Epigenetic regulation of immune memory. Immune memory cells emerge from the dynamic and transient immune response to deliver two critical abilities: to produce rapid recall responses upon reinfection but also to persist for decades. This project aims to define how the polycomb repressive complexes regulate immune cell fate, by utilising cutting-edge cell and chromatin biology techniques coupled with bioinformatic pipelines. Expected outcomes of the proposed research include key insights into epi ....Epigenetic regulation of immune memory. Immune memory cells emerge from the dynamic and transient immune response to deliver two critical abilities: to produce rapid recall responses upon reinfection but also to persist for decades. This project aims to define how the polycomb repressive complexes regulate immune cell fate, by utilising cutting-edge cell and chromatin biology techniques coupled with bioinformatic pipelines. Expected outcomes of the proposed research include key insights into epigenetic programming required for immune cell differentiation and longevity. This should provide significant benefits such as knowledge creation that may lead to development of technology that reprograms cell behaviour, and contribution to Australian research recognition and capacity.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100705
Funder
Australian Research Council
Funding Amount
$462,948.00
Summary
Decoding the enigmatic biology of human gamma-delta T cells. The immune system surveys our body examining molecules that signal whether or not everything is ok. T cells are a central to this and use their receptors to monitor these molecular signals. A specialised subset of T cells known as gamma-delta T cells are critical to detecting infection and cancer, yet their fundamental biology is poorly understood. This project aims to unravel this elusive biology. The aims are to understand 1. The div ....Decoding the enigmatic biology of human gamma-delta T cells. The immune system surveys our body examining molecules that signal whether or not everything is ok. T cells are a central to this and use their receptors to monitor these molecular signals. A specialised subset of T cells known as gamma-delta T cells are critical to detecting infection and cancer, yet their fundamental biology is poorly understood. This project aims to unravel this elusive biology. The aims are to understand 1. The diversity in function between gamma-delta T cell subsets, and 2. The diversity in gamma-delta T cell receptors and the molecules that these receptors detect. This work is essential for understanding gamma-delta T cell immunology which is critical if we ultimately wish to harness this to improve human health.Read moreRead less
Unraveling the chromatin networks that control T lymphocyte differentiation. The development of T cell responses is essential for fighting infection but in some cases T cells can also cause allergy and autoimmune diseases. Previous research has shown by understanding the complex chromatin circuitry that underlie T cell function, therapies can be designed to rewire harmful T cells. This project will use a multi-disciplinary approach that combines expertise in cutting-edge molecular techniques wit ....Unraveling the chromatin networks that control T lymphocyte differentiation. The development of T cell responses is essential for fighting infection but in some cases T cells can also cause allergy and autoimmune diseases. Previous research has shown by understanding the complex chromatin circuitry that underlie T cell function, therapies can be designed to rewire harmful T cells. This project will use a multi-disciplinary approach that combines expertise in cutting-edge molecular techniques with unique mouse models and bioinformatics to develop a fundamental understanding of the chromatin architecture and epigenetic networks that control important steps of T cell differentiation during development, allergy and infection.Read moreRead less