Constructing an embryo. This project investigates the cellular and molecular mechanisms underlying temporal and spatial organisation in the eutherian preimplantation embryo. It will examine: the relative roles of cell cycle and circadian clocks in developmental timing; the molecular mechanism by which intercellular adhesion patterns influence spatial organisation; the extent to which marsupials use similar timing and spatial localisation mechanisms to eutherians; the impact of in-vitro manipulat ....Constructing an embryo. This project investigates the cellular and molecular mechanisms underlying temporal and spatial organisation in the eutherian preimplantation embryo. It will examine: the relative roles of cell cycle and circadian clocks in developmental timing; the molecular mechanism by which intercellular adhesion patterns influence spatial organisation; the extent to which marsupials use similar timing and spatial localisation mechanisms to eutherians; the impact of in-vitro manipulations over the first 5 days of mouse pregnancy on embryonic temporal and spatial organisation.Read moreRead less
Rapid functional analysis of genes involved in skeletal development. Abnormalities of the skeleton are of enormous clinical significance in terms of both number of individuals affected and the cost of treatment. Data derived from this project will underpin targeted research on the mechanisms of inherited and common diseases of cartilage and bone, yielding novel diagnostic and therapeutic targets. In addition, the improved knowledge of cartilage and bone cell development will inform new approache ....Rapid functional analysis of genes involved in skeletal development. Abnormalities of the skeleton are of enormous clinical significance in terms of both number of individuals affected and the cost of treatment. Data derived from this project will underpin targeted research on the mechanisms of inherited and common diseases of cartilage and bone, yielding novel diagnostic and therapeutic targets. In addition, the improved knowledge of cartilage and bone cell development will inform new approaches for developing stem cell therapies and the production of novel biomaterials for the repair of bones and joints. The outcomes of this study will therefore benefit the full spectrum of society from infants to the aged.Read moreRead less
Identification and characterisation of caspase inhibitors. Organisms use a tightly controlled process of cell death (termed apoptosis) to remove dangerous and unwanted cells. Dysregulation of this process can contribute to diseases such as cancer and autoimmune disease. Caspases are protease effectors of apoptosis. Regulation of their activity is vital for effective control of cell survival and death. Using a functional screening system invented by the 1st CI, we aim to isolate and characterise ....Identification and characterisation of caspase inhibitors. Organisms use a tightly controlled process of cell death (termed apoptosis) to remove dangerous and unwanted cells. Dysregulation of this process can contribute to diseases such as cancer and autoimmune disease. Caspases are protease effectors of apoptosis. Regulation of their activity is vital for effective control of cell survival and death. Using a functional screening system invented by the 1st CI, we aim to isolate and characterise novel inhibitors of caspases. Such inhibitors may in time be used as targets for development of therapeutic or diagnostic reagents aimed at manipulating the apoptotic process to diagnose, prevent or treat disease.Read moreRead less
Awaking quiescent neural stem cells. This project aims to generate new knowledge in the area of the evolutionary size of animals and plants, which is determined by intrinsic cell regulation and is constrained by nutrient availability. Brain size is perhaps the most profound example of this. Brain size regulation is underpinned by control of proliferation of neural stem cells (NSCs). Using Drosophila NSCs, the project will examine how nutrients impact on NSC quiescence versus activation, a key ch ....Awaking quiescent neural stem cells. This project aims to generate new knowledge in the area of the evolutionary size of animals and plants, which is determined by intrinsic cell regulation and is constrained by nutrient availability. Brain size is perhaps the most profound example of this. Brain size regulation is underpinned by control of proliferation of neural stem cells (NSCs). Using Drosophila NSCs, the project will examine how nutrients impact on NSC quiescence versus activation, a key characteristic of stem cell control throughout evolution. This will increase our understanding of how energy metabolism and nutrition influence organ size control in multicellular organisms, by determining how organs communicate with each other to convert nutrient signals to action stem cell proliferation.Read moreRead less
Gene Discovery and Functional Analysis of Copper Homeostasis Genes in Drosophila. Copper is a vital nutrient required for the formation and maintenance of bones, blood vessels and the central nervous system, but copper is also potentially toxic when in excess. Homeostatic mechanisms are needed to maintain safe levels of copper in the body and disruptions to these mechanisms are associated with disorders such as Alzheimer's disease, heart disease and osteoporosis. We are investigating the regulat ....Gene Discovery and Functional Analysis of Copper Homeostasis Genes in Drosophila. Copper is a vital nutrient required for the formation and maintenance of bones, blood vessels and the central nervous system, but copper is also potentially toxic when in excess. Homeostatic mechanisms are needed to maintain safe levels of copper in the body and disruptions to these mechanisms are associated with disorders such as Alzheimer's disease, heart disease and osteoporosis. We are investigating the regulation of a key copper pump, the Menkes protein, which helps control copper levels in the body and we are using the genetic advantages of the fruit fly Drosophila to discover new genes that regulate Menkes activity and therefore copper levels. These studies could lead to novel therapies for a range of copper-related disorders.Read moreRead less
Regulation of DNA replication initiation during Drosophila development. This proposal addresses the fundamental issue of the regulation of DNA
replication during development, using the animal model system, Drosophila melanogaster. This research uses a whole animal genetic and cell biological approach to explore DNA replication regulatory mechanisms that are present in multicellular organisms but not in yeast. The work undertaken here will make a significant contribution to our understanding of ....Regulation of DNA replication initiation during Drosophila development. This proposal addresses the fundamental issue of the regulation of DNA
replication during development, using the animal model system, Drosophila melanogaster. This research uses a whole animal genetic and cell biological approach to explore DNA replication regulatory mechanisms that are present in multicellular organisms but not in yeast. The work undertaken here will make a significant contribution to our understanding of DNA replication regulation within a developing organism that will be relevant to all animals.Read moreRead less
A novel DNA damage repair protein as a regulator of DNA double strand break repair and genome integrity. This project aims to define the function of a novel DNA damage repair protein. These data will provide a better understanding of DNA repair biology and may reveal novel diagnostic and treatment options for many diseases associated with DNA repair defects, including cancer.
Unveiling and characterisation of a fundamental pathway important in cell division. This work will have a major impact by producing top quality research that addresses a fundamental biological question of relevance to all organisms. The research will advance understanding of genetic factors important in foetal and early childhood development and proliferative disorders that occur during ageing. This work will provide intellectual and practical training to Honours and PhD students and postdoctora ....Unveiling and characterisation of a fundamental pathway important in cell division. This work will have a major impact by producing top quality research that addresses a fundamental biological question of relevance to all organisms. The research will advance understanding of genetic factors important in foetal and early childhood development and proliferative disorders that occur during ageing. This work will provide intellectual and practical training to Honours and PhD students and postdoctoral researchers in the disciplines of Molecular Genetics, Molecular & Cellular Biology, Developmental Cell Biology, Mass Spectrometry and Proteomics, which will be of immense benefit to their scientific careers and the Australian scientific community.Read moreRead less
Role of Musashi in the regulation of cell cycle proteins. We have identified a protein family that directs cell fate and maintains male fertility. This project will provide new avenues for generation of contraceptives in male animals and to regulate stem cells for production of specialised cell types in biotechnological applications.
Understanding self-organising tissues. This project will discover how an organ can form from a mixture of component cells by 'self-organisation'. Understanding of how this can occur, could potentially be applied to the bioengineering of organs from component cells.