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
Cellular genomic approach to the pathogenesis of multiple sclerosis. This project compares the levels of gene usage in two important immune cell types between patients with multiple sclerosis and people who do not have the disease. It aims to identify the molecular basis for the disease, in order to identify new diagnostic, preventative and treatment options.
Development of the PD GeneChip: a research and diagnostic tool for Parkinson's disease. The PD GeneChip will provide both social and economic benefits to Australia. It will be a key research platform for Australian scientists, and will facilitate collaboration both within Australia and overseas. It will assist with health care management of PD (Parkinson's disease) patients by providing a cost-effective diagnostic tool and the possibility of predicting the clinical course of disease. This inform ....Development of the PD GeneChip: a research and diagnostic tool for Parkinson's disease. The PD GeneChip will provide both social and economic benefits to Australia. It will be a key research platform for Australian scientists, and will facilitate collaboration both within Australia and overseas. It will assist with health care management of PD (Parkinson's disease) patients by providing a cost-effective diagnostic tool and the possibility of predicting the clinical course of disease. This information will provide the basis for tailoring treatment to a patients needs. It is anticipated that marketing of the PD GeneChip within Australia and overseas may produce revenue of at least $40 million annually.Read moreRead less
Gene therapy to enhance auditory prosthesis performance for cochlear implants. The cochlear implant is the most effective neural prosthesis, restoring hearing to the deaf. The research aims to develop a new type of implant compatible with delivery of therapeutic genes to the cells lining the cochlea. Gene therapy DNA constructs will be developed that will enhance neural survival and growth, improving cochlear implant performance. The research will provide advances in understanding how to tran ....Gene therapy to enhance auditory prosthesis performance for cochlear implants. The cochlear implant is the most effective neural prosthesis, restoring hearing to the deaf. The research aims to develop a new type of implant compatible with delivery of therapeutic genes to the cells lining the cochlea. Gene therapy DNA constructs will be developed that will enhance neural survival and growth, improving cochlear implant performance. The research will provide advances in understanding how to transfer genes into cochlear tissue, as well as development of gene cassettes for effective neural repair. The work will advance the field of bionics, an area where Australia is establishing international preeminence.Read moreRead less
Generating a targeted mutation resource in zebrafish. How do genes function to build organisms and how are they regulated to produce organs and tissues? Using a new technique to target specific genes in the genome of zebrafish, this project will determine how genes control formation of different tissues. The new gene "knockout" technology will fundamentally change our understanding of how genes work during development.
Improving the efficiency of CRISPR gene editing in cells. Human red blood cells are well-characterised and the globin gene locus is a model system for the study of gene regulation. Gene editing technologies and delivery tools are evolving rapidly and the globin gene locus is the perfect model for gene editing optimisation. This collaboration between UNSW Sydney and CSL aims to bring together our combined expertise and new technologies to develop an optimal platform for genetic modification in a ....Improving the efficiency of CRISPR gene editing in cells. Human red blood cells are well-characterised and the globin gene locus is a model system for the study of gene regulation. Gene editing technologies and delivery tools are evolving rapidly and the globin gene locus is the perfect model for gene editing optimisation. This collaboration between UNSW Sydney and CSL aims to bring together our combined expertise and new technologies to develop an optimal platform for genetic modification in a red blood cell line. Simultaneously, this project aims to generate fundamental insights into mechanisms of human gene regulation. The technological and biological outcomes of this project will be of benefit for future gene editing applications.Read moreRead less
Mammalian chitinases and gene therapy: new weapons to combat fungal and insect attack in mammals. Plants combat fungal and insect attack by producing chitin degrading enzymes. Related, chitinolytic enzymes have been identified in mammals, but their functions are unclear. We found that chitinases from human macrophages inhibited fungal growth. We hypothesise that, like plants, mammalian chitinases are produced to fight chitin containing pathogens. We will transform cells with a chitotriosidase ge ....Mammalian chitinases and gene therapy: new weapons to combat fungal and insect attack in mammals. Plants combat fungal and insect attack by producing chitin degrading enzymes. Related, chitinolytic enzymes have been identified in mammals, but their functions are unclear. We found that chitinases from human macrophages inhibited fungal growth. We hypothesise that, like plants, mammalian chitinases are produced to fight chitin containing pathogens. We will transform cells with a chitotriosidase gene and encapsulate them, creating bioreactors secreting chitinases. Therapeutic effects will be tested by grafting bioreactors to mice inoculated with Aspergillus. The research is a new approach to fighting chitin containing pathogens, with potential applications from parasite infestations in livestock to fungal infections in humans.Read moreRead less
Development of a gene delivery system to access neuronal cells. Understanding the pathways for gene delivery and efficient expression will result in new knowledge in the areas of biotechnology and cell biology. This project will result in significant new information on vesicular trafficking pathways in neurons. An effective gene delivery system will realise significant commercial potential for our partner organisations and economic benefit to other Australian industry. This project aligns direct ....Development of a gene delivery system to access neuronal cells. Understanding the pathways for gene delivery and efficient expression will result in new knowledge in the areas of biotechnology and cell biology. This project will result in significant new information on vesicular trafficking pathways in neurons. An effective gene delivery system will realise significant commercial potential for our partner organisations and economic benefit to other Australian industry. This project aligns directly with the National Research Priority of "Promoting and maintaining good health" with a specific benefit for patients that suffer mental and physical degeneration and for their families.Read moreRead less
Developing technologies that support the genetic modification of rats. Rats and the mouse play critical roles in medical research. Until recently, the targeted genetic modification of a mammal was limited to the mouse. This was due to a technology that was unique to the mouse: embryonic stem (ES) cells. These cells have not been isolated from any other species. The recent development of animal cloning allows for an alternate strategy for targeting genes. We propose to develop cloning strate ....Developing technologies that support the genetic modification of rats. Rats and the mouse play critical roles in medical research. Until recently, the targeted genetic modification of a mammal was limited to the mouse. This was due to a technology that was unique to the mouse: embryonic stem (ES) cells. These cells have not been isolated from any other species. The recent development of animal cloning allows for an alternate strategy for targeting genes. We propose to develop cloning strategies in the rat that supports the genetic modification of this animal. The development of this technology will bring considerable benefits to the areas of physiological research and drug design.Read moreRead less
DNA methylation-based diagnosis of cancer and identification of novel therapeutic targets. In our aging society, cancer represents a severe economic and quality-of-life threat. DNA methylation switches genes off, and recently, it was shown that defects in DNA methylation contribute to human diseases including cancer. This project will identify defects in DNA methylation associated with cancer. Identifying these defects will enable us to design non-invasive, early diagnostic tests for cancer on b ....DNA methylation-based diagnosis of cancer and identification of novel therapeutic targets. In our aging society, cancer represents a severe economic and quality-of-life threat. DNA methylation switches genes off, and recently, it was shown that defects in DNA methylation contribute to human diseases including cancer. This project will identify defects in DNA methylation associated with cancer. Identifying these defects will enable us to design non-invasive, early diagnostic tests for cancer on blood or bodily excretions, and to pursue novel therapeutic approaches for treating cancer. The expected outcomes would generate exports to markets in the USA and Europe and replace imports of drugs and technology to treat cancer.Read moreRead less