Application Deadline: 17 January 2025
Details
You will use modern techniques to study the development and/or physiology of one of the most powerful water-conserving systems in nature – the beetle cryptonephridial (or ‘buried kidney’) complex.
Insects can live and thrive in some of the most inhospitable environments on earth, including extremely desiccating conditions such as deserts. Many species possess a powerful water-conserving system called the cryptonephridial (or ‘buried kidney’) complex (CNC), which recovers water from the rectum and recycles it back to the body. This remarkable system even allows water vapour absorption from moist air, providing a novel physiological mechanism for water uptake. It is estimated that >400,000 insect species have a CNC, with CNCs being particularly common in beetles. The broad principles underpinning CNC physiology were laid down half a century ago, and the system has since become a staple textbook example of a countercurrent exchange system. Despite this, next to nothing is known about CNC development, molecular physiology, endocrinological regulation or evolution.
In this project you will use the model beetle species Tribolium and exploit enabling technologies including genomics, single-nuclei RNAseq, informatics, imaging and in-vivo analysis to identify how this system develops and functions. We have catalogued gene expression profiles (using snRNAseq) from the CNC of this species (in both embryo and adult), providing a window into its embryonic development and the molecular players involved in its physiological function at single-cell resolution.
The techniques you will use and be trained in include: (1) Bioinformatics. You will use this to prioritise key genes involved in the development and function of the system. (2) Hybridisation chain reaction fluorescent in situ hybridisation. You will use this to map expression of candidate genes in embryonic, larval and adult CNCs. (3) Gene knock-down: you will use RNAi to knock-down gene activity for each candidate and, use (4) Microscopy (both fluorescence confocal and electron microscopy) and simple physiological assays to establish roles for these genes in CNC development and function.
Results from this project will significantly expand our understanding of one of the most powerful water-conserving systems in nature, one that is fundamental to insect physiology, ecology and evolutionary success.
Further information about this project should be sought by emailing the lead supervisor Barry.Denholm@ed.ac.uk
How To Apply
This 4 year PhD project is part of a competition funded by EASTBIO BBSRC Doctoral Training Partnership (DTP). Detailed guidance on the application process, and the EASTBIO Application and Reference Forms can be found on the EASTBIO DTP Website
Please send your completed EASTBIO Application Form along with a copy of your academic transcripts (as a pdf) to sbms-postgraduate@ed.ac.uk You should also contact your referees and ask them to submit their references (on the EASTBIO reference form template) to sbms-postgraduate@ed.ac.uk by the application deadline of 17th January 2025.
Funding Notes
This opportunity is open to UK and international students and provides funding covering stipend and UK level tuition fees. The University of Edinburgh covers the difference between home and international fees meaning that the EASTBIO DTP offers fully-funded studentships to all appointees. There is a cap on the number of international students the DTP recruits. It is therefore important for us to know from the outset which fees status category applicants will fall under when applying to our University.
Please refer to UKRI website for full eligibility criteria: Get a studentship to fund your doctorate – UKRI
