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This proposal uses the zebra fish system, which it is uniquely suited to investigate the regulation of disease genes. In all of these diseases preliminary work has already been performed and screening assays have been developed in a previous project (ZF-MODELS). In addition, the project will investigate genetic abnormalities of the eye and visual processing, genetic pathways underlying tissue regeneration and repair, and homologs of human genes related to diabetes and obesity, as well as infecti ....This proposal uses the zebra fish system, which it is uniquely suited to investigate the regulation of disease genes. In all of these diseases preliminary work has already been performed and screening assays have been developed in a previous project (ZF-MODELS). In addition, the project will investigate genetic abnormalities of the eye and visual processing, genetic pathways underlying tissue regeneration and repair, and homologs of human genes related to diabetes and obesity, as well as infectious disease and cancer. The Australian component will perform a systematic characterisation of enhancer elements of potential disease genes. This characterisation will build on the concept of genomic regulatory blocks (GRBs) which contain highly conserved non-coding elements (HCNEs) acting as long-range enhancers of developmental genes (recently discovered by T. Becker in the ZF-MODELS project).Read moreRead less
Use Of The Norfolk Island Genetic Isolate For Disease Gene Mapping
Funder
National Health and Medical Research Council
Funding Amount
$978,500.00
Summary
This gene mapping study will use a unique founder effect population to investigate two major public health disorders. We aim to identify genes that play a role in migraine and in cardiovascular disease, using a population from Norfolk Island. The Norfolk Island community is a population of ~1200 permanent residents, the majority of whom are direct descendents of 18th century English Bounty mutineers and Polynesian women. We will undertake a full genome scan to identify migraine gene loci and QTL ....This gene mapping study will use a unique founder effect population to investigate two major public health disorders. We aim to identify genes that play a role in migraine and in cardiovascular disease, using a population from Norfolk Island. The Norfolk Island community is a population of ~1200 permanent residents, the majority of whom are direct descendents of 18th century English Bounty mutineers and Polynesian women. We will undertake a full genome scan to identify migraine gene loci and QTL that influence cardiovascular disease using samples from this population isolate.Read moreRead less
Retroviral Expression Cloning Using An Arrayed Full Length CDNA Gene Set
Funder
National Health and Medical Research Council
Funding Amount
$1,841,500.00
Summary
The sequencing of the human genome has revealed the blueprint for life, but the identities and-or functions of the majority of genes remain unknown. Here we propose to establish a radically modified retroviral expression cloning system that will, in principle, allow identification of all genes that confer a particular dominant phenotype. To do this we will establish an arrayed retroviral library of sequence-verified genes covering the entire human transcriptome. This technology will be used to i ....The sequencing of the human genome has revealed the blueprint for life, but the identities and-or functions of the majority of genes remain unknown. Here we propose to establish a radically modified retroviral expression cloning system that will, in principle, allow identification of all genes that confer a particular dominant phenotype. To do this we will establish an arrayed retroviral library of sequence-verified genes covering the entire human transcriptome. This technology will be used to identify genes involved in a wide range of medically-important biological processes.Read moreRead less
Genetic And Evironmenal Risk Factors For Melanoma: Translation Into Behavioural Change
Funder
National Health and Medical Research Council
Funding Amount
$250,900.00
Summary
GenoMEL, formerly known as the Melanoma Genetics Consortium, has focused on the identification of familial high penetrance melanoma genes. The joint programme of research has been very successful in the identification of susceptibility genes and developing joint data collection for gene-environment interaction studies. In order to continue its proactive role, GenoMEL wishes to develop a multidisciplinary European platform, directed towards: 1. developing shared resources and activities 2. identi ....GenoMEL, formerly known as the Melanoma Genetics Consortium, has focused on the identification of familial high penetrance melanoma genes. The joint programme of research has been very successful in the identification of susceptibility genes and developing joint data collection for gene-environment interaction studies. In order to continue its proactive role, GenoMEL wishes to develop a multidisciplinary European platform, directed towards: 1. developing shared resources and activities 2. identification of new susceptibility genes and understanding the role of these genes in tumours 3. investigation of genotype-phenotype interaction and gene-environment interaction for known susceptibility genes 4. investigation of attitudes to risk of melanoma in Europe, and translation of that risk perception into behavioural change 5. spreading excellence by creating a widely accessible web-based content management system (CMS) to address prevention, early detection, dealing with the diagnosis of melanoma and genetic counselling. Through GenoMEL's jointly executed research, groups will support the network's goal to maintain excellence in research, increase institutional integration and create an enduring structure of translational melanoma genetics research in Europe and other countries. European integration will enhance dialogue, disseminate expertise and resources, provide training and allow mobility of scientists within Europe. It is aimed to keep the network open and dynamic by adding new partners, especially in Eastern Europe where melanoma incidence rates may rise most precipitously in the near future, if the expected increase in wealth results in greater levels of sun exposure. There will be participation from four new European groups and others from Australia, the USA and Israel to capitalize on latitudinal (sun exposure) differences between these groups.Read moreRead less
Identifying Long-range Regulatory Elements Of The Breast Cancer Susceptibility Gene, BRCA1
Funder
National Health and Medical Research Council
Funding Amount
$612,842.00
Summary
BRCA1 is a breast cancer susceptibility gene implicated in both familial and sporadic breast cancers. The mechanisms controlling BRCA1 expression are poorly understood. We will identify DNA sequences critical for regulation of the BRCA1 gene. We hypothesise that these regions are mutational hot spots conferring an increased breast cancer risk. A better understanding of the pathways responsible for promoting BRCA1-associated breast cancer will provide important diagnostic and treatment targets.
Regulatory architecture of the trunk-to-tail transition. This project aims to elucidate gene regulatory mechanisms that control how the head-to-tail axis is laid down during embryonic development. The project capitalises on unique pluripotent stem cell resources and cutting-edge genomic technology developed by the team. This project expects to generate new knowledge in the area of developmental biology and gene regulation that is anticipated to have wider application to the understanding of evol ....Regulatory architecture of the trunk-to-tail transition. This project aims to elucidate gene regulatory mechanisms that control how the head-to-tail axis is laid down during embryonic development. The project capitalises on unique pluripotent stem cell resources and cutting-edge genomic technology developed by the team. This project expects to generate new knowledge in the area of developmental biology and gene regulation that is anticipated to have wider application to the understanding of evolutionary mechanisms and ultimately regenerative medicine.Read moreRead less
Visualising genetic mosaicism during development. Genetic diversity is the variation in DNA sequence among individuals. We now know that there are also differences in the DNA sequences of cells within the same individual, known as genetic mosaicism. The aims of this proposal are 1) to develop a system to visualise genetic mosaicism 2) arising during embryonic development and 3) in the brain, driven by mobile DNA activity. The expected outcome of this proposal is an unprecedented understanding of ....Visualising genetic mosaicism during development. Genetic diversity is the variation in DNA sequence among individuals. We now know that there are also differences in the DNA sequences of cells within the same individual, known as genetic mosaicism. The aims of this proposal are 1) to develop a system to visualise genetic mosaicism 2) arising during embryonic development and 3) in the brain, driven by mobile DNA activity. The expected outcome of this proposal is an unprecedented understanding of the scope and consequences of mobile DNA-driven mosaicism. This work will have significant impacts in developmental genetics and neurogenetics, and has the benefit of introducing an innovative experimental system with the potential to spark international scientific collaboration and recognition.Read moreRead less
Early evolution of the endomesoderm gene regulatory network. This project aims to unravel the endomesoderm gene network’s evolutionary history by identifying its conserved components’ target genes in the calcareous sponge Sycon. Little is known about the evolutionary origin of the developmental gene regulatory networks active in the development of all Eumetazoans (animals with nerves and digestive systems). Sponges are key models to study the transition from protists to eumetazoans, and gene exp ....Early evolution of the endomesoderm gene regulatory network. This project aims to unravel the endomesoderm gene network’s evolutionary history by identifying its conserved components’ target genes in the calcareous sponge Sycon. Little is known about the evolutionary origin of the developmental gene regulatory networks active in the development of all Eumetazoans (animals with nerves and digestive systems). Sponges are key models to study the transition from protists to eumetazoans, and gene expression data supports homology between sponge and eumetazoan tissues and body plans. This project could illuminate the evolutionary history of the animal body plan.Read moreRead less
Genome-wide Combined Linkage-association Scan Of Multiply Phenotyped Twin Sibships
Funder
National Health and Medical Research Council
Funding Amount
$1,920,000.00
Summary
We have a large ongoing study of adolescent twins, their siblings and parents who are multiply phenotyped in many domains including melanoma risk factors, serum biochemistry, and cognition. We used our first Medical Genomics grant to obtain a 5cM linkage scan for>500 families and have identified linkage peaks for many different phenotypes. To fine map these it will be most efficient to carry out a genome-wide association scan. We request funds to type a 500k SNP chip on 1000 individuals.
Old genes learning new tricks: characterising regulatory changes driving increased heart complexity during vertebrate evolution. The heart has dramatically increased in morphological complexity during vertebrate evolution but the molecular basis driving these major changes remains unknown. Using comparative genomics approaches, this project will explore changes in the regulation of genes involved in heart formation that lead to changes in cardiac structure. It will elucidate for the first time t ....Old genes learning new tricks: characterising regulatory changes driving increased heart complexity during vertebrate evolution. The heart has dramatically increased in morphological complexity during vertebrate evolution but the molecular basis driving these major changes remains unknown. Using comparative genomics approaches, this project will explore changes in the regulation of genes involved in heart formation that lead to changes in cardiac structure. It will elucidate for the first time the cardiac regulatory repertoire in zebrafish and will compare it with that of fly and mouse using cutting-edge bioinformatics pipelines. This work will unravel cardiac-specific regulatory modifications that give rise to evolutionary changes. On a broader scale, it will shed new light on the role of regulatory innovations over gene innovations in the emergence of new traits.Read moreRead less