Old Road Campus Research Building
Associate Professor, Principal Investigator, Group Head / PI, Member of congregation and Supervisor
One theme in our group is to understand how specific HLA-B*27 subtypes pre-dispose to inflammatory autoimmune condition, most notably Ankylosing Spondylitis (AS), a condition that affects the spine and specific joints. This association has been recognised for over 5 decades, but the biological basis of disease initiation is not well understood. Through international collaboration, we recently re-explored an original disease model suggesting that a case of mistaken identity (autoimmunity) contributes to disease pathology where CD8+ T cells initially triggered by microbial epitopes bound to HLA-B*27 subsequently attack HLA-B*27-bound to self-peptides. We addressed this by testing a HLA-B*27 yeast display platform expressing large numbers (~108) of random peptides which we then tested for binding to AS-enriched T cell receptors (TCRs). This strategy led to the identification of peptides with sequences that are shared between microbial and self-proteins, adding strong support to the autoimmune disease hypothesis. These T cells have distinct transcriptional profiles that related to inflammatory CD8+ subsets described in other autoimmune conditions, and we next aim to interrogate these cellular phenotypes further to understand how the inflammatory environment modulates the functions, both spatially and temporally. We also plan to interrogate the gut-joint axis to understand the phenotypes and trajectories of T cells at these different sites. In addition to deciphering the complex biology of AS, a goal of this work is to elucidate if these finding could underpin the development of targeted therapies for AS.
Our second theme follows the unprecedented success of a CMV-SIV vaccine in rhesus macaques that elicited protective, SIV-specific CD8+ T cells targeting multiple peptides restricted by the MHC-E, has stemmed considerable interest in HLA-E (human MHC-E), a non-classical MHC protein originally described in the context of NK cell regulation and function. Unlike classical MHC class I, HLA-E proteins are near monomorphic and therefore offer a ‘universally’-conserved T cell restriction element. Our recent HLA-E structural studies have revealed the molecular basis underlying HLA-E-peptide binding and our biochemical studies have revealed unusual HLA-E properties that might explain how HLA-E picks up peptide epitopes in vivo. This work has also enabled us to improve HLA-E ELISA-based screening methods to quantitate peptide binding and to generated improved HLA-E tetramer tools to study HLA-E restricted T cells. With collaborators we aim to develop therapeutic reagents (primarily antibodies that recognise HLA-E-peptide antigen) targeting both viruses such as HIV in addition to tumour specific/associated antigens (e.g. from AML or HPV+ tumours). Our goals are to ultimately develop such reagents as CAR T cell-based therapeutics, alongside T cell receptor-based therapies, in addition to devising methods to create novel HLA-E targeting vaccine platforms.
Intracellular trafficking of HLA-E and its regulation.
He W. et al, (2023), J Exp Med, 220
Adaptive meets innate: CD8+ T cells kill MHC-I-negative tumour cells.
Peeters BWA. and Gillespie GM., (2023), Nature reviews. Immunology, 23
Autoimmunity-associated T cell receptors recognize HLA-B*27-bound peptides.
Yang X. et al, (2022), Nature
Primary and secondary functions of HLA-E are determined by stability and conformation of the peptide-bound complexes.
Walters LC. et al, (2022), Cell reports, 39
Mouse and human antibodies bind HLA-E-leader peptide complexes and enhance NK cell cytotoxicity.
Li D. et al, (2022), Commun Biol, 5