cell-cell adhesive force in vascular development. This project aims to utilize groundbreaking new approaches to visualize cell-cell adhesive forces in vascular development. Vascular system development is one of the earliest events in the vertebrate embryo. It has long been established that one major contributor to the formation of new vessels is physical force, which can be generated through blood flow or cell-cell interactions during tissue morphogenesis. The project plan utilizes live imaging ....cell-cell adhesive force in vascular development. This project aims to utilize groundbreaking new approaches to visualize cell-cell adhesive forces in vascular development. Vascular system development is one of the earliest events in the vertebrate embryo. It has long been established that one major contributor to the formation of new vessels is physical force, which can be generated through blood flow or cell-cell interactions during tissue morphogenesis. The project plan utilizes live imaging in zebrafish and a new generation of biosensors to gain a vastly deeper understanding of how force controls vessel formation.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
Genetic variation of single cell transcriptional heterogeneity in HiPSCs. This project aims to investigate whether induced pluripotent stem cells (iPSC) can be used to study the functions of genetic variants associated with human phenotypes and cell fate decisions. The project will utilise technology to produce single cell RNA sequence data for 100,000s of cells. By sequencing individual cells, the genetic control of cellular heterogeneity both within and between cells can be identified, and in ....Genetic variation of single cell transcriptional heterogeneity in HiPSCs. This project aims to investigate whether induced pluripotent stem cells (iPSC) can be used to study the functions of genetic variants associated with human phenotypes and cell fate decisions. The project will utilise technology to produce single cell RNA sequence data for 100,000s of cells. By sequencing individual cells, the genetic control of cellular heterogeneity both within and between cells can be identified, and in doing so, will provide significant benefit by revealing the potential for iPSC to be used for functional translation of human genomics.Read moreRead less
Molecular characterization of the role of menin in embryonic development. Menin is a protein that is necessary to prevent development of tumours. Deletion of menin in mice causes embryonic death. We think this is because menin is necessary in the placenta. This project will examine the role of menin in the fetus and the placenta, and provide information about how normal pregnancy and fetal growth is controlled.
The structure and patterning of branching morphogenesis in the developing kidney. This project aims to understand a fundamental developmental process known as branching morphogenesis, which drives the formation of many organs including the kidney, lungs and glands. Understanding this process will be of key importance in understand how our organs form.
Investigating spermatogonial stem cell allocation in the fetal testis. This project aims to determine when and how spermatogonial stem cells (SSCs) are specified, and whether a genetic pathway that is used by in vitro stem cells is also employed, in vivo, by testicular stem cells. The project aims to deliver insight into the mechanisms of adult stem cell specification and regulation, in general. Intended practical outcomes of this work will underpin new methods for fertility management in animal ....Investigating spermatogonial stem cell allocation in the fetal testis. This project aims to determine when and how spermatogonial stem cells (SSCs) are specified, and whether a genetic pathway that is used by in vitro stem cells is also employed, in vivo, by testicular stem cells. The project aims to deliver insight into the mechanisms of adult stem cell specification and regulation, in general. Intended practical outcomes of this work will underpin new methods for fertility management in animals (in agriculture and conservation of endangered species) and humans. Knowledge gained will inform our understanding of stem cell biology more broadly and guide efforts to treat infertility or control fertility in animals and humans.Read moreRead less
Deciphering the cellular functions of caveolae that govern lymphatic vascular development. Lymphatic vessels play crucial roles in tissue fluid homeostasis, immunity, and fatty acid transport. Despite our recent understanding of genetic pathways that modulate lymphatic cell fate specification, how cellular changes mediate morphogenesis of the lymphatic tree remains to be elucidated. This study will combine cell biology and developmental genetics approaches using mouse and zebrafish transgenic li ....Deciphering the cellular functions of caveolae that govern lymphatic vascular development. Lymphatic vessels play crucial roles in tissue fluid homeostasis, immunity, and fatty acid transport. Despite our recent understanding of genetic pathways that modulate lymphatic cell fate specification, how cellular changes mediate morphogenesis of the lymphatic tree remains to be elucidated. This study will combine cell biology and developmental genetics approaches using mouse and zebrafish transgenic lines that label lymphatic endothelial cells to investigate the role of caveolae proteins in the construction of the lymphatic vascular network. This project aims to improve our fundamental understanding of the processes that govern vascular system assembly and will broaden basic knowledge of organ morphogenesis. Read moreRead less
Regulation of mammalian differentiation by methylation of histones and transcription factors. The objective of this proposal is to examine the functional role of arginine and lysine methylation during skeletal muscle differentiation. Differentiation, i.e the acquisition of a specific phenotype, is the biological end point of the ?Genome-Phenome? transition. Specifically, the proposal will seek to understand the role of protein methylation in the control of tissue specific gene expression and ce ....Regulation of mammalian differentiation by methylation of histones and transcription factors. The objective of this proposal is to examine the functional role of arginine and lysine methylation during skeletal muscle differentiation. Differentiation, i.e the acquisition of a specific phenotype, is the biological end point of the ?Genome-Phenome? transition. Specifically, the proposal will seek to understand the role of protein methylation in the control of tissue specific gene expression and cell signaling during differentiation. Key areas of study in the ARC priority area of Genome-Phenome research. We will test the hypothesis that the activity/function of the hierarchical myogenic transcription factors and cofactors that control skeletal myogenesis is influenced by protein methylation.Read moreRead less
Foundations of a good egg: correctly transitioning from mitosis to meiosis. Production of viable offspring is essential to the survival of any species. In all sexually reproducing species, this requires a unique cell type, the germ cell. Germ cells undergo a special type of cell division, called meiosis, so that they can eventually produce gametes (sperm in males and eggs in females). This project aims to discover how germ cells halt the standard form of cell division, called mitosis, and initia ....Foundations of a good egg: correctly transitioning from mitosis to meiosis. Production of viable offspring is essential to the survival of any species. In all sexually reproducing species, this requires a unique cell type, the germ cell. Germ cells undergo a special type of cell division, called meiosis, so that they can eventually produce gametes (sperm in males and eggs in females). This project aims to discover how germ cells halt the standard form of cell division, called mitosis, and initiate meiotic division instead. It is important to understand all the fundamental processes that occur during normal germ cell development so that, in the future, we can use this knowledge to support agricultural advances, rescue endangered species and solve human problems such as infertility and genetic disease.Read moreRead less
Inter-kingdom signalling in animal health and disease. This project aims to understand how animals can control their bacterial associates. Animals evolved in a world dominated by bacteria, and intimately associated microbes affect the development, health and disease of all animals – from corals to man. To date, animal-microbe interactions have been studied nearly exclusively in terms of how bacteria affect animals. the researchers have discovered that the coral Acropora can control its associate ....Inter-kingdom signalling in animal health and disease. This project aims to understand how animals can control their bacterial associates. Animals evolved in a world dominated by bacteria, and intimately associated microbes affect the development, health and disease of all animals – from corals to man. To date, animal-microbe interactions have been studied nearly exclusively in terms of how bacteria affect animals. the researchers have discovered that the coral Acropora can control its associated bacteria. Understanding how a simple animal manipulates its microbial associates should have implications for coral disease and resilience and for health and disease across the animal kingdom.Read moreRead less