Research in the School of Biosciences revolves around understanding systems and processes in the living cell. It has a strong molecular focus with leading-edge activities that are synergistic with one another and complementary to the teaching provision.
Minimum 2.1 degree in a relevant subject. Acceptance of any candidate is at the discretion of the supervisor, following an interview.
All applicants are considered on an individual basis and additional qualifications, professional qualifications and relevant experience may also be taken into account when considering applications.
Please see our International website for entry requirements by country and other relevant information. Due to visa restrictions, international fee-paying students cannot study part-time unless undertaking a distance or blended-learning programme with no on-campus provision.
The University requires all non-native speakers of English to reach a minimum standard of proficiency in written and spoken English before beginning a postgraduate degree. Certain subjects require a higher level.
For detailed information see our English language requirements web pages.
Please note that if you are required to meet an English language condition, we offer a number of pre-sessional courses in English for Academic Purposes through Kent International Pathways.
Duration: 3 to 4 years full-time, 5 to 6 years part-time
The 2020/21 annual tuition fees for this programme are:
For details of when and how to pay fees and charges, please see our Student Finance Guide.
For students continuing on this programme fees will increase year on year by no more than RPI + 3% in each academic year of study except where regulated.* If you are uncertain about your fee status please contact firstname.lastname@example.org
Find out more about general additional costs that you may pay when studying at Kent.
Search our scholarships finder for possible funding opportunities. You may find it helpful to look at both:
In The Complete University Guide 2020, the University of Kent was ranked in the top 10 for research intensity. This is a measure of the proportion of staff involved in high-quality research in the university.
Please see the University League Tables 2020 for more information.
In the Research Excellence Framework (REF) 2014, research by the School of Biosciences was ranked 7th for research intensity and in the top 20 in the UK for research output.
An impressive 93% of our research-active staff submitted to the REF and 100% of our research was judged to be of international quality, with 88% of this judged world-leading or internationally excellent. The School’s environment was judged to be conducive to supporting the development research of international excellence.
Within our collaborative research community, the School offers an inspiring environment where researchers at all levels can produce their best work.
An impressive 93% of our active research staff submitted to the 2014 Research Excellence Framework and 88% of this research was classed as 'world-leading' or 'internationally excellent'.
Our research is focussed on biological processes at the molecular and cellular level and spans the disciplines of biochemistry, genetics, biotechnology and biomedical research. The five main research themes within the School are:
Each theme is supported by specialist facilities.
The Kent Fungal Group (KFG) brings together a number of research groups in the School of Biosciences that primarily use yeasts or other fungi as ‘model systems’ for their research. One strength of the KFG is the range of model fungi being exploited for both fundamental and medical/translational research. These include Bakers’ yeast (Saccharomyces cerevisiae) and Fission yeast (Schizosaccharomyces pombe) and yeasts associated with human disease, specifically Candida albicans and Cryptococcus neoformans.
In addition to studying key cellular processes in the fungal cell such as protein synthesis, amyloids and cell division, members of the KFG are also using yeast to explore the molecular basis of human diseases such as Alzheimer’s, Creutzfeldt-Jakob, Huntington’s and Parkinson’s diseases as well as ageing. The KFG not only provides support for both fundamental and medical/translational fungal research, but also provides an excellent training environment for young fungal researchers.
The School houses one of the University’s flagship research centres – the Industrial Biotechnology Centre (IBC). Here, staff from Biosciences, Mathematics, Chemistry, Physics, Computing and Engineering combine their expertise into a pioneering interdisciplinary biosciences programme at Kent, in order to unlock the secrets of some of the essential life processes. These approaches are leading to a more integrated understanding of biology in health and disease. In the Centre, ideas and technology embodied in different disciplines are being employed in some of the remaining challenges in bioscience. With such an approach, new discoveries and creative ideas are generated through the formation of new collaborative teams. In this environment, the Centre is broadening and enriching the training of students and staff in science and technology.
The centre comprises several like-minded academics dedicated to the study of reproduction in all its forms. Drawing on a range of academic disciplines, CISoR's core philosophy is that the study of this fascinating field will advance further through a multidisciplinary approach. Impactful, excellent research forms the basis of CISoR’s activities including scientific advance, new products and processes, contribution to public policy, and public engagement.
Kent’s world-class academics provide research students with excellent supervision. The academic staff in this school and their research interests are shown below. You are strongly encouraged to contact the school to discuss your proposed research and potential supervision prior to making an application. Please note, it is possible for students to be supervised by a member of academic staff from any of Kent’s schools, providing their expertise matches your research interests. Use our ‘find a supervisor’ search to search by staff member or keyword.
Full details of staff research interests can be found on the School's website.
The elucidation and role of protein structure and function in molecular processes, in particular those with a potential for therapeutic intervention through drug design.View Profile
Genetics and epigenetics of repetitive DNA domains.View Profile
How the mechanochemistry of the myosin motor domain is tuned to produce widely differing activities and how the motor activity is regulated.View Profile
Investigating the regulation of mitochondria in cell health and ageing; Regulation of microbiomes in human health; Identification of new methods to combat human fungal pathogens; Yeast as a model for Motor Neurone Disease.View Profile
The cytogenetic basis of gametogenesis, in particular genome organisation; chromosomes in early mammalian development and implications for pre-implantation genetic diagnosis. Comparative genomics and genome evolution in avian and mammalian species.View Profile
Cellular responses to DNA damage, with particular emphasis on the repair of DNA damage in human cells induced by environmental and clinical agents; novel radiopharmaceuticals used in the imaging treatment of cancer.View Profile
Cancer cell biology and cancer cell response to therapy with a focus on drug resistance; Virus biology, pathogenicity, and antiviral therapies.View Profile
The characterisation of myosins from the fission yeast Schizosaccharomyces pombe, which have been implicated in diverse roles in its life cycle; characterising enzymatic properties of these myosins and correlating these with established in vivo assays.View Profile
Gap junctions in nervous and immune systems; assembly, regulation and functions of innexin-based junctions.View Profile
Mechanisms of protein transport across biological membranes; the twin-arginine translocation (Tat) system in bacteria and chloroplasts; protein sorting in cyanobacteria.View Profile
Microbial communication and microbial biotechnology.View Profile
The role of morphology on the influenza virus lifecycle and pathogenesis.View Profile
Antimicrobial resistance in bacterial pathogens; resistance mechanisms of bacterial pathogens to nitric oxide; biochemical/genetic studies on bacterial respiration; biofuel production using solventogenic Clostridium species.View Profile
Protein and cell biotechnology; synthetic biology, metabolic engineering, animal cell engineering; proteomics and protein bioprocessing, biotherapeutic drug development.View Profile
Exploring the biological role of parasites within the microbiome and their biochemical interactions with their hosts .View Profile
The mechanism and control of translation in yeast; yeast prion proteins; molecular chaperones.View Profile
How the protein synthesis apparatus is regulated in cells and how it can achieve synthesis of exactly the right proteome for the right occasion.View Profile
Metabolic and genetic engineering; protein structure and function; biosynthesis of natural products including vitamins, cofactors and prosthetic groups.View Profile
The use of bioinformatics approaches to analyse big data across many areas of biology. These include analysis of genetic variation and its link with disease, drug resistance in cancer and also analysis of determinants of virus pathogenicity including that of Ebola viruses.View Profile
The structure and function of proteins that play key biological roles within the body or that are known to be important in human disease; protein folding.View Profile
Investigation of the structure, the assembly mechanism, the biological function, the disease-associated properties, and the physiochemical properties of forms of protein known as amyloid, and transmissible amyloid know as prions. Key methods include Protein chemistry, atomic force microscopy and transmission election microscopy.View Profile
Reproductive functions in models of infertility, genes on the mouse Y chromosome and their roles in spermatogenesis and in genome evolution, DNA repair mechanisms in meiosis and cancer.View Profile
Research is focussed on cell signalling and cell division, and how these cellular processes can be targeted for the treatment of cancer.View Profile
How cells sense mechanical forces. Mechanical signalling, Cell-extracellular matrix (ECM) adhesion complexes, cell migration, Mechanobiology, Structural BiologyView Profile
Understanding Ageing: Our lab exmines the molecular detail of the ageing process and how this interacts with the environment. We achieve this using the nematode worm C. elegas combined with powerful genetic, molecular and cell biological techniques. Check us out: www.jennytulletlab.comView Profile
Wet lab and computational approaches, focusing on human papillomavirus (HPV)-driven carcinogenesis as a paradigm for understanding tumour development.View Profile
Investigating the molecular mechanisms of membrane transport proteins involved in important physiological processes, including; antimicrobial resistance (AMR) and nutrient uptake in bacteria, and the onset of age-related metabolic diseases (diabetes and obesity) in humans. Key questions include how transporters recognise compounds and inhibitors, how they harness different energy sources to power transport across the the membrane, and how these proteins move during the transport cycle.View Profile
A postgraduate degree in the School of Biosciences is designed to equip our graduates with transferable skills that are highly valued in the workplace. Our research-led ethos ensures that students explore the frontiers of scientific knowledge, and the intensive practical components provide rigorous training in cutting edge technical skills that are used in the modern biosciences while working in areas of world-leading expertise within the School.
Destinations for our graduates include the leading pharmaceutical and biotechnological companies within the UK and leading research institutes both at home and abroad.
The School is well equipped, with excellent general research laboratories, together with a range of specialised research resources including facilities for growing micro-organisms of all kinds, extensive laboratories for animal cell culture and monoclonal antibody production and an imaging suite providing high-resolution laser confocal and electron microscopy. Additionally, the macromolecular analysis facility provides resources for protein and mass spectrometry, CD and fluorescence spectroscopy, surface plasmon resonance, and HPLC and FPLC systems for all aspects of biochemical and microbiological research. Notably, the School has a new state-of-the-art Bruker Avance III four-channel 600 MHz NMR spectrometer equipped with a QCI cryoprobe. Our NMR spectrometer was upgraded to this status via an equipment research award from the Wellcome Trust.
All research students are supervised closely and are regularly monitored online using the University progression and monitoring system. All postgraduate students have access to electronic and other resources providing information regarding technical issues relevant to their degrees, as well as subject-specific and transferable skills training. All research students are allocated a Postgraduate Supervisory Team, consisting of one or more day-to-day supervisors, and one or more members not involved in day-to-day supervision whose task it is to serve as independent monitors of progress.
Every week, Biosciences runs school seminars where external guest speakers or staff, talk about recent research. In addition, the department runs FIREBio (Forum for Innovation, Research and Enterprise in Biosciences), which is a weekly informal meeting for staff, postdocs and postgraduates involving short presentations and discussions. Postgraduates can use the opportunity to present unpublished research findings and discuss them in a supportive environment.
Staff in the School of Biosciences not only collaborate extensively with other universities in the UK (Cambridge, Cardiff, King’s College London, University College London, Newcastle, Oxford, Sussex, York, Manchester, Durham and Sheffield), but also have a wide-ranging network across the world with institutes including: the Boston Biomedical Research Institute; University of Hanover; Monash University Melbourne; Harvard; University of California, Davis; Université Claude Bernard – Lyon 1; Goethe-Universität Frankfurt; University of Queensland, Australia; University of Utah; Texas A&M University; and Braunschweig University of Technology. We also collaborate with organisations such as the Marie Curie Research Institute, Cancer Research UK, National Institute for Medical Research, MRC London, GlaxoSmithKline and the European Union Framework 5 CYTONET.
The School currently receives funding from: BBSRC; Biochemical Society; British Heart Foundation; E B Charitable Hutchinson Trust; the EC; EPSRC; Kent Cancer Trust;The Leverhulme Trust; National Institutes of Health (USA); Nuffield Foundation; Royal Society; Wellcome Trust. It also receives funding on specific projects from a number of industrial organisations and collaborators.
Staff publish regularly and widely in journals, conference proceedings and books. Among others, they have recently contributed to: Nature Chemical Biology; Journal of Biological Chemistry; Cell; Molecular Cell; Proceedings of the National Academy of Sciences USA; PLOS One; and Journal of Cell Science.
Kent's Graduate School co-ordinates the Researcher Development Programme for research students, which includes workshops focused on research, specialist and transferable skills. The programme is mapped to the national Researcher Development Framework and covers a diverse range of topics, including subject-specific research skills, research management, personal effectiveness, communication skills, networking and teamworking, and career management skills.