Discovery Early Career Researcher Award - Grant ID: DE190101209
Funder
Australian Research Council
Funding Amount
$390,000.00
Summary
Genes underlying enteric neuron subtype differentiation. This project aims to use new RNA-sequencing technology to identify genes important for differentiation of several major enteric neuron subtypes. Proper development and function of the digestive tract is crucial for good health. Gastrointestinal function relies on the co-ordinated activity of neural circuits in the enteric nervous system. This project will advance Australia's knowledge base and research capabilities in the field basic devel ....Genes underlying enteric neuron subtype differentiation. This project aims to use new RNA-sequencing technology to identify genes important for differentiation of several major enteric neuron subtypes. Proper development and function of the digestive tract is crucial for good health. Gastrointestinal function relies on the co-ordinated activity of neural circuits in the enteric nervous system. This project will advance Australia's knowledge base and research capabilities in the field basic developmental neuroscience, by innovative use of Next Generation RNA-sequencing technology to investigate enteric neuron subtype differentiation. The project outcomes include the generation of neuron subtype specific progenitors from naïve stem cells, which will in the longer term have significant health benefits, as gastrointestinal dysfunction is a large health and economic burden in Australia.Read moreRead less
The role of gene isoforms in human brain development. This project aims to investigate how genes vary their products to control human brain development, by creating new methods to study gene activity in individual brain cells. Using these innovative methods, this project expects to generate fundamental new knowledge of how the human brain forms. Expected outcomes of this project include widely applicable techniques, strengthened international (UK) research collaborations and highly trained perso ....The role of gene isoforms in human brain development. This project aims to investigate how genes vary their products to control human brain development, by creating new methods to study gene activity in individual brain cells. Using these innovative methods, this project expects to generate fundamental new knowledge of how the human brain forms. Expected outcomes of this project include widely applicable techniques, strengthened international (UK) research collaborations and highly trained personnel in genomics and neuroscience. This should deliver many benefits, including a better understanding of how the brain forms, training of higher degree by research students, as well as tools and methods of benefit to the academic research and biotechnology sectors.Read moreRead less
Understanding the determinants of age-related muscle wasting in females . This project aims to investigate the fundamental mechanisms underlying age-related muscle wasting in females. Females live longer than males and are more susceptible to the consequences of muscle ageing. Yet, our current knowledge is overwhelmingly inferred from findings from male cohorts. By comprehensively mapping the functional, molecular and epigenetic mechanisms of ageing in female muscle, this project will generate n ....Understanding the determinants of age-related muscle wasting in females . This project aims to investigate the fundamental mechanisms underlying age-related muscle wasting in females. Females live longer than males and are more susceptible to the consequences of muscle ageing. Yet, our current knowledge is overwhelmingly inferred from findings from male cohorts. By comprehensively mapping the functional, molecular and epigenetic mechanisms of ageing in female muscle, this project will generate new, fundamental knowledge that will allow a unique interpretation of previous research through a sex-specific lens. This knowledge will contribute to better inform sex-specific models of research and practice in the future, ultimately delivering economic and social benefits for Australia and international communities.Read moreRead less
Differentiation of effector and tissue regulatory T cells . Regulatory T cells (Tregs) populate almost every organ of the body and play a central role in preventing inflammation and maintaining health. To exercise these functions, Tregs undergo a developmental program, the details of which are poorly known. This project will utilize newly developed biological tools and state-of-the-art technology to uncover the molecular mechanisms that govern Treg development and function. The project will gene ....Differentiation of effector and tissue regulatory T cells . Regulatory T cells (Tregs) populate almost every organ of the body and play a central role in preventing inflammation and maintaining health. To exercise these functions, Tregs undergo a developmental program, the details of which are poorly known. This project will utilize newly developed biological tools and state-of-the-art technology to uncover the molecular mechanisms that govern Treg development and function. The project will generate basic scientific knowledge and new intellectual property that will afford new opportunities for research and development. The outcomes of this project will help to devise strategies to treat diseases such as autoimmunity, cancer and metabolic syndrome, and will thus benefit veterinary and human health.Read moreRead less
The T cell genome in 3D: linking chromatin structure to cellular function. Adaptive immune cell activation results in the acquisition and long term maintenance of specific cellular function that enables efficient immune control of infections. Using advanced cellular and genomic approaches, combined with high-resolution microscopy and cutting edge computational biology, this proposal aims to address major gaps in our knowledge about how alterations in genomic 3D architecture and targeted biochemi ....The T cell genome in 3D: linking chromatin structure to cellular function. Adaptive immune cell activation results in the acquisition and long term maintenance of specific cellular function that enables efficient immune control of infections. Using advanced cellular and genomic approaches, combined with high-resolution microscopy and cutting edge computational biology, this proposal aims to address major gaps in our knowledge about how alterations in genomic 3D architecture and targeted biochemical modifications impact cell specific gene nuclear positioning and how this regulates changes in gene expression associated with immune cell activation. An outcome will be identification of novel molecular mechanisms that will have broad applicability across cellular biology, and provide novel targets for drug development.Read moreRead less