Investigating the role of gene loops in regulating gene expression. The ability to identify functional variants in regulatory elements will have implications for researchers in multiple fields of biology, from molecular medicine to agriculture. Transfer of expertise and application of the knowledge generated by our research to such fields stands to improve diagnosis of disease predisposition and to improve quality of animal and plant products. These outcomes will benefit all Australians. This kn ....Investigating the role of gene loops in regulating gene expression. The ability to identify functional variants in regulatory elements will have implications for researchers in multiple fields of biology, from molecular medicine to agriculture. Transfer of expertise and application of the knowledge generated by our research to such fields stands to improve diagnosis of disease predisposition and to improve quality of animal and plant products. These outcomes will benefit all Australians. This knowledge will also improve the education of Australian University students as it contributes to the development of advanced curricula and access to more powerful research methods. In addition, the project will foster important collaborations between Australian researchers and those overseas.Read moreRead less
Drinking from the fire hose - Making sense of high density genetic and genomic data. The project will improve our understanding of the genetic component of common complex diseases such as cancer. Identification of genetic variants underlying disease risk is currently one of the primary means for increasing our understanding of the biochemical and developmental pathways involved. Genetic studies rely on sophisticated statistical and computational (bioinformatics) techniques. This project centres ....Drinking from the fire hose - Making sense of high density genetic and genomic data. The project will improve our understanding of the genetic component of common complex diseases such as cancer. Identification of genetic variants underlying disease risk is currently one of the primary means for increasing our understanding of the biochemical and developmental pathways involved. Genetic studies rely on sophisticated statistical and computational (bioinformatics) techniques. This project centres on the development, refinement and application of novel statistical analysis methods in genetics. Future advances in statistical and computational methods are essential if we are to exploit the large volumes of genome data now being generated to help develop diagnostics and interventions to improve public health.Read moreRead less
Regulation of the EphA3 receptor tyrosine kinase in vertebrate development. The Eph/ephrin system has a critical role in normal embryonic development. Amongst vertebrates, the EphA3 gene is one of the most highly conserved genes in this system with critical roles in development of the visual system and in other developmental processes. Understanding how this gene is regulated will help us to understand the critical role of EphA3 in the basic biology of humans and other animals. This knowledge ma ....Regulation of the EphA3 receptor tyrosine kinase in vertebrate development. The Eph/ephrin system has a critical role in normal embryonic development. Amongst vertebrates, the EphA3 gene is one of the most highly conserved genes in this system with critical roles in development of the visual system and in other developmental processes. Understanding how this gene is regulated will help us to understand the critical role of EphA3 in the basic biology of humans and other animals. This knowledge may also shed light on the basis of congenital abnormalities and other pathological processes and possibly help us to understand how to prevent or treat these conditions.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
The MYB gene as a model for global transcriptional regulation: stopping, starting and looping. This project will study how transcriptional elongation controls the MYB gene, a key regulator of normal and cancerous growth and regulation. There are three major benefits that are likely to flow from the proposed research It will strengthen research in new and important areas of transcriptional regulation, by building research capacity in Australia in the area of gene expression, particularly with res ....The MYB gene as a model for global transcriptional regulation: stopping, starting and looping. This project will study how transcriptional elongation controls the MYB gene, a key regulator of normal and cancerous growth and regulation. There are three major benefits that are likely to flow from the proposed research It will strengthen research in new and important areas of transcriptional regulation, by building research capacity in Australia in the area of gene expression, particularly with respect to transcriptional elongation and long-range regulation. It will highlight a new approach to the therapeutic targeting of MYB in cancer: data generated from this research may enable us to target MYB expression in a range of cancers including breast cancer by inhibiting transcriptional elongation. And it will provide training in advanced molecular biology to postdoctoral scientists and students.Read moreRead less
Genetic analysis of lymphatic vascular development. This project investigates the fundamental molecular components that regulate lymphatic vascular system development in the zebrafish embryo. Lymphatic vessels play critical roles in vascular diseases and cancer metastasis. This study will identify and examine key new molecules that will further our basic understanding of lymphatic development.
The molecular control of lymphatic vascular differentiation. This project aims to improve our understanding of how a new vascular system forms and the molecules that control this process. Lymphatic vasculature plays roles in fluid drainage, inflammation, obesity, metastasis and tissue repair, yet we cannot readily promote or inhibit lymphatic vessel formation. This project aims to build new knowledge that is expected to improve our ability to generate lymphatic vessels for stem cell application ....The molecular control of lymphatic vascular differentiation. This project aims to improve our understanding of how a new vascular system forms and the molecules that control this process. Lymphatic vasculature plays roles in fluid drainage, inflammation, obesity, metastasis and tissue repair, yet we cannot readily promote or inhibit lymphatic vessel formation. This project aims to build new knowledge that is expected to improve our ability to generate lymphatic vessels for stem cell applications, tissue engineering, tissue repair and regeneration. This project will use zebrafish embryos, new genomic datasets and novel tools to uncover the genetic control of this process, and should have implications in stem cell biology, tissue engineering, repair and regeneration.Read moreRead less
Origin of multicellularity in animals: identification and analysis of intercellular signalling pathways in a basal metazoan, the demosponge Reniera. The Reniera genome project is a multi-million dollar collaboration between JGI (US-DOE) and Australian scientists that will see the sequencing of the first Australian marine animal by 2006. This project will significantly advance our understanding of the origins of animals and contribute to the reconstruction of creatures that lived over 600 million ....Origin of multicellularity in animals: identification and analysis of intercellular signalling pathways in a basal metazoan, the demosponge Reniera. The Reniera genome project is a multi-million dollar collaboration between JGI (US-DOE) and Australian scientists that will see the sequencing of the first Australian marine animal by 2006. This project will significantly advance our understanding of the origins of animals and contribute to the reconstruction of creatures that lived over 600 million years ago. A major outcome of this reconstruction will be a fundamental understanding of how cells communicate with each other during the process of development to give rise to the diversity of cell types within multicellular animals. This study will also shed light on what happens when cell communication goes astray, as observed in a range of human malignancies, including cancer. Read moreRead less
Co-ordinated Action of ATM and DNA-PK in DNA damage recognition. The aim of this project is to investigate the mechanism of repair of double straind breaks in DNA sustained after radiation damage. Specifically we will focus on two proteins ATM (mutated in the genetic disorder ataxia-telangiectasia) and DNA-PK mutated in scid mice. There two proteins recognize double straind breaks in DNA and signal this damage to the DNA repair machinery of the cell and to cell cycle checkpoints. The emphasis ....Co-ordinated Action of ATM and DNA-PK in DNA damage recognition. The aim of this project is to investigate the mechanism of repair of double straind breaks in DNA sustained after radiation damage. Specifically we will focus on two proteins ATM (mutated in the genetic disorder ataxia-telangiectasia) and DNA-PK mutated in scid mice. There two proteins recognize double straind breaks in DNA and signal this damage to the DNA repair machinery of the cell and to cell cycle checkpoints. The emphasis here will be in the relationship between the two proteins in co-ordinating the repair of breaks in DNA. This information will be important in understanding mechanisms for maintaining the integrity of the genome.Read moreRead less
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