Leyrer, Vinzent scite author profile

Climate is changing and predicted future scenarios include both changes in long‐term mean climatic conditions and intensification of extreme events such as drought. Drought can have a major impact on soil functional processes; soil microorganisms, key to these processes, depend on water and temperature dynamics. Consequently, feedback mechanisms regarding microbially mediated carbon and nitrogen cycling in soils may be affected. There are indications that microbial exposure to increasingly unfavorable environmental conditions influences their stress responses. Here, the long‐term field experiment Hohenheim Climate Change (HoCC) provided a research platform to explore how microbial exposure to long‐term reduced water availability and soil warming modifies microbially driven soil processes, especially gas fluxes from soil, both during drought and after rewetting. The HoCC experiment is an agroecosystem in which the soil microbiome has been exposed to reduced annual mean precipitation and elevated temperature since 2008. Treatment levels were chosen based on a realistic future climate scenario. In June 2019, we exposed this system to a drought period of four weeks. We found that even after 11 years, warming remained a driver of CO2 and N2O fluxes across the different soil moisture conditions in our drought experiment. Importantly, however, microbial exposure to long‐term reduced water availability limited the stimulatory effect of warming on gas fluxes during drought and after rewetting. Our results were neither related to a legacy effect within overall microbial biomass carbon levels nor a shift towards enhanced fungal abundance. We found no indications that extracellular enzyme activities or microbial substrate availability explained the gas flux dynamics observed in our drought experiment. Our study indicates that soil warming promotes gaseous C and N loss even under extreme drought conditions. We suspect, however, that a shift in microbial function following long‐term water limitation can hamper the enhancing effect of warming on soil gas fluxes.

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The need to decipher plant drought stress along the soil–plant–atmosphere continuum

Schweiger

Zimmermann

Poll

et al. 2023

Oikos

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Lacking comparability among rainfall manipulation studies is still a major limiting factor for generalizations in ecological climate change impact research. A common framework for studying ecological drought effects is urgently needed to foster advances in ecological understanding the effects of drought. In this study, we argue, that the soil–plant–atmosphere‐continuum (SPAC), describing the flow of water from the soil through the plant to the atmosphere, can serve as a holistic concept of drought in rainfall manipulation experiments which allows for the reconciliation experimental drought ecology. Using experimental data, we show that investigations of leaf water potential in combination with edaphic and atmospheric drought – as the three main components of the SPAC – are key to understand the effect of drought on plants. Based on a systematic literature survey, we show that especially plant and atmospheric based drought quantifications are strongly underrepresented and integrative assessments of all three components are almost absent in current experimental literature. Based on our observations we argue, that studying dynamics of plant water status in the framework of the SPAC can foster comparability of different studies conducted in different ecosystems and with different plant species and can facilitate extrapolation to other systems, species or future climates.

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Long-term manipulation of mean climatic conditions alters drought effects on C- and N-cycling in an arable soil

Vinzent

Patulla

Hartung

et al. 2021

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Long-term manipulation of mean climatic conditions alters drought effects on C- and N-cycling in an arable soil

Vinzent

Patulla

Hartung

et al. 2022

View full text Add to dashboard Cite

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Leyrer, Vinzent

Long‐term manipulation of mean climatic conditions alters drought effects on C‐ and N‐cycling in an arable soil

The need to decipher plant drought stress along the soil–plant–atmosphere continuum

Long-term manipulation of mean climatic conditions alters drought effects on C- and N-cycling in an arable soil

Long-term manipulation of mean climatic conditions alters drought effects on C- and N-cycling in an arable soil

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