Sidney Truelove Professor of Gastroenterology
Infectious diseases such as HIV, hepatitis B and C, affect hundreds of millions of people worldwide. Our group works on the immune response to these infections, focusing on both the host and the pathogen. As there is currently no vaccine to prevent hepatitis C infection, many of our projects have addressed aspects of chronic hepatitis C virus (HCV) infection and vaccine responses. In addition, our group also looks at a range of viruses and bacteria. Overall our main contributions to date have been to define mechanisms of viral persistence, including: T cell escape, antagonism, original antigen sin, integration of non-retroviral RNA viruses; to define the key features of successful immune responses against HCV, leading to trials of a T cell vaccine; and to define the distinctive CD161+ T cell population, which dominates in the human liver.
We are currently working on three main strands of research:
1. CD161++/MAIT cell biology. These lymphocytes, which are abundant in human blood and highly enriched in the liver, have the capacity to respond to both bacterial and inflammatory signals. We are trying to understand their in vivo role in host defence and immunopathology, through the analysis of patients and in vitro studies of function and activation.
2. HCV immune defence. In collaboration with the groups of Ellie Barnes and Adrian Hill, we are involved in vaccine studies using adenoviral vectors to track vaccine-induced cells and analyse their capacity to recognise viral variants. Upcoming studies include an analysis of host responses in relation to novel drug therapies and the use of new viral sequencing approaches to define the impact of host immunity.
3. Memory inflation. Some persistent virus infections induce a striking host response, which we have termed memory "inflation"; this includes the generation of very large functional T cell populations, which can increase with time. While this was first noted in cytomegalovirus infections, we have found a similar profile of cells after adenoviral vector vaccination. Our group is working to define the qualities of these induced cells, and the critical factors that drive memory inflation.
MAIT Cells in Health and Disease.
Provine NM. and Klenerman P., (2020), Annual review of immunology, 38, 203 - 228
Local heroes or villains: tissue-resident memory T cells in human health and disease.
Sasson SC. et al, (2020), Cell Mol Immunol
Human MAIT Cell Activation In Vitro.
Hagel JP. et al, (2020), Methods in molecular biology (Clifton, N.J.), 2098, 97 - 124
Guidelines for the use of flow cytometry and cell sorting in immunological studies (second edition).
Cossarizza A. et al, (2019), European journal of immunology, 49, 1457 - 1973
Prolonged evolution of virus-specific memory T cell immunity after severe avian influenza A (H7N9) virus infection
Zhao M. et al, (2019), EUROPEAN JOURNAL OF IMMUNOLOGY, 49, 1045 - 1045