Qualification Type: | PhD |
---|---|
Location: | Devon, Exeter |
Funding for: | EU Students, International Students, Self-funded Students, UK Students |
Funding amount: | £19,237 annual stipend |
Hours: | Full Time |
Placed On: | 20th November 2024 |
---|---|
Closes: | 11th December 2024 |
Reference: | 5380 |
About:
The BBSRC-funded SWBio DTP involves a partnership of world-renown universities, research institutes and industry, based mainly across the South West and Wales.
This partnership has established international, national and regional scientific networks, and widely recognised research excellence and facilities.
We aim to provide you with outstanding interdisciplinary bioscience research training, underpinned by transformative technologies.
Project Description
Living organisms are continuously exposed to environmental stressors that affect their health, survival and ability to reproduce. In some highly stressful environments however, such as heavily polluted ecosystems that would be expected to cause high mortality rates, populations are thriving. This phenomenon has been attributed for the most part to genetic adaptation, but in many cases the extend of genetic adaptation observed is insufficient to explain the level of stressor resistance seen. Epigenetic changes contributing to phenotypic plasticity and microbiome-extension of host adaptive phenotypic plasticity are two likely important, and interacting, contributing mechanisms, but remain poorly characterised. Addressing this knowledge gap will provide novel and fascinating insight into how organisms interact with their environment in order to overcome adverse conditions and result in important knowledge to understand the consequences of exposure to stressors in natural and anthropogenic environments. The applications of this knowledge are vast and range from improvement of the resilience and welfare of farmed animals, contributing to food security, to a better management of the sustainability of wild populations and preserving biodiversity.
This project will address the following questions: How do organisms cope with stressors in their environment? What are the molecular mechanisms employed to allow survival under stressful conditions? What are the temporal dynamics and broader consequences of the alterations seen?
The student will test the hypothesis that epigenetic variation and microbiome plasticity, in addition to genetic adaptation, contribute to stressor tolerance.
The student will use Daphnia pulex, a keystone small crustacean species in freshwaters, as a model system. We have already identified a number of natural Daphnia populations with extensive metal tolerance, which is partly heritable in clean conditions and partly due to plasticity. Metals are particularly interesting because they constitute one of the most common contaminants in freshwater systems while many metals are also essential elements within the body, and therefore they will be used as an exemplar stressor in this project. The student will be able to utilise this unique biological resource to investigate how their genome, epigenome and microbiome quantitatively account for metal tolerance and whether tolerance to a specific metal is developed at the expense of loss of fitness (growth; reproduction; survival; resistance to other stressors).
The student will receive extensive training in state of the art techniques including, in vivo experimental techniques, genome, epigenome and microbiome sequencing and advanced bioinformatics analysis.
Type / Role:
Subject Area(s):
Location(s):