The School of Biological and Behavioural Sciences at Queen Mary is one of the UK’s elite research centres, according to the 2021 Research Excellence Framework (REF). We offer a multi-disciplinary research environment and have approximately 180 PhD student. Our students have access to a variety of research facilities supported by experienced staff, as well as a range of student support services.
The successful applicant will enter a vibrant research environment, under the supervision of Dr Lee Henry. The lab is well equipped to carry out the proposed research with world-class facilities in genomics and molecular biology. The student will also have access to ample funds to facilitate the research through Dr. Henry's external funding (~£2.5M to date), including a recently acquired BBSRC-NSF grant on a similar topic (£1.04M) that will support the students research. Dr. Henry current supervises 3 PhD students, 2 postdoctoral researcher, and a technician and has an outstanding record with student supervision with a focus on students generating high impact first authorship publications (e.g. Jackson et al 2022 ISME Journal, Wu et al 2022 Proc Soc B, Monnin et al 2020 Current Biology).
Dr Lee Henry is a Reader in Molecular Microbial Ecology. For research details see https://www.henry-lab.co.uk/
Our PhD students become part of Queen Mary’s Doctoral College which provides training and development opportunities, advice on funding, and financial support for research. Our students also have access to a Researcher Development Programme designed to help recognise and develop key skills needed to effectively manage research, and to prepare for the next stages of their career.
The PhD student will gain experience in advanced molecular techniques (e.g. RNAi, CRISPR, GFP), analyses of high-throughput data (e.g. bioinformatics of transcriptomic/genomic data), experimental and field techniques, and statistics.
Insects vector globally important disease in agriculture and humans that pose significant health and economic burdens (e.g. dengue, malaria, mosaic viruses). Current insecticide-based control methods are becoming ineffective and undesirable due to environmental pollution, and insecticide resistant insect populations. Endosymbionts provide a promising new approach for controlling disease by making insects less susceptible to carrying pathogens by up regulating host immune systems, while also rapidly spreading through insect population via maternal transmission.For example, introducing Wolbachia to mosquitos has reduced dengue virus by 77% in Indonesian field trails1. However, our current understanding of how symbionts interact with hosts is limited by a lack of genome editing tools in symbionts, most of which cannot be cultured outside of hosts. New models are urgently needed to understand how symbionts interact with host immunity, cause virulence, and transmit through host populations to improve their efficacy and applicability in vector-borne disease control. In this PhD, we will take advantage of a newly discovered culturable endosymbiont, Serratia symbiotica CWBI-2.3, which can be genetically engineered and tracked using fluorescent protein expression (GFP). We aim to identify symbiont genes responsible for up regulate host immunity, causing virulence, and improving symbiont transmission to gain a mechanistic understanding of traits important for designing symbionts to effectively combating vector borne diseases. The PhD will build off our pilot data that revealed candidate symbiont genes interacting with host immunity and causing virulence in aphids. The student will silence candidate genes in CWBI-2.3, quantify impacts on hosts, and track the symbiosis using GFP. These techniques will then be applied to symbionts found in other insect vectors using a novel culturing method developed by US collaborators. Our goal is to develop symbiont-based control strategies for diverse insect vectors of global importance in agriculture and human health (e.g. aphids, sandflies, ticks).
This studentship is open to students applying for CONACyT funding. CONACyT will provide a contribution towards your tuition fees each year and Queen Mary will waive the remaining fee. CONACyT will pay a stipend towards living costs to its scholars. Further information can be found here: https://conacyt.mx/convocatorias/convocatorias-becas-al-extranjero/
Please refer to the CONACyT website here: https://conacyt.mx/convocatorias/convocatorias-becas-al-extranjero/ for full details on eligibility and conditions on the scholarship.
Applications are invited from outstanding candidates with or expecting to receive a first or upper-second class honours degree in an area relevant to the project (e.g. microbiology, evolutionary or molecular biology, bioinformatics/computer science). A masters degree is desirable, but not essential.
Experience in microbiology or molecular biology or bioinformatics is desirable, but not essential.
Applicants from outside of the UK are required to provide evidence of their English language ability. Please see our English language requirements page for details: https://www.qmul.ac.uk/international-students/englishlanguagerequirements/postgraduateresearch/
Informal enquiries about the project can be sent to Lee Henry at l.henry@qmul.ac.uk
Applicants will need to complete an online application form to be considered, including a CV, personal statement and qualifications. Shortlisted applicants will be invited for a formal interview by the project supervisor. Those who are successful in their application for our PhD programme will be issued with an offer letter which is conditional on securing a CONACyT scholarship (as well as any academic conditions still required to meet our entry requirements).
Once applicants have obtained their offer letter from Queen Mary they should then apply to CONACyT for the scholarship as per their requirements and deadlines, with the support of the project supervisor.
Only applicants who are successful in their application to CONACyT can be issued an unconditional offer and enrol on our PhD programme.
Apply Online
Recent PhD lead papers from the Henry Lab:
Wu T, Monnin D, Lee RAR, Henry LM (2022) Local adaptation to hosts and parasitoids shape Hamiltonella defensa genotypes across aphid species. Proceedings of the Royal Society B 289: 20221269
Jackson R, Monnin D, Patapiou PA, Golding G, Helanterä H, Oettler J, ... Henry LM (2022) Convergent evolution of a labile nutritional symbiosis in ants. The ISME journal 16: 2114-2122
Jackson R, Henry LM, Wurm Y (2020). Evolution: The Legacy of Endosymbiosis in Ants. Current Biology 30:R1385-R1387.
Monnin D, Jackson R, Kiers ET, Bunker M, Ellers J, Henry LM (2020). Parallel Evolution in the Integration of a Co-obligate Aphid Symbiosis. Current Biology 30: R446-R448
References:Simmons CP et al. (2012) Dengue. N Engl J Med 366:1423-1432
Perreau J et al (2021) Engineering a Culturable Serratia symbiotica Strain for Aphid Paratransgenesis. Appl. Environ. Microbiol. 87:e02245-20.
Brandt JW et al. (2017) Culture of an aphid heritable symbiont demonstrates its direct role in defence against parasitoids. Proc Biol Sci 284:20171925Patel et al (2019) Cultivation-Assisted
Genome of Candidatus Fukatsuia symbiotica; the Enigmatic “X-Type” Symbiont of Aphids. Genome Biol. Evol. 11:3510.