Discovery Early Career Researcher Award - Grant ID: DE180100261
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Understanding interactions between gut epithelial stem cells and neurons. This project aims to investigate the interaction between gut neurons and the epithelial stem cell compartment, as well as the relationship between age-related loss of enteric neurons and changes in gut epithelial stem cells. This project will include novel co-culturing of organoids and enteric neurospheres, which will identify mechanisms by which nerves influence the epithelia. The outcome of the project will be a better u ....Understanding interactions between gut epithelial stem cells and neurons. This project aims to investigate the interaction between gut neurons and the epithelial stem cell compartment, as well as the relationship between age-related loss of enteric neurons and changes in gut epithelial stem cells. This project will include novel co-culturing of organoids and enteric neurospheres, which will identify mechanisms by which nerves influence the epithelia. The outcome of the project will be a better understanding of the biology of the body’s most highly proliferative, long-lived stem cells, intestinal epithelial stem cells. This could have significant long term impact on the quality of life in an ageing population.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100825
Funder
Australian Research Council
Funding Amount
$422,955.00
Summary
Functional insights into the roles of enteric glia. This project aims to review our current definition of enteric glia populations, and our understanding of their communication mechanisms in the mouse and primate colon. It will generate new knowledge of enteric glia biology using advanced microscopy and image analysis. Calcium imaging and novel biosensors will measure cell signalling in enteric glia. It will provide the most comprehensive analysis of glia connectivity, morphology and receptor ex ....Functional insights into the roles of enteric glia. This project aims to review our current definition of enteric glia populations, and our understanding of their communication mechanisms in the mouse and primate colon. It will generate new knowledge of enteric glia biology using advanced microscopy and image analysis. Calcium imaging and novel biosensors will measure cell signalling in enteric glia. It will provide the most comprehensive analysis of glia connectivity, morphology and receptor expression in the primate colon. Expected outcomes include a detailed map of enteric glia and definitions of their basic biology. This project builds on the techniques and collaborations made by the candidate over recent years. This will benefit our basic understanding of enteric glia biology.Read moreRead less