Most eye diseases have a genetic contribution, whether rare disorders affecting children such as retinoblastoma or congenital cataracts through to common disorders of older people such as myopia, age-related macular degeneration or glaucoma. We will continue our successful research to find genes that cause these diseases and use this to improve patient care and prevent blindness. We will work out how families can use this genetic information to participate in trials to develop new treatments.
Use of Gradipore technology to develop novel methods for the preparation and segregation of mammalian spermatozoa. The purpose of this project is to harness the expertise available within an Australian biotechnology company, Gradipore, to develop novel methods for the preparation of mammalian spermatozoa and the segregation of these cells into X-and Y- bearing populations. This technology will find application in: (1)clinical andrology, where rapid, safe protocols for the preparation and segrega ....Use of Gradipore technology to develop novel methods for the preparation and segregation of mammalian spermatozoa. The purpose of this project is to harness the expertise available within an Australian biotechnology company, Gradipore, to develop novel methods for the preparation of mammalian spermatozoa and the segregation of these cells into X-and Y- bearing populations. This technology will find application in: (1)clinical andrology, where rapid, safe protocols for the preparation and segregation of human spermatozoa are being actively sought in the context of assisted conception and the management of sex-linked genetic diseases and (2) agriculture, particularly the cattle industry, where a capacity to predetermine the sex of the offspring would be extremely valuable.Read moreRead less
Linking mutant zebrafish phenotypes with their underlying genetic lesions. Zebrafish mutants have been generated with many interesting abnormalities, but to understand these abnormalities, the defective genes must be identified by positional cloning. We seek to identify the defective genes underpinning four mutants. Mutant #562 develops a normal nervous system which then undergoes rapid degeneration. The mutant flotte lotte has abnormal gut development. Two mutants with defective early blood for ....Linking mutant zebrafish phenotypes with their underlying genetic lesions. Zebrafish mutants have been generated with many interesting abnormalities, but to understand these abnormalities, the defective genes must be identified by positional cloning. We seek to identify the defective genes underpinning four mutants. Mutant #562 develops a normal nervous system which then undergoes rapid degeneration. The mutant flotte lotte has abnormal gut development. Two mutants with defective early blood formation will be studied. We will establish techniques for several steps that will be useful for all zebrafish mapping projects. We expect the genetic characterization of these mutants to provide new insights into nerve cell survival, gut development, and blood formation.Read moreRead less
Molecular control of embryonic patterning: The function of Rhou gene in mediating response to WNT signalling. The scientific knowledge gained from this investigation of the early development of embryos will inform us of how the essential building blocks of the body are assembled, and provide insights into the genetic and developmental causes of birth defects. This will benefit the health professionals, the research community, the education sector and the general public, by underpinning the form ....Molecular control of embryonic patterning: The function of Rhou gene in mediating response to WNT signalling. The scientific knowledge gained from this investigation of the early development of embryos will inform us of how the essential building blocks of the body are assembled, and provide insights into the genetic and developmental causes of birth defects. This will benefit the health professionals, the research community, the education sector and the general public, by underpinning the formulation of new research hypotheses, enriching the curriculum and the provision of informed counselling. The embryological expertise developed for this project will enhance the nation's research capability through the sharing of skills and knowledge with a national network of academic and industrial research teams. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347245
Funder
Australian Research Council
Funding Amount
$630,000.00
Summary
Functional Genomics Analysis - linking a multicentred facility. The aim of this project is to enhance and network the functions and activities of the Clive and Vera Ramaciotti Centre for Gene Function Analysis (CGRCGFA), a joint venture that services five major universities in the Sydney-Newcastle area. This application is for equipment that will improve the speed of DNA analyses, and for a laboratory information management system that will standardise the handling of data and sample information ....Functional Genomics Analysis - linking a multicentred facility. The aim of this project is to enhance and network the functions and activities of the Clive and Vera Ramaciotti Centre for Gene Function Analysis (CGRCGFA), a joint venture that services five major universities in the Sydney-Newcastle area. This application is for equipment that will improve the speed of DNA analyses, and for a laboratory information management system that will standardise the handling of data and sample information at all nodes of the CVRCGFA.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0232455
Funder
Australian Research Council
Funding Amount
$545,000.00
Summary
The Molecular Analysis of Variation and Gene Function. The aim of this project is to establish the nodes of the Clive and Vera Ramaciotti Centre for Gene Function Analysis (CVRCGFA) which is a joint venture that serves the five major universities and three Institutes in the Sydney-Newcastle region. The primary focus of this application is to create new facilities at the hubs of CVRCFGA that are integral to the analysis of molecular variation in a range of organisms. The study of molecular vari ....The Molecular Analysis of Variation and Gene Function. The aim of this project is to establish the nodes of the Clive and Vera Ramaciotti Centre for Gene Function Analysis (CVRCGFA) which is a joint venture that serves the five major universities and three Institutes in the Sydney-Newcastle region. The primary focus of this application is to create new facilities at the hubs of CVRCFGA that are integral to the analysis of molecular variation in a range of organisms. The study of molecular variation will enable researchers to understand better how organisms interact with each other, how they respond to environmental stress and aid in the identification of complez traits.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453724
Funder
Australian Research Council
Funding Amount
$532,824.00
Summary
Functional Genomics - Linking Genomics and Proteomics. This application is to enhance the capacity of the Ramaciotti Centre for Gene Function Analaysis (RCFGA) and its Nodes to support research in Functional Genomics by expanding its ability to link genomic analysis (including transcriptomics) with proteomic and cell biological analysis. It will provide access to novel methods for analysing interactions of proteins with other molecules by enabling the manufacture of protein arrays as well as DN ....Functional Genomics - Linking Genomics and Proteomics. This application is to enhance the capacity of the Ramaciotti Centre for Gene Function Analaysis (RCFGA) and its Nodes to support research in Functional Genomics by expanding its ability to link genomic analysis (including transcriptomics) with proteomic and cell biological analysis. It will provide access to novel methods for analysing interactions of proteins with other molecules by enabling the manufacture of protein arrays as well as DNA microarrays and to analyse the data obtained from them. This is a vital component to maintain gene function analysis at the cutting edge of current technology.Read moreRead less
Mouse models for the identification of factors involved in muscle adaptation. The ability of muscle to adapt to meet functional demands is essential for mobility in normal daily life, in ageing well, in individuals with muscle diseases and nerve damage and in athletes. The ability of muscle to change its cellular composition is desirable for the livestock industry. Knowledge of how genes in muscle cells are regulated to adapt to demands has significant implications for public health and economic ....Mouse models for the identification of factors involved in muscle adaptation. The ability of muscle to adapt to meet functional demands is essential for mobility in normal daily life, in ageing well, in individuals with muscle diseases and nerve damage and in athletes. The ability of muscle to change its cellular composition is desirable for the livestock industry. Knowledge of how genes in muscle cells are regulated to adapt to demands has significant implications for public health and economic benefits. We have devised model systems that will allow us to identify the regulators of these genes in order to develop therapies to combat these changes in ageing and damaged muscle, to improve the quality of meat and optimise sport performance.Read moreRead less
Evaluating The Genetic Contribution To Rheumatic Heart Disease Pathogenesis In Australian Aboriginal And Torres Strait Islander Communities
Funder
National Health and Medical Research Council
Funding Amount
$1,782,074.00
Summary
Rheumatic heart disease is highly prevalent in Aboriginal people in Australia and leads to early cardiac disease. Despite decades of research, the underlying genetic mechanisms for why it occurs are not well understood. We are conducting a genetic study to better understand why some people are susceptible to RHD and others are not. The study will involve substantial Aboriginal leadership and consultation and will be a model for the conduct of genetic studies in Aboriginal populations.
Gene regulation by retroelement encoded natural antisense transcripts. Genetic information underpins all life on earth and is processed to make proteins, which determine the characteristics of an organism. However, only about 2% of our whole genome is made up of genes that encode proteins; the other 98% is non-coding and its function remains poorly understood. Aims and Significance: This proposal aims to utilise cutting edge genomic technologies to generate new knowledge about how the non-coding ....Gene regulation by retroelement encoded natural antisense transcripts. Genetic information underpins all life on earth and is processed to make proteins, which determine the characteristics of an organism. However, only about 2% of our whole genome is made up of genes that encode proteins; the other 98% is non-coding and its function remains poorly understood. Aims and Significance: This proposal aims to utilise cutting edge genomic technologies to generate new knowledge about how the non-coding genome regulates the expression of protein coding genes. Expected Outcomes and Benefits: This proposal will provide novel targets and methodology for gene modulation with broad applications from biology to environmental sciences.Read moreRead less