Don't miss our weekly PhD newsletter | Sign up now Don't miss our weekly PhD newsletter | Sign up now

  Climate change and pesticides: molecular and physiological processes underpinning pollinator responses to stress.


   School of Biosciences

This project is no longer listed on FindAPhD.com and may not be available.

Click here to search FindAPhD.com for PhD studentship opportunities
  Dr Scott Hayward, Prof J Colbourne, Prof Luisa Orsini  No more applications being accepted  Competition Funded PhD Project (European/UK Students Only)

About the Project

Establishing agricultural resilience and food security in the face of environmental change is of intense global interest, and pollinators will play a key role in achieving this objective. Pollinators are in severe decline however, encountering stressors on multiple fronts: climate change, pesticides, pathogens, parasites, etc. While omic technologies have greatly enhanced our understanding of the molecular processes underpinning responses to individual stressors 1, few studies have considered how multiple stressors interact. This project will employ state-of-the-art physiological and molecular techniques to investigate how a key UK pollinator responds to combined stress events, and the impact on survival/tolerance thresholds.

Virtually all temperate insects, including most pollinators, survive winter in a state of dormancy – diapause 2. A primary driver of pollinator decline at temperate latitudes is climate change disruption of diapause, because it leaves bees vulnerable to winter cold 3. In combination, bees are exposed to increasing quantities and different cocktails of pesticides. However, we currently have a very poor understanding of how pesticide exposure might influence the regulation of diapause, or its impact on cold tolerance/winter survival. For some species, disruption of diapause can be catastrophic due to severe population bottlenecks during winter, e.g. for the bumblebee Bombus terrestris, it is only queens that enter diapause, while all workers and males die during autumn.

B. terrestris is an ideal study system for many reasons: an important pollinator of key crops globally; commercially produced on a massive scale to supplement natural populations; highly tractable for molecular studies. The B. terrestris genome has been sequenced, and recent advances in high-throughput cDNA sequencing (RNA-seq) can reveal new genes and splice variants and quantify expression genome-wide in a single assay. In addition, RNAi knockdown has been successfully employed in this species4, permitting functional analysis of gene transcripts underpinning diapause and stress responses. In a commercial setting this could have fundamental applications in e.g. controlling diapause duration and/or cold tolerance to then facilitate long term cold storage of bees helping make them available ‘off the shelf’.

Core objectives are to: i) Characterise gene expression networks underpinning diapause. ii) Determine the impact of pesticide exposure on diapause regulation and winter survival. iii) Develop new molecular and physiological methods to enhance commercial pollinator culturing practises.

Funding Notes

Full details of the Midlands Integrative Biology Training Partnership (MIBTP) Candidate Selection Criteria can be found at: http://www.birmingham.ac.uk/research/activity/mibtp/index.aspx
In summary, applicants for this project must have:
1. Relevant degree in Biological Sciences.
2. A level maths or equivalent/evidence of mathematical competence.
3. Ideally a (predicted) first class degree or equivalent with evidence of good research skills from project work; a (predicted) 2i or equivalent can be acceptable if accompanied by really excellent marks in a research project.
Also desirable:
4. Research experience e.g. internships, vacation scholarships, or year abroad/in industry.
5. Employment experience.
6. Clear ideas of career options.

References

1. Hayward S. A. L. (2014) Application of functional ‘Omics’ in environmental stress physiology: insights, limitations, and future challenges. Current Opinion in Insect Science 4: 35-41.
2. Bale, J. S. and Hayward, S. A. L. (2010) Insect overwintering in a changing climate. Journal of Experimental Biology 213: 980-994.
3. Owen, E. L., Bale, J. S. and Hayward, S. A. L. (2013) Can winter-active bumblebees survive the cold? Assessing the cold tolerance of Bombus terrestris audax and the effects of pollen feeding. PLoS ONE 8: e80061
4. Deshwal S. and Mallon E. B. (2014) Antimicrobial peptides play a functional role in bumblebee anti-trypanosome defense. Developmental and Comparative Immunology 42: 240–243

How good is research at University of Birmingham in Biological Sciences?


Research output data provided by the Research Excellence Framework (REF)

Click here to see the results for all UK universities

Where will I study?