Drought Reduces Release of Plant Matter Into Dissolved Organic Matter Potentially Restraining Ecosystem Recovery

GND
1305421906
Affiliation
Molecular Biogeochemistry, Max Planck Institute for Biogeochemistry ,Jena
Orme, Alice May;
GND
1184820147
Affiliation
Molecular Biogeochemistry, Max Planck Institute for Biogeochemistry ,Jena
Lange, Markus;
GND
1233500279
ORCID
0000-0002-9868-5954
Affiliation
Molecular Biogeochemistry, Max Planck Institute for Biogeochemistry ,Jena
Schroeter, Simon Andreas;
Affiliation
Zwillenberg-Tietz Foundation, Linde Research Station ,Märkisch Luch, State of Brandenburg ,Germany
Wicke, Marcus;
GND
1278351434
ORCID
0000-0002-7373-7519
Affiliation
Molecular Biogeochemistry, Max Planck Institute for Biogeochemistry ,Jena
Kolle, Olaf;
GND
1131364872
Affiliation
Bioorganic Analytics, Institute for Inorganic and Analytical Chemistry, Friedrich Schiller University ,Jena
Pohnert, Georg;
GND
118494881X
Affiliation
Molecular Biogeochemistry, Max Planck Institute for Biogeochemistry ,Jena
Gleixner, Gerd

Future climate scenarios indicate increasing drought intensity that threatens ecosystem functioning. However, the behavior of ecosystems during intense drought, such as the 2018 drought in Northern Europe, and their respective response following rewetting is not fully understood. We investigated the effect of drought on four different vegetation types in a temperate climate by analyzing dissolved organic matter (DOM) concentration and composition present in soil leachate, and compared it to two accompanying years. DOM is known to play an important role in ecosystem recovery and holds information on matter flows between plants, soil microorganisms and soil organic matter. Knowledge about DOM opens the possibility to better disentangle the role of plants and microorganisms in ecosystem recovery. We found that the average annual DOM concentration significantly decreased during the 2018 drought year compared to the normal year. This suggests a stimulation of DOM release under normal conditions, which include a summer drought followed by a rewetting period. The rewetting period, which holds high DOM concentrations, was suppressed under more intense drought. Our detailed molecular analysis of DOM using ultrahigh resolution mass spectrometry showed that DOM present at the beginning of the rewetting period resembles plant matter, whereas in later phases the DOM molecular composition was modified by microorganisms. We observed this pattern in all four vegetation types analyzed, although vegetation types differed in DOM concentration and composition. Our results suggest that plant matter drives ecosystem recovery and that increasing drought intensity may lower the potential for ecosystem recovery.

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License Holder: Copyright © 2022 Orme, Lange, Schroeter, Wicke, Kolle, Pohnert and Gleixner

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