About the Project
Rationale: Droughts can alter microbial processes as stress tolerant microbes are selected due to their competitive advantage or as stress tolerance is acquired through evolution. However, how these ecological and evolutionary pressures impact overall community physiology in response to drought stress is not well understood. This brings uncertainty in understanding and predicting drought impact on microbial processes and consequences for soil carbon cycling.
Aims and approach: This PhD project aims to reveal the mechanisms of drought stress response in microbial populations and impacts on overall community traits and soil carbon cycling processes. The aim is to study the ecological (selective) and evolutionary (adaptative) processes that shape communities under long-term drought. We will use a trait-based approach to explore population-level trade-offs between stress tolerance and growth. A combination of microbial culture isolation-based and non-cultivation molecular-based population genomics will be used to study drought-tolerant microbes. Targeted lab mesocosm experiments will also be conducted to understand the response of drought-tolerant and drought-sensitive populations to water stress and the consequences on their fitness. This population-level understanding will be used to assess community shifts in response to drought and predict ecosystem functions such as organic matter decomposition and storage.
Methods and training: We seek an enthusiastic PhD student with microbiology, ecology or soil science background with interest in omics technologies. We will have access to multiple sites with long-term drought treatment. Research training will be available in molecular tools, bioinformatics and ecological statistics. The Centre for Genome Enabled Biology and Medicine at University of Aberdeen houses DNA sequencing platforms which will be available to the project including training. The genomes of individual populations will be obtained through genomic sequencing of culture isolates and de novo assembly of individual genomes from shotgun metagenomics data. Analytical facilities for gas and compound-specific 13C isotope analysis will be available to the student to quantify traits like growth rate and growth yield for individual isolates using stable isotope tracers. Student will be trained in using and applying these cutting-edge tools and to integrate the microbiome data with ecosystem measures. Such a combination of microbial culturing, population genomics and stable isotope tracing approaches will allow the student to gain unique technical skills across disciplines and apply them to address key challenges linked to climate change.
More project details are available here: https://www.quadrat.ac.uk/projects/eco-evolutionary-responses-of-soil-microbes-to-drought-stress/
How to apply: https://www.quadrat.ac.uk/how-to-apply/
Before applying please check full funding and eligibility information: View Website
S. Manzoni, J. P. Schimel, A. Porporato, Responses of soil microbial communities to water stress: Results from a meta-analysis. Ecology 93, 930-938 (2012).
A. A. Malik, et al., Drought and plant litter chemistry alter microbial gene expression and metabolite production. ISME J. (2020) https:/doi.org/10.1038/s41396-020-0683-6.
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