Ezrin deficiency triggers glial fibrillary acidic protein upregulation and a distinct reactive astrocyte phenotype

GND
1162166207
Affiliation
Leibniz Institute on Aging Fritz Lipmann Institute Jena Germany
Schacke, Stephan;
ORCID
0000-0001-9291-7294
Affiliation
Leibniz Institute on Aging Fritz Lipmann Institute Jena Germany
Kirkpatrick, Joanna;
Affiliation
Leibniz Institute on Aging Fritz Lipmann Institute Jena Germany
Stocksdale, Amy;
GND
120228920
ORCID
0000-0002-4294-3758
Affiliation
Institute of Molecular Cell Biology CMB, Jena University Hospital Jena Germany
Bauer, Reinhard;
Affiliation
Institute of Neuropathology University Medical Center Hamburg‐Eppendorf Hamburg Germany
Hagel, Christian;
GND
1122141947
ORCID
0000-0002-1992-4591
Affiliation
Leibniz Institute on Aging Fritz Lipmann Institute Jena Germany
Riecken, Lars Björn;
GND
1246120615
ORCID
0000-0003-4938-1409
Affiliation
Faculty of Biological Sciences Friedrich‐Schiller University Jena Germany
Morrison, Helen

Astrocytes are increasingly being recognized as contributors to physiological brain function and behavior. Astrocytes engage in glia‐synaptic interactions through peripheral astrocyte processes, thus modulating synaptic signaling, for example, by handling glutamate removal from the synaptic cleft and (re)provision to axonal terminals. Peripheral astrocyte processes are ultrafine membrane protrusions rich in the membrane‐to‐actin cytoskeleton linker Ezrin, an essential component of in vitro filopodia formation and in vivo peripheral astrocyte process motility. Consequently, it has been postulated that Ezrin significantly contributes to neurodevelopment as well as astrocyte functions within the adult brain. However, while Ezrin has been studied in vitro within cultured primary astrocytes, in vivo studies on the role of Ezrin in astrocytes remain to be conducted and consequences of its depletion to be studied. Here, we investigated consequences of Ezrin deletion in the mouse brain starting from early neuronal specification. While Ezrin knockout did not impact prenatal cerebral cortex development, behavioral phenotyping depicted reduced exploratory behavior. Starting with postnatal appearance of glia cells, Ezrin was verified to remain predominantly expressed in astrocytes. Proteome analysis of Ezrin deficient astrocytes revealed alterations in glutamate and ion homeostasis, metabolism and cell morphology – important processes for synaptic signal transmission. Notably, Ezrin deletion in astrocytes provoked (GFAP) glial fibrillary acidic protein upregulation – a marker of astrocyte activation and reactive astrogliosis. However, this spontaneous, reactive astrogliosis exhibited proteome changes distinct from ischemic‐induced reactive astrogliosis. Moreover, in experimental ischemic stroke, Ezrin knockout mice displayed reduced infarct volume, indicating a protective effect of the Ezrin deletion‐induced changes and astrogliosis.

Cite

Citation style:
Could not load citation form.

Rights

License Holder: © 2022 Wiley Periodicals LLC.

Use and reproduction: