Investigation Into The Roles Of A Novel Vertebrate Gene, S52, In CNS Development And Pathogenesis
Funder
National Health and Medical Research Council
Funding Amount
$272,389.00
Summary
Developmentally regulated genes when mutated or deleted can cause a variety of diseases including neurological diseases in humans. It is therefore important to understand the fundamental molecular genetics of development. We have discovered a novel human gene, termed S52, and its equivalent gene in the mouse. The predicted protein derived from these genes would indicate that S52 protein may interact with other proteins, possibly nerve growth factors, in the body to regulate normal development an ....Developmentally regulated genes when mutated or deleted can cause a variety of diseases including neurological diseases in humans. It is therefore important to understand the fundamental molecular genetics of development. We have discovered a novel human gene, termed S52, and its equivalent gene in the mouse. The predicted protein derived from these genes would indicate that S52 protein may interact with other proteins, possibly nerve growth factors, in the body to regulate normal development and possibly facilitate the survival of nerve cells in embryos. Strikingly, the worm C. elegans, an evoluationary very distant animal, also has a very similar gene to human. The fact that the protein has been so conserved throughout evolution supports the idea that S52 function is important in development. S52 mRNA is expressed in the developing brain, particularly in a special group of cells called the floor plate. Floor plate is a tissue that has ability to organize the patterning and differentiation of cells within the developing brain. S52 is also expressed in motor neurons in early stages of development and later in a subset of dorsal spinal cord neurons. We have mapped S52 to the short arm of human chromosome 2 (2p15-22). This region of chromosome 2 is linked to several human genetic diseases with neurological defects. Based on our preliminary data, we think S52 is not only important for normal brain development but may be mutated in a human neurological disease called Spastic Paraplegia Type 4 (SPG4) which is characterized by a degeneration of nerve cells in the spinal cord. The aim of this project is to further our understanding of the function of this gene and investigate its role in disease. This knowledge will contribute to an overall increase in our understanding of the molecular basis of brain development and neurological disease in humans.Read moreRead less
The presenilin proteins are key components in the development of Alzheimer's disease. Mutations in these proteins can cause early Alzheimer's disease. We will continue our study of the biochemistry and cell biology of these proteins using tools and experimental models that we have already developed. This will provide important information on the mechanism of the disease process and give new leads in the treatment of the disease. The new technologies of genetic screening for presenilin mutations ....The presenilin proteins are key components in the development of Alzheimer's disease. Mutations in these proteins can cause early Alzheimer's disease. We will continue our study of the biochemistry and cell biology of these proteins using tools and experimental models that we have already developed. This will provide important information on the mechanism of the disease process and give new leads in the treatment of the disease. The new technologies of genetic screening for presenilin mutations will be developed and utilized as a National referral base.Read moreRead less
Antecedents Of Renal Disease In Aboriginal Children And Young Adults - 12 Year Follow-up
Funder
National Health and Medical Research Council
Funding Amount
$1,845,061.00
Summary
Aboriginal Australians have 2 to 10 times the rate of chronic kidney disease and premature death from cardiovascular disease compared with non-Aboriginal Australians. Our 6 year follow-up of Aboriginal children from diverse NSW areas has shown no increase in risk for these diseases when compared with non-Aboriginal children. The ARDAC Second Phase Study will follow the participants for another 6 years to determine whether these health disparities start to manifest in young Aboriginal adults.
Site-specific Integration Of Functional Genomic Loci: Applications In Gene Therapy
Funder
National Health and Medical Research Council
Funding Amount
$442,664.00
Summary
Gene therapy strategies have traditionally focused on the delivery of therapeutic genes by viral vectors. Mindful of the limitations and potential problems of viral gene delivery, non-specific viral integration and limited transgene expression, this investigation will explore the delivery and site-specific integration of large genomic fragments into human stem cells. It is anticipated this approach will avoid some of the problems associated with poor gene expression and insertional oncogenesis.
Genetic And Phenotype Studies Of Partial Epilepsy In Gypsies
Funder
National Health and Medical Research Council
Funding Amount
$646,136.00
Summary
Epilepsy is one of the most common serious neurological disorders, which affects more than 50 million people worldwide. Genetic research, with a major contribution from Australian researchers, has led to the discovery of many rare forms of the disease caused by mutations in single genes of large effect. However, the vast majority of cases worldwide belong to the so-called genetically complex forms, involving multiple interacting genes and environmental factors. The genetically complex epilepsies ....Epilepsy is one of the most common serious neurological disorders, which affects more than 50 million people worldwide. Genetic research, with a major contribution from Australian researchers, has led to the discovery of many rare forms of the disease caused by mutations in single genes of large effect. However, the vast majority of cases worldwide belong to the so-called genetically complex forms, involving multiple interacting genes and environmental factors. The genetically complex epilepsies have proved particularly difficult to understand and the numerous genetic studies conducted so far have failed to produce important and replicable results. It is becoming increasingly clear that enormous genetic heterogeneity, with many rare mutations occurring in different affected subjects, will be a major obstacle to understanding the molecular basis of complex epilepsies. In this context, genetically isolated populations, which stem from a small number of ancestors, can be particularly helpful and revealing, since their limited genetic diversity means that the number of genes involved in causing complex epilepsies may be smaller and shared between individuals and families. In this study, we will analyze affected families, as well as non-familial cases of epilepsy, from a genetically isolated population - the European Roma-Gypsies. We will determine the number of potential susceptibility genes involved in familial forms, the overlap and differences between families, as well as the contribution of the genes identified in families to the development of sporadic epilepsy.Read moreRead less