The aim of this proposal is to evaluate a novel therapy option for children with a genetic disorder called mucopolysaccharidosis (MPS). MPS arise from the build up of complex carbohydrates in cells within the body due to the deficiency of an enzyme required for their degradation. By decreasing the synthesis of carbohydrate we can manipulate the level of stored carbohydrate and alleviate the pathology associated with MPS. The novel therapy is based on a chemical modification of glucose that inhib ....The aim of this proposal is to evaluate a novel therapy option for children with a genetic disorder called mucopolysaccharidosis (MPS). MPS arise from the build up of complex carbohydrates in cells within the body due to the deficiency of an enzyme required for their degradation. By decreasing the synthesis of carbohydrate we can manipulate the level of stored carbohydrate and alleviate the pathology associated with MPS. The novel therapy is based on a chemical modification of glucose that inhibits carbohydrate synthesis and is termed substrate deprivation therapy.Read moreRead less
Molecular Genetics Of Dyslexia: A Component Processes Approach
Funder
National Health and Medical Research Council
Funding Amount
$348,960.00
Summary
With the advent of the human genome project, Australian researchers into serious childhood reading disorders are now in a position to make breakthroughs in understanding the complex linkages between genes and dyslexia. It is widely acknowledged that previous studies on the genetics of dyslexia have been limited by their failure to distinguish the different component processes in reading and the different patterns of dyslexia that they produce, and by being unable to look widely across the human ....With the advent of the human genome project, Australian researchers into serious childhood reading disorders are now in a position to make breakthroughs in understanding the complex linkages between genes and dyslexia. It is widely acknowledged that previous studies on the genetics of dyslexia have been limited by their failure to distinguish the different component processes in reading and the different patterns of dyslexia that they produce, and by being unable to look widely across the human genome. This new research addresses these two problems. Firstly, the researchers have developed a computational model of reading that identifies around a dozen basic mental processes which are recruited during skilled reading. This model provides the extremely precise phenotypes required for genetic research. Secondly, the researchers will take advantage of both very high density scans within known regions of interest on chromosomes 2,6, and 15, as well as a genome-wide scan of 400 markers small elements of DNA whose position within the genome is known, thus allowing researchers to narrow-down the location of new genes for reading. The research thus promises not only to refine our understanding of the basis for three previous genetic markers of dyslexia, but also to potentially uncover new genes related to specific elements of reading across the genome. The project pools the resources of the Macquarie Centre for Cognitive Science, the Australian Genome Research Facility, and The Garvan Institute and the researchers hope that the work will lead eventually to identifying the genes for dyslexia and to improved diagnosis and treatment of reading disorders in Australia.Read moreRead less
Skeletal disease is a major problem for children with mucopolysaccharidoses (MPS). Patients suffer from early onset osteoporosis and osteoarthritis, severely affecting their quality of life. We will evaluate a lentiviral gene therapy vector developed in-house for its capacity to transduce bone, cartilage, synovial and ligament cells in a mouse model of MPS VI. Our goal is to generate high level, sustained expression of the deficient MPS enzyme and alter the course of skeletal disease in MPS.
Evaluation And Comparison Of Lentiviral And AAV Vector Mediated Gene Therapy For The Mucopolysaccharidoses
Funder
National Health and Medical Research Council
Funding Amount
$521,320.00
Summary
The mucopolysaccharidoses are a group of inherited diseases that have profound consequences for affected individuals. They have pleiotropic effects and usually result in premature death. Although intravenous enzyme replacement therapy has been developed for a number of these disorders, this approach to therapy is invasive, very expensive, of limited efficacy, and is completely ineffective in treating brain pathology. The principal reason for this is the protected nature of the brain which preven ....The mucopolysaccharidoses are a group of inherited diseases that have profound consequences for affected individuals. They have pleiotropic effects and usually result in premature death. Although intravenous enzyme replacement therapy has been developed for a number of these disorders, this approach to therapy is invasive, very expensive, of limited efficacy, and is completely ineffective in treating brain pathology. The principal reason for this is the protected nature of the brain which prevents enzymes that are administered intravenously from entering. Therefore, alternative therapies must be considered in order to provide more effective therapy for the mucopolysaccharidoses, especially those that have significant brain pathology. Gene therapy is one such alternative therapy but this still faces the problem of introducing the therapeutic agent (in this case the gene encoding the requisite enzyme) into the brain. This project aims to provide a comparitive evaluation of two gene therapy vectors for their efficacy in treating all aspects of the pathology found in the mucopolysaccharidoses. Both vectors have the properties of being able to efficiently deliver genes to different cell types and result in the stable genetic modification of the target cell, making them ideal for long-term treatment. However, for effective gene therapy, significant and widely distributed gene delivery to the brain, as well as to other tissues, will be required. This project aims to compare the efficacy of these vectors in two different animal models of the mucopolysaccharidoses that exhibit a wide range of the clinical problems associated with these diseases, importantly including brain pathology.Read moreRead less
Understanding The Role That Cellular Hypoxia Plays In Normal Heart Development
Funder
National Health and Medical Research Council
Funding Amount
$522,773.00
Summary
Congenital heart defects (CHD) are the most common type of birth defects, being present in 6 out of every 1000 live births, and 10% of stillbirths. In addition to the danger of death during childhood, such heart defects also increase the risk of heart disease during adulthood. Our research project involves looking for the genetic causes of CHD. We are looking at two genes , called HIF1a and CITED2, for which we already have evidence that they are very important in allowing the heart to form norm ....Congenital heart defects (CHD) are the most common type of birth defects, being present in 6 out of every 1000 live births, and 10% of stillbirths. In addition to the danger of death during childhood, such heart defects also increase the risk of heart disease during adulthood. Our research project involves looking for the genetic causes of CHD. We are looking at two genes , called HIF1a and CITED2, for which we already have evidence that they are very important in allowing the heart to form normally within the embryo. Because the heart is the first organ to form in the embryo (during the first trimester), we cannot use humans to study this process. Instead we have two lines of mice which specifically lack either the HIF1a or CITED2 genes throughout the embryo. Both of these mouse lines have severe heart defects similar to some types of CHD seen in humans. However, removal of either of these genes also causes severe defects in other tissues, complicating our study. To overcome this problem, we will use a slightly different technique to remove either gene specifically in the entire developing heart of the embryo, while leaving the normal gene in the rest of the embryo. Thus we will be able for the first time to study the effects of these genes on the heart alone. We suspect that the defects in the hearts of such embryos will be of a particular sub-type of CHD. If this is true, in the future we hope to be able show that mutation of either of these genes will cause a specific type of human CHD. This will enable genetic screening of families with a history of CHD, assist in genetic counselling, and promote the development of therapies.Read moreRead less
The Unfolded Protein Stress Response In Inherited Skeletal Disease: Mechanism And Therapeutic Strategies
Funder
National Health and Medical Research Council
Funding Amount
$549,092.00
Summary
In genetic diseases, gene mutations commonly cause proteins to fold abnormally. This can cause cell stress resulting in cell death. Our studies will determine the role of cell stress in a clinically important group of skeletal diseases caused by collagen mutations. We will also test how we can use small chemicals to alleviate the damage done to the cells by the misfolded proteins, in the hope that this approach will provide new therapeutic strategies for these disorders.
Bipolar affective disorder (BP), or manic-depressive illness, is a major cause of disability and mortality worldwide. It has a lifetime prevalence of about 1% and suicide risk of about 20%. The disorder is characterised by episodes of mania or hypomania and depression, appearing in varying succession, with or without intermission. Twin, family, and adoptive studies point to a strong genetic component leading to the development of bipolar disorder, with a heritability of the order of 80%. Yet the ....Bipolar affective disorder (BP), or manic-depressive illness, is a major cause of disability and mortality worldwide. It has a lifetime prevalence of about 1% and suicide risk of about 20%. The disorder is characterised by episodes of mania or hypomania and depression, appearing in varying succession, with or without intermission. Twin, family, and adoptive studies point to a strong genetic component leading to the development of bipolar disorder, with a heritability of the order of 80%. Yet the identification of the genetic basis of the disease has proved exceedingly difficult, with numerous studies producing no definitive data. The lack of convincing results has been interpreted as an indication of complex genetic mechanisms and underlying differences between affected families and ethnic groups. Genetically isolated populations, where most individuals descend from a small number of founders, are believed to hold great potential for understanding the genetic basis of complex diseases, such as bipolar disorder. Affected subjects in such populations are likely to share the same predisposing genes, making these genes easier to identify. During the last 10 years, we have been involved in the study of bipolar disorder in one such population, with very promising results. In this project, we propose to take the research further by collecting more affected families, confirming the current positive findings and narrowing down the search to a small region, possibly a single gene. If successful, the study will be a major breakthrough which, by identifying a molecular pathway and disease mechanism, will contribute valuable and generally valid information on the biological basis of mood disorders.Read moreRead less