Deciphering genome function in animal development. The normal development of an embryo depends on complex and finely tuned gene regulatory mechanisms. In this Fellowship, I will use sophisticated new technologies to discover which of our 30,000 genes is important for embryonic development, reveal the roles of these genes, and identify the control mechanisms that can go awry to cause birth defects. Our research will suggest new ways to diagnose and deal with these conditions, and will be applicab ....Deciphering genome function in animal development. The normal development of an embryo depends on complex and finely tuned gene regulatory mechanisms. In this Fellowship, I will use sophisticated new technologies to discover which of our 30,000 genes is important for embryonic development, reveal the roles of these genes, and identify the control mechanisms that can go awry to cause birth defects. Our research will suggest new ways to diagnose and deal with these conditions, and will be applicable to stem cell technologies, tissue regeneration, cancer biology, conservation, pest management and livestock breeding, thus delivering significant economic and social benefits to Australia. Read moreRead less
The Role Of Crim1, A Novel TGFb Superfamily Modulator, In Early Vertebrate Patterning, Vascular And Renal Development.
Funder
National Health and Medical Research Council
Funding Amount
$501,300.00
Summary
The transforming growth factor (TGF) beta superfamily is a large group of secreted growth factors who play many different roles in normal development of tissues such as the brain, skeleton, heart, kidney, eyes, teeth and limbs. One of the groups within the superfamily, the bone morphogenetic proteins (BMPs), are being used in clinical trials to assist in regrowing bones after fracture. These molecules are also of interest for clinical reasons as growth factors within this family can also be dele ....The transforming growth factor (TGF) beta superfamily is a large group of secreted growth factors who play many different roles in normal development of tissues such as the brain, skeleton, heart, kidney, eyes, teeth and limbs. One of the groups within the superfamily, the bone morphogenetic proteins (BMPs), are being used in clinical trials to assist in regrowing bones after fracture. These molecules are also of interest for clinical reasons as growth factors within this family can also be deleterious, with their overexpression leading to conditions such as renal fibrosis and cataract. The activity of these growth factors is regulated by many other proteins, including protein antagonists which bind and inactivate them. It is therefore possible that by understanding these antagonists, we can find new ways of altering TGF beta superfamily activity. We have previously identified a novel protein, Crim1, which we have now shown can bind to TGF superfamily members and can reduce their secretion. We believe that Crim1 plays a role in the patterning of the central nervous system, the development of the blood vessels and the kidneys by regulating the TGFbeta superfamily. In this grant we will be investigating what the effect of disruption to Crim1 is on these organ systems and working out which members of the TGFbeta superfamily it is affecting to cause these effects. To do this, we will knock out the gene in zebrafish and characterise the defects found in a mouse line in which the gene has been disrupted. This may be important in developing new ways of activating or inactiviating these growth factors in a number of clinical conditions.Read moreRead less
A new paradigm of gene regulation - implications in embryogenesis and disease. The proposed analysis of a new paradigm of gene regulation will provide a new key to understanding genome function and inform some of the most compelling biological issues of our time such as stem cell biology, tissue and organ regeneration and genetic programming. The insights and technologies developed in this program will be widely applicable in biotechnological and pharmacogenomic research in Australia and worldwi ....A new paradigm of gene regulation - implications in embryogenesis and disease. The proposed analysis of a new paradigm of gene regulation will provide a new key to understanding genome function and inform some of the most compelling biological issues of our time such as stem cell biology, tissue and organ regeneration and genetic programming. The insights and technologies developed in this program will be widely applicable in biotechnological and pharmacogenomic research in Australia and worldwide, and assert Australia's leadership in this area of research.Read moreRead less
Genetic control of plant organ growth. Plants organs, such as leaves and petals, have a distinct size and shape reflecting differences in growth. Despite its importance, very little is known about the mechanisms that regulate growth. The objectives of this proposal are a) to test whether organ growth depends on cell-cell signalling and b) to identifying genes that regulate growth, and to characterize their molecular function.
Evolution of nervous system patterning processes: characterisation of homologs of key Drosophila regulatory genes from the coral Acropora. Defining the common mechanisms of nervous system development is one of the major goals of modern biology, but is presently being addressed largely by comparisons between a few very advanced (and therefore specialised) animals. Comparative data from a lower animal is urgently needed, and will clarify many aspects of nervous system evolution and development. Th ....Evolution of nervous system patterning processes: characterisation of homologs of key Drosophila regulatory genes from the coral Acropora. Defining the common mechanisms of nervous system development is one of the major goals of modern biology, but is presently being addressed largely by comparisons between a few very advanced (and therefore specialised) animals. Comparative data from a lower animal is urgently needed, and will clarify many aspects of nervous system evolution and development. The pioneering work carried out on Acropora in this laboratory suggests that it is perhaps the best choice currently available for this purpose. This project will use Acropora to address fundamental questions about the evolution of nervous system developmental processes.Read moreRead less
Body Segment Identity Specification By The Transcription Regulator, Moz
Funder
National Health and Medical Research Council
Funding Amount
$366,301.00
Summary
One in 28 newborns have birth defects. Cleft palate and aortic arch defects are among the most common, always requiring surgery and often causing lethality. We propose to study a protein, Moz, which is essential for palate and aortic arch development. Moz (Monocytic leukaemia zinc finger protein) was first identified in human chromosomal abnormalities causing particularly aggressive forms of childhood and adult leukaemia. We have shown previously that Moz is essential for the formation of blood ....One in 28 newborns have birth defects. Cleft palate and aortic arch defects are among the most common, always requiring surgery and often causing lethality. We propose to study a protein, Moz, which is essential for palate and aortic arch development. Moz (Monocytic leukaemia zinc finger protein) was first identified in human chromosomal abnormalities causing particularly aggressive forms of childhood and adult leukaemia. We have shown previously that Moz is essential for the formation of blood stem cells. Moz can regulate the activity of genes, but which genes it regulates in vivo is unknown. In the absence of Moz, mice are born with a cleft palate, lack the thymus, where immune cells are instructed, and fail to form the lung blood circulation, so that they are unable to supply their blood with oxygen after birth. Moz deficiency also causes defects of the vertebrate column, such that individual vertebrae acquire the appearance of their neighbours. These symptoms are typical for a general defect in positional information of individual body segments with respect to their location along the body axis. We will investigate the molecular mechanisms that require Moz in patterning of the body axis. This project will characterize a genetic mechanism that is crucial for normal development of the palate, the aorta and the vertebrate column.Read moreRead less
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
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
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