15) are not linked to p31comet function, so that these 
reactions remain kinetochore controlled with rates multiplied by the switching 
parameter u. Thus, the reaction scheme (Eqs. (4.11) -(4.18)) remains kinetochore 
dependent. We studied the in
uence of p31comet on the behavior of this model 
and observed, as for the Template model (Chapter 3), that u in reactions (4.1) 
and (4.2) can be replaced by p31comet function without changing the behavior 
of Cdc20 and MCC (data not shown). In this respect, the switching parameter 
u additionally represents p31comet function and further potentially unidentied 
reactions by additional proteins. An example could be UbcH10 (Townsley et al., 
1997), which plays a role in checkpoint inactivation (Reddy et al., 2007). Also 
other eects like protein activation, inhibition, or degradation might contribute 
to u. 

When keeping the original KDM (with reactions (4.1) and (4.2) controlled by u, 
instead of uncontrolled (4.11) and (4.12)) and including the p31comet contribution 
(Eqs. (4.17) and (4.18)), the system behaviour virtually does not change (data 
not shown). 

4.4.5 Maximum sequestering of Cdc20 
For realistic parameter values, Cdc20 cannot be totally sequestered in the MCC 
models analysed. As shown in in vitro assays (Fang, 2002), complete Cdc20 
binding is obtained when the Mad2 concentration is increased to at least eightfold beyond experimentally measured physiological values. Figure 4.6 shows 
that indeed for eight-fold higher Mad2 concentrations, the Cdc20 concentration 
decreased down to zero for low values of k3 and high values of k2 in our simulation 
of the KDM, while the MCC concentration slightly increased independently of 
k3. The MCC concentration increased since there is more Cdc20:Mad2 available. 
The concentration increase is limited due to limitations in the BubR1:Bub3 
concentration. 

In addition to Cdc20 reduction to zero due to high Mad2 values, Cdc20 can also 
be strongly reduced for high values of k5. In this case, most of BubR1:Bub3 
binds Cdc20 and removes it from the cell plasma. Figure 4.7 displays the low 

88



4.4 Dynamics of dierent MCC models
Cdc20 concentrations for low values of k3 and high values of k2 as well as the 
fast switching behavior of the model. However, most of BubR1:Bub3 is used{up 
for this reaction so that hardly any MCC can form (see Figure 4.7, a2, for the 
lowest value of k3). For higher k3, there is virtually no MCC assembled. Thus, 
for high values of k5, strong Cdc20 sequestering is combined with MCC depletion 
which would leave the APC uncontrolled. On the other hand, maximum MCC 
concentration was obtained for low values k5: in this case, most BubR1:Bub3 
contributes to MCC formation so that hardly any BubR1:Bub3:Cdc20 can form 
(data not shown). 

Thus, for the assumed concentrations of [Bub3:BubR1] = 1:5 10..7M and [Cdc20] 

· 

=2:2 10..7M (Table 4.1), MCC cannot sequester Cdc20 totally. In addition, the 

· 

formation of Bub3:BubR1:Cdc20 (Eq. 4.5) and Cdc20:C-Mad2 by the two step 
catalysis (Eq. 4.1 and 4.2) and the direct reaction (Eq. 4.6) are not well suited to 
sequester a considerable amount of Cdc20, as Figure 4.3a showed. We therefore 
studied the eect of the initial Bub3:BubR1 concentration on the system by 
increasing it 8-fold to 10:4 10..7 M. The result is shown in Figure 4.8. Comparing 

· 

it to Figure 4.2 with [Bub3:BubR1] = 1:3 10..7 M, we see a slightly better degree 

· 

of Cdc20 sequestering to about 45% of the initial concentration for all values of k3 
and k2 = 107 . In these cases, also [MCC] attains it maximal level of about 1:310..7 




M. The corresponding values in Figure 4.2 are depentent on k3. Also, the switching 
behaviour for both Bub3:BubR1 concentrations is comparable. Altogether, we 
conclude that the Bub3:BubR1 initial concentration has no major in
uence on 
Cdc20 sequestration. 
89



4. MODELING MCC ASSEMBLY
0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
a1) k3 = 0.001 s..1 a2) k3 = 0.001 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
b1) k3 = 0.01 s..1 b2) k3 = 0.01 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
c1) k3 = 0.1 s..1 c2) k3 = 0.1 s..1 

Figure 4.6: Maximal Cdc20 sequestering through increase of free Mad2. The 
dynamical behavior of the KDM showing the time evolution of [Cdc20] (a1-c1) 
and [MCC] (a2-c2) for the same values of k2 and k3 as in Figure 4.2. In contrast, 
here the Mad2 initial level is 8-fold increased. Cdc20 concentration decreases 
to zero for low k3 and high k2, while the MCC concentration increases slightly 
independent of k3. 

90



4.4 Dynamics of dierent MCC models
0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
a1) k3 = 0.001 s..1 c1) k3 = 0.1 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
b1) k3 = 0.01 s..1 a2) k3 = 0.001 s..1 

Figure 4.7: Maximal Cdc20 sequestering through increased BubR1 rates. The 
dynamical behavior of the KDM for k5 = 108 M..1 s..1showing low [Cdc20] for low 
k3 and high k2 (a1-c1). Obviously, most of BubR1:Bub3 binds Cdc20, but hardly 
any MCC can form (a2, for k3 = 0.001 s..1). On the other hand, good switching 
behaviour for Cdc20 is correlated to a low sequestering degree. 

91



4. MODELING MCC ASSEMBLY
0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
a1) k3 = 0.001 s..1 a2) k3 = 0.001 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
b1) k3 = 0.01 s..1 b2) k3 = 0.01 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
c1) k3 = 0.1 s..1 c2) k3 = 0.1 s..1 

Figure 4.8: KDM with 8-fold increased BubR1:Bub3 initial concentration. Same 
representation as in Figure 4.2. The comparison shows that BubR1:Bub3 initial 
concentration has no major in
uence on Cdc20 sequestration. 

92



4.4 Dynamics of dierent MCC models
0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
a1) k3 = 0.001 s..1 a2) k3 = 0.001 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
b1) k3 = 0.01 s..1 b2) k3 = 0.01 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
c1) k3 = 0.1 s..1 c2) k3 = 0.1 s..1 

Figure 4.9: KDM with 2-fold increased Free Mad2 initial concentration. Cdc20 
got maximum sequestering only for small k3 and very high k2. 

93



4. MODELING MCC ASSEMBLY
0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
a1) k3 = 0.001 s..1 a2) k3 = 0.001 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
b1) k3 = 0.01 s..1 b2) k3 = 0.01 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
c1) k3 = 0.1 s..1 c2) k3 = 0.1 s..1 

Figure 4.10: KDM with 2-fold increased Bub3:BubR1 initial concentration. Same 
representation as in Figure 4.2. The comparison shows that BubR1:Bub3 initial 
concentration has no major in
uence on Cdc20 sequestration. 

94



4.4 Dynamics of dierent MCC models
0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
a1) k3 = 0.001 s..1 a2) k3 = 0.001 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
b1) k3 = 0.01 s..1 b2) k3 = 0.01 s..1 

0100020003000400000.511.52x 10-7Time (s)
[Cdc20] (M)
k2 
105106107108109
0100020003000400000.511.52x 10-7Time (s)
[MCC] (M)
k2 
105106107108109
c1) k3 = 0.1 s..1 c2) k3 = 0.1 s..1 

Figure 4.11: KDM with 2-fold increased of both free Mad2 as well as Bub3:BubR1 
initial concentration. This demonstrates that Cdc20 can be sequestered for very 
high k2. Additionally, only the case in which MCC amount can be get about 
doubling. 

95



4. MODELING MCC ASSEMBLY
4.5 Discussion and Conclusions 
Building on our investigation (Chapter 3) of dierent models for Cdc20:Mad2 
complex formation, we have extended the mathematical description of the Template 
model by those reaction equations, which describe Cdc20 sequestration. The major 
role is played by Bub3:BubR1 and the MCC, which, in turn, blocks the APC. 
We analysed MCC formation, distinguishing a \kinetochore dependent model” 
(KDM) and a \kinetochore independent model” (KIM). The latter failed to 
describe correct metaphase to anaphase switching. Considering the KDM under 
realistic conditions, Cdc20 is not sequestered completely but instead remains 
in the cell plasma to a considerable amount. Complete Cdc20 binding is either 
attained for unrealistically high concentrations of Mad2 or for high rate values 
of BubR1:Bub3:Cdc20 formation; the latter, however, sacrifying MCC formation 
and thus APC control. The behaviour of the KDM is virtually independent of the 
Bub3:BubR1 initial concentration. Amplication eects or a detailed desciption 
of p31comet contribution did not improve the situation. These results indicate 
that, on the basis of the reactions considered here, the MSAC regulation does not 

function through Cdc20 sequestration. 

Extending previous work (Sear and Howard, 2006; Doncic et al., 2005) based on 
partial dierential equations, Doncic et al. (2006) showed in an analysis based on 
ordinary dierential equations that MSAC can act through Cdc20 sequestration. 
Investigating statistical error propagation in two models describing abstract 
kinetochore mediated inhibition mechanisms, they exclude that Cdc20 is inhibited 
solely by protein degradation. However, both mechanisms, sequestration and 
degradation, can act in parallel showing almost linear behaviour in combination. 
Their model includes only two species, Cdc20 and an abstract signalling complex 
m which could be Mad2 or another sequestering molecule. This comes very close 
to our analysis (Chapter 3) of the Template model, where we found complete 
sequestering of Cdc20 as conrmed by in vitro assays (Fang, 2002), but only 

for unphysiological parameter sets. The same holds true for this investigation 
(Figures 4.6, c1, d1, and 4.7, a1, b1). 

96 


4.5 Discussion and Conclusions
Which complexes Bub3:BubR1 is able to form, is a crucial question for MCC 
formation. It is a general problem of simulation studies to identify all reaction 
schemes and to incorporate them with the correct reaction kinetics. In general, 
our study can help to falsify assumptions, but can hardly proof the correctness 
of a pathway (Popper, 1935). In our analysis, we have found that the KIM is 
very unlikely to describe MCC assembly, but that the KDM could be a basis for 
further pathway design. 

In our model, we analysed the in
uence of Cdc20 sequestration on MSAC operation 
(Musacchio and Salmon, 2007). In how far partial inhibition of the APC by 
the MSAC is tolerable by cell cycle control, is currently unclear. As the basic 
reactions, described here and previously (Chapter 3), do not lead to complete 
Cdc20 sequestration, we speculate that the MCC binds and completely blocks 
the APC. APC activation might then be a consequence of a MCC:APC complex 
modication or rearrangement. To investigate the further reaction scheme for 
checkpoint function, we have integrated the \kinetochore dependent model” (KDM) 
investigated here into a model describing APC inhibition and APCCdc20 formation 
after metaphase to anaphase transition, which should be the basis of more complex 
investigations. The \tightness” of the APC control might be a topic of these 
future studies. 

Table 4.1: Initial Concentrations for Integration 

Species Initial Comments and References 
Concentration 
[Cdc20] 2:2 * 10..7M Fang (2002); Howell et al. (2000b); Tang et al. (2001) 
[O-Mad2] 1:5 * 10..7M Fang (2002); Howell et al. (2000b); Tang et al. (2001) 
[Mad1:C-Mad2] 0:5 * 10..7M Luo et al. (2004); Fang (2002); Howell et al. (2000b) 
[Bub3:BubR1] 1:3 * 10..7M Fang (2002); Tang et al. (2001) 
[p31comet ] 1 * 10..6M Xia et al. (2004); Mapelli et al. (2006) 

Initial Concentrations of other species are zero.


97



4. MODELING MCC ASSEMBLY
Table 4.2: Kinetic Parameters


Parameter Value or Range Comments and References


k1 2 * 105 M..1 s..1 Vink et al. (2006) 
k..1 0:2s..1 Vink et al. (2006) 
k2 105 , 106 , 107 , 108 , 109 M..1 s..1 Chapter 3 
k3 10..3 , 10..2 , 10..1s..1 Chapter 3 
k4 107 M..1 s..1 This study 
k..4 0:02 s..1 This study 
k5 104 , 108 M..1 s..1 This study 
k..5 0:2s..1 This study 
k6 103 M..1 s..1 Musacchio and Salmon (2007) 
k7 104 
(slow), 106 
(fast) M..1 s..1 This study 
k..7 0:2s..1 This study 
k8 104 
(slow), 106 
(fast) M..1 s..1 This study 
k7p 1:7 * 106 M..1 s..1 Vink et al. (2006) 
k..7p 0:037 s..1 Vink et al. (2006) 
k8p 105 M..1 s..1 This study 
k..8p 0:3s..1 This study 

98



\There is no way in which a simple substance could begin 
in the course of nature, since it cannot be formed by 
means of compounding". Gottfried Leibniz (1646 -1716) 

\In mathematics you don't understand things. You just 
get used to them". Johann von Neumann (1903 -1957) 

Chapter 5 
Modeling APC Control 

Contents 

5.1 Summary .......................... 100


5.2 Biochemicalbackground ................. 100


5.2.1 Mad2TemplateModel.................. 101


5.2.2 MCCAssembly...................... 101


5.2.3 APCInhibition ...................... 102


5.2.4 ControlbyAttachment ................. 103


5.2.5 ChemicalReactionScheme . . . . . . . . . . . . . . . 104 

5.2.6 Mathematical Treatment and Simulation . . . . . . . 105 

5.3 Results............................ 107


5.3.1 MSACModelBehavior .................. 109


5.3.2 Model Validation by Mutation Experiments . . . . . . 115 

5.4 Discussion.......................... 119


99



5. MODELING APC CONTROL
5.1 Summary 
We have constructed and validated for the human MSAC mechanism an in silico 
dynamical model, integrating 11 proteins and complexes. The model incorporates 
the perspectives of three central control pathways, namely Mad1/Mad2 induced 
Cdc20 sequestering based on the Template Model (Chapter 3), MCC formation 
(Chapter 4), and APC inhibition. Originating from the biochemical reactions for 
the underlying molecular processes, non-linear ordinary dierential equations for 
the concentrations of 11 proteins and complexes of the MSAC are derived. Most 
of the kinetic constants are taken from literature, the remaining four unknown 
parameters are derived by an evolutionary optimization procedure for an objective 
function describing the dynamics of the APC:Cdc20 complex. MCC:APC dissociation is described by two alternatives, namely the \Dissociation” and the \Convey” 
model variants. The attachment of the kinetochore to microtubuli is simulated 
by a switching parameter silencing those reactions which are stopped by the 
attachment. For both, the Dissociation and the Convey variants, we compare two 
dierent scenarios concerning the microtubule attachment dependent control of 
the dissociation reaction. Our model is validated by simulation of ten perturbation 
experiments. Only in the controlled case, our models show MSAC behaviour at 
meta-to anaphase transition in agreement with experimental observations. Our 
simulations revealed that for MSAC activation, Cdc20 is not fully sequestered; 

instead APC is inhibited by MCC binding. 

5.2 Biochemical background 
Our model incorporates three MSAC -related mechanisms: the Template Model, 
the (kinetochore dependent) MCC formation, and the APC inhibition. Their 
biochemical details will be explained in the following. 

100 


5.2 Biochemical background
5.2.1 Mad2 Template Model 
DeAntoni et al. (2005a) proposed the \Template Model” explaining the mechanism 
of Mad2 recruitment to the kinetochore during checkpoint activation and subsequent transfer to sequester Cdc20. Recent work by Vink et al. (2006) and Mapelli 
et al. (2006) provide additional support for the Template Model. Moreover, this 
model has been conrmed by Nezi et al. (2006), and is entirely consistent with 
recent Fluorescence Recovery After Photobleaching (FRAP) data (Vink et al., 
2006). The Template Model (DeAntoni et al., 2005a) is superior and more solid 
than the Exchange Model (Luo et al., 2004), which we conrmed in a recent in 
silico study (for comparison and details see Chapter 3). 

The Mad2 Template Model is described by the reaction equations Eqs. (5.1)-(5.3) 
(see chemical reaction scheme, below). It is assumed that Mad1 and C-Mad2 
form a stable core complex Mad1:C-Mad2 at unattached kinetochores (DeAntoni 
et al., 2005a). In our nonlinear ordinary dierential equations (ODEs) model, 
we assume that this process has already been completed. Therefore, there is no 
free Mad1. Equation (5.1) describes how the Mad1:C-Mad2 core complex binds 
additional molecules of O-Mad2 through formation of conformational heterodimers 
between the C-Mad2 subunit of the Mad1:C-Mad2 complex and O-Mad2. Upon 
Mad1:C-Mad2 binding, O-Mad2 adopts an intermediate conformation (O-Mad2*), 
which can quickly and eciently bind Cdc20 and switch to the C-conformation. 
This process is documented by Eq. (5.2): Cdc20 binding to the complex Mad1:CMad2:O-Mad2* leads to the conversion of O-Mad2* to C-Mad2 forming together 
with Cdc20 the complex Cdc20:C-Mad2; Cdc20:C-Mad2 is assumed then to 
dissociate off Mad1:C-Mad2 (Fang, 2002). Finally, we assume that the Cdc20:C

Mad2 complex can dissociate into Cdc20 and O-Mad2 (Eq. (5.3)). 

5.2.2 MCC Assembly 
Equations (5.4) and (5.5) describe the formation of the MCC, which contains 
Mad2, Bub3, BubR1 and Cdc20 in apparently equal stoichiometries (Sudakin 
et al., 2001; Hardwick et al., 2000; Millband and Hardwick, 2002; Chung and Chen, 

101



5. MODELING APC CONTROL
2003). Bub3 associates quite stably with BubR1 (Sudakin et al., 2001; Taylor et al., 
2004, 1998a). This interaction is constitutive and is required for the localization 
of BubR1 to the kinetochores during mitosis. Like for the Mad1:C-Mad2 complex, 
we do not model the dynamics of the formation of the BubR1:Bub3 complex. 
BubR1 cannot bind Mad2 directly (Fang, 2002). Moreover, BubR1 does not 
form a ternary complex with Mad2 and Cdc20. Two Cdc20 binding sites were 
identied on BubR1 (Bolanos-Garcia et al., 2005; Davenport et al., 2006). Binding 
of the N-terminal region of BubR1 to Cdc20 requires prior binding of Mad2 to 
Cdc20 (Davenport et al., 2006). Consistently, the Bub3:BubR1 complex can bind 
to Cdc20:C-Mad2 in order to form the MCC (Eq. (5.4), rate constants k4 and k-4). 
The other site of BubR1 (between residues 490 and 560) can bind Cdc20 tightly 
regardless of Mad2 being bound to Cdc20 (Davenport et al., 2006). Thus, BubR1 
can form a ternary complex with Bub3 and Cdc20 (Eq. (5.5)) which however 
has no inhibitory activity at the APC (unpublished data (Sudakin et al., 2001)). 

Equation (5.6) and its low rate were mentioned Musacchio and Salmon (2007) 
(details are discussed in Chapter 4). 

5.2.3 APC Inhibition 
The MCC is considered to be essential for MSAC function, because it binds and 
inhibits the APC (see Chapter 2) However, MCC inhibits only the mitotic, and not 
the interphase APC (Pinsky and Biggins, 2005). The interaction between APC 
and MCC is quite labile in the absence of unattached kinetochores (Sudakin et al., 
2001). How the MCC inhibits APC activity is poorly understood (Musacchio and 
Salmon, 2007). The MCC might bind to the APC as a pseudosubstrate due to a 
KEN-box motif in BubR1 (Fang, 2002; Morrow et al., 2005; Burton and Solomon, 
2007; King et al., 2007). This indicates that the MCC needs to disassemble from 
the APC at metaphase to elicit anaphase (Morrow et al., 2005; Fang, 2002). Bub1 
and Aurora-B kinase contribute directly to the formation of a complex of the MCC 
with the APC (Morrow et al., 2005) (represented by k7 in Eq. (5.7)). Unattached 
kinetochores might sensitize the APC for inhibition by the MCC (Sudakin et al., 
2001; Chan et al., 2005; Doncic et al., 2005; Sear and Howard, 2006) (represented 

102



5.2 Biochemical background
by u in Eq. (5.7), see below). In addition to kinetochore attachment, tension 
is important for MSAC inactivation (Nicklas et al., 1995; Nicklas, 1997): if both 
sister kinetochores attach to microtubules from the same pole, not enough tension 
is generated and microtubules kinetochore attachment is destabilized to correct 
the problem (Musacchio and Salmon, 2007). This destabilization depends on 
Aurora-B kinase (Hauf et al., 2003; Pinsky and Biggins, 2005; Tanaka et al., 
2002; Lampson et al., 2004). Again, these eects are subsumed by the switching 
parameter u. For complex dissociation we consider two model variants: 

In the \Dissociation variant", we assume that MCC binds to APC and that this 

binding is reversible (Eq. (5.7)). Free Cdc20 has to bind reversibly to APC (Eq. 
(6.7a)), eectively competing with MCC. 

In the \Convey variant", we do not assume that the APC:MCC complex simply 
dissociates into APC and MCC, but that the MCC complex falls apart so that 
the Cdc20 contained in the MCC complex can bind to the APC (Eq. (6.7b)). 

5.2.4 Control by Attachment 
Several reactions in the reaction scheme are controlled by the attachment of 
microtubules to the kinetochore which is realized by the factor u present in several 
reaction equations (Chapter 3). Factor u represents the function of proteins like 
p31comet , UbcH10, and Dynein (and its activator Spindly (Gris et al., 2007)). 
p31comet prevents further Mad2 turnover on Mad1 and neutralizes the inhibitory 
activity of Cdc20-bound Mad2 (Habu et al., 2002; Xia et al., 2004; Mapelli et al., 
2006; Yang et al., 2007). Catalytically active UbcH10 can promote the release 
of checkpoint proteins from APC (Reddy et al., 2007). Dynein (Howell et al., 
2001) removes the Mad1:C-Mad2 2:2 complex from the kinetochore site after 
microtubule attachment. Thus, p31comet , UbcH10, and Dynein work in concert 
during checkpoint inactivation. 

Also the MCC:APC complex dissociation might be attachment controlled. We 
therefore introduced the factor u. in Eq. (6.7a) and Eq. (6.7b), allowing us to 
compare the uncontrolled (u0= 1) with the controlled (u0= 0 before and u0=1 

103



5. MODELING APC CONTROL
after attachment) case. The switching parameter u. might represent the protein 
function of Usp44, which deubiquitinates the APC co-activator Cdc20 both in 
vitro and in vivo, and thereby directly counteracts the APC-driven disassembly of 
Mad2:Cdc20 complexes (Stegmeier et al., 2007; Diaz-Martinez and Yu, 2007). 

5.2.5 Chemical Reaction Scheme 
In our model of the MSAC mechanism, 9 biochemical reaction equations describe 
the dynamics of the following 11 species: Mad1:C-Mad2, O-Mad2, Mad1:CMad2:O-Mad2*, Cdc20, Cdc20:C-Mad2, Bub3:BubR1, MCC, Bub3:BubR1:Cdc20, 
APC, MCC:APC, and APC:Cdc20. Because the dissociation of the MCC:APC 
complex is not known in detail, we introduce two variants for the reaction equation 
for MCC:APC dissociation. 

The Dissociation variant is dened by the following reaction rules (Figure 5.1, red 
lines): 

Mad1:C-Mad2 + O-Mad2 . 
k1:u. Mad1:C-Mad2:O-Mad2 * (5.1)

- --

k..1 

k2:u

Mad1:C-Mad2:O-Mad2 * + Cdc20 ....... Cdc20:C-Mad2 + Mad1:C-Mad2 (5.2) 

k3

Cdc20:C-Mad2 O-Mad2 + Cdc20 (5.3)

-..... 

k4:u 

Cdc20:C-Mad2 + Bub3:BubR1 ). MCC (5.4)

- --

k..4 

k5:u 

Cdc20 + Bub3:BubR1 ). Bub3:BubR1:Cdc20 (5.5)

- --

k..5 

k6

Cdc20 + O-Mad2 Cdc20:C-Mad2 (5.6)

-..... 

k7:u

MCC + APC ....... MCC:APC (5.7) 

k..7:u0

MCC:APC ....... APC + MCC (6.7a) 
k8

APC + Cdc20 . APC:Cdc20 (5.8)

..--. 

k..8- 

104



5.2 Biochemical background
The reaction rules dening the second variant, the Convey variant, are dierent from this set by replacing the back reaction Eq. (6.7a) by Eq. (6.7b) (see 
Figure 5.1, green lines): 

k..7:u0

MCC:APC ....... APC:Cdc20 + O-Mad2 + Bub3:BubR1 (6.7b) 

Both variants are controlled by the switching parameters u and u0. They represent 
a signal generated by the unattached and attached kinetochores, respectively. If 
the kinetochore is unattached, we set u = 1, otherwise u= 0. For instance, 
formation of Mad1:C-Mad2:O-Mad2* (Eq. 5.1) can only take place as long as the 
kinetochores are unattached (DeAntoni et al., 2005a). 

The switching parameter u. represents an additional hypothetical control, whose 
biochemical realization is described above. For each of the two resolution pathways, 
we therefore considered two scenarios: In the rst, we assume that this control 
does not exist by setting u0= 1. In the second, we assume that there is a control 
by setting u0=1 - u. This is summarized in Table 5.1: 

Model Variants 

Scenario Model Reaction rules Control of MCC:APC 
variants dissociation 

Uncontrolled Dissociation Eqs. (5.1)-(5.7), (6.7a), (5.8) u0=1 

Controlled Dissociation Eqs. (5.1)-(5.7), (6.7a), (5.8) u0=1..u 

Uncontrolled Convey Eqs. (5.1)-(5.7), (6.7b), (5.8) u0=1 

Controlled Convey Eqs. (5.1)-(5.7), (6.7b), (5.8) u0=1..u 

Table 5.1: Model Variants, related equations, control status of MCC:APC dissociation. 

5.2.6 Mathematical Treatment and Simulation 
By applying general principles of mass-action kinetics, we converted the reaction 
rules into sets of time dependent nonlinear ordinary dierential equations (ODEs) 
for the Dissociation variant (Appendix D, Eqs. (D.1)-(D.11)) and for the Convey 
variant (Appendix D, Eqs. (D.12)-(D.22)). 

105 


5. MODELING APC CONTROL
Figure 5.1: Schematic network of the MSAC model. The arrows describe the interactions between the proteins and complexes. Red lines represent the \Dissociation 
variant", green lines represents the \Convey variant", while the black arrows are 
common to both. The switching parameter u models the eect of the attachment. 
We set u= 1 for the unattached case and u= 0 for the attached case. We set 
u0= 1 for the uncontrolled scenario and u0=1 - u for the controlled scenario(see 
Table 5.1). 

106



5.3 Results
For the rate constants ki, we selected experimentally determined values, if available 
(Table 5.2). In the other cases, we selected representative values exemplifying 
their whole physiologically possible range. We also tted unspecied parameters by minimizing an APC:Cdc20 concentration dependent objective functional 
(Appendix D, D.3), taking into account the range of parameter values from experiments (Fang, 2002; Howell et al., 2000a; Tang et al., 2001; Vink et al., 2006; 

Musacchio and Salmon, 2007). 

In a typical simulation, we initialized all reaction partners according to Table 5.2 
and numerically integrated the ODEs until steady state was reached using u= 1 
(denoting unattached kinetochores). Then we set u= 0 (kinetochores attached) 
and continued integrating the ODEs until we again reached a steady state. 

The minimum concentration of APC:Cdc20 before attachment and the speed of 
recovery after attachment (recovery time) are criteria for MSAC function and were 
analyzed to compare the models. Deduced from the biochemical data (see above), 
the APC:Cdc20 concentration must be low before and the recovery must be fast 
after attachment. 

5.3 Results 
We developed a theoretical model of the human biochemical mitotic checkpoint 
at meta-to anaphase transition. As described in the literature, many proteins 
contribute to checkpoint function. The key players and their interactions are 
captured by the reaction equations introduced in the previous section. We 
transformed these equations into ODEs and selected specic values for the initial 
concentrations and rate constants from the literature and our previous publications 
(summarized by Table 5.2). For only four values we could not identify specic 
data in the literature. We obtained these values by optimizing the properties of 
the model according to the APC:Cdc20 level: this complex level should be low in 
metaphase and high in anaphase; furthermore, the switching should be fast (see 
Appendix D for details). We found good behavior of the model network for the 
values k7 = 108M..1 s..1,k..7 =0:08s..1,k8 =5 * 106M..1 s..1, and k..8 =0:08s..1 . 

107



5. MODELING APC CONTROL
Model parameters


Parameters Comments and References


Species initial concentration 

[Cdc20]= 2:2 * 10..7M (Fang, 2002; Howell et al., 2000a; Tang et al., 2001)
[Mad2]total =2 * 10..7M (Fang, 2002; Howell et al., 2000a; Tang et al., 2001)
[BubR1:Bub3]= 1:3 * 10..7M (Fang, 2002; Tang et al., 2001)
[APC]= 0:9 * 10..7M (Stegmeier et al., 2007)
Other species are zero


Species concentration ratios 

25% of [Mad2]total associated with (Luo et al., 2004; Fang, 2002) 
Mad1, [Mad1:C-Mad2]=25%[Mad2]total 
[O-Mad2]= 75%[Mad2]total 

Model -Parameters 

k1 =2 * 105 M..1 s..1 (Vink et al., 2006) 
k..1 =2 * 10..1 s..1 (Vink et al., 2006) 
k2 = 108M..1 s..1 Chapter 3 
k3 =1 * 10..2s..1 Chapter 3 
k4 = 107 M..1 s..1 Chapter 3 
k..4 =2 * 10..2 s..1 Chapter 3 
k5 = 104 M..1 s..1 Chapter 3 
k..5 =2 * 10..1 s..1 Chapter 3 
k6 = 103 M..1 s..1 (Musacchio and Salmon, 2007) 
k7 = 108 M..1 s..1 This study 
k..7 =8 * 10..2 s..1 This study 
k8 =5 * 106 M..1 s..1 This study 
k..8 =8 * 10..2 s..1 This study 

Table 5.2: Model parameters: Initial concentration and rate constants. 

108



5.3 Results
5.3.1 MSAC Model Behavior 
We analyzed the dynamics of the model integrating 11 proteins and complexes 
of the MSAC . The literature does not provide a clear view, yet, about how 
the MCC:APC complex dissociates resulting in APC activation. Therefore, we 
introduced two alternative reaction pathways: In the rst variant, we assume 
that the MCC:APC complex dissociate into MCC and APC (reaction Eq. (6.7a)), 
subsequently allowing the MCC to disassemble into its parts according to reaction 
Eq. (5.4) (Dissociation variant). In the second variant, the MCC component 
Cdc20 may stay in the complex with APC and only the further MCC complex 
members dissociate according to reaction Eq. ( 6.7b)(Convey variant). 

Figure 5.2 displays the APC:Cdc20 concentrations over time. For both, Dissociation and Convey variant, we have selected the time range such that each 
concentration can reach steady state. For all calculations, the concentrations and 
rates of Table 5.2 were chosen including those for k7,k8, and k..8. We varied 
the rate of k..7 (dissociation of MCC:APC) between 0.0008 and 0.08, because 
k..7 is unknown and crucial for model behavior. For both model variants, we 
distinguished 2 scenarios: in one scenario reaction Eq. (6.7a) (or Eq. (6.7b)) 
of the checkpoint is valid all the time (\uncontrolled"), while in the other case 
this reaction is silenced until it is activated by microtubule attachment to the 
kinetochore (\controlled"). This property of the controlled case is realized by 
introducing the factor u0for reaction Eq. (6.7a) and Eq. (6.7b). 

In the uncontrolled case, our model cannot explain the checkpoint behavior, 
independently of which pathway is chosen (Figure 5.2 A-B). For the Dissociation 
variant, the APC:Cdc20 concentration is low for low values of k..7, however, in 
this case the switching recovery is unrealistically slow. On the other hand, for fast 
switching, k..7 must be high resulting in an increased APC:Cdc20 concentration 
before attachment (Figure 5.2 A-B). This behavior is even worse for the Convey 
variant in the uncontrolled case (Figure 5.2 B). For low values of k..7, both 
pathways behave rather similarly; for higher values of k..7 the Convey variant is 
even less satisfying compared to the Dissociation variant. 

109 


5. MODELING APC CONTROL
The Dissociation variant The Convey variant


AB
0100020003000400000.20.40.60.81x 10-7Time (s)
[APCCdc20] (M)
k-7 
0.00080.0010.0040.0080.08
0100020003000400000.20.40.60.81x 10-7Time (s)
[APCCdc20] (M)
k-7 
0.00080.0010.0040.0080.08
uncontrolled (u0= 1) uncontrolled (u0= 1) 

CD
0100020003000400000.20.40.60.81x 10-7Time (s)
[APCCdc20] (M)
k-7 
0.00080.0010.0040.0080.08
0100020003000400000.20.40.60.81x 10-7Time (s)
[APCCdc20] (M)
k-7 
0.00080.0010.0040.0080.08
controlled (u0=1..u) controlled (u0=1..u) 

Figure 5.2: Dynamical behavior of APC:Cdc20 concentration versus time for the 
Dissociation variant (A, C) and the Convey variant (B, D) each in the uncontrolled 
(A, B) and the controlled (C, D) case. Calculation results are presented for dierent 
values of the rate k7 in [s..1], as indicated. The APC:Cdc20 concentration should be 
close to zero before attachment and should rise quickly after attachment. Spindle 
attachment occurs at t=2000s (switching parameter u from 1 to 0). Parameters 
setting according to Table 5.1 and Table 5.2. 

110



5.3 Results
In the controlled case, we introduced the factor u0(see above) regulating reaction 
Eq. (6.7a) and Eq. (6.7b), and re-calculated the model. Both pathways fully inhibit 
APC:Cdc20 before attachment and both show very fast switching recovery for 
high k..7 values (Figure 5.2 C-D). Thus, a distinction between the two pathways 
in the controlled case is not possible based on our theoretical results. We observed 
that the controlled Convey variant is slightly faster (by about 5 mins) in switching 
compared to the controlled Dissociation variant. This makes the Convey variant 
slightly superior, however, we think that this dierence is too small for a clear 
preference between the two pathways. Experimental measurements have to 
distinguish between these cases. Such experiments are in progress in our laboratory. 

In addition to the APC:Cdc20 concentration values, we also analyzed the timedependent concentrations of all reaction components. We observed dierences 
between the two pathways in the controlled case for sub-complexes like Cdc20:CMad2 and MCC (Figures 5.4 5.5). 

In our simulations, the MCC completely sequesters the APC so that no free APC 
is available until the microtubules are attached. Thus, Cdc20 has a dual function: 
until kinetochore attachment, Cdc20 contributes to MCC formation and thus 
APC inhibition, while after attachment Cdc20 acts as the APC activator. The 
eect of the switching parameter u is presented in Figure 5.3, where u varied 
between 1 and 0 for 101 time instead of two values 1 and 0. 

111



5. MODELING APC CONTROL
The Dissociation variant The Convey variant


AB
00.10.20.30.40.50.60.70.80.9100.20.40.60.811.21.4x 10-7Kinetochores signalSpecies concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2O:Mad2Cdc20Cdc20:C-Mad2Bub3:BubRMCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
00.10.20.30.40.50.60.70.80.9100.20.40.60.811.21.4x 10-7Kinetochores signalSpecies concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2O:Mad2Cdc20Cdc20:C-Mad2Bub3:BubRMCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
uncontrolled (u0= 1) uncontrolled (u0= 1) 

CD
00.10.20.30.40.50.60.70.80.9100.20.40.60.811.21.4x 10-7Kinetochores signalSpecies concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2O:Mad2Cdc20Cdc20:C-Mad2Bub3:BubRMCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
00.10.20.30.40.50.60.70.80.9100.20.40.60.811.21.4x 10-7Kinetochores signalSpecies concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2O:Mad2Cdc20Cdc20:C-Mad2Bub3:BubRMCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
controlled (u0=1..u) controlled (u0=1..u) 

Figure 5.3: Kinetochore switching signal (u and u0) on Models Simulation. The 
signal has taken for 101 increments between 0 and 1. Figures A and B for the 
controlled case. Figures C and D for the uncontrolled case. 

112



5.3 Results
TheDissociationvariant
0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
Figure 5.4: Species concentration over time for the controlled Dissociation (wild 
type). Spindle attachment occurs at t = 2000s (switching parameter u from 1 to 
0 and u0from 0 to 1). Parameters setting according to Table 5.2. 

113



5. MODELING APC CONTROL
The Convey variant


0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
Figure 5.5: Species concentration over time for the controlled Convey variants 
(wild type). Spindle attachment occurs at t = 2000s (switching parameter u from 
1 to 0 and u0from 0 to 1). Parameters setting according to Table 5.2. 

114



5.3 Results
5.3.2 Model Validation by Mutation Experiments 
In order to validate our model, we tested dierent mutations (deletion and over

expression) of the proteins and complexes involved, measured in dierent organisms 
(Table 5.3). 

Recent experimental studies report that deletion in dierent organisms of any 
of Mad2 (Nezi et al., 2006; Dobles et al., 2000; Michel et al., 2001; Fang et al., 
1998b),Mad1 (Kienitz et al., 2005; Lee and Spencer, 2004; Iwanaga et al., 2007; 
Hardwick and Murray, 1995; Chen et al., 1999b), Bub3 (Kalitsis et al., 2000; Taylor 
et al., 1998b), BubR1 (Davenport et al., 2006; Wang et al., 2004b; Schmidt and 
Medema, 2006; Hanks et al., 2004), Cdc20 (Zhang and Lees, 2001b), Bub1 (Basu 
et al., 1999; Taylor et al., 1998b), or Aurora B (Kallio et al., 2002b; Biggins and 
Murray, 2001; Cheeseman et al., 2002) resulted in MSAC defects like premature 
sister-chromatid separation, no mitotic arrest, reduced partner binding, increase 
of polyploidy, or death. Experimental details and our model predictions are in 
qualitative agreement as summarized in Table 5.3: For example, over-expression 
of Mad2 (He et al., 1997; DeAntoni et al., 2005a) activates the MSAC resulting in 
mitotic arrest, while over-expression of Cdc20 (Hwang et al., 1998) allows cells 
to exit from mitosis, however with a depolymerized spindle or damaged DNA. 
Deletion of any of the APC subunits Cdc26, Apc9, Cdc6 or Doc1 disrupts complex 
association (Passmore, 2004b; Boronat and Campbell, 2007) with no anaphase 
initiation. We observed that deletions and/or over-expression of proteins, realized 
experimentally or in our model, change checkpoint function in the same way. 

For the essential checkpoint proteins, Mad2 and Cdc20, we present the mutation 
eect on our model in detail in Figure 5.6 for the Convey variant. The eect is 
basically the same for the Dissociation variant (Figure 5.7). For Mad2 or Cdc20 
deletion, the concentrations of all model components are rather stable, that is, 
they are almost not aected by microtubule attachment. However, in the case 
of Mad2 deletion, the APC:Cdc20 concentration is high (Figure 5.6 A) while 
for Cdc20 deletion this concentration is zero by denition (Figure 5.6 C). In the 
case of Mad2 or Cdc20 over-expression, many component concentrations were 
aected. In particular, for Mad2 over-expression the APC:Cdc20 concentration 

115



5. MODELING APC CONTROL
remains low before and signicantly lower than in the wild type after attachment, 
explaining mitotic arrest and the delay of exit from mitosis (Figure 5.6 B). In 
contrast, for Cdc20 over-expression, the APC:Cdc20 concentration is high before 
and after attachment (Figure 5.6 D) resulting in total checkpoint failure. Thus, 
our MSAC model is able to explain the presented mutation phenotypes (Table 5.3, 
Figures 5.6 5.7 5.9 5.8). 

116



Model 
Validation


No. 
Species 
Organisms 
Exp. 
Experimental 
eff 
ects 
Eects 
in 
our 
models


117


1. 
Mad2 
H. 
s. 
D 
-Impaired 
M 
SAC 
(Nezi 
et 
al.
, 
2006) 
SAC 
fails 
to 
arrestMad2 
M. 
D 
-Unable 
to 
arrest 
(Dobles 
et 
al.
, 
2000) 
no 
Cdc20 
SequesteringMad2 H. 
s.
& 
M. 
D 
-Defective 
M 
SAC 
(Michel 
et 
al.
, 
2001) 
[APC:Cdc20] 
very 
highMad2 
H. 
s. 
D 
-Unable 
to 
bind 
Cdc20 
or 
Mad1 
(Fang 
et 
al.
, 
1998b)
More 
refs. 
(Chen 
et 
al.
, 
1999c; 
DeAntoni 
et 
al.
, 
2005bLuo 
et 
al.
, 
2000b; 
Zhang 
and 
Lees, 
2001a)

2. 
Mad2 
H. 
s. 
O 
-Activates 
the 
M 
SAC 
(DeAntoni 
et 
al.
, 
2005a) 
Activates 
the 
SAC 
Mad2 
S.p. 
O 
-Blocks 
mitosis 
(He 
et 
al.
, 
1997) 
full 
Cdc20 
sequestering[APC:Cdc20] 
very 
low

3. 
Mad1 
H.s. 
D 
-
M 
SAC 
inactivation 
SAC 
fails 
to 
arrestand 
aneuploidy 
(Kienitz 
et 
al.
, 
2005) 
no 
Cdc20 
sequestering
Mad1 
S.p. 
D 
-Cell 
death 
(Lee 
and 
Spencer, 
2004)
. 
[APC:Cdc20] 
very 
highMore 
refs. (Iwanaga 
et 
al.
, 
2007Chen 
et 
al.
, 
1999b; 
Hardwick 
and 
Murray, 
1995).

4. 
BubR1 
H. 
s. 
D 
-Reduced 
M 
SAC 
function, 
reduce 
M 
SAC 
binding 
to 
SAC 
fails 
to 
arrestCdc20:C-Mad2 
(Davenport 
et 
al.
, 
2006) 
[APC:Cdc20] 
very 
high
M. 
D 
Increase 
polyploidy 
(Wang 
et 
al.
, 
2004b)
More 
refs.(Schmidt 
and 
Medema, 
2006
Hanks 
et 
al.
, 
2004)
5. 
Bub3 
M. 
D 
-Fail 
to 
arrest 
(Kalitsis 
et 
al.
, 
2000 
SAC 
fails 
to 
arrestTaylor 
et 
al.
, 
1998b) 
[APC:Cdc20] 
very 
high
(P.S. 
same 
as 
BubR1) 

Model 
Validation 
(continued)


118


No. 
Species 
Organisms 
Exp. 
Experimental 
eects 
Eects 
in 
our 
models


6. 
Cdc20 
S.c. 
O 
-Allows 
cells 
with 
a 
depolymerized 
spindle 
or 
SAC 
fails 
to 
arrestdamaged 
DNA 
to 
leave 
mitosis 
(Hwang 
et 
al.
, 
1998)
[APC:Cdc20] 
very 
high
-Impairment 
M 
SAC 
and 
aneuploidization 
inoral 
cancer 
(Mondal 
et 
al.
, 
2007b)

7. 
Cdc20 
H. 
s. 
D 
-Reduce 
binding 
to 
Mad2 
and 
selective 
Mitosis 
blocks 
disruption 
from 
Mad2 
(Zhang 
and 
Lees, 
2001b)
. 
[APC:Cdc20] 
very 
low
S.p. 
D 
-Arrest 
in 
metaphase 
(Shirayama 
et 
al.
, 
1999).
8. 
Bub1 
Drosophila Inh. 
-Chromosome 
missegregation 
(Basu 
et 
al.
, 
1999) 
SAC 
fails 
to 
arrest
H. 
s. 
Inh. 
-Disrupt 
Bub3 
localization, 
disrupt 
of 
[APC:Cdc20] 
very 
highBub3 
binding 
to 
BubR1 
(Taylor 
et 
al.
, 
1998b)
9. 
Aurora 
B 
Xenopus 
Inh. 
-Override 
the 
M 
SAC 
function, 
Perturbs 
MTs 
SAC 
fails 
to 
arrestDynamics 
(Kallio 
et 
al.
, 
2002b) 
[APC:Cdc20] 
very 
high
S.c. 
Inh. 
-Unregulated 
MTs, 
M 
SAC 
fails 
to 
arrest 
(P.S. 
same 
as 
Bub1)
(Biggins 
and 
Murray, 
2001; 
Cheeseman 
et 
al.
, 
2002).
10. 
APC 
units 
S.p. 
D 
-Disrupt 
complex 
association 
Activates 
the 
SAC 
cdc26, 
apc9 
(Passmore, 
2004b; Boronat 
and 
Campbell, 
2007) 
[APC:Cdc20] 
very 
lowcdc6, 
Doc1 
More 
refs.(Chang 
et 
al.
, 
2001)
Table 
5.3: 
Mutation 
Experiments; 
D 
for 
deletion 
or 
knockdown 
experiments, 
O 
for 
over-expression 
experiments, 
andInh. 
for 
inhibition; 
S.c.
, 
Saccharomyces 
cerevisiae; 
S.p.
, 
Schizosaccharomyces 
pombe; 
H. 
s.
, 
Homo 
sapiens(Human);
and 
M.
, 
Murine 


5.4 Discussion
5.4 Discussion 
Although our model is able to explain checkpoint function, this explanation does 
not contain details regarding the bio-molecular nature of the switching signal 
represented by the abstract factor u in our model. For a general explanation of 
mitosis it is desirable to replace the abstract factor u by chemical reactions of 
species like p31comet , Dynein, Usp44, and/or UbcH10. These species play a role 
in the signaling of the attachment to the MSAC control network we modeled here. 
When further biochemical details become available, we will replace u by a network 
model encompassing these species. Other additional proteins and complexes 
are involved in MSAC function implicitly. These species grant localization of 
outer kinetochore proteins as well as checkpoint proteins, which do not appear 
in our model explicitly. Examples are Bub1 (responsible for Bub3 and BubR1 
localization (Taylor et al., 1998a; Chen, 2002b; Larsen et al., 2007)) and Mps1, 
an essential component of the MSAC (Hardwick et al., 1996; Stucke et al., 2002; 
Palframan et al., 2006; Abrieu et al., 2001; Millband and Hardwick, 2002) required 
for kinetochore localization of Mad1 and Mad2 (Vigneron et al., 2004; Liu et al., 
2003; Stucke et al., 2004; Homan et al., 2001; Fisk et al., 2004; Fisk and Winey, 
2004, 2001; Tang et al., 2004). Considering these additional proteins and their 
spatial localization would be an important next step towards a systems level model 
of mitosis. 

119



5. MODELING APC CONTROL
AB


0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
0500100015002000250030003500400000.511.52x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
Mad2 deletion Mad2 over-expression 

CD 

0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
Cdc20 deletion Cdc20 over-expression 

Figure 5.6: Simulation of Mad2 and Cdc20 mutations for the controlled Convey 
variant. For deletion we set the respective initial concentration 100 times lower, 
and for over-expression 1000 times higher. Further setting as in Figure5.4 

120



5.4 Discussion
AB
0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
0500100015002000250030003500400000.511.52x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
Mad2 deletion Mad2 over-expression 

CD 

0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
Cdc20 deletion Cdc20 over-expression 

Figure 5.7: Simulation of Mad2 and Cdc20 mutations for the controlled Dissociation variant. For deletion we set the respective initial concentration 100 times 
lower, and for over-expression 10000 times higher. Note that Bub3 deletion has 
same eect as BubR1 (data not shown), and Bub1 has the same eect as aurora 
B (data not shown). Further setting as in Figure 5.2. 

121



5. MODELING APC CONTROL
AB
0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
BubR1 deletion Aurora B deletion 

CD 

0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
Mad1 deletion APC subunit deletion 

Figure 5.8: Simulation of BubR1, Aurora B, Mad1, and APC (subunits) for 
the controlled Dissociation variant. For deletion we set the respective initial 
concentration 100 times lower. Further setting as in Figure 5.2. 

122



5.4 Discussion
AB
0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
0500100015002000250030003500400000.511.52x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
BubR1 deletion Aurora B deletion 

CD 

0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
0500100015002000250030003500400000.20.40.60.811.21.41.61.82x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20
Mad1 deletion APC subunit deletion 

Figure 5.9: Simulation of BubR1, Aurora B, Mad1, and APC (subunits) for the 
controlled Convey variant. For deletion we set the respective initial concentration 
100 times lower. Further setting as in Figure 5.2. 

123



5. MODELING APC CONTROL
124



\If I feel unhappy, I do mathematics to become happy. 
If I am happy, I do mathematics to keep happy.". 

Alfred Renyi (1921 -1970). 

\A Mathematician is someone who can take a cup of coee and 
turn it into a theory". Paul Erdos (1913 -1996) 

Chapter 6 
Robustness and Stochasticity Eect 

Contents 

6.1 Summary .......................... 126


6.2 Introduction ........................ 126


6.3 TheModelanditsSimulation.............. 127


6.4 Results............................ 133


6.5 DiscussionandConclusion ................ 134


125



6. ROBUSTNESS AND STOCHASTICITY EFFECT
6.1 Summary 
Intrinsic 
uctuations due to the stochastic nature of biochemical reactions can 
have large eects on the response of biochemical networks. In this chapter, we 
view results from stochastic dierential equations to capture noise and 
uctuations 
eects. We have developed a \qualitative” model based on 14 proteins and 
complexes to describe concentration dynamics by nonlinear ordinary dierential 
equations in three compartments coupled by diusion. One kinetochore in each 
compartment determines the attachment status to the spindle pole. Here, we 
focus on the role of noise in the segregation surveillance process. The deterministic 
dierential equations are enriched by a stochastic term adding white noise of 
dierent amplitudes. Obviously, for the known physiological parameter ranges, 
noise does not disturb the checkpoint function. On the other hand, there is 
a connection between diusion and noise, that could become important when 
considering a larger number of chromosomes. 

6.2 Introduction 
Several deterministic models have been presented for the mitosis control during 
the past few months (Ibrahim et al., 2008a,b; Toth et al., 2007). When studying 
the behavior of these deterministic models, it has become clear that, with the 
given parameter values, the deterministic models, and in more general cell cycle 
models, are not capable of reproducing the experimentally observed irregular 
behavior in vitro in response to noise (Steuer, 2004). 

Although most cellular processes proceed in a spatially and temporally ordered 
fashion, not all noise is rejected (Rao et al., 2002). Moreover, it has become clear 
that the role of intrinsic noise in cellular functions may be complex and cannot 
always be treated as a small perturbation to the deterministic behavior (Steuer 
et al., 2003). Dierent studies have explored the in
uence of molecular 
uctuations 
on complex processes and cases have been found where noise seems to be essential 
for the required biological function (Steuer, 2004). In addition, this type of 

126



6.3 The Model and its Simulation
modeling is becoming increasingly important in the eld of systems biology, e.g. 
for modeling the cell cycle and gene regulation (Steuer, 2004; Battogtokh and 
Tyson, 2004; Chen et al., 2005; Steuer et al., 2003; Kaern et al., 2005; Kepler 
and Elston, 2001). Cell cycle control is subject to 
uctuations from dierent 
sources (Battogtokh and Tyson, 2004; Steuer, 2004) in a natural environment. 

In this chapter, we focus on the investigation of the role of noise in a qualitative 
deterministic model as it studied and mentioned in (Ibrahim et al., 2007; Lenser 
et al., 2007). Here, we make use of stochastic dierential equations (SDEs) to simulate in particular the implications of molecular 
uctuations on the Mitotic Spindle 
Assembly Checkpoint (MSAC ). Regarding the concentrations of [APC:Cdc20] 
and [MCC:APC] as measurements for the switch triggering exit from metaphase 
to anaphase, we model the dynamics of these concentrations in dependency of 
attachment states of the involved kinetochores by a deterministic description of 
a network of 14 proteins and protein complexes which regulate the dynamics 
of [APC:Cdc20] and [MCC:APC]. Only when the last kinetochore attaches, the 
APC:Cdc20 complex is allowed to form and thus starts a signalling cascade leading 
to onset of anaphase. Adding white noise to the deterministic equations allows 
the investigation of 
uctuation eects. 

6.3 The Model and its Simulation 
In our model, we consider 14 proteins and protein complexes, called species here, 
namely Mad2, Mad1, BubR1, Bub3, Mad2, Mad1, BubR1, BubR1:Bub3, APC, 
Cdc20, MCC, MCC:APC, Cdc20:Mad2, and APC:Cdc20. A detailed quantitative 
bio-molecular description of the reactions involved can be found in (Ibrahim et al., 
2008a). In an illustration( Figure6.1), we show the proteins, indicating also their 
localization in the reaction process. Here, we summarize the reaction equations. 
Three activation reactions are mediated by the kinetochore: 

127 


6. ROBUSTNESS AND STOCHASTICITY EFFECT


Mad2 ..-)k
*- Mad2 * (6.1) 

..1 



Mad1 ..-)k
*- Mad1 * (6.2) 

..2 




BubR1 ..-)*- BubR1 * (6.3) 

k

..3 

The forward reactions with kinetic constants , , and . (Table 6.1) in the 
unattached state stop when the kinetochore attaches. Therefore, in the attached 
state, we put a = ß = . =0. Therefore, Mad2, Mad1, and BubR1* are not 
any longer produced by activation at the respective kinetochore, but they are 
still supplied by diusion from other compartments with unattached kinetochores. 
The backward reactions as well as all other reaction equations are not in
uenced 
by the attachment status of the kinetochore: 

k

BubR1 + Bub3 ..-)
4*- BubR1:Bub3 (6.4) 

k

..4 

Mad2 + BubR1:Bub3 + Cdc20 
k5 MCC (6.5)

..-)k
*..

..5 

MCC + APC 
k6 MCC : AP C (6.6)

..-)k
*..

..6 

k7

Mad2 +Mad1 +Cdc20 ..... Cdc20:Mad2 + Mad1 (6.7) 

k8

Cdc20:Mad2 ..... Cdc20 + Mad2 (6.8) 

MCC:APC Inhibitors APC:Cdc20 + BubR1:Bub3 + Mad2 (6.9)

............

?

BubR1* 
Cdc20:Mad2 

k9

APC:Cdc20 ..-)k
*- APC + Cdc20 (6.10) 

..9 

k10

Cdc20:Mad2 + BubR1:Bub3 -. MCC (6.11) 

The reaction equations dene ordinary dierential equations for the concentrations 

of the respective molecules. Mass action kinetics is assumed for reaction rules 

(6.1)-(6.8) and (6.10)-(6.11). Not much is known about MCC:APC dissociation 

128



6.3 The Model and its Simulation
(6.9), so we have used a mixed inhibition function of Michaelis-Menten type: 

V * S 

fInh(S, I)= 

II 

km * (1+ )+ S * (1+ )
kis kic 

where S = [MCC:APC] is the substrate , I = [BubR1] + [Cdc20:Mad2] is the
inhibitor concentration, V is the forward maximum velocity, km is the forward
Michaelis-Menten constant, kis is the specic (competitive) inhibition constant,
and kic is the catalytic (noncompetitive) inhibition constant.
Here, we give examples for two of the 14 ordinary dierential equations, namely
for the concentration of the complexes MCC:APC and APC:Cdc20 :


d[MCC:APC] 

=k6[MCC][APC] - k..6[MCC:APC] - fInh(S, I) (6.12)

dt
d[APC:Cdc20]


= fInh(S, I) - k10[APC:Cdc20] + k..10[APC][Cdc20](6.13) 

dt 

The equations described so far show the evolution in time of the concentrations 
of the 14 species near one kinetochore. To concentrate on the main eects, we 
consider three compartments X, Y, and Z in a linear spatial arrangement, so 
that molecules can only diuse between X and Y , and between Y and Z. Each 
compartment contains one kinetochore, which can be attached or not attached 
to the spindle. As mentioned before, the attachment of the spindle within a 
specic compartment is represented as a change of parameters , , and . in that 
compartment according to the values in Table 6.1 (unattached) and the value 0 
(attached). 

Instead of introducing spatial variables, we use Fick's rst law to describe diusion 
between compartments. In our simulation with discretized time, diusion is then 

D 

discribed by a characteristic constant O = (Paliwal et al., 2004; Thorwarth 

l2 

et al., 2005) that multiplies the concentration dierences. We obtain for a species 
i and reaction terms Ri;A in compartment A the following equations: 

129 


6. ROBUSTNESS AND STOCHASTICITY EFFECT
d[i]X =dt = 
([i]Y - [i]X )+ Ri;X (6.14) 
d[i]Y =dt = 
([i]X - 2[i]Y +[i]Z)+ Ri;Y (6.15) 
d[i]Z =dt = 
([i]Y - [i]Z )+ Ri;Z (6.16) 

Because many biological details are yet unknown, we set O = 1s..1 , assuming 
a diusion constant of D =0:01m2s..1 and a distance of l = 10m between 
compartments for all substances. This estimate is based on the known diusion 
constants. 

In these equations, subscripts X, Y, and Z denote the concentrations of the specic 
species in the respective compartment. Hence, the complete system consists of 42 
concentration functions of time as solution of a system of 42 ordinary dierential 
equations. Note, that attachment states of the three compartments are additional 
parameters. Beginning with initial concentrations taken from literature (e.g. (Chen 
et al., 2004)), the equations are integrated with all attachment parameters in 
the state \unattached” (symbolized by UUU) until equilibrium is reached. Then, 
attachment parameter of compartment X is turned on (UUA), and the three 
activation reactions (6.1)-(6.3) in X are set to zero. After equilibrium is reached 
again, attachment in compartment Y is turned on (UAA) until equlibrium is 
reached. Finally, all three kinetochores are attached (AAA). These symbols are 
also used in Figures 6.2{6.4, where they designate the end of the simulation time 
of the respective phase. 

For integration, those kinetic constants, which are documented in the literature, 
are used directly, whereas for all other constants physiologically reasonable values 
are substituted. This is done for many choices, and performance of the model 
is optimized according to an objective function measuring the concentration of 
APC:Cdc20, which should be 0 for the rst three phases UUU, UUA, UAA, and 
should rise to a maximal value in phase AAA within a time scale of about 3 
to 5 minutes. The optimization details can be found in (Ibrahim et al., 2008a). 
As a result, the values in Table 6.1 were found as optimal values for the kinetic 
parameters. They are also used in our perturbation model here. 

130 


6.3 The Model and its Simulation
Figure 6.1: Reaction network for one compartment. The activation reactions with 
parameters , , and . continue, as long as the kinetochore is unattached (left). 
When the respective kinetochore attaches, , , and . are set to 0. A network 
of reactions leads to the formation of the MCC:APC complex (middle). These 
reactions continue as long as there is at least one unattached kinetochore. This is 
the consequence of the diusion in the system, because the respective kinetochore 
does not any longer supply activated Mad1, Mad2, and BubR1. When the 
last kinetochore attaches, the APC:Cdc20 complex begins to form and leads to a 
cascade of reactions cutting cohesin in the end and initiating anaphase (right). 

131



6. ROBUSTNESS AND STOCHASTICITY EFFECT
Kinetic parameters


a = 4.82 k..1 = 0.00752 k7 = 10.0 
ß = 9.92 k..2 = 0.00100 k8 = 0.00235 
. = 6.08 k..3 = 9.83 k9 = 0.00271 k..9 = 10.0 
k4 = 0.412 k..4 = 3.44 k10 = 10.0 
k5 = 0.00100 k..5 = 0.00100 V = 0.0197 kic = 6.84 
k6 = 10.0 k..6 = 0.00100 km = 9.21 kis = 0.00100 

Table 6.1: Kinetic parameters used for simulation: reaction rates for mass action 
and Michaelis-Menten kinetics. 

As we do not have any special information about the origin of 
uctuations in 
the cell cycle (Steuer, 2004; Battogtokh and Tyson, 2004), we assume random 
extrinsic 
uctuations, mathematically described by white noise (Rao et al., 2002; 
Gillespie, 2002; Battogtokh and Tyson, 2004). For each species i in compartment 
j, the stochastic Langevin-type equation has the following form: 

d[i]j 

dt 
= C(i)j + Wi(t)2 · Ni · [i]j 

where C(i)j is the original right-hand side of the deterministic equation and Wi(t) 
is the (multiplicative) Gaussian white noise for species i with zero mean and unit 
variance 

hWi(t). =0, hWi(t)Wi(t0). = (t - t0). 

N = Ni denotes the noise amplitude parameter, which, for simplicity, is the same 
for all species. 

We computed the concentration functions for several values of N. Here, we show 
the results for N = 10..8 (almost no noise) and N = 10..5 . Weused
=1asin 
the deterministic simulation, but in addition, to simulate the in
uence of diusion 
on the system, we used O = 0:01 and 
=0:005. 

The simulations were performed using standard numerical techniques for stochas

132



6.4 Results
tic dierential equations (including the strong implicit 1.5 order Runge-Kutta 
method (Kloeden and Platen, 1999a), and the explicit Runge-Kutta method of 
order 1.5 (Kloeden and Platen, 1999a)). We implemented our code in (MATLAB 
, Matrix Labrotory). 

6.4 Results 
In Figure 6.2, the concentration curves for APC:Cdc20 and MCC:APC complexes 
are shown for a time period of about 12 minutes. The noise amplitude is N = 10..8 . 
In all simulations, steady state conditions (regarding noise, this means constant 
average of concentration) are reached within less than 3 minutes in all 3 phases 
(UUU, UUA, UAA) with at least one unattached kinetochore. For O = 1 (top), 
there are no visible dierences between the concentration curves for compartments 
X, Y, and Z (data not shown). Diusion is obviously fast enough to level out 
the small dierences induced by noise. In addition, after steady state is reached 
in phase UUU, the concentrations remain at that level during phases UUA 
and UAA. The graphs are almost identical to the concentration curves in the 
deterministic simulation without noise ( (Lenser et al., 2007)). For O = 0:01 
(middle), rst dierences appear in phases UUA and UAA as compared to UUU: 
the equilibrium value is rising. Also in phase AAA, the onset of APC:Cdc20 
increase and MCC:APC decrease is much faster. Also, concentration dynamics 
dierences between compartments X, Y, and Z become visible (data not shown). 
For 
=0:005 (bottom), these eects become even more pronounced. 

In Figure 6.3, showing the same concentration functions in the same ordering of 
, 
the noise level is much higher at N = 10..5 . Whereas for O = 1 the overall shapes 
of the curves still resemble the curves for low noise level, there is a large overshoot 
of [MCC:APC] (O = 0:01) in phase UUU, and, for O = 0:005, [MCC:APC] 
decays very rapidly already in phase UAA. It is also questionable, whether the 
concentration reached is enough to prevent exit from metaphase to anaphase. 
These eects increase for even higher N..values and disrupt mitotic control. To 
give an impression of the dierent behaviour in the three compartments, we have 

133



6. ROBUSTNESS AND STOCHASTICITY EFFECT
included Figure 6.4 which shows the respective dynamics in these compartments 
for N = 10..5 and 
=0:005. 

6.5 Discussion and Conclusion 
The proper segregation of sister chromatids at onset of anaphase is surveyed by the 
mitotic spindle assembly checkpoint. The concentration dynamics of the complexes 
APC:Cdc20 and MCC:APC determine exit from metaphase to anaphase. Our 
model, describing concentration dynamics by ordinary dierential equations, is 
based on 14 proteins and complexes, which determine increase or decrease of 
the two key complexes near a kinetochore, dependent on its attachment status. 
To investigate the interaction of concentrations near dierent kinetochores, we 
have coupled three compartments by diusion. As for many reaction constants 
only ranges, but no exact values, are known, we optimized a particular objective 
function based on the expected dynamics of APC:Cdc20 concentration in (Ibrahim 
et al., 2008a), where the details of this procedure can be found. The result was a 
set of concentration parameters and initial values, allowing the simulation of the 
deterministic model showing a correct behaviour of the spindle checkpoint and also 
reproducing over-expression and deletion eects (Ibrahim et al., 2008a). The model 
is based on mass action laws for all reactions except one (6.9), which is described 
by a mixed Michaelis-Menten kinetic. This may be an oversimplication, because 
non-linear eects may be involved. On the other hand, this argument applies to 
almost all reactions considered here. It is even questionable, how diusion can be 
described correctly, as ongoing research shows that certain signalling molecules 
seem to travel along one dimensional bres. So, the formulation of the reaction 
equations might be only a rst step. However, for example the mixed Michaelis-
Menten kinetic, we used here, has several parameters which were optimized and 
could in this way provide a description which is close to the actual reaction. 

As in natural processes noise is a never neglectable ingredient, we have addressed 
here the question, whether noise has a destructive in
uence, or, as in Steuer (2004), 
is even essential for the correct function. We therefore take the same description 

134



6.5 Discussion and Conclusion
by dierential concentration equations for the single compartments and also the 
same geometric arrangement of three compartments as in (Lenser et al., 2007). 
But here, the deterministic dierential equations are enriched by a stochastical 
term adding white noise of dierent amplitudes. 

We could show that the spindle checkpoint dynamics as described by our model 
is stable with respect to extrinsic white noise to a rather large extend. Only 
for a noise amplitude larger than N = 10..4 , the function of the checkpoint is 
disrupted. The in
uence of noise, on the other hand, is dependent on the diusion 
coecient. Whereas diusion in the known physiological parameter ranges is fast 
enough to level out concentration dierences in the distinct compartments, noise is 
able to build up considerably dierent dynamics near dierent kinetochores when 
the diusion constant is decreased. This eect could become important when 
considering more chromosomes, which is necessary to simulate human checkpoint 
behaviour. 

We did not nd indications that noise is essential for the checkpoint function, in 
contrast to the eects of noise in the cell cycle as a whole, where noise seems 
to prevent dynamics from getting stuck in singular points (Steuer, 2004). Our 
results suggest that a fast diusion, as in the physiologically relevant parameter 
ranges, helps to stabilize the system and to prevent noise to disrupt the checkpoint 
function. Along these lines it will be interesting to investigate the system using 
methods developed in (Levine and Hwa, 2007). They show, using a master 
equation approach, that in certain metabolic networks noise is not propagated, 
but has only local in
uence. These ndings coincide with ours on a global level. 
On the other hand, we did not yet investigate the in
uence of a single perturbation 
on the system, e.g. by a concentration impulse response, as they suggest. But 
this will be a challenging task for us for the future. 

In the model presented here, a linear arrangement of three compartments was used. 
This is only a rst approximation to a more complex model for 46 chromosomes, 
arranged in a two dimensional mitotic equatorial plate, where each inner kinetochore has six neighbors – for mathematical symmetry. The outside kinetochores 
in this geometry have also connection to an outer region without any kinetochores, 
which is also connected to all kinetochores via the third dimension. Presently, we 

135



6. ROBUSTNESS AND STOCHASTICITY EFFECT
are modeling this situation, which is much more involved. There are still debates 
about the exact ranges of diusion coecients, and also the dimensionality is in 
question. There are hints for one dimensional diusion in certain cases, possibly 
enabled by diusion along bres. In further investigations, we will therefore use 
dierent diusion constants for distinct reactants and also try to simulate dierent 
dimensionalities. A further goal is also the investigation of the in
uence of the 
geometry (e.g. in the mitotic equatorial plate) on the checkpoint dynamics using 
partial dierential equations. Here, the localization of the reactions and reactants 
to the kinetochore, on the one hand side, or to the 'nucleosol', on the other hand 
side, may play an important role. 

136



6.5 Discussion and Conclusion
[APC:Cdc20]inY-compartment[MCC:APC]inY-compartment
01000200030004000500060007000800000.050.10.150.20.250.30.35APCCdc20Plot wild typeUUUUUAUAAAAACompartment YAPCCdc20UUUAPCCdc20UUAAPCCdc20UAAAPCCdc20AAA
01000200030004000500060007000800000.050.10.150.20.250.30.35MCCAPCPlot wild typeUUUUUAUAAAAACompartment YMCCAPCUUUMCCAPCUUAMCCAPCUAAMCCAPCAAA

=1 
=1 

01000200030004000500060007000800000.050.10.150.20.250.30.35APCCdc20Plot wild typeUUUUUAUAAAAACompartment YAPCCdc20UUUAPCCdc20UUAAPCCdc20UAAAPCCdc20AAA
01000200030004000500060007000800000.050.10.150.20.250.30.35MCCAPCPlot wild typeUUUUUAUAAAAACompartment YMCCAPCUUUMCCAPCUUAMCCAPCUAAMCCAPCAAA
O = 0.01 O = 0.01 

01000200030004000500060007000800000.050.10.150.20.250.30.35APCCdc20Plot wild typeUUUUUAUAAAAACompartment YAPCCdc20UUUAPCCdc20UUAAPCCdc20UAAAPCCdc20AAA
01000200030004000500060007000800000.050.10.150.20.250.30.35MCCAPCPlot wild typeUUUUUAUAAAAACompartment YMCCAPCUUUMCCAPCUUAMCCAPCUAAMCCAPCAAA
O = 0.005 O = 0.005 

Figure 6.2: Concentration of APC:Cdc20 (left) and MCC:APC (right) as a function 
of time (8000 iterations corresponding to 12 min) in the middle compartment Y 
at noise amplitude N = 10..8 . The rst part (orange, from time 0 to 'UUU') of 
the curves describes the phase with three kinetochores Unattached (UUU); the 
second part (red, 'UUU'-'UUA'), the phase with two kinetochores Unattached 
and one Attached (UUA); etc. (cf. insert). With decreasing diusion coecient 
O (cf. text), the concentration dierences within the 3 phases UUU, UUA, UAA, 
increase more and more. Steady state is reached after at most 3 min. When all 
kinetochores are attached (green curve 'UAA'-'AAA', phase AAA), APC:Cdc20 
rises immediately and MCC:APC decays. 

137 


6. ROBUSTNESS AND STOCHASTICITY EFFECT
[APC:Cdc20]inY-compartment[MCC:APC]inY-compartment
01000200030004000500060007000800000.050.10.150.20.250.30.35APCCdc20Plot wild typeUUUUUAUAAAAACompartment YAPCCdc20UUUAPCCdc20UUAAPCCdc20UAAAPCCdc20AAA
01000200030004000500060007000800000.050.10.150.20.250.30.35MCCAPCPlot wild typeUUUUUAUAAAAACompartment YMCCAPCUUUMCCAPCUUAMCCAPCUAAMCCAPCAAA

=1 
=1 

01000200030004000500060007000800000.050.10.150.20.25APCCdc20Plot wild typeUUUUUAUAAAAACompartment YAPCCdc20UUUAPCCdc20UUAAPCCdc20UAAAPCCdc20AAA
01000200030004000500060007000800000.050.10.150.20.250.30.350.40.45MCCAPCPlot wild typeUUUUUAUAAAAACompartment YMCCAPCUUUMCCAPCUUAMCCAPCUAAMCCAPCAAA
O = 0.01 O = 0.01 

01000200030004000500060007000800000.020.040.060.080.10.120.140.16APCCdc20Plot wild typeUUUUUAUAAAAACompartment YAPCCdc20UUUAPCCdc20UUAAPCCdc20UAAAPCCdc20AAA
01000200030004000500060007000800000.050.10.150.20.250.30.35MCCAPCPlot wild typeUUUUUAUAAAAACompartment YMCCAPCUUUMCCAPCUUAMCCAPCUAAMCCAPCAAA
O = 0.005 O = 0.005 

Figure 6.3: Concentration of APC:Cdc20 (left) and MCC:APC (right) as a function 
of time (8000 iterations corresponding to 12 min) in the middle compartment Y 
at noise amplitude N = 10..5 . With decreasing diusion coecient 
, dynamics 
in the phases with one kinetochore unattached (UAA) become more and more 
distinct, and in some cases a steady state equilibrium is not reached any more 
within phase simulation time (3 min). 

138



6.5 Discussion and Conclusion
[APC:Cdc20]incompartmentsX,Y,Z[MCC:APC]incompartmentsX,Y,Z
01000200030004000500060007000800000.020.040.060.080.10.120.14TimeAPCCdc20Plot wild typeUUUUUAUAAAAACompartment XAPCCdc20UUUAPCCdc20UUAAPCCdc20UAAAPCCdc20AAA
01000200030004000500060007000800000.050.10.150.20.250.30.35TimeMCCAPCPlot wild typeUUUUUAUAAAAACompartment XMCCAPCUUUMCCAPCUUAMCCAPCUAAMCCAPCAAA
XX 

01000200030004000500060007000800000.020.040.060.080.10.120.140.16APCCdc20Plot wild typeUUUUUAUAAAAACompartment YAPCCdc20UUUAPCCdc20UUAAPCCdc20UAAAPCCdc20AAA
01000200030004000500060007000800000.050.10.150.20.250.30.35MCCAPCPlot wild typeUUUUUAUAAAAACompartment YMCCAPCUUUMCCAPCUUAMCCAPCUAAMCCAPCAAA
YY 

01000200030004000500060007000800000.020.040.060.080.10.120.140.16APCCdc20Plot wild typeUUUUUAUAAAAACompartment ZAPCCdc20UUUAPCCdc20UUAAPCCdc20UAAAPCCdc20AAA
01000200030004000500060007000800000.050.10.150.20.250.30.35MCCAPCPlot wild typeUUUUUAUAAAAACompartment ZMCCAPCUUUMCCAPCUUAMCCAPCUAAMCCAPCAAA
ZZ 

Figure 6.4: Concentration of APC:Cdc20 (left) and MCC:APC (right) in the three 
compartments X,Y,Z, at a noise amplitude of N = 10..5 for diusion coecient 

=0:005. For these parameters, strong dierences in the [APC:Cdc20] and 
[MCC:APC] dynamics in the dierent compartments become visible. 

139



6. ROBUSTNESS AND STOCHASTICITY EFFECT
140



Mitosis Consolidation


141



\Imagination is more important than knowledge...". 

Albert Einstein (1879 -1955) 

\To create a good philosophy you should renounce 
metaphysics but be a good mathematician". 

Bertrand Russell (1772 -1970) 

Chapter 7 

Integrative Model of Mitosis 
Transition Control Mechanisms 

Contents 

7.1 Summary .......................... 144


7.2 Biochemical Background of the Integrative Model . 146 

7.3 Simulation.......................... 148


7.3.1 Optimization ....................... 149


7.3.2 ModelBehavior...................... 153


7.4 ModelValidation...................... 155


7.5 ConcludingRemarks ................... 158


143



7. INTEGRATIVE MODEL OF MITOSIS TRANSITION 
CONTROL MECHANISMS 
7.1 Summary 
Two forms of the Anaphase Promoting Complex (APC), bound to Cdc20 or 
Cdh1, regulate mitosis transition. During the metaphase-to-anaphase transition, 
APC:Cdc20 mediates the ubiquitination and degradation of Securin protein, 
leading to the activation of Separase, dissolution of the Cohesin complex, and 
chromatid separation. In addition, APC:Cdc20 mediates the rst phase of Cyclin 
B proteolysis. During anaphase and transition to telophase, APC:Cdh1 is turned 
on and completely ubiquitinates Cyclin B, thus inactivating the CyclinB:Cdk1 
mitotic kinase and triggering the exit from mitosis to cytokinesis. 

Herein, we incorporated an adapted Exit From Mitosis (EFM) model that involves 
the activity of APC:Cdh1 and build an integrative model that also involves the 
activity of APC:Ccd20. Hence, we addressed simultaneously the functioning of 
both transition control mechanisms, MSAC and EFM (see Figure 7.1). This new 
model consists of 19 species and 15 reactions. It is validated by simulation of 
mutation experiments. The model is described by non-linear ordinary dierential 
equations. The values of the kinetic parameters are derived from literature and 
the remaining values of parameters are obtained with parameter optimization. 
The parameter optimization will be performed with three optimization techniques, 
two evolutionary and one deterministic technique; namely Covariance Matrix 
Adaptation Evolutionary Strategy (CMA-ES), Dierential Evolution (DE), and 
the Hooke-Jeeves (HJ) algorithm, respectively. 

144



145
Figure 
7.1: 
Schematic 
networks 
of 
an 
integrative 
model 
of 
mitosis 
transition 
control 
mechanisms. 
Module 
representsthe 
M 
SAC 
mechanism 
(Chapter 
5)
, 
in 
which 
APC 
activation 
by 
Cdc20 
is 
the 
output. 
Module 
B 
represents 
the 
EFMmechanism, 
in 
which 
APC 
functions 
by 
both 
Cdc20 
and 
Cdh1 
are 
analyzed 
(for 
details 
see text)



7. INTEGRATIVE MODEL OF MITOSIS TRANSITION 
CONTROL MECHANISMS 
7.2 Biochemical Background of the Integrative 
Model 
The integrative model includes two sub-models; MSAC and EFM model. 
MSAC model is described as mass-action kinetics (reaction Eqs.(7.1)-(7.8)) 
in two model variants (see Chapter 5), the \Dissociation"(Eq. (7.D)) and 
the \Convey"(Eq. (7.C)) model. The output signal of MSAC model (Anaphase 
initiation) is the activation of APC by its rst mitotic co-activator Cdc20 in 
APC:Cdc20 complex form. The APC:Cdc20 complex has two main functions. 
One is to activate Separase by ubiquitylating of Securin (Eq.(7.9)). The other 
function is to proteolysis the rst phase of Cyclin B (Eq.(7.10)) that occurs 
when cellular levels of the Cyclin B are high. Here Cyclin B activity refers to 
Cdk1:Cyclin B complex. However, APC:Cdc20 is unable to reduce Cyclin B 
activity to a level low enough to complete exit from mitosis (Yeong et al., 2000). 
These two reactions of APC functions are important to connect the MSAC model 
with the EFM model. Both reactions are based on empirical data (e.g, Morgan, 
1999; King et al., 1996; Alexandru et al., 1999; Nasmyth et al., 2000; Uhlmann 
et al., 1999). 

The EFM model is described by reaction Eqs.(7.11)-(7.15). Three of these reactions 
are taken from the model proposed by Toth et al. (2007) for budding yeast which is 
used as a basis for our Human EFM model. Reaction equation (7.11) describes the 
constant production of Cyclin B. Reaction equation (7.12) describes the regulation 
of a phosphatase, called Cdc14 (human homology hCdc14A, we will use Cdc14A 
for simplicity now on). The inactivation of Cdc14A is considered to be mass-action 
kinetics, while the activation as Michael-Menten kinetics. The activation of Cdc14 
is better understood in Yeast, through two networks (Toth et al., 2007) called 
FEAR (Cdc Fourteen Early Anaphase Release) (Stegmeier et al., 2002; Sullivan 
and Uhlmann, 2003) and MEN (Mitotic Exit Network) (Jaspersen et al., 1998; 
Lee et al., 2001; Stegmeier and Amon, 2004). The FEAR network is assumed 
to be less essential than MEN because mutants in FEAR pathway show only a 
delay in activation of Cdc14 while mutants of MEN block at telophase (Stegmeier 
et al., 2002). In spite of this assumption, Separase plays an essential role in 

146



7.2 Biochemical Background of the Integrative Model
Cdc14 activation which is also a component of FEAR pathway (Queralt et al., 
2006; Sullivan and Uhlmann, 2003). Because of this function and the lack of 
knowledge for Human Cdc14A regulation, we propose a Michaelis-Menten kinetic 
function based on a rate limiting function of Separase as well as both parametric 
FEAR and MEN pathways (reaction Eq.(7.12)). Moreover, we think such a 
function can mathematically be consistent with the empirical data as we will see 
in the model validation section. Active Cdc14A (Cdc14A* nomenclature will be 
used from now on) dephosphorylates (and thereby activates) the second APC 
co-activator, Cdh1 (a human homology is hCdh1, Cdh1 will be used from now 
on) (Eq.(7.13)) (Bembenek and Yu, 2001b). We refer to phosphorylated Cdh1 
by (Cdh1P). For both phosphorylation and the dephosphorylation Michaelis-
Menten kinetics are used (Toth et al., 2007). The conversion between both APC's 
activators, Cdc20 and Cdh1 is an uncatalyzed reaction and therefore described 
with mass-action kinetics (Eq.(7.14)), this reaction models the exchange of Cdc20 
by Cdh1 and Cdc20 degradation in single reaction. Subsequently, APC:Cdh1 
promotes completion of Cyclin B destruction (Eq.7.15) (Prinz et al., 1998). 

Mad1:C-Mad2 + O-Mad2 . 
k1:u. Mad1:C-Mad2:O-Mad2 * (7.1)

- --

k..1 

k2:u

Mad1:C-Mad2:O-Mad2 * + Cdc20 ....... Cdc20:C-Mad2 + Mad1:C-Mad2 (7.2) 

k3

Cdc20:C-Mad2 O-Mad2 + Cdc20 (7.3)

-..... 

k4:u 

Cdc20:C-Mad2 + Bub3:BubR1 ). MCC (7.4)

- --

k..4 

k5:u 

Cdc20 + Bub3:BubR1 ). Bub3:BubR1:Cdc20 (7.5)

- --

k..5 

k6

Cdc20 + O-Mad2 Cdc20:C-Mad2 (7.6)

-..... 

k7:u

MCC + APC ....... MCC:APC (7.7) 

k..7:u0

MCC:APC ....... APC + MCC (7.D) 

k..7:u0

MCC:APC ....... APC:Cdc20 + O-Mad2 + Bub3:BubR1 

(7.C) 
k8

APC + Cdc20 . APC:Cdc20 (7.8)

..--. 

k..8- 

147 


7. INTEGRATIVE MODEL OF MITOSIS TRANSITION 
CONTROL MECHANISMS 
APC:Cdc20, k9

Separse:Securin Separase + waste (7.9)

-............................. 

APC:Cdc20, k10

Cyclin B waste (7.10)

-............................. 

k11 

............................... Cyclin B (7.11) 
Cdc14A . 
k12 Cdc14A * (7.12)

..--------------. 

f(Separase;R), k..12,k..12M- 

Cdh1P . 
Cdc14A*, k13,k13M . Cdh1 (7.13)

- -------------

Cyclin B, k..13,k..13M 

k14

APC:Cdc20 + Cdh1 ............................... APC:Cdh1 + waste (7.14) 

APC:Cdh1, k15

Cyclin B (7.15)

............................... waste 

7.3 Simulation 
By applying general principles of mass-action as well as Michaelis-Menten kinetics, 
we convert the reaction rules (Eqs.(7.1)-(7.15)) into sets of nonlinear Ordinary 
Dierential Equations (ODEs) for the Dissociation variant (Appendix E , Eqs. 
(E.1)-(E.19)) and similarly for the Convey variant (Appendix E , Eqs. (E.20)
(E.38)). Starting from initial concentrations for all reactions taken from literature 
listed in Table 5.2, Cdh1P is assumed to be equal to the initial concentration of 
Cdc20. In this manner there will be enough Cdh1 to convert all the APC:Cdc20 

into APC:Cdh1. 

The initial concentrations of Cdc14A and Separase:Securin are set equal to the 
initial Cyclin B concentration (200nM, Moore et al. (2003)). 

The product of APC:Cdc20 subjected to high initial concentration of both APC and 
Cdc20 for the rst few seconds should be avoided. During the rst time steps APC 
may be activated and will cause undesirable model behavior. This is prevented 
by cutting the rst step into two sub-steps. During the rst 120 sec APC:Cdc20 
reaction is slower 1000folds as for the relation to prophase. Afterwards MSAC is 

148



7.3 Simulation
completely active and APC cannot be activated by Cdc20 anymore. The initial 
concentration for the succeeding steps will be equal to the nal concentrations of 
the previous step. The ODEs are integrated until steady state is reached before 
attachment (using u = 1, time is about 25 mins: Prometaphase and Metaphase). 
After switching u to 0 (about 50 mins: Anaphase and Telophase), the equations 
are again integrated until steady state is reached. The minimum concentration of 
APC:Cdc20, APC:Chd1, Cyclin B, Cdc14A*, and Securin before attachment and 
the recovery after attachment are criteria for tness function as explained in the 
following section. 

7.3.1 Optimization 
This objective function f(P ) compares the model behavior with current parameters 
to prescribed model behavior. It assigns a quality (i.e., a positive real number) 
to a given set of parameters P =(kn, n=1,...,12). In our case, the parameters 
are the reaction constants. In order to t the parameters with respect to the 
observed qualitative function of the MSAC and EFM control mechanisms, 5 model 
outputs will be used: APC:Cdc20, APC:Cdh1, Cyclin B, Cdc14A* and Securin. 
APC:Cdc20, APC:Cdh1 and Cdc14A* have switch-like behavior. APC:Cdc20 
reaches its maximum concentration of 90 nM in the rst simulation phase (t< 25 
mins), and APC:Cdh1 (t>25 mins) reaches the same concentration in the second 
simulation phase. Cdc14A* can reach the maximum concentration (200 nM) only 
after 25 mins. Cyclin B and Securin have a similar behavior (Hagting et al., 2002), 
which is high in the st simulation phase, and once APC:Cdc20 appears they will 
degrade. We used a general form of the following tness function: 

56

f(P )= fW0([xj]0 - A0;j)2 + Wi([xj]i - Ai;j)2} (7.16) 
j=1 i=1 

j 2{ APC:Cdc20, APC:Cdh1, Cyclin B, Cdc14A*, Securin} 

i has seven time points. i = 0 refers to the steady state of the simulation where 
kinetochore is unattached (u= 1). i =1, :::, 6 are six dierent time points after 

149



7. INTEGRATIVE MODEL OF MITOSIS TRANSITION 
CONTROL MECHANISMS 
attachment (silence MSAC and EFM). 

More specically, the comparisons of the measurement occur at 25%, 50%, 60%, 
70%, 80% and 100% of the simulated time after attachment. Ai;j is a matrix in which each row is related to time point i, each column is related to 
species element j (Table 7.1). Each element of the matrix Ai;j is xed number 
between 0 and related species maximum. W is the weight constants vector: 
W = [100, 200, 250, 350, 300, 150], which focuses on some term more and by which 
gives the best result. 

Fitness function constant values 

i Time Ai;[APC:Cdc20] Ai;[APC:Cdh1] Ai;[Cyclin B] Ai;[Cdc14A*] Ai;[securin:Separase] 
0 100%F 0 0 1.0[ ]IC 0 1.0[ ]IC 
1 25%S 0.9[ ]IC 0.1[ ]IC 0.75[ ]IC 0.3[ ]IC 0.75[ ]IC 
2 50%S 0.8[ ]IC 0.2[ ]IC 0.5[ ]IC 0.4[ ]IC 0.5[ ]IC 
3 60%S 0.5[ ]IC 0.5[ ]IC 0.35[ ]IC 0.5[ ]IC 0.35[ ]IC 
4 70%S 0.3[ ]IC 0.7[ ]IC 0.15[ ]IC 0.6[ ]IC 0.15[ ]IC 
5 80%S 0.1[ ]IC 0.9[ ]IC 0.05[ ]IC 0.75[ ]IC 0.05[ ]IC 
6 100%S 0 1.0[ ]IC 0 1.0[ ]IC 0 

Table 7.1: Fitness function constant values, F refers to the rst phase and S refers 
to the second simulation phase. [ ]IC represents the initial concentration for a 
related species j. Ai;j refers to the comparisons of the measurements. 

. 

Parameter optimization was performed for the Dissociation variant of the integrative model using three optimization techniques: CMA-ES (Hansen and Kern, 
2004), DE (Storn and Price, 1997) and HJ (Hooke and Jeeves, 1961). All optimization techniques were used with the same objective function. Because of the wide 
parameters range (e.g. 10..12 and 1012), we used an exponential scaling, by which 
parameter estimation can be eciently and more accurately performed (Rohn 
et al., 2008). The optimization algorithms in the unscaled case allow parameters 
P (vector) in the range between 10..n and 10n, where n is any real number, the 



scaled case considers parameters P between 0 and 1. The changed parameters P 

150



7.3 Simulation


were inserted and evaluated. The relationship between P and P is 

P= a 10b+c
P (7.17)

· 

where e.g., a = 1, b = ..12 and c = 24 resulting in 10..12 = P= 1012 . As a result 
of this scaling, search steps are larger for high parameter values and smaller for low 
values, independently of the optimization procedure. This allows a optimization 
procedure to investigate small parameter values with high resolution and large 
parameter values with low resolution without having to internally adapt the search 
step-size. 

We ran the three optimization techniques 90 times in total and picked the best 
tness and model behavior. Parameter optimization with CMA-ES as well as HJ 
were much faster than optimization with DE. Optimization showed that good 
parameter sets could be found within the parameter ranges (Table 7.2), in which 
HJ was a bit better than CMA-ES as well as DE. These local minima varied slightly. 
All parameters value lie within realistic range (see for example, Chapter 5). 

151



7. INTEGRATIVE MODEL OF MITOSIS TRANSITION 
CONTROL MECHANISMS 
Integrative model parameters


Parameters Comments and References


k1 =2 * 105 M..1 s..1 Chapter 5 
k..1 =2 * 10..1 s..1 Chapter 5 
k2 = 108M..1 s..1 Chapter 5 
k3 =1 * 10..2s..1 Chapter 5 
k4 = 107 M..1 s..1 Chapter 5 
k..4 =2 * 10..2 s..1 Chapter 5 
k5 = 104 M..1 s..1 Chapter 5 
k..5 =2 * 10..1 s..1 Chapter 5 
k6 = 103 M..1 s..1 Chapter 5 
k7 = 108 M..1 s..1 Chapter 5 
k..7 =8 * 10..2 s..1 Chapter 5 
k8 =5 * 106 M..1 s..1 Chapter 5 
k..8 =8 * 10..2 s..1 Chapter 5 
k9 = 1.55104 M..1 s..1 This study 
k10 = 1.6104 M..1 s..1 This study 
k11 = 1.1610..12 Ms..1 This study 
k12 = 1.53103 s..1 This study 
k13 =4104 s..1 This study 
k14 = 1.47109 M..1 s..1 This study 
k15 = 1.4105 M..1 s..1 This study 
k-12 = 5.4103 s..1 This study 
k-13 = 2.78109 s..1 This study 
k13M = 3.310..8 M This study 
k-12M = 4.5610..7 M This study 
k-13M = 104 M This study 

Table 7.2: Model parameters: rate constants of mass-action and Michaelis-Menten 
kinetics. Last 12 parameters in bold line (k9-to-k-13M) are the result from 
optimization techniques. 

152 


7.3 Simulation
7.3.2 Model Behavior 
We analyzed the dynamics of the integrative model of MSAC and EFM mechanisms. 

Figure 7.2 displays concentrations of the key players over time. For the Dissociation 
variant, we have selected the time range such that each concentration can reach 
steady state. For all species dynamic of both Dissociation as well as Convey variant 
see Figure 7.3. For all integrations, the concentrations and rates of Table 7.2 were 
chosen including those 12 parameters that were optimized. Before attachment (25 
mins), four of these key players (APC:Cdc20, APC:Cdh1; Cdh1, Cdc14A*) are 
very low, while only, Cyclin B, Securin, and Cdc14A have high concentration. Once 
attachment takes place, things are changed (after 25 mins). In general, Cdc14A*, 
Separase, become high gradually over time. Cyclin B and Securin are degrading 
gradually once MSAC deactivates. APC:Cdc20 activates fast, degradates Securin 
and the rst phase of Cyclin B to be ended with very low concentration at 30mins 
of its activation. Meanwhile, once Cdh1 is available, APC:Cdh1 will be formed 
and increase fast. APC:Cdh1 make full degradation of Cyclin B as well as Cdc20. 

153



05001000150020002500300035004000450000.511.52x 10-7Time (s)
Species concentration (M) 
APC:Cdc20APC:Cdh1Cdh1Cdc14A*
Cdc14ASeparaseCyclinBSeparaseSecurinAPC:Cdc20154
Figure 
7.2: 
Key 
species 
concentration 
over 
time 
for 
the 
Dissociation. 
Spindle 
attachment 
occurs 
at 
1500 
sec 
(switching 
parameter 
u 
from 
1 
to 
0 
and 
u
. 
from 
0 
to 
1)
. 
Parameters 
are 
setting 
according 
to 
Table 
7.2. 


7.4 Model Validation
7.4 Model Validation 
The optimized parameter set and initial concentration results in the expected 
model behavior. Yet, when an initial concentration or a kinetic parameter value 
is changed the model behavior might change as well accordingly. In order to 
validate our model, we tested dierent mutations (deletion and over-expression) 
of the proteins and complexes involved, measured in dierent organisms. Model 
validation will be performed for a number of species elements. That are either 
part of the MSAC or the EFM mechanisms. Numerous empirical data have been 
reported for mutation experiments (see Chapter 5.3.2). Our integrative model is 
able to explain dierent mutation phenotypes. We will discuss, some mutations 
of essential proteins in details, namely the APC's activators, Cdc20 and Cdh1. 
We also discuss the eect of FEAR and MEN parameter. 

Cdc20 deletion might cause checkpoint failure (e.g. reduce the binding of C-Mad2 
to Cdc20, cells leave mitosis and oral cancer, see for example, Hwang et al., 1998; 
Mondal et al., 2007b). In dierent organisms Cdh1 deletion can cause delay of 
Cyclin B degradation as well as EFM delay but does not block mitosis (Sudo 
et al., 2001; Sigrist and Lehner, 1997; Kitamura et al., 1998; Yamaguchi et al., 
1997; Schwab et al., 1997). With respect to over-expression, Cdc20 over-expression 
cause failure in MSAC function and arrests in metaphase (Zhang and Lees, 2001b; 
Shirayama et al., 1999). Cdh1 over-expression data is not available yet. 

For Cdc20 deletion in our model, the concentrations of the model components are 
rather stable, that is, they are almost not aected by microtubule attachment. 
However, in the case of Cdh1 (inactive form) deletion (100folds), the APC:Cdc20 
concentration stays high and no APC:Cdh1 is presented (Figure 7.5 B) which 
means Cyclin B inhibition failure, while for Cdc20 deletion (100folds) these 
concentrations are approximately zero (Figure 7.5 A). In the case of Cdh1 or Cdc20 
over-expression, many component concentrations were aected. In particular, for 
Cdh1 over-expression (100folds) the APC:Cdc20 concentration remains low before 
attachment and switches to high after attachment rather short time, which aect 
Securin degradation (Figure 7.6 B). For Cdc20 over-expression (10000folds, less 

155



7. INTEGRATIVE MODEL OF MITOSIS TRANSITION 
CONTROL MECHANISMS 
A-DissociationVariant
05001000150020002500300035004000450000.511.52x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20APC:Cdh1Cdh1Cdc14A*
Cdc14ASeparaseCyclinB
B-Convey variant


05001000150020002500300035004000450000.511.52x 10-7Time (s)
Species concentration (M) 
Mad1:C-Mad2O-Mad2Mad1:C-Mad2:OMad2*
Cdc20:C-Mad2Bub3:BubR1MCCBub3:BubR1:Cdc20APCMCC:APCAPC:Cdc20APC:Cdh1Cdh1Cdc14A*
Cdc14ASeparaseCyclinB
Figure 7.3: Species concentration over time for the both Dissociation and Convey 
variant (wild type). Spindle attachment occurs at t = 1500s, then MSAC becomes 
silent and EFM triggers. Parameters are setting according to Table 7.2. Both 
variants are equally suitable, by which the Convey variant is slightly faster). 

156



7.4 Model Validation
has no qualitative eect), the APC:Cdc20 concentration is relatively high before 
attachment (Figure 7.6 A) resulting in checkpoint failure. 

Mutants in FEAR pathway show only delay in activation of Cdc14 while mutants 
in MEN block at telophase (Stegmeier et al., 2002). The FEAR pathway is still 
essential (Queralt et al., 2006; Sullivan and Uhlmann, 2003), but maybe its full 
mechanism is not yet known. In human, most FEAR as well as MEN candidates 
are not yet identied. Therefore, we discuss the eect of both FEAR and MEN 
pathways qualitatively as a function of separase with an additional parameter R 
(see reaction Eq.(7.12)), which is dened mathematically as follows: 

f(Separase;R) = [Separase] * R (7.18) 

where R dened as: 
1 + FEAR 

R = MEN * (). (7.19)

2 + FEAR

Note that R is set to be the Michaelis-Menten constant k..12 (see Table 7.2). The 
dependence of R on the FEAR pathway can be seen in Figure 7.4. 

010203040506070809010000.20.40.60.811.2FEAR pathwayEffect 
FEAR pathway
Figure 7.4: FEAR pathway eect on the parameter R. FEAR eect is between 0 
and 1 which has only very limited impact on R. In contrast MEN eect is linear 
as dened in Eq.7.19. 

157 


7. INTEGRATIVE MODEL OF MITOSIS TRANSITION 
CONTROL MECHANISMS 
When we reduce the parameter R by inhibiting FEAR pathway, we found very 
similar behavior to the wild type (see Figure 7.7 B), while when inhibiting the 
eect of MEN (only reduced 10 order of magnitude), we got mitosis block (see 
Figure 7.7 B). For quantitative eect of FEAR and MEN, more experimental data 
is required. These can be easily integrated into our model. 

7.5 Concluding Remarks 
We have consolidated and validated an in silico dynamical model based on a 
biomolecular reaction network (Figure 7.1). The model consists of 19 species, 15 
reactions and 27 parameters. Twelve parameters are unknown and have been tted 
using two evolutionary and one deterministic optimization techniques; namely 
CMA-ES, DE, and HJ algorithm, respectively. Despite the model complexity, the 
network still does not contain all the biochemical interactions (e.g. FEAR and 
MEN details). The reason is that most of these reactions are not yet identied in 
Human. However, it can be easily integrated into our model. 

The most important features are to show the interaction and dynamics of each 
species over time (Figure 7.3). In particular, to capture APC functions which were 
not computed in Chapter 5. APC:Cdc20 function is the activation of Separase and 
dissolution of the Cohesin complex, and chromatid separation. Another function is 
to degrade the rst phase of mitotic Cyclin (Cyclin B:Cdk1). APC:Cdh1 function 
is to fully degrade the mitotic cyclin. Our integrative model of mitosis transition 
control mechanisms reproduces in detail the behavior of wild-type and mutant. 

158



7.5 Concluding Remarks
A-Cdc20deletion
05001000150020002500300035004000450000.511.52x 10-7Time (s)
Species concentration (M) 
APC:Cdc20APC:Cdh1Cdh1Cdc14A*
Cdc14ASeparaseCyclinBSeparaseSecurin
B-Cdh1 deletion


05001000150020002500300035004000450000.511.52x 10-7Time (s)
Species concentration (M) 
APC:Cdc20APC:Cdh1Cdh1Cdc14A*
Cdc14ASeparaseCyclinBSeparaseSecurin
Figure 7.5: Simulation of Cdc20 and Cdh1 mutations. For deletion we set the 
respective initial concentration 100 times lower. 

159



7. INTEGRATIVE MODEL OF MITOSIS TRANSITION 
CONTROL MECHANISMS 
A-Cdc20 over-expression


05001000150020002500300035004000450000.511.52x 10-7Time (s)
Species concentration (M) 
APC:Cdc20APC:Cdh1Cdh1Cdc14A*
Cdc14ASeparaseCyclinBSeparaseSecurin
B-Cdh1 over-expression


05001000150020002500300035004000450000.511.52x 10-7Time (s)
Species concentration (M) 
APC:Cdc20APC:Cdh1Cdh1Cdc14A*
Cdc14ASeparaseCyclinBSeparaseSecurin
Figure 7.6: Simulation of Cdc20 and Cdh1 mutations. For for over-expression 
10000 times higher of Cdc20 while only 100 times higher Cdh1. 

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7.5 Concluding Remarks
A-FEARinhibition
05001000150020002500300035004000450000.511.52x 10-7Time (s)
Species concentration (M) 
APC:Cdc20APC:Cdh1Cdh1Cdc14A*
Cdc14ASeparaseCyclinBSeparaseSecurin
B-MEN inhibition


05001000150020002500300035004000450000.511.52x 10-7Time (s)
Species concentration (M) 
APC:Cdc20APC:Cdh1Cdh1Cdc14A*
Cdc14ASeparaseCyclinBSeparaseSecurin
Figure 7.7: Simulation of FEAR or MEN pathway inhibition. Parameter R is 
reduces 10 order of magnitude for MEN inhibition and 0.1 for FEAR according to 
Section 7.4 

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7. INTEGRATIVE MODEL OF MITOSIS TRANSITION 
CONTROL MECHANISMS 
162



\Every object that biology studies is a system of systems.” 

Francois Jacob (1974) 

\How everything is connected to everything else and what 
it means for science, business and everyday life". 

Albert-Laszlo Barabasi (2002) 

Chapter 8 

Conclusion 

Mitosis progression is a tightly regulated process. Eukaryotic cells, indeed, have 
evolved surveillance transition control mechanisms regulating the transition from 
any given stage of cell division to the next one. The so called `Mitotic-Spindle-
Assembly-Checkpoint (MSAC)’ and `Exit-From-Mitosis (EFM)’ are examples 
of such mechanisms. MSAC prevents a dividing cell's progression into anaphase 
until all chromosomes are properly attached to the mitotic spindle, whereas 
EFM guarantees that each of the two daughter nuclei receives a single copy 
of each chromosome. In principle, MSAC controls the activity of a complex of 
proteins called \Anaphase Promoting Complex", or APC, during the transition 
from metaphase to anaphase, when chromosomes are not yet attached. APC 
becomes inactive after all chromosomes are attached. APC interacts with its 
co-activator, a protein called \Cell Division Cycle", or Cdc20. The function of 
the ensuing complex `APC:Cdc20’ is twofold. First, it activates a protein called 
`Separase', involved in breaking-up the so called `Cohesion ring'; this leads to 
the separation of the sister chromatids. Second, APC:Cdc20 is involved in the 
partial degradation of `Cyclin B', a mitotic cyclin. Mitosis then progresses and 
becomes the subject of the second transition control mechanism, EFM. Generally 
speaking, EFM guarantees a full degradation of Cyclin B via the activity of a 
complex called `APC:Cdh1', formed by APC and its second co-activator, a protein 
called Cdh1. After the full degradation of Cyclin B, the process of cell division 

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8. CONCLUSION
progresses into cytokinesis. Both MSAC and EFM have complex dynamics and 
involve numerous interacting elements. This is probably the reason why their 
functional and topological structures remain still poorly understood. At present, 
for example, no model provides a satisfactory account of how MSAC actually works. 
In contrast, there are several models -all them based on data from yeast-describing 
how EFM works. Still, these two mechanisms have not yet been incorporated into 
a single model. We aimed to contribute towards an integrative model addressing 
both MSAC and EFM in human cells. 

To this end, we built-up a series of dynamic models based on empirical data, 
and tested their ensuing predictions on the functioning of both MSAC and EFM. 
Our in-silico approach suggests that cells are unable to completely sequester 
`Cdc20', thereby preventing the formation of the complex `APC:Cdc20'. It also 
suggests that it is an interaction between APC and another regulatory element of 
mitosis, MCC, that explains APC's lack of activity of during metaphase, necessary 
for the progression of the ongoing process (see Chapters 5 and 4). Moreover, 
previous modeling approaches to MSAC , captured by the so called \Template” 
and \Exchange” models, had led to somehow contradictory views on its underlying 
regulation. Intriguingly, our simulations gave partial support to only one of such 
models (see Chapter 3). Finally, we simultaneously addressed the functioning 
of both transition control mechanisms, MSAC and EFM, by incorporating an 
adapted EFM model involving the activity of `APC:Cdh1’ into an integrative 
model that also involves the activity of `APC:Ccd20’ (see Chapter 7). Our results 
also stress important, additional questions. Answering these questions, however, 
demands understanding how the mechanisms controlling mitosis work in three 
dimensions. This requires, in turn, developing specic and suitable tools. We 
currently develop a software tool called \Mitosis Arena", in order to test network 
models of mitosis embedded in a three-dimensional (3-D) framework. \Mitosis 
Arena” will be available to the scientic community so that alternative models 
could easily be studied within a dynamical 3-D environment. It has been designed 
in accordance with standard languages, and would eventually be combined with 

other Systems Biology software tools. 

164 


Molecular biology has progressed extraordinarily by rapidly producing huge 
amounts of empirical data. Yet, what is frequently missing in molecular approaches to biology is a robust account of the structure and dynamics of the 
-typically complex-networks serving the various cellular functions being studied. 
The emergent interdisciplinary eld of \Systems Biology” studies cells as networks 
of interacting molecules using an integrative approach to theory. It deals with 
modeling and simulation, and involves concepts from mathematics, computer 
science, physics, biochemistry, and engineering. Typically, in such studies models 
are used to highlight principles, design experiments, or to act in a predictive 
mode to specically modify cellular behavior. Mitosis is an exceedingly complex 
process, and molecular biologists typically characterize the activity, aggregation 
and interactions of tens of cellular elements involved in mitosis, although the 
relation between such interacting elements and their respective environment remains still elusive. Predictions, therefore, are not straightforward. There is a 
need for a system-level understating of the regulatory mechanisms involved in 
mitosis. This might be of major relevance for medical research, and for a better 
understating of other cellular processes, as well. We refer to the present work 
as to a \Systems Biology of Mitosis", with emphasis on human cells, simply 
because we beneted from modeling and simulation approaches embedded in a 
cross-disciplinary framework, in order to contribute to a deeper understanding 
of mitotic regulatory mechanisms. Eventually, our \Dissociation” and \Convey” 
model variants would prove fruitful in designing further laboratory experiments. 

165



8. CONCLUSION
166



\Every new body of discovery is mathematical in form 
because there is no other guidance we can have". 

Charles Darwin (1809-1882) 

\No great discovery was ever made without a bold guess". 

Isaac Newton (1642-1727) 

Appendix A 

Modeling and Simulation for 
Systems Biology 

A.1 Prologue 
\Today we increasingly recognize that nothing happens in isolation. Most events 
and phenomena are connected, caused by, and interacting with a huge number of 
other pieces of a complex universal puzzle. We have come to see that we live in a 
small world, where everything is linked to everything else. We are witnessing a 
revolution in the making as scientists from all dierent disciplines discover that 
complexity has a strict architecture. We have come to grasp the importance of 
networks” (Barabasi, 2002). 

Biological regulatory mechanisms, including mitosis, are inherently complex and 
highly cross linked (as seen in Chapter 2). They cannot be understood from 
re
ections on the individual components (proteins, complexes etc) alone, but 
should be understood through considerations involving all components at the 
same time. Thus, mathematical network models formalism is used. It is a 
fundamental and quantitative way to understand and analyze complex systems 
and phenomena, complement to theory and experiments, and often integrate them, 

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A. MODELING AND SIMULATION FOR SYSTEMS BIOLOGY
Models Classications


Quantitative Qualitative 
Deterministic Stochastic (Probabilistic) 
Geometrical Physical 
Static Dynamic 
Descriptive Normative 
Linear Non-Linear 
low dimension space 
. . . . . . 

Table A.1: Several model classications in science and engineering 

synthesize control, verify hypotheses, improve design, and prediction. It becomes 
widespread in biology and medicine. 

In a more general overview, models are either stochastic, deterministic or mixed 
approaches. Many model classications can be found in the literature where they 
might dier for each eld of research (e.g. Table A.1). It is rather dicult to do 
such classications for systems biology. For instance, biological systems are not 
binary entities, in which something is either on or o; they could be stochastic, 
subject to nonlinear behavior. Nevertheless, in this chapter we will try to give an 
overview classications of modeling for systems biology, taking into account aim(s) 
and ability(ies) of a model; namely, \Network (descriptive) models", \Algebraic 
(discrete dynamical) models ", \Time dynamical models", and \Space dynamical 

models". 

Before starting our classication, you can have an outlook on the process of 
building a model (Figure A.1). Moreover, we are going to review, in particular, 
for non modelers, some colligated concepts that you might need to follow this 
chapter. 
System: is a set of interacting or interdependent entities working together 
towards some kind of process. All systems have inputs, outputs, and feedback, 
and maintain a basic level of equilibrium. For example, in the human body the 
heart functions to support the circulatory system, which is vital to the survival of 

168



A.1 Prologue
Figure A.1: Models build and use. Starting from the real world system. Gathering knowledge, make hypothesis, then build a model using a suitable modeling 
approach. The model should capture the expected behavior and in agreement 
with experimental ndings. Validation like mutation experiments will explain the 
solidity of the model. Intrinsic properties can lead to deeper understanding (e.g. 
robustness, sensitivity of parameters, bifurcation analyzes). Ended with possible 
prediction and experimental design. Solid lines refers to usual interactions, while 
dash lines refers to possible interactions. 

169 


A. MODELING AND SIMULATION FOR SYSTEMS BIOLOGY
the entire body. Scientists have examined and classied many types of systems, 
following some examples: 
-Isolated System -a system that has no interactions beyond its boundary layer. 
Many controlled laboratory experiments are this type of system. 

-Closed System -is a system that transfers energy, but not matter, across its 
boundary to the surrounding environment. Our planet is often viewed as a 
closed system, also mechanical systems are closed systems. 

-Open System -is a system that transfers both matter and energy can cross its 
boundary to the surrounding environment. People are open systems in that 
they must interact with their environment in order to take in food, water, and 
obtain shelter. 

-Control System -a system that can be intelligently manipulated by an external 
action. 

Model: is a simplied description or representation of a system that may be 
used to predict or explain the behavior of the system. 

Ordinary Dierential Equation (frequently called ODE): a dierential equations1(DE) that involves only one independent variable is called ordinary dierential equation. 

An ODE of order n is an equation2 of the form F (t, y, y0, :::, y[n], P) = 0, where 
t is the time, y is an independent variable, and P is vector of phenomenological parameters. ODEs may have initial conditions3 or boundary conditions4 . 

1Dierential Equation (frequently called DE): is an equation that involves the deriva
tives of a function as well as the function itself. 
2Equation(s): describe the relations between the dependent and independent variables. 
An equal sign \=” is required in every equation. 

3Initial Condition: Constrains that are specied at the initial point, generally time point, 
are called initial conditions. Problems with specied initial conditions are called initial value 
problems (IVPs). 

4Boundary Condition: Constrains that are specied at the boundary points, generally 
space points, are called boundary conditions. Problems with specied boundary conditions are 
called boundary value problems (BVPs). 

170 


A.1 Prologue
Moreover, ODEs have properties like order1 and degree2 and could be linear3 or 
homogeneous4 . 

Partial Dierential Equation (frequently called PDE): a DE that involves 
two or more independent variables is called partial dierential equations. An 
widespread example for systems biology is the Reaction-Diusion systems: 

@[Ci] 

@t 
= 
. 
Dir{. 
2[Ci]
. 
+ 
. 
Ri(f[C
{zj]g, P)
. 

Diusion Reaction 

The rst term on the right hand side represent the diusion and the second one 
represent the biochemical reactions. Where [Ci] refers to the concentration of 
species, . is the spatial gradient. Di denotes to the constant diusion coecients 
for species, i =1, :::, n, t adverts the time, and P refers to phenomenological 
parameters. 

Stochastic Dierential Equation (frequently called SDE): is a DE in which 
one or more of the terms is a stochastic process, thus resulting in a solution which 
is itself a stochastic process. Typically, SDEs incorporate white noise (see example 
below) which can be thought of as the derivative of Brownian motion (or the 
Wiener Process); however, it should be mentioned that other types of random 

uctuations are possible. We should emphasize, that SDEs can be ordinary (see 
following example) or partial, which is hard to handel numerically. 

1Order: The order of a dierential equation is the highest power of derivative which occurs 
in the equation, e.g., Newton's second law produces a 2nd order dierential equation because 
the acceleration is the second derivative of the position. 

2Degree: The degree of a dierential equation is the power of the highest derivative term. 

3Linearity: A dierential equation is said to be linear if each term in the equation has only 
one order of derivative, e.g., no term has both y and the derivative of y with respect to time. 
Also, no derivative is raised to a power. 

4Homogeneousity: A dierential equation is said to be homogeneous if there is no isolated 
constant term in the equation, e.g., each term in a dierential equation for y has y or some 
derivative of y in each term. 

171 


A. MODELING AND SIMULATION FOR SYSTEMS BIOLOGY
For each species i, the stochastic Langevin-type equation (a well known example 
type of SDEs) has the following form: 

d[Ci] . 

dt 
=RH(f[Cj]g, P) + Wi(t)2 · [Ci]

Ni · 

where RH is the original right-hand side of the deterministic equation and Wi(t) 
is the (multiplicative) Gaussian white noise for species i with zero mean and unit 
variance 

hWi(t). =0, hWi(t)Wi(t0). = (t - t0). 

N = Ni denotes the noise amplitude parameter, which, for simplicity, is the same 
for all species. P refers to a vector of phenomenological parameters. 

172



A.2 Network Models
A.2 Network Models 
Network models are crucial for shaping our understanding of complex networks 
and help to explain the origin of observed network characteristics. Rapid advances 
in biological network indicate that cellular networks are governed by universal laws 
and oer a new conceptual framework that could potentially revolutionize our view 
of biology and disease pathologies in the twenty-rst century (Barabasi and Oltvai, 
2004). Network models have become common in a wide range of disciplines. In 
particular, systems biology has focused attention on the need to study biological 
systems from a \top-down” point of view rather than from a reductionist \bottomup” point of view. Thus, networks have to be studied. Recent revolutionary 
technological advances have made it possible to study the molecular networks 
that make up the complex intracellular biochemistry of organisms, including gene 
regulatory networks, signal transduction networks, and metabolic networks. The 
availability of system-level data for these networks makes it possible to represent 
complex biochemical reaction networks through mathematical network models. 

Gene Regulatory Networks. (also called a GRN or genetic regulatory network). 
Genes are stretches of DNA that, once activated, are transcribed into mRNA. 
The mRNA fragments then are translated into proteins that carry out the cellular 
processes. The activation of genes depends on the binding of specic proteins called 
transcription factors to the promoter region of a gene. Within gene regulatory 
networks, the nodes represent genes, and the links specify how a gene activates or 
inactivates other genes. Gene regulatory networks are modeled using a variety of 
dierent techniques. See review by de Jong (2002) for an overview. 

Signal Transduction Networks. Cells detect external signals by receptor proteins permeating the cell membrane. The signal is then propagated through a 
phosphorylation cascade inside the cell and nally reaches the nucleus where a 
change in transcription constitutes the response to the extracellular signal. In 
such networks, the nodes represent proteins and compounds that are involved in 
signal detection, propagation, and processing. The links can detail biochemical 
reactions or on a more abstract level functional and causal relationships between 

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A. MODELING AND SIMULATION FOR SYSTEMS BIOLOGY
the nodes. A review on the reconstruction and analysis of signal transduction 
networks is provided by Papin et al. (2005). 

Metabolic Networks. The uptake and utilization of nutrients within the cell 
is detailed in metabolic networks. Nutrients enter the cell and are consecutively 
transformed into dierent metabolites by enzymes. These processes can be modeled 
in networks where the nodes represent the metabolites and the links the enzymatic 
reactions. An overview on modeling and analyzing metabolic networks is given 
in (Heinrich and Schuster, 1996). 

Beside these intracellular networks, many more biological networks exist. Considering a slightly larger scale, cells communicate with each other in intercellular 
networks as the endocrine network and the immune network. On an even larger 
scale, the species within an ecosystem form foodwebs, a special network describing 
which species depend on which others as their food source. And nally, on a 
more abstract level, the evolutionary lineage of species can be depicted in phylogenetic trees and networks (reviewed by Centler (2008)). In this studies, we use 
biochemical network (signal transduction networks) as a base of our models. 

A.3 Algebraic Models (Discrete/State Time) 
In recent years, methods from algebra, and discrete mathematics play an important 
role in systems biology, through the use of discrete dynamical models and the use 
of theoretical concepts for their analyzes. We are going to give a brief review of two 
algebraic methodologies for systems biology: Theory of Chemical Organizations 
and Petri Nets (PNs) models. We will explain PNs because its widespread use 
and application as well as Organization theory which is new and growing fast 
approach. 

A.3.1 Theory of Chemical Organizations 
The theory of chemical organizations (Dittrich and Speroni di Fenizio, 2006) 
provides a new method to analyze complex reaction networks. Extending ideas 

174



A.3 Algebraic Models (Discrete/State Time)
by Fontana and Buss (1994), one main objective is to determine combinations of 

network species that are more likely to be present over long periods of (simula

tion) time than others. Such sets of species are called organizations. To be an 

organization, a species set has to fulll two properties (for review see Kaleta et al. 
(2007). 

Algebraic closure and self-maintenance. The rst property – closure – ensures 
that given the molecular species of an organization, there is no reaction within 
the reaction network that could create a novel species not yet present in the 
organization. The second property – self-maintenance – guarantees that every 
molecular species that is consumed within the organization can be recreated from 
organization species at a sucient rate for its maintenance. 

A rigorous link between organizations and the potential dynamics of a reaction 
system is provided by Theorem 1 from Ref. (Dittrich and Speroni di Fenizio, 2006): 
Assume that the dynamics is modeled as a \chemical” dierential equation system 
dx(t)=dt = Sv(x(t)),(where S is a Stoichiometry matrix1, and v is a 
ux2 vector) 
then all steady states of the system are instances of organizations. In other words, 
the species with concentration levels greater than zero in a particular steady state 
are exactly those species contained in a corresponding organization. Note that 
organizations do not necessarily contain a steady state, as they can also embody 
growth in which species have increasing concentrations. 

Organization theory is an ecient approach to analyze large scale network models. 
The theory handles a discrete time state, and has been applied in dierent 
areas (Centler, 2008). However, this theory is not able yet to include rates of 
a chemical reaction (fast, intermediate, slow,...) and inhibition rules. Future 
work needs for recognizing dierent types of steady states (e.g. nd and handel 
chaotic behavior), or even include time. These more open question need to be 
addressed by the organization theory teams in the future. Finally, if you will 
try our MSAC models for instance with organization theory, we see only two 
organization, one for all species and one with very low number. It can give 

1Stoichiometry Matrix: is the calculation of the quantities of reactants and products in 
a chemical reaction. 

2Flux: is the speed of a chemical reaction 

175 


A. MODELING AND SIMULATION FOR SYSTEMS BIOLOGY
us qualitative behavior, or steady states. It is unable, yet, to reproduce any 
quantitative results. Thus, we are not going to use organization theory in this 
thesis. 

A.3.2 Petri Nets 
Petri nets (PNs) have been named after Carl Adam Petri who invented them early 
sixties (Petri, 1962). It provides a graphical notation with a formal mathematical 
semantics for modeling and reasoning about concurrent, asynchronous, distributed 
systems. A Petri net is a directed bipartite graph and consists of four basic 
components: places, which are denoted by circles; transitions denoted by rectangles; 
arcs denoted by arrows; and tokens denoted by black dots. An example of a Petri 
net for the template model is given in Figure A.2. The places, transitions and 
arcs describe the static structure of the Petri net. Each transition has a number 
of input places (places with an arc leading to the transition) and a number of 
output places (places with an arc leading to them from the transition). It normally 
views places as representing resources or conditions and transitions as representing 
actions or events. Note arcs that directly connect two transitions or two places 
are not allowed (Murata, 1989; Steggles et al., 2007). 

Petri Nets of various dierent kinds have been used in several studies in systems 
biology, both as structural network models for qualitative analyzes and as quantitative models using high level nets (Pinney et al., 2003; Sackmann et al., 2006; 
Chaouiya, 2007). 

These discrete-qualitative methods have the advantage that they only require 
information about the stoichiometry and reversibility of the constituent reactions, 
rather than relying on the availability of measurements of kinetic parameters. 
However, overcoming the combinatorial explosion associated with larger networks 
is recognized as a dicult challenge for these new approaches to networks analyzes. 

Since our aim and interest is on quantitative approaches and therefore, we are 
not going to use PNs model. We show here an example of the template model 
(Figure A.2), in such an example and so for our models and in general for 

176



A.4 Time Dynamical Models
O-Mad2Mad1:C-Mad2Mad1:C-Mad2:O-Mad2SCdc20:C-Mad2Cdc20PlaceTokenTransitionArcLegend
Figure A.2: Petri Net example: The Template model for Mad1 and Mad2 function 
of sequestering Cdc20 (for details see Chapter 3). We use colored Petri Net, e.g. 
red transition to emphasize the kinetochore eects (details in Chapter 3). 

modelers, PNs is a good starting point to get an idea about the discrete dynamics 

or what could be expected from a dynamical model. In the following section, rich 
(continuous) dynamical modeling will be surveyed. 

A.4 Time Dynamical Models 
Understanding the dynamical behavior of a biological systems from the interaction 
of its molecular species is a rather dicult task (Bryja et al., 2004). A model based 
approach proposes a framework to express some hypotheses about a dynamical 
system and make some predictions out of it, in order to compare with experimental 
observations. Traditional approaches include dierential equations (deterministic 
models) or stochastic processes (stochastic models). 

A.4.1 Deterministic versus Stochastic (Probabilistic) Models 
The most widespread formalism to model dynamical systems in science and 
engineering, ordinary dierential equations (ODEs) have been widely used to 
analyze biological systems. The ODE formalism models the concentrations of 

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A. MODELING AND SIMULATION FOR SYSTEMS BIOLOGY
proteins, and other molecules by time-dependent variables with values contained 
in the set of nonnegative real numbers. Regulatory interactions take the form of 
functional and dierential relations between the concentration variables. 

Stochastic (or Probabilistic) modeling usually starts by describing real world 
objects on dierent spatial and temporal scales and uses dierent advanced 
mathematical approaches and techniques. It can be simple to reproduce the 
deterministic behavior (e.g. ODEs), or to bring more detailed modeling (interacting 
systems of individual agents or particles, random walks, random media). 

Generally, stochastic kinetic models are more detailed. The disadvantage of a 
stochastic kinetic analyzes is that it can be computationally expensive, making 
such implementations impractical or impossible. A comparison between both 
approaches is shown in Table A.2. 

178



A.4 Time Dynamical Models
Deterministic versus Stochastic models


-Deterministic approaches -Stochastic approaches


-Less complicated. -More complicated.
-Input determines unique output. -Produce dierent results for


the same input. 
-Reproducible results/simulations. -Include random in
uences. 
-Easy to analyze. -Rather dicult to analyze and 

usually averaged results of interest. 
-Often good enough and secure. -Could lead to a insecure sense. 
-DEs methods require considerable -Common and easy to impliment. 

mathematical skill and understanding 

(not common among biologists). 
-Hard to capture noise or any stochasticity. -Can be captured noise and stochasticity. 
-In some cases, it can not (or hardly) -Can be always simulated. 

simulated 
-Required less knowledge. -Required more knowledge 
-Computationally less expensive. -Computationally much more expensive. 

.. 

.. 

.. 

Table A.2: Deterministic versus stochastic models: A comparison overview.


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A. MODELING AND SIMULATION FOR SYSTEMS BIOLOGY
A.4.2 Multi-Scale Models 
Typically, the same system can be modeled on dierent scales, and it is of crucial 
interest to study the interaction of dierent modeling approaches in systems 
biology. Practitioners even describe dierent scales of biological models, which are 
generally grouped into the three scaling categories: macroscopic1 , mesoscopic2 , 
and microscopic3, (or concisely, as macro-, meso-, micro-, scales). 


Figure A.3: Multi-scale modeling scheme in systems biology. Characterizing the 
simulation time and length scales. starting from Macroscale and ended with 
Molecular scale, where u is meter unit. 

1The prex \macro” comes from the Greek word, \mackros” that means long. Macroscopic 
objects are those that can easily be seen by humans. 

2The prex \meso” comes from the Greek word \mesos” meaning \intermediate". 

3The prex \Micro” comes from the Greek word \mikros” meaning small. In the everyday 
world the word microscopic is used to refer to objects that are too small for the unaided eye to 
see. People often think of bacteria or viruses when considering the microscopic world. 

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A.4 Time Dynamical Models
Macroscopic. The term \Macroscopic” is used to describe the largest scale of 
modeling. For example, dynamic of molecule concentrations mostly is represented 
in deterministic models (dierential equations). 

Advantages and disadvantages at macroscopic scales: 
-Macroscopic model fails in small-length-scale regions. 
-Microscopic details are usually not included. 
-Lot of calculations but fast (should be carefully handel, e.g. stiness systems). 

Microscopic. Microscopic simulation models on the other hand are at the opposite end of the spectrum which is mostly stochastic models (e.g. interacting 
systems of individual agents or particles, random walks, random media). 

Advantages and disadvantages at microscopic scales: 

-Control over each component. 

-Dicult implementation and tune. 

-Most realistic. 

Mesoscopic. Mesoscopic models fall between microscopic and macroscopic models. Dynamic of single molecules, without consideration of physical forces, mostly 
stochastic models. 

Advantages and disadvantages at mesoscopic scales: 

-Micro scale components deployed in a macro scale scenario. 

-Better interactions tuning. 

-Attributes of molecules are not consider. 

One can start with macroscopic level (usually dierential equations), for an 
overview of an essential continuous dynamics, then one moves to detailed microscopic level, the analysis of their long-time or average behavior and large deviations 
gives rise to models on the mesoscopic level. Analyzing these models on any level 
is a necessary prerequisite for their practical use. 

We should emphasize that properties of a stochastic model could lead to a dierent 
behavior from that of a deterministic model for intracellular kinetics that initially 

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A. MODELING AND SIMULATION FOR SYSTEMS BIOLOGY
involved a low number of reactants. The reason might be due to the assumption 
of continuity of biochemical species in the deterministic model. In this thesis, 
quantitative modeling approach will be used. Additionally, stochastic eects will 
be examined. 

A.5 Space Dynamical Models 
Time dynamics can produce quantitative output for each time step. It can capture 
behavior, intrinsic properties, like bifurcation analyzes, robustness, etc, and even 
predict. Thus, it is widely used in systems biology. To keep going for deeper 
understanding of topological 'environment’ (structure, diusion, locations, binding 
sides) There are two disadvantages of space dynamical models. First, they need 
more kinetic knowledge, which are usually hard to get from the lab and not precise; 
second, it is computationally very expensive (consume very long time). 

Classic spatial approaches use PDEs or SPDEs, which are able to acquire macroscopic details of a system for each time point and anywhere. Stochastic simulations 

(e.g. cellular automata, particles simulations) are used for capturing meso or 
microscopic levels. 
A.6 Methods 
\An idea which can be used once is a trick. If it can be used more than once it 
becomes a method.” George Polya and Gabor Szego 

Broadly speaking, we can divided methods into two categories our modeling 
approaches: Solvers (solving DEs mostly) and optimizations (parameters tting). 
For solving DEs dierent, we used dierent methods base on the DEs type. 

For ODEs, to solve the nonlinear systems of highly stiff ODEs, which arise in 
our optimization besides non stiff systems, a variety of computational approaches 
have been applied. In particular, we use high order (seven-eighth) Runge-Kutta 
(Fehlberg and Prince) formulas, a modied Rosenbrock formula, variable order 

182



A.6 Methods
Adams-Bashforth-Moulton, an explicit Runge-Kutta, backward dierentiation 
formulas, and an implicit Runge-Kutta formula. We switch between these methods 
automatically according to the system's stiness state. We implemented our code 
in MATLAB. The numerical results were also validated Octave's (Eaton, 2008) 
ODEs solver (LSODE solver) and Copasi (Mendes group at VBI and Kummer 
group at EML research, 2008). For SDEs, the simulations were performed using 
standard numerical techniques for stochastic dierential equations (including the 
strong implicit 1.5 order Runge-Kutta method, and the explicit Runge-Kutta 
method of order 1.5, Kloeden and Platen, 1999b). We implemented our code 
in (MATLAB , Matrix Labrotory) and/or Octave (Eaton, 2008). For PDEs 
in general use of Finite Element Methods (see tools example, COMSOL, 2008 
and VCell, 2008). 

Optimization methods for the estimation of unknown parameters are central 
and of great importance to this eld of research. For this task, evolutionary 
approaches as well as deterministic algorithms have been applied to infer parameters in biochemical models. The nonlinear evolutionary optimization was usually 
validated with an independent evolutionary optimizer (Ibrahim et al., 2007). For 
optimization we applied the covariance matrix adaptation nonlinear evolutionary 
strategy (CMA-ES) (Hansen and Kern, 2004; Hansen et al., 2003), Quasi-Newton 
and sequential quadratic programming. We validate with Dierential Evolution 
(DE) Storn and Price (1997). We encountered with problems in case of large 
search space. We demonstrate that parameter estimation can be eciently and 

more accurately performed using scaled search steps (Rohn et al., 2008). 

183



A. MODELING AND SIMULATION FOR SYSTEMS BIOLOGY
184



\Examples...show how dicult it often is for an 
experimenter to interpret his results without 
the aid of mathematics". Lord Rayleigh (1842 -1919) 

(Nobel Prize Laureate in Physics 1904) 

\The great tragedy of Science the slaying of a beautiful 
hypothesis by an ugly fact". Thomas H. Huxley (1725-95) 

Appendix B 

Template-like models 

B.1 ODEs of the Exchange model 
d[Mad1] 

= ..E :u[Mad1][O-Mad2] + k..2[Mad1:C-Mad2] + 

dt 
k3[Mad1:C-Mad2] - k..3[C-Mad2][Mad1] (B.1) 
d[O-Mad2] 

= ..k1[O-Mad2] + k..1[C-Mad2]..E :u[Mad1][O-Mad2] + k..2[Mad1:C-Mad2] + 

dt 
E[Cdc20:C-Mad2] (B.2) 
d[Mad1:C-Mad2] 

= E :u[Mad1][O-Mad2] - k..2[Mad1:C-Mad2] - k3[Mad1:C-Mad2] + 

dt 
k..3[C-Mad2][Mad1] (B.3) 
d[C-Mad2] 

= k1[O-Mad2] - k..1[C-Mad2] + k3[Mad1:C-Mad2] - k..3[C-Mad2][Mad1] ..

dt 
kE [C-Mad2][Cdc20] (B.4) 
d[Cdc20] 

= ..kE [C-Mad2][Cdc20] + E [Cdc20:C-Mad2] (B.5)

dt
d[Cdc20:C-Mad2]


= kE [C-Mad2][Cdc20] - E[Cdc20:C-Mad2] (B.6)

dt 

185



B. TEMPLATE-LIKE MODELS
B.2 ODEs of the Template model 
d[Mad1:C-Mad2] 

= ..T :u[Mad1:C-Mad2][O-Mad2] + T [Mad1:C-Mad2:O-Mad2]+ 

dt 

T :u[Mad1:C-Mad2:O-Mad2][Cdc20] (B.7) 
d[O-Mad2] 

= ..T :u[Mad1:C-Mad2][O-Mad2] + T [Mad1:C-Mad2:O-Mad2]+ 

dt 
T [Cdc20:C-Mad2] (B.8) 
d[Mad1:C-Mad2:O-Mad2] 

= T :u[Mad1:C-Mad2][O-Mad2] - T [Mad1:C-Mad2:O-Mad2] ..

dt 

T :u[Mad1:C-Mad2:O-Mad2][Cdc20] (B.9) 
d[Cdc20] 

= ..
T :u[Mad1:C-Mad2:O-Mad2][Cdc20] + T [Cdc20:C-Mad2] (B.10)

dt
d[Cdc20:C-Mad2]


= 
T :u[Mad1:C-Mad2:O-Mad2][Cdc20] - T [Cdc20:C-Mad2] (B.11)

dt 

B.3 ODEs of the Template model with the Ampli
cation eects 
d[Mad1:C-Mad2] 

= ..T :u[Mad1:C-Mad2][O-Mad2] + T [Mad1:C-Mad2:O-Mad2]+ 

dt 

T :u[Mad1:C-Mad2:O-Mad2][Cdc20] - 
k4[Cdc20:C-Mad2][O-Mad2] + k..4[Cdc20:C-Mad2:O-Mad2] (B.12) 
d[O-Mad2] 

= ..T :u[Mad1:C-Mad2][O-Mad2] + T [Mad1:C-Mad2:O-Mad2]+ 

dt 
T [Cdc20:C-Mad2] - k4[Cdc20:C-Mad2][O-Mad2] + 
k..4[Cdc20:C-Mad2:O-Mad2] (B.13) 
d[Mad1:C-Mad2:O-Mad2] 

= T :u[Mad1:C-Mad2][O-Mad2] - T [Mad1:C-Mad2:O-Mad2] ..

dt 

T :u[Mad1:C-Mad2:O-Mad2][Cdc20] (B.14) 
d[Cdc20:C-Mad2:O-Mad2] 

= k4[Cdc20:C-Mad2][O-Mad2] - k..4[Cdc20:C-Mad2:O-Mad2] ..

dt 
k5[Cdc20:C-Mad2:O-Mad2][Cdc20] (B.15) 
d[Cdc20] 

= ..
T :u[Mad1:C-Mad2:O-Mad2][Cdc20] + T [Cdc20:C-Mad2] ..

dt 
k5[Cdc20:C-Mad2:O-Mad2][Cdc20] (B.16) 
d[Cdc20:C-Mad2] 

= 
T :u[Mad1:C-Mad2:O-Mad2][Cdc20] - T [Cdc20:C-Mad2] ..

dt 
k4[Cdc20:C-Mad2][O-Mad2] + k..4[Cdc20:C-Mad2:O-Mad2]+ 

2k5[Cdc20:C-Mad2:O-Mad2][Cdc20] (B.17) 

186



B.4 ODEs of of p31 eects on the Template model
B.4 ODEs of of p31 eects on the Template model
d[Mad1:C-Mad2] 
dt 

d[O-Mad2] 
dt 

d[Mad1:C-Mad2:O-Mad2] 
dt 

d[Cdc20] 
dt 
d[Cdc20:C-Mad2] 
dt 
d[p31] 
dt 
d[Mad1:C-Mad2:p31] 
dt 

= ..T :u[Mad1:C-Mad2][O-Mad2] + T [Mad1:C-Mad2:O-Mad2]+ 

T :u[Mad1:C-Mad2:O-Mad2][Cdc20] 
..T :v[Mad1:C-Mad2][p31] + T [Mad1:C-Mad2:p31] (B.18) 
= ..T :u[Mad1:C-Mad2][O-Mad2] + T [Mad1:C-Mad2:O-Mad2]+ 
T [Cdc20:C-Mad2] (B.19) 
= T :u[Mad1:C-Mad2][O-Mad2] - T [Mad1:C-Mad2:O-Mad2] - 

T :u[Mad1:C-Mad2:O-Mad2][Cdc20] (B.20) 
= ..
T :u[Mad1:C-Mad2:O-Mad2][Cdc20] + T [Cdc20:C-Mad2] (B.21) 

= 
T :u[Mad1:C-Mad2:O-Mad2][Cdc20] - T [Cdc20:C-Mad2] (B.22) 

= ..T :v[Mad1:C-Mad2][p31] + T [Mad1:C-Mad2:p31] (B.23) 

= T :v[Mad1:C-Mad2][p31] - T [Mad1:C-Mad2:p31] (B.24) 

187



B. TEMPLATE-LIKE MODELS
B.5 ODEs of of p31 eects on the Template model 
with amplication 
d[Mad1:C-Mad2] 

= ..T :u[Mad1:C-Mad2][O-Mad2] + T [Mad1:C-Mad2:O-Mad2]+ 

dt 

T :u[Mad1:C-Mad2:O-Mad2][Cdc20] - 
k4[Cdc20:C-Mad2][O-Mad2] + k..4[Cdc20:C-Mad2:O-Mad2] - 
T :v[Mad1:C-Mad2][p31] + T [Mad1:C-Mad2:p31] (B.25) 
d[O-Mad2] 

= ..T :u[Mad1:C-Mad2][O-Mad2] + T [Mad1:C-Mad2:O-Mad2]+ 

dt 
T [Cdc20:C-Mad2] - k4[Cdc20:C-Mad2][O-Mad2] + 
k..4[Cdc20:C-Mad2:O-Mad2] (B.26) 
d[Mad1:C-Mad2:O-Mad2] 

= T :u[Mad1:C-Mad2][O-Mad2] - T [Mad1:C-Mad2:O-Mad2] ..

dt 

T :u[Mad1:C-Mad2:O-Mad2][Cdc20] (B.27) 
d[Cdc20:C-Mad2:O-Mad2] 

= k4[Cdc20:C-Mad2][O-Mad2] - k..4[Cdc20:C-Mad2:O-Mad2] ..

dt 
k5[Cdc20:C-Mad2:O-Mad2][Cdc20] (B.28) 
d[Cdc20] 

= ..
T :u[Mad1:C-Mad2:O-Mad2][Cdc20] + T [Cdc20:C-Mad2] ..

dt 
k5[Cdc20:C-Mad2:O-Mad2][Cdc20] (B.29) 
d[Cdc20:C-Mad2] 

= 
T :u[Mad1:C-Mad2:O-Mad2][Cdc20] - T [Cdc20:C-Mad2] ..

dt 
k4[Cdc20:C-Mad2][O-Mad2] + k..4[Cdc20:C-Mad2:O-Mad2]+ 
2k5[Cdc20:C-Mad2:O-Mad2][Cdc20] - 
T :v[Cdc20:C-Mad2][p31] + T [Cdc20:C-Mad2:p31] (B.30) 
d[p31] 

= ..T :v[Mad1:C-Mad2][p31] + T [Mad1:C-Mad2:p31] ..

dt 
T :v[Cdc20:C-Mad2][p31] + T [Cdc20:C-Mad2:p31] (B.31) 
d[Mad1:C-Mad2:p31] 

= T :v[Mad1:C-Mad2][p31] - T [Mad1:C-Mad2:p31] (B.32)

dt
d[Cdc20:C-Mad2:p31]


= T :v[Cdc20:C-Mad2][p31] - T [Cdc20:C-Mad2:p31] (B.33)

dt 

B.6 Materials, Methods, and Optimization 
The objective function f(P ) assigns a quality (i.e., a positive real number) to a 
given set of parameters P . In our case, the parameters are the reaction constants. 
In order to t the parameters with respect to the observed qualitative function of 
the MSAC control, we use the Cdc20 concentration before and after kinetochore 

188



B.6 Materials, Methods, and Optimization
attachment as a criterion. In each single simulation experiment, we simulate two 
phases of the spindle attachment status. Our simulation begins in the kinetochore 
unattached case (phase 1), until equilibrium is reached, then it continues in the 
attached state (phase 2), again, until steady state conditions are met. We measure 
the Cdc20 concentration at the end of each phase i, when all concentrations have 
reached steady state, and compare it with a user given value Ai, which describes the 
experimentally observed behavior. The two dierence values are combined linearly: 

f(P )= W1([Cdc20]Unattached - A1)2 + W2([Cdc20]Attached - A2)2 

where W1, and W2 are the weights which were 10, and 1 respectively. A1, and A2 
are the desired phase levels, which we set 0 and 0.01, respectively. 

For optimization we applied the covariance matrix adaptation nonlinear evolution strategy (CMA-ES) Hansen and Kern (2004), Quasi-Newton and sequential 
quadratic programming. To solve the nonlinear systems of highly stiff ODEs, which 
arise in our optimization besides non stiff systems, a variety of computational 
approaches have been applied. In particular, we use high order (seven-eighth) 
Runge-Kutta (Fehlberg and Prince) formulas, a modied Rosenbrock formula, 
variable order Adams-Bashforth-Moulton, an explicit Runge-Kutta, backward 
dierentiation formulas, and an implicit Runge-Kutta formula. We switch between these methods automatically according to the system's stiness state. We 
implemented our code in MATLAB. The numerical results were also validated 
with Copasi. The nonlinear evolutionary optimization was validated with an 
independent evolutionary optimizer. 

189



B. TEMPLATE-LIKE MODELS
190



\As far as the laws of mathematics refer to reality, 
they are not certain; and as far as they are certain, 
they do not refer to reality". Albert Einstein (1779 -1955) 

\If you don't fail regularly you are not trying hard enough 
things". Ivan Sutherland (1938-) 

Appendix C 
MCC formation models 

C.1 MCC \kinetochore dependent model” 
d[Mad1:C-Mad2] 

= ..k1:u[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 

dt 
k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] (C.1) 
d[O-Mad2] 

= ..k1:u[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 

dt 
k3[Cdc20:C-Mad2] - k6[Cdc20][O-Mad2] (C.2) 
d[Mad1:C-Mad2:O-Mad2] 

= k1:u[Mad1:C-Mad2][O-Mad2] - k..1[Mad1:C-Mad2:O-Mad2] ..

dt 
k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] (C.3) 
d[Cdc20] 

= ..k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] + k3[Cdc20:C-Mad2] ..

dt 
k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] - 
k6[Cdc20][O-Mad2] (C.4) 
d[Cdc20:C-Mad2] 

= k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] - k3[Cdc20:C-Mad2] ..

dt 
k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] + k6[Cdc20][O-Mad2](C.5) 
d[Bub3:BubR1] 

= ..k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] ..

dt 
k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] (C.6) 
d[MCC] 

=+k4:u[Cdc20:C-Mad2][Bub3:BubR1] - k..4[MCC] (C.7)

dt
d[Bub3:BubR1:Cdc20]


= k5:u[Cdc20][Bub3:BubR1] - k..5[Bub3:BubR1:Cdc20] (C.8)

dt 

191



C. MCC FORMATION MODELS
C.2 Amplication eects
d[Mad1:C-Mad2] 
dt 

d[O-Mad2] 
dt 

d[Mad1:C-Mad2:O-Mad2] 
dt 

d[Cdc20] 
dt 

d[Cdc20:C-Mad2] 
dt 

d[Bub3:BubR1] 
dt 

d[MCC] 
dt 
d[Bub3:BubR1:Cdc20] 
dt 
d[Cdc20:C-Mad2:O-Mad2] 
dt 

= ..k1:u[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 

k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] (C.9) 

= ..k1:u[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 

k3[Cdc20:C-Mad2] - k6[Cdc20][O-Mad2] - 

k7[Cdc20:C-Mad2][O-Mad2] + k..7[Cdc20:C-Mad2:O-Mad2] (C.10) 
= k1:u[Mad1:C-Mad2][O-Mad2] - k..1[Mad1:C-Mad2:O-Mad2] - 

k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] (C.11) 

= ..k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] + k3[Cdc20:C-Mad2] - 

k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] - k6[Cdc20][O-Mad2] 

..k8[Cdc20:C-Mad2:O-Mad2][Cdc20] (C.12) 

= k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] - k3[Cdc20:C-Mad2] - 

k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] + k6[Cdc20][O-Mad2] - 

k7[Cdc20:C-Mad2][O-Mad2] + k..7[Cdc20:C-Mad2:O-Mad2]+ 

2k8[Cdc20:C-Mad2:O-Mad2][Cdc20] (C.13) 
= ..k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] - 

k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] (C.14) 
=+k4:u[Cdc20:C-Mad2][Bub3:BubR1] - k..4[MCC] (C.15) 

= k5:u[Cdc20][Bub3:BubR1] - k..5[Bub3:BubR1:Cdc20] (C.16) 

=+k7[Cdc20:C-Mad2][O-Mad2] - k..7[Cdc20:C-Mad2:O-Mad2] - 
k8[Cdc20:C-Mad2:O-Mad2][Cdc20] (C.17) 

192



C.3 p31comet contribution 
C.3 p31comet contribution 
d[Mad1:C-Mad2] 
dt 

d[O-Mad2] 
dt 

d[Mad1:C-Mad2:O-Mad2] 
dt 

d[Cdc20] 
dt 

d[Cdc20:C-Mad2] 
dt 

d[Bub3:BubR1] 
dt 

d[MCC] 
dt 
d[Bub3:BubR1:Cdc20] 
dt 
d[p31comet ] 
dt 

d[Mad1:C-Mad2:p31comet ] 
dt 
d[Cdc20:C-Mad2:p31comet ] 
dt 

= ..k1[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 
k2[Mad1:C-Mad2:O-Mad2][Cdc20]..k7p:v[Mad1:C-Mad2][p31comet ] + 
k..7p[Mad1:C-Mad2:p31comet ] (C.18) 
= ..k1[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 
k3[Cdc20:C-Mad2] - k6[Cdc20][O-Mad2] (C.19) 
= k1[Mad1:C-Mad2][O-Mad2] - k..1[Mad1:C-Mad2:O-Mad2] - 
k2[Mad1:C-Mad2:O-Mad2][Cdc20] (C.20) 
= ..k2[Mad1:C-Mad2:O-Mad2][Cdc20] + k3[Cdc20:C-Mad2] - 
k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] - k6[Cdc20][O-Mad2]

(C.21) 
= k2[Mad1:C-Mad2:O-Mad2][Cdc20] - k3[Cdc20:C-Mad2] - 
k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] + k6[Cdc20][O-Mad2] - 
k8p:v[Cdc20:C-Mad2][p31comet ] + k..8p[Cdc20:C-Mad2:p31comet ] (C.22) 
= ..k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] - 
k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] (C.23) 
=+k4:u[Cdc20:C-Mad2][Bub3:BubR1] - k..4[MCC] (C.24) 

= k5:u[Cdc20][Bub3:BubR1] - k..5[Bub3:BubR1:Cdc20] (C.25) 

= ..k7p:v[Mad1:C-Mad2][p31comet ] + k..7p[Mad1:C-Mad2:p31comet ] - 
k8p:v[Cdc20:C-Mad2][p31comet ] + k..8p[Cdc20:C-Mad2:p31comet ] (C.26) 
= k7p:v[Mad1:C-Mad2][p31comet ] - k..7p[Mad1:C-Mad2:p31comet ] (C.27) 

= k8p:v[Cdc20:C-Mad2][p31comet ] - k..8p[Cdc20:C-Mad2:p31comet ] (C.28) 

C.4 Fitness function 
Same as in Appendix B.6. 

193



C. MCC FORMATION MODELS
194



\The great aim of education is not knowledge but action". 

Herbert Spencer (1820 -1903) 

Appendix D 

The Dissociation and the Convey 
Model 

195



D. THE DISSOCIATION AND THE CONVEY MODEL
D.1 ODEs of the MSAC model Dissociation variant 
. First (uncontrolled) case: u0=1 
. Second (controlled) case: u0=1..u 

where u = 1 for unattached kinetochore and u = 0 at the attached kinetochore. 

d[Mad1:C-Mad2] 
dt 

d[O-Mad2] 
dt 

d[Mad1:C-Mad2:O-Mad2] 
dt 

d[Cdc20] 
dt 

d[Cdc20:C-Mad2] 
dt 

d[Bub3:BubR1] 
dt 

d[MCC] 
dt 

d[Bub3:BubR1:Cdc20] 
dt 
d[APC] 
dt 

d[MCC:APC] 
dt 
d[APC:Cdc20] 
dt 

= ..k1:u[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 
k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] (D.1) 
= ..k1:u[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 
k3[Cdc20:C-Mad2] - k6[Cdc20][O-Mad2] (D.2) 
=k1:u[Mad1:C-Mad2][O-Mad2] - k..1[Mad1:C-Mad2:O-Mad2] - 
k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] (D.3) 
= ..k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] + k3[Cdc20:C-Mad2] - 
k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] - k6[Cdc20][O-Mad2] - 
k8[APC][Cdc20] + k..8[APC:Cdc20] (D.4) 
=k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] - k3[Cdc20:C-Mad2] - 
k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] + k6[Cdc20][O-Mad2] (D.5) 
= ..k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] - 
k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] (D.6) 
= +k4:u[Cdc20:C-Mad2][Bub3:BubR1] - k..4[MCC] - 
k7:u[MCC][APC] + k..7:u0[MCC:APC] (D.7) 
=k5:u[Cdc20][Bub3:BubR1] - k..5[Bub3:BubR1:Cdc20] (D.8) 

= ..k7:u[MCC][APC] + k..7:u0[MCC:APC] - k8[APC][Cdc20] + 
k..8[APC:Cdc20] (D.9) 
= +k7:u[MCC][APC] - k..7:u0[MCC:APC] (D.10) 

= +k8[APC][Cdc20] - k..8[APC:Cdc20] (D.11) 

196



D.2 ODEs of the MSAC model Convey variant 
D.2 ODEs of the MSAC model Convey variant 
. First (uncontrolled) case: u0=1 
. Second (controlled) case: u0=1..u 
where u = 1 for unattached kinetochore and u = 0 at the attached kinetochore. 

d[Mad1:C-Mad2] 
dt 

d[O-Mad2] 
dt 

d[Mad1:C-Mad2:O-Mad2] 
dt 

d[Cdc20] 
dt 

d[Cdc20:C-Mad2] 
dt 

d[Bub3:BubR1] 
dt 

d[MCC] 
dt 

d[Bub3:BubR1:Cdc20] 
dt 
d[APC] 
dt 
d[MCC:APC] 
dt 
d[APC:Cdc20] 
dt 

= ..k1:u[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 
k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] (D.12) 
= ..k1:u[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 
k3[Cdc20:C-Mad2] - k6[Cdc20][O-Mad2] + k..7:u0[MCC:APC] (D.13) 
=k1:u[Mad1:C-Mad2][O-Mad2] - k..1[Mad1:C-Mad2:O-Mad2] - 
k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] (D.14) 
= ..k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] + k3[Cdc20:C-Mad2] - 
k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] - k6[Cdc20][O-Mad2] - 
k8[APC][Cdc20] + k..8[APC:Cdc20] (D.15) 
=k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] - k3[Cdc20:C-Mad2] - 
k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] + k6[Cdc20][O-Mad2] (D.16) 
= ..k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] - 
k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] + 
k..7:u0[MCC:APC] (D.17) 
= +k4:u[Cdc20:C-Mad2][Bub3:BubR1] - k..4[MCC] - 
k7:u[MCC][APC] (D.18) 
=k5:u[Cdc20][Bub3:BubR1] - k..5[Bub3:BubR1:Cdc20] (D.19) 

= ..k7:u[MCC][APC] - k8[APC][Cdc20] + k..8[APC:Cdc20] (D.20) 

= +k7:u[MCC][APC] - k..7:u0[MCC:APC] (D.21) 

= +k8[APC][Cdc20] - k..8[APC:Cdc20] + k..7:u0[MCC:APC] (D.22) 

197



D. THE DISSOCIATION AND THE CONVEY MODEL
D.3 Optimization 
The objective function f(P ) assigns a quality (i.e., a positive real number, P=(k7, 
k..7,k8,k..8)T) to a given set of parameters P . In our case, the parameters 
are the reaction constants. In order to t the parameters with respect to the 
observed qualitative function of the MSAC control, we use the APC:Cdc20 
concentration before and after kinetochore attachment as a criterion. In each 
single simulation experiment, we simulate two phases of the spindle attachment 
status. Our simulation begins in the kinetochore unattached case (phase 1), 
until equilibrium is reached, then it continues in the attached state (phase 
2), again, until steady state conditions are met. We measure the APC:Cdc20 
concentration at the end of each phase i, when all concentrations have reached 
steady state, and compare it with a user given value Ai, which describes the 
experimentally observed behavior. The two dierence values are combined linearly: 

55

f(P )= W1( [APC:Cdc20]i;Unattached - A1;i)2 + W2( [APC:Cdc20]i;Attached - 

i=1 i=1 
A2;i)2 

where W1, and W2 are the weights which were 10, and 1 respectively. A1, and A2 
are the desired phase levels for 5 dierent point at the beginning, and at the end 
of each phase ( we set A1;i =0, 0, 0, 0, 0 and A2;i =0:001, 0:005, 0:01, 0:01, 0:01 
respectively). 

For optimization Techniques and ODEs solvers see Appendix B. 

198



\Gravitation cannot be held responsible for people falling in love. 
How on earth can you explain in terms of chemistry and physics 
so important a biological phenomenon as rst love? Put your hand 
on a stove for a minute and it seems like an hour. Sit with that 
special girl for an hour and it seems like a minute. That's relativity". 

Albert Einstein (1879 -1955) 

Appendix E 

The Integrative Model of MSAC and 
EFM Mechanisms 

199



E. THE INTEGRATIVE MODEL OF MSAC AND EFM 
MECHANISMS 
E.1 ODEs of the integrative model of MSAC (Dissociation 
variant) and EFM 
d[Mad1:C-Mad2] 
dt 

d[O-Mad2] 
dt 

d[Mad1:C-Mad2:O-Mad2] 
dt 

d[Cdc20] 
dt 

d[Cdc20:C-Mad2] 
dt 

d[Bub3:BubR1] 
dt 

d[MCC] 
dt 

d[Bub3:BubR1:Cdc20] 
dt 
d[APC] 
dt 

d[MCC:APC] 
dt 
d[APC:Cdc20] 
dt 
d[APC:Cdh1] 
dt 
d[Cdh1] 
dt 

d[Cdh1]P 
dt 
d[Separase:Securin] 
dt 
d[Separase] 

dt
d[Cyclin B]
dt


d[Cdc14A] 
dt 
d[Cdc14A*] 
dt 

= ..k1:u[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 
k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] (E.1) 

= ..k1:u[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 
k3[Cdc20:C-Mad2] - k6[Cdc20][O-Mad2] (E.2) 

=k1:u[Mad1:C-Mad2][O-Mad2] - k..1[Mad1:C-Mad2:O-Mad2] - 
k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] (E.3) 

= ..k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] + k3[Cdc20:C-Mad2] - 
k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] - k6[Cdc20][O-Mad2] - 
k8[APC][Cdc20] + k..8[APC:Cdc20] (E.4) 

=k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] - k3[Cdc20:C-Mad2] - 
k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] + k6[Cdc20][O-Mad2] (E.5) 

= ..k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] - 
k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] (E.6) 

= +k4:u[Cdc20:C-Mad2][Bub3:BubR1] - k..4[MCC] - 
k7:u[MCC][APC] + k..7:u0[MCC:APC] (E.7) 

=k5:u[Cdc20][Bub3:BubR1] - k..5[Bub3:BubR1:Cdc20] (E.8) 

= ..k7:u[MCC][APC] + k..7:u0[MCC:APC] - k8[APC][Cdc20] + 
k..8[APC:Cdc20] (E.9) 

= +k7:u[MCC][APC] - k..7:u0[MCC:APC] (E.10) 

= +k8[APC][Cdc20] - k..8[APC:Cdc20]+k14[APC:Cdc20][Cdh1] (E.11) 

= +k14[APC:Cdc20][Cdh1] (E.12) 
[Cdh1] 

= ..k14[APC:Cdh1][Cdh1]..k13[Cyclin B] 

k13M + [Cdh1] 
[Cdh1P]

+k..13[Cdc14A*] (E.13)
k-13M + [Cdh1P] 

[Cdh1] [Cdh1P] 

= +k13[Cyclin B] 
k13M + [Cdh1] ..k..13[Cdc14A*] 
k-13M + [Cdh1P] 
(E.14) 

= ..k9[APC:Cdc20][Separase:Securin] (E.15) 

= +k9[APC:Cdc20][Separase:Securin] (E.16) 

= +k11..k10[APC:Cdc20][Cyclin B]..k15[APC:Cdh1][Cyclin B] (E.17) 
[Cdc14A] 

= +k12[Cdc14A*]..k..12[Separase] (E.18)

k-12M + [Cdc14A] 
[Cdc14A] 

= ..k12[Cdc14A*]+k..12[Separase] (E.19)

k-12M + [Cdc14A] 

200 


E.2 ODEs of the integrative model of MSAC ( Convey variant ) and 
EFM 
E.2 ODEs of the integrative model of MSAC ( Convey variant ) and EFM 
d[Mad1:C-Mad2] 
dt 

d[O-Mad2] 
dt 

d[Mad1:C-Mad2:O-Mad2] 
dt 

d[Cdc20] 
dt 

d[Cdc20:C-Mad2] 
dt 

d[Bub3:BubR1] 
dt 

d[MCC] 
dt 

d[Bub3:BubR1:Cdc20] 
dt 
d[APC] 
dt 
d[MCC:APC] 
dt 
d[APC:Cdc20] 
dt 
d[APC:Cdh1] 
dt 
d[Cdh1] 
dt 

d[Cdh1]P 
dt 
d[Separase:Securin] 
dt 
d[Separase] 

dt
d[Cyclin B]
dt


d[Cdc14A] 
dt 
d[Cdc14A*] 
dt 

= ..k1:u[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 
k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] (E.20) 

= ..k1:u[Mad1:C-Mad2][O-Mad2] + k..1[Mad1:C-Mad2:O-Mad2]+ 
k3[Cdc20:C-Mad2] - k6[Cdc20][O-Mad2] + k..7:u0[MCC:APC] (E.21) 

=k1:u[Mad1:C-Mad2][O-Mad2] - k..1[Mad1:C-Mad2:O-Mad2] - 
k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] (E.22) 

= ..k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] + k3[Cdc20:C-Mad2] - 
k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] - k6[Cdc20][O-Mad2] - 
k8[APC][Cdc20] + k..8[APC:Cdc20] (E.23) 

=k2:u[Mad1:C-Mad2:O-Mad2][Cdc20] - k3[Cdc20:C-Mad2] - 
k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] + k6[Cdc20][O-Mad2] (E.24) 

= ..k4:u[Cdc20:C-Mad2][Bub3:BubR1] + k..4[MCC] - 
k5:u[Cdc20][Bub3:BubR1] + k..5[Bub3:BubR1:Cdc20] + 
k..7:u0[MCC:APC] (E.25) 

= +k4:u[Cdc20:C-Mad2][Bub3:BubR1] - k..4[MCC] - 
k7:u[MCC][APC] (E.26) 

=k5:u[Cdc20][Bub3:BubR1] - k..5[Bub3:BubR1:Cdc20] (E.27) 

= ..k7:u[MCC][APC] - k8[APC][Cdc20] + k..8[APC:Cdc20] (E.28) 

= +k7:u[MCC][APC] - k..7:u0[MCC:APC] (E.29) 

= +k8[APC][Cdc20] - k..8[APC:Cdc20] + k..7:u0[MCC:APC]..k14[APC:Cdc20][Cdh1]

(E.30) 
= +k14[APC:Cdc20][Cdh1] (E.31) 
[Cdh1] 

= ..k14[APC:Cdh1][Cdh1]..k13[Cyclin B] 

k13M + [Cdh1] 
[Cdh1P]

+k..13[Cdc14A*] (E.32)
k-13M + [Cdh1P] 

[Cdh1] [Cdh1P] 

= +k13[Cyclin B] 
k13M + [Cdh1] ..k..13[Cdc14A*] 
k-13M + [Cdh1P] 
(E.33) 

= ..k9[APC:Cdc20][Separase:Securin] (E.34) 

= +k9[APC:Cdc20][Separase:Securin] (E.35) 

= +k11..k10[APC:Cdc20][Cyclin B]..k15[APC:Cdh1][Cyclin B] (E.36) 
[Cdc14A] 

= +k12[Cdc14A*]..k..12[Separase] (E.37)

k-12M + [Cdc14A] 
[Cdc14A] 

= ..k12[Cdc14A*]+k..12[Separase] (E.38)

k-12M + [Cdc14A] 

201 


E. THE INTEGRATIVE MODEL OF MSAC AND EFM 
MECHANISMS 
202



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233



234



¨ 

Uber den Autor 
Lebenslauf und wissenschaftlicher Werdegang 

Name: Bashar Ibrahim
Geburtsdatum: 28. August 1976
Geburtsort: Mosul, Irak
E-Mail: bininua@yahoo.com


Ausbildung 

. Friedrich Schiller Universitat Jena, Deutschland. 
Doktorand, Bioinformatik, April 2005 -September 2008 
Finanzierung: Deutscher Akademischer Austauschdienst (DAAD). 
. Universitat Kopenhagen, Danemark. 
Bio-Math Summer School, August 3rd - 16th, 2008. 
Finanzierung: Marie Curie 
. Universitat Trento, Italien. 
Computational and Systems Biology course (CoSBi), 10.-14. Marz 2008. 
Finanzierung: Microsoft research. 
¨ 

. Universitat Graz, Osterreich. 
School in Biomedical Modeling, 22. Juli bis 4. August 2007. 
Finanzierung: Marie Curie. 
¨ 

. RICAM & Johannes Kepler Universitat, Linz, Osterreich. 
EMS School Mathematics in Molecular Cell Biology, 9.-23. September 2006. 
Finanzierung: Lize Universitat. 
. Universitat Southampton, Southampton, Grobritannien. 
School in Complexity Science, 9. Marz bis 12. April 2006. 
Finanzierung: EPSRC Grobritannien. 
. InterDaF e.V. am Herder-Institut der Universitat Leipzig, Deutschland. 
Sprachintensivkurs Deutsch, 4. Oktober 2004 bis 31. Marz 2005. Finanzierung: 
DAAD. 
. Universitat Mosul, Mosul, Irak. 
Master of Science (M.Sc.) mit Auszeichnung in Angewandter Mathematik, Juli 
2000. 
. Universitat Mosul, Mosul, Irak. 
Bachelor of Science (B.Sc.) mit Auszeichnung in Mathematik, 1998. 
235 


Stipendium 

Deutscher Akademischer Austauschdienst Oktober 2004 -September 
2008 

Forschungsinteressen 

Systembiologie, Modellierung und Simulation, Spindelkontrollpunkt-Mechanismus, 
Endphase der Mitose, ODEs, SDEs, Reaktions-Diusions-Systeme und Optimierungstechniken. 

Akademische Erfahrungen 

. Friedrich Schiller Universitat Jena, Deutschland 
-Mitglied der Forschungsgruppe seit April 2005 
Biosystemanalyse. Einschlielich Promotion. 
Leibniz-Institut fur Altersforschung, Jena, Deutschland. 
-Forschungsprojekt 
Zusammenarbeit mit Humanbiologen, Modellierung des Zellzyklus. 
. Fakultat der Wissenschaften, Al-Byda, Libyen. 
Lehrtatigkeit Oktober 2002 -Oktober 2004 

Beteiligung an Kursen im Grundstudium in gemeinschaftlicher Verantwortung 
fur Vorlesung, Hausarbeiten und Bewertung. 

. Fakultat fur Mathematik und Informatik, Mosul, Irak. 
Lehrtatigkeit Oktober 2000 -Oktober 2002 

Beteiligung an Kursen im Grundstudium in gemeinschaftlicher Verantwortung 
fur Vorlesung, Hausarbeiten und Bewertung. 

Lehrerfahrung 

Systembiologie des Zellzyklus 

Beteiligung an der Betreung von Diplomarbeiten 

. Maiko Lohel, MSc. Bioinformatik (2008), Friedrich Schiller Universitat Jena. 
. Gerd Gruenert, MSc. Bioinformatik (2008), Friedrich Schiller Universitat Jena. 
. Margriet Palm, Engineer (2008), Eindhoven University of Technology, Niederlande. 
. Sarah Werner, MSc. Bioinformatik (2007), Friedrich Schiller Universitat Jena. 
236



Veroentlichungen 

Peer-reviewed articles in international journals 

. Ibrahim, B., Dittrich, P., Diekmann, S., Schmitt, E. Mad2 binding is not 
sucient for complete Cdc20 sequestering (an in-silico study). BioPhy Chem. 
Journal, 134, 93-100., 2008. 
. Ibrahim, B., Diekmann, S., Schmitt, E., Dittrich, P. In-silico Modeling of the 
Mitotic Spindle Assembly Checkpoint. PLoS ONE Journal, 3(2): e1555, 2008. 
. Ibrahim, B., Schmitt, E., Dittrich, D., Diekmann, D. In-silico study of 
kinetochore control, amplication, and inhibition eects in MCC assembly. 
BioSystems Journal, 2008. (In press) 
. Ibrahim, B, Dittrich, P., Diekmann, S., Schmitt, E. Stochastic eects in a 
compartmental model for mitotic checkpoint regulation. Journal of Integrative 
Bioinformatics, 4(3):66, 2007. 
Peer-reviewed full articles in proceedings 

. Rohn, H., Ibrahim, B., Lenser, T., Hinze, T., Dittrich., Enhancing Parameter 
Estimation of Biochemical Networks by Exponentially Scaled Search Steps. 
In: E. Marchiori and J. H. Moore (Eds.), Proceedings of the Sixth European 
Conference on Evolutionary Computation, Machine Learning and Data Mining 
in Bioinformatics (EvoBIO), Napoli, LNCS 4973, pp. 177-187, Springer Verlag, 
2008. 
. Lenser, T., Hinze, T., Ibrahim, B., Dittrich, P., Towards evolutionary network 
reconstruction tools for systems biology. In: E. Marchiori, J.H. Moore, J.C. Rajapakse (Eds.), Proceedings of the Fifth European Conference on Evolutionary 
Computation, Machine Learning and Data Mining in Bioinformatics (EvoBIO), 
Valencia, LNCS 4447, pp 132-142, Springer Verlag, 2007. 
237



Posters 

. Ibrahim, B., Schmitt, E., Diekmann, S., Dittrich, P. The \Convey” and the 
\Dissociation” model: Meta-to Anaphase Transition Control, CoSBi, March 
10-14, 2008, Trento, Italy. 

. Ibrahim, B., Schmitt, E., Diekmann, S., Dittrich, P. Modeling Mitosis Transition Controls, ECCS, October 1-5, 2007, Dresden, Germany. 
. Dittrich, P., Hinze, T., Ibrahim, B., Lenser, T., Matsumaru, N. Hierarchically 
Evolvable Components for Complex Systems: Biologically Inspired Algorithmic 
Design ECCS, October 1-5, 2007, Dresden, Germany. 
. Ibrahim, B., Schmitt, E., Diekmann, S., Dittrich, P. Neither Mad2 nor 
p31comet alone are sucient for MSAC regulation. European Life Scientist 
Organization \ELSO", September 1-4, 2007, Dresden, Germany. 
. Ibrahim, B., Schmitt, E., Diekmann, S., Dittrich, P. Modeling and simulation 
of the Mitotic Spindle Mechanism. Gold Springer Harbor Laboratory Computational Cell Biology, March 6-9, 2007, New York, USA. 
238



Teilnahme an Konferenzen und Tagungen 

2007 

. European Life Scientist Organization \ELSO” , September 1-4, 2007, Dresden, 
Germany. 
. Data Mining and Modeling in Systems Biology Workshop and Spring School, 
March 15-16, 2007, Jena, Germany. 
2006 

. Applications of Semantic Technologies Workshop, October 6, 2006, Dresden, 
Germany. 
. Organic Computing Workshop, October 5, 2006, Dresden, Germany. 
. International BCB -Workshop on Computational Proteomics, August 24-25, 
2006, Berlin, Germany. 
. 7th 

German Workshop on Articial Life \GWAL7", July 26-28, 2006, Jena , 
Germany. 

. International Conference on Systems Biology of Mammalian Cells \SBMC", 
July 12-14 2006, Heidelberg, Germany. 
2005 

. International BCB -Workshop on Machine Learning in Bioinformatics, October 
10, 2005, Berlin, Germany. 
239



About the Author 
Scientic Curriculum Vitae 

Name: Bashar Ibrahim
Date of Birth: August 28, 1976
Place of Birth: Mosul, Iraq
Email: bininua@yahoo.com


Education 

. Friedrich Schiller University Jena, Germany. 
Ph.D. Candidate, Bioinformatics, April 2005 -September 2008 
Financially supported by the German Academic Exchange Service (DAAD). 
. University of Copenhagen, Denmark. 
Bio-Math Summer School, August 3rd - 16th, 2008. 
Financially supported by Marie Curie 
. University of Trento, Italy. 
Computational and Systems Biology course (CoSBi), March 10th-14th, 2008. 
Financially supported by Microsoft research. 
. University of Graz, Austria. 
School in Biomedical Modeling, 22nd July to August 4th, 2007. 
Financially supported by Marie Curie 
. RICAM & Johannes Kepler University, Linz, Austria. 
EMS School Mathematics in Molecular Cell Biology, September 9th-23rd, 2006. 
Financially supported by Lize University 
. University of Southampton, Southampton, UK. 
School in Complexity Science, 9th March to April 12th, 2006. 
Financially supported by EPSRC UK 
. InterDaF e.V. am Herder-Institut der Universitat Leipzig, Germany. 
Intensive course in German language and culture, 4th October 2004 to March 
31th, 2005. Financially supported by the DAAD 
. University of Mosul, Mosul, Iraq. 
Master of Science (M.Sc.) with honor degree in Applied Mathematics, July 
2000. 
. University of Mosul, Mosul, Iraq. 
Bachelor of Science (B.Sc.) with honor degree in Mathematics, 1998. 
241 


Awarded Fellow 

German Academic Exchange Service October 2004 -September 2008 

Research Interests 

Systems biology, modeling and simulation, spindle assembly checkpoint, exit 
from mitosis, ODEs, SDEs, reaction-diusion system, and optimization techniques. 

Academic Experience 

. Friedrich Schiller University Jena, Germany 
-Research group member April, 2005 -present 
Bio Systems Analysis Group. Includes current Ph.D. research. 
Leibniz Institute for Age Research\FLI"-Molecular Biology Group, Jena, Germany. 
-Research Project 
Collaboration research with human biology problems, modeling cell cycle. 
. Faculty of Science, Al Byda, Libya. 
Teaching Assistance October, 2002 -October, 2004 

Co-taught undergraduate level courses. Shared responsibility for lectures, 
exams, homework assignments, and grades. 

. Faculty of Mathematics and Computer Science, Mosul, Iraq. 
Teaching Assistance October, 2000 -October, 2002 

Co-taught undergraduate level course. Shared responsibility for lectures, exams, 
homework assignments, and grades. 

Teaching 

Systems Biology of the Cell Cycle 

Thesis advisor or assist advisor 

. Maiko Lohel, MSc. Bioinformatics (2008), Friedrich Schiller University Jena. 
. Gerd Gruenert, MSc. Bioinformatics (2008), Friedrich Schiller University Jena. 
. Margriet Palm, Engineer (2008), Eindhoven University of Technology, Holland. 
. Sarah Werner, MSc. Bioinformatics (2007), Friedrich Schiller University Jena. 
242



Publications 

Peer-reviewed articles in international journals 

. Ibrahim, B., Dittrich, P., Diekmann, S., Schmitt, E. Mad2 binding is not 
sucient for complete Cdc20 sequestering (an in-silico study). BioPhy Chem. 
Journal, 134, 93-100., 2008. 
. Ibrahim, B., Diekmann, S., Schmitt, E., Dittrich, P. In-silico Modeling of the 
Mitotic Spindle Assembly Checkpoint. PLoS ONE Journal, 3(2): e1555, 2008. 
. Ibrahim, B., Schmitt, E., Dittrich, D., Diekmann, D. In-silico study of 
kinetochore control, amplication, and inhibition eects in MCC assembly. 
BioSystems Journal, 2008. (In press) 
. Ibrahim, B, Dittrich, P., Diekmann, S., Schmitt, E. Stochastic eects in a 
compartmental model for mitotic checkpoint regulation. Journal of Integrative 
Bioinformatics, 4(3):66, 2007. 
Peer-reviewed full articles in proceedings 

. Rohn, H., Ibrahim, B., Lenser, T., Hinze, T., Dittrich., Enhancing Parameter 
Estimation of Biochemical Networks by Exponentially Scaled Search Steps. 
In: E. Marchiori and J. H. Moore (Eds.), Proceedings of the Sixth European 
Conference on Evolutionary Computation, Machine Learning and Data Mining 
in Bioinformatics (EvoBIO), Napoli, LNCS 4973, pp. 177-187, Springer Verlag, 
2008. 
. Lenser, T., Hinze, T., Ibrahim, B., Dittrich, P., Towards evolutionary network 
reconstruction tools for systems biology. In: E. Marchiori, J.H. Moore, J.C. Rajapakse (Eds.), Proceedings of the Fifth European Conference on Evolutionary 
Computation, Machine Learning and Data Mining in Bioinformatics (EvoBIO), 
Valencia, LNCS 4447, pp 132-142, Springer Verlag, 2007. 
243



Posters 

. Ibrahim, B., Schmitt, E., Diekmann, S., Dittrich, P. The \Convey” and the 
\Dissociation” model: Meta-to Anaphase Transition Control, CoSBi, March 
10-14, 2008, Trento, Italy. 

. Ibrahim, B., Schmitt, E., Diekmann, S., Dittrich, P. The \Convey” and the 
\Dissociation” model: Meta-to Anaphase Transition Control, CoSBi, March 
10-14, 2008, Trento, Italy. 

. Ibrahim, B., Schmitt, E., Diekmann, S., Dittrich, P. Modeling Mitosis Transition Controls, ECCS, October 1-5, 2007, Dresden, Germany. 
. Dittrich, P., Hinze, T., Ibrahim, B., Lenser, T., Matsumaru, N. Hierarchically 
Evolvable Components for Complex Systems: Biologically Inspired Algorithmic 
Design ECCS, October 1-5, 2007, Dresden, Germany. 
. Ibrahim, B., Schmitt, E., Diekmann, S., Dittrich, P. Neither Mad2 nor 
p31comet alone are sucient for MSAC regulation. European Life Scientist 
Organization \ELSO", September 1-4, 2007, Dresden, Germany. 
. Ibrahim, B., Schmitt, E., Diekmann, S., Dittrich, P. Modeling and simulation 
of the Mitotic Spindle Mechanism. Gold Springer Harbor Laboratory Computational Cell Biology, March 6-9, 2007, New York, USA. 
244



Conferences and Workshops 

2007 

. European Life Scientist Organization \ELSO” , September 1-4, 2007, Dresden, 
Germany. 
. Data Mining and Modeling in Systems Biology Workshop and Spring School, 
March 15-16, 2007, Jena, Germany. 
2006 

. Applications of Semantic Technologies Workshop, October 6, 2006, Dresden, 
Germany. 
. Organic Computing Workshop, October 5, 2006, Dresden, Germany. 
. International BCB -Workshop on Computational Proteomics, August 24-25, 
2006, Berlin, Germany. 
. 7th 

German Workshop on Articial Life \GWAL7", July 26-28, 2006, Jena , 
Germany. 

. International Conference on Systems Biology of Mammalian Cells \SBMC", 
July 12-14 2006, Heidelberg, Germany. 
2005 

. International BCB -Workshop on Machine Learning in Bioinformatics, October 
10, 2005, Berlin, Germany. 
245



246



Erklarung 

Ich erklare, da ich die vorliegende Arbeit selbstandig und nur unter Verwendung 
der angegebenen Quellen und Hilfsmittel angefertigt habe. 

Bashar Ibrahim 
Jena, 14. Mai 2008