Identification Of Genes Important In Myeloid And Haemopoietic Development By Genetic Screening In Zebrafish
Funder
National Health and Medical Research Council
Funding Amount
$425,250.00
Summary
Zebrafish have emerged as a powerful experimental model in developmental genetics. Their favourable attributes include their reproductive biology, the optical clarity of embryos, and the accessibility of embryos for experimental procedures. Previous studies overseas have recovered over 1500 strains of zebrafish with inherited diseases due to induced mutations in about 500 genes. Many of these zebrafish have abnormalities of unexpected precision and are leading to new genes with novel specialized ....Zebrafish have emerged as a powerful experimental model in developmental genetics. Their favourable attributes include their reproductive biology, the optical clarity of embryos, and the accessibility of embryos for experimental procedures. Previous studies overseas have recovered over 1500 strains of zebrafish with inherited diseases due to induced mutations in about 500 genes. Many of these zebrafish have abnormalities of unexpected precision and are leading to new genes with novel specialized functions. About 50 mutant zebrafish strains exist in which red blood cell development is perturbed - this was easily recognized because the transparency of embryos enabled lack of blood be easily seen. Our new studies aim primarily to recover mutant zebrafish with disorders of white blood cell formation. We have identified methods to recognize failure of white blood cell formation in zebrafish, and will employ these methods to look for inherited disorders that specifically affect white blood cell development in a process called genetic screening. Fish with different sets of randomly mutated genes will be systematically screened to identify those with abnormal white blood cell development. We have tested our approach and identified several mutants affecting white blood cell development. Once these new strains of fish are identified, we will find the genetic lesion responsible for the abnormality in several of the most interesting strains by gene mapping and positional cloning. Hence, the mutant zebrafish identified in the screen will eventually lead to the discovery of new genes important in white blood cell growth and development. The fish themselves will provide insights into the causes of congenital diseases of white blood cells. Since many genes involved in early development are also important in cancer, we believe that newly identified genes will also help understand the causes of abnormal growth of white blood cells in leukaemia.Read moreRead less
An RNA interference based genetic screen for novel epigenetic modifiers involved in mammalian X inactivation. All the information required to form an adult human is contained in the DNA of the fertilized egg. Development is achieved by a complex orchestration of genes being switched on and off, controlled by proteins called epigenetic modifiers. Sometimes this goes awry, leading to disease. Despite their vital role, only around ten percent of the potential epigenetic modifiers have been characte ....An RNA interference based genetic screen for novel epigenetic modifiers involved in mammalian X inactivation. All the information required to form an adult human is contained in the DNA of the fertilized egg. Development is achieved by a complex orchestration of genes being switched on and off, controlled by proteins called epigenetic modifiers. Sometimes this goes awry, leading to disease. Despite their vital role, only around ten percent of the potential epigenetic modifiers have been characterized in humans, making it impossible to interpret how they work together, or when they fail. We will develop a novel screen-based technology to find hundreds more true epigenetic modifiers. This technology will aid us and other Australian scientists to understand the role of epigenetics in normal development and disease, ultimately leading to better public health.Read moreRead less
Socs proteins in development and disease. Socs proteins are a component of a pathway that is central to a range of developmental processes, including embryonic development. In addition, there is evidence that these proteins are perturbed in several disorders. This Project will enhance our understanding of the Socs proteins and their role in disease, and ultimately provide an opportunity to identify new therapeutic strategies.