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
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
Predicting adaptation and range expansion under climate change. This project investigates the repeatability and thereby the predictability of adaptation to climate change by leveraging 1000 genomes sampled over 150 years and multiple climatic gradients in the rapidly adapting, globally invasive, and highly allergenic ragweed. We expect to deepen our understanding of the genetic basis of adaptation and decipher the circumstances under which adaptive genetic change is repeatable, by integrating a ....Predicting adaptation and range expansion under climate change. This project investigates the repeatability and thereby the predictability of adaptation to climate change by leveraging 1000 genomes sampled over 150 years and multiple climatic gradients in the rapidly adapting, globally invasive, and highly allergenic ragweed. We expect to deepen our understanding of the genetic basis of adaptation and decipher the circumstances under which adaptive genetic change is repeatable, by integrating a novel evolutionary model with genomic data. We will develop the capacity to predict species’ distributions and trait evolution under climate change using a powerful empirical dataset. This will provide us with the capacity to anticipate and manage the effects of climate change on noxious and threatened species.Read moreRead less
Understanding Mitotic Telomere Deprotection. This project aims to study telomeres, the DNA and protein structures that protect chromosome ends. During cell division, cells under stress intentionally uncap their telomeres. This project expects to generate new knowledge that challenges the conventional notion of telomeres as static elements, showing instead that telomeres can be dynamic signalling hubs. Expected outcomes of this project include an understanding of the genetic, proteomic, and signa ....Understanding Mitotic Telomere Deprotection. This project aims to study telomeres, the DNA and protein structures that protect chromosome ends. During cell division, cells under stress intentionally uncap their telomeres. This project expects to generate new knowledge that challenges the conventional notion of telomeres as static elements, showing instead that telomeres can be dynamic signalling hubs. Expected outcomes of this project include an understanding of the genetic, proteomic, and signalling pathways involved in this novel phenomenon. This should provide significant benefits to our fundamental understanding of biological processes that protect human genomes and provide a valuable dataset for research on telomere biology, DNA repair, and genome stability.Read moreRead less
Identification of Biological pathways regulated by circular RNAs. Circular RNAs (circRNAs) are a, recently discovered molecule. circRNAs are highly abundant and expressed in a tissue and disease specific manner. Yet, currently the understanding of how circRNAs regulate biological processes is very poor. This project aims to use pooled shRNA libraries to screen a large panel of cell lines and systematically identify cellular activities that are regulated by circRNAs. The expected outcome of this ....Identification of Biological pathways regulated by circular RNAs. Circular RNAs (circRNAs) are a, recently discovered molecule. circRNAs are highly abundant and expressed in a tissue and disease specific manner. Yet, currently the understanding of how circRNAs regulate biological processes is very poor. This project aims to use pooled shRNA libraries to screen a large panel of cell lines and systematically identify cellular activities that are regulated by circRNAs. The expected outcome of this study will be a catalogue of functionally active circRNAs. Over the past decades, the wealth of knowledge on the function of linear mRNAs has had a significant impact on medicine and agriculture. Similarly understanding how circRNAs regulate cellular activities may have an analogous impact on humans.Read moreRead less
How do stem cells get specified during embryonic muscle development? This project aims to investigate the mechanisms by which muscle stem cells first form in the embryo. This project expects to generate new knowledge on the mechanism that patterns cell types in the embryonic myotome. Expected outcomes of this project include uncovering the developmental mechanisms of cell type specification in the myotome with specific reference to the generation of stem cells. This should provide significant be ....How do stem cells get specified during embryonic muscle development? This project aims to investigate the mechanisms by which muscle stem cells first form in the embryo. This project expects to generate new knowledge on the mechanism that patterns cell types in the embryonic myotome. Expected outcomes of this project include uncovering the developmental mechanisms of cell type specification in the myotome with specific reference to the generation of stem cells. This should provide significant benefits as it will inform how long lived tissue resident stem cells can be made in the first instance, knowledge that is critical for making stem cells on demand outside the animal and manipulating stem cells in living tissue.Read moreRead less
The impact of Hyaluronic Acid on growth factor signalling and angiogenesis. Blood vessel development is controlled by growth factor signalling. Vessels are attracted by and migrate along growth factor gradients, and this is controlled by the extracellular matrix (ECM). From the zebrafish model, we have identified a novel gene that modulates the ECM, impacting growth factor signalling and vessel development. The project will explore by what mechanism this gene impacts signalling. It will comprehe ....The impact of Hyaluronic Acid on growth factor signalling and angiogenesis. Blood vessel development is controlled by growth factor signalling. Vessels are attracted by and migrate along growth factor gradients, and this is controlled by the extracellular matrix (ECM). From the zebrafish model, we have identified a novel gene that modulates the ECM, impacting growth factor signalling and vessel development. The project will explore by what mechanism this gene impacts signalling. It will comprehensively define where in the embryo it is required and investigate what cofactors it interacts with to perform its function. Using genetic zebrafish and mouse models as well as cell culture models we will investigate the fundamental biology of this gene.Read moreRead less
Understanding telomere privilege in pluripotent stem cells. We recently identified that fundamental mechanisms which protect chromosome ends (i.e. “telomeres”) are not conserved between somatic and embryo-derived stem cells. This discovery is without precedent and challenges the dogmatic expectation that cellular functions promoting genome stability are conserved in stem cells. We term the unexpected protective capacity of pluripotent chromosome ends “telomere privilege”. Here we will uncover th ....Understanding telomere privilege in pluripotent stem cells. We recently identified that fundamental mechanisms which protect chromosome ends (i.e. “telomeres”) are not conserved between somatic and embryo-derived stem cells. This discovery is without precedent and challenges the dogmatic expectation that cellular functions promoting genome stability are conserved in stem cells. We term the unexpected protective capacity of pluripotent chromosome ends “telomere privilege”. Here we will uncover the molecular, genomic, and proteomic regulators or telomere privilege; determine the breath of telomere privilege in stem cell lineages; elucidate the functional significance of telomere privilege; and exploit telomere privilege to study fundamental biology related to telomeres and the DNA damage response.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101315
Funder
Australian Research Council
Funding Amount
$461,154.00
Summary
The dynamic interplay between the matrix and cell fate in developing heart. Malformations in the developing heart can lead to catastrophic defects and embryonic loss. The valves play a critical role in blood flow regulation and are made of a stratified matrix that is laid down early in development. This project aims to determine how the cellular fate of the early valve cells establish the layered matrix and in turn how the matrix can influence cell fate by utilising a multi-omics approach to ide ....The dynamic interplay between the matrix and cell fate in developing heart. Malformations in the developing heart can lead to catastrophic defects and embryonic loss. The valves play a critical role in blood flow regulation and are made of a stratified matrix that is laid down early in development. This project aims to determine how the cellular fate of the early valve cells establish the layered matrix and in turn how the matrix can influence cell fate by utilising a multi-omics approach to identify unique cell populations and integrate transcriptional and protein changes during matrix disruption. This project expects to generate fundamental knowledge on how matrix structure can influence cell fate in the valves and will advance Australia's knowledge base and research capabilities in developmental biology.Read moreRead less
Characterising a new regulator of the Hedgehog pathway . The Hedgehog pathway is crucial for embryonic development, and disruption causes multi-organ morphogenesis defects. The CI team has uncovered a new gene required for Hedgehog signalling in mouse, zebrafish, and Drosophila. Preliminary data hints at mechanism for this novel gene and shows it may in fact be a member of a new superfamily. The project will examine gene function and identify interacting protein partners, using the zebrafish, Dr ....Characterising a new regulator of the Hedgehog pathway . The Hedgehog pathway is crucial for embryonic development, and disruption causes multi-organ morphogenesis defects. The CI team has uncovered a new gene required for Hedgehog signalling in mouse, zebrafish, and Drosophila. Preliminary data hints at mechanism for this novel gene and shows it may in fact be a member of a new superfamily. The project will examine gene function and identify interacting protein partners, using the zebrafish, Drosophila, and cell-based models. Findings will provide basic knowledge about this mysterious gene and uncover how it modulates an essential pathway in embryonic development. This research is expected to impact knowledge generation, health, and well-being.Read moreRead less