SubsidieMeestersThe Role of Microbial Dormancy as an Ecological and Biogeochemical Regulator on Earth
This project aims to investigate microbial dormancy's role in ecological functioning and biogeochemical cycles in the cryosphere, using data-driven experiments and modeling to enhance our understanding of life’s resilience.
Projectdetails
Introduction
Dramatic shifts in Earth’s climate and geography have profoundly influenced biological innovation and biogeochemical cycles. Despite widespread and extreme environmental change, including global glaciations lasting millions of years, microbial life has thrived, accruing distinct phylogenies, morphologies, physiologies, and functions over geological time.
Microbial Dormancy
Microorganisms use dormancy as a survival strategy to persist throughout unfavorable changes in their environment. Dormant organisms withdraw from the present environment and become part of a seed bank, investing instead in contributing to the diversity and function of future ecosystems.
Ecological Implications
This leads to the rousing proposition that a shift in the active/dormant fraction of a microbial population may profoundly affect ecological functioning and elemental cycling. Despite this intriguing connection, we lack fundamental knowledge on the prevalence, triggers, and timescales of dormancy, and how these factors affect ecosystems and elemental budgets.
Research Objectives
I will address this by elucidating the role of microbial dormancy as an ecological and biogeochemical regulator on Earth. The cryosphere provides a unique testing ground to meet my goals. Here, microbes contend with dramatic variations in environmental extremes on timescales ranging from days to thousands of years.
Methodology
Through an innovative data-driven approach involving experiments and modeling, I will:
- Quantify the prevalence of dormancy among taxonomically and functionally diverse microbial communities.
- Identify the triggers and timescales of dormancy.
- Link dormancy to the emergence, survival, and evolution of microbial populations.
- Elucidate the role of dormancy as a regulator of biogeochemical cycles.
Conclusion
Understanding the interplay between microbial dormancy, ecological processes, and biogeochemical cycles holds the key to understanding the co-evolution of life and our planet, and how life excels throughout glacial-interglacial cycles and other global changes.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.089.972 |
| Totale projectbegroting | € 2.089.972 |
Tijdlijn
| Startdatum | 1-9-2024 |
| Einddatum | 31-8-2029 |
| Subsidiejaar | 2024 |
Partners & Locaties
Projectpartners
- CENTRE NATIONAL DE LA RECHERCHE SCIENTIFIQUE CNRSpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
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|---|---|---|---|---|
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Ecological memory of extreme drought events in soil microbial communities
EcoMEMO investigates the role of ecological memory in soil microbial communities' responses to extreme drought, aiming to enhance understanding of their impact on biogeochemical processes under climate change.
Resolving mechanisms of microbiome rescue to promote resilience to climate change
The project aims to develop the Microbiome Rescue framework to reactivate dormant soil microorganisms, enhancing ecosystem resilience and food security in response to climate change.
Propagation of cellular memory through dormancy
DOR-CODE aims to uncover the genomic mechanisms of embryonic dormancy to enhance understanding of cellular identity propagation and improve embryo preservation techniques.
Microbial interactions driven by organic and inorganic metabolic exchange and their role in present and future biogeochemical cycles
This project aims to uncover the molecular mechanisms of algal-bacterial interactions in marine ecosystems under climate change to enhance biogeochemical models and inform ocean stewardship policies.
Global Adaptation of soil Microbes under Environmental Change
The GAMEchange project aims to develop a novel coupled soil microbe-land model using genomic data to enhance soil organic carbon predictions for IPCC climate projections.