Treatment Of Lysosomal Storage Disorder Patients By Drug-enhanced Premature Stop Codon Read-through
Funder
National Health and Medical Research Council
Funding Amount
$431,764.00
Summary
Lysosomal storage disorders are a devastating set of genetic diseases with very severe clinical symptoms. In this project, we will investigate a new treatment strategy that is non-invasive and that will be applicable for a wide range of lysosomal storage disorder patients. The therapy will over-ride the molecular genetic lesion and will be preferentially targeted for patients who are at the severe end of the clinical spectrum, where treatment options are currently limited.
Targeted Corrective Gene Conversion (TCGC): Application In DMD Mutations And Delivery To Dystrophic (mdx) Muscle
Funder
National Health and Medical Research Council
Funding Amount
$496,500.00
Summary
The muscular dystrophies are inherited diseases that lead to muscle wastage and severe disabilities. The most severe forms result in the early death of newborns, but a large number are diagnosed in children showing early mild symptoms and progress steadily to severe disabling forms in the juvenile and young adult. Perhaps the most devastating of these dystrophies is Duchenne Muscular Dystrophy (DMD). This condition affects 1 in 3,300 boys, who show symptoms at around 5 years of age until wheelch ....The muscular dystrophies are inherited diseases that lead to muscle wastage and severe disabilities. The most severe forms result in the early death of newborns, but a large number are diagnosed in children showing early mild symptoms and progress steadily to severe disabling forms in the juvenile and young adult. Perhaps the most devastating of these dystrophies is Duchenne Muscular Dystrophy (DMD). This condition affects 1 in 3,300 boys, who show symptoms at around 5 years of age until wheelchair confinement by early teens. DMD boys undergo major clinical and surgical treatments which at present only provide small but significant improvements to their lives. The median age at death for Duchenne boys is 22 years. The cause of DMD has been known for almost 2 decades and is a defect in just a single component of muscle, Dystrophin which is produced by muscle cells. In general, boys with DMD possess Dystrophin which is missing an important part that prevents the breakdown of muscles during activity. As a consequence, all the muscles in DMD boys slowly break down over their lifetime until they die because the muscle which helps in drawing breath (Diaphragm) is no longer capable of helping them to breathe. The muscle component Dystrophin is produced by a gene (the dys gene) and the defect of Dystrophin is caused by a defect in the dys gene. If the dys gene defect was able to be corrected in boys with DMD, their Dystrophin may also be corrected and the breakdown of their muscle prevented. We have been able to correct the dys gene in muscle cells from a mouse with DMD. We wish to improve this technology and allow muscle to be corrected with genetically corrected fibres to form a basis for treatment of human DMD. In this way we hope to significantly improve and lengthen these boys' lives and even lead to a cure for DMD and other genetic muscle diseaseRead moreRead less
The Role Of Netrin-DCC In The Development Of The Corpus Callosum
Funder
National Health and Medical Research Council
Funding Amount
$512,065.00
Summary
During embryonic development neurons send out axons that connect to other target neurons within the brain. The proper connectivity of these axons is vital to brain function. The largest axon tract in the brain is called the corpus callosum and connects neurons in the left and right cerebral hemispheres. When the corpus callosum does not form, significant cognitive, motor and sensory deficits occur in patients. This condition, known as agenesis of the corpus callosum (ACC), is associated with ove ....During embryonic development neurons send out axons that connect to other target neurons within the brain. The proper connectivity of these axons is vital to brain function. The largest axon tract in the brain is called the corpus callosum and connects neurons in the left and right cerebral hemispheres. When the corpus callosum does not form, significant cognitive, motor and sensory deficits occur in patients. This condition, known as agenesis of the corpus callosum (ACC), is associated with over 50 different human congenital syndromes. Thus understanding how the genes and molecules involved in the formation of the corpus callosum function in normal development can provide the basis for our understanding of what goes wrong in ACC. In this proposal we will investigate the role of the axon guidance molecule Netrin1, and its receptor DCC, in development of the corpus callosum in both a mouse model and in humans with malformations of the corpus callosum. Although Netrin1-DCC signalling has traditionally been associated with mechanisms of axon guidance, we hypothesize that these molecules may play a different role, specifically in cellular adhesion and ultimately in the fusion of the two cerebral hemispheres, in a manner that allows the corpus callosum to form. A second role for Netrin1-DCC signalling may be in the guidance of these axons once the midline has fused correctly and we investigate this in Aim 2 of the proposal. Finally, we are collaborating with a paediatric neurologist at UCSF, who has identified several mutations in the DCC gene in patients with ACC. In Aim 3 we test whether these mutations disrupt the function of DCC in callosal axon pathfinding. Understanding how these genes function during development of the brain and how their function may be altered in ACC is crucial to providing a proper diagnosis and prognosis for these patients. Ultimately, understanding more about how these genes function could also lead to prevention of these disorders.Read moreRead less
Identification Of A Genetic Defect Characterized By Radiosensitivity And Defective P53 Stabilization
Funder
National Health and Medical Research Council
Funding Amount
$267,750.00
Summary
Radiation is an important therapeutic agent for the treatment of a variety of cancers. However, radiation also causes cancers, certainly at high doses but it remains unclear as to the threat from low dose radiation eg in the vicinity of radiation accidents and at high altitudes. A greater understanding of the threats of radiation exposure is possible from the study of a number of rare syndromes characterized by extreme sensitivity to radiation and predisposition to develop cancer. The identifica ....Radiation is an important therapeutic agent for the treatment of a variety of cancers. However, radiation also causes cancers, certainly at high doses but it remains unclear as to the threat from low dose radiation eg in the vicinity of radiation accidents and at high altitudes. A greater understanding of the threats of radiation exposure is possible from the study of a number of rare syndromes characterized by extreme sensitivity to radiation and predisposition to develop cancer. The identification of new syndromes with radiosensitivity assists in delineating the overall response to radiation and the connection with cancer. This project is designed to identify the molecular basis of what appears to be a novel defect. It has some of the characteristics of a well described syndrome ataxia-telangiectasia (A-T), namely signs of neurodegeneration and sensitivity to radiation but the protein defective in A-T appears to have normal function in this case. A comprehensive investigation of a number of pathways of radiation signaling is planned to identify the nature of the defect.Read moreRead less
Mechanism Of Activation Of ATM By DNA Double Strand Breaks And Other Stimuli
Funder
National Health and Medical Research Council
Funding Amount
$517,751.00
Summary
The human genetic disorder ataxia-telangiectasia is a rare human disease characterised by cancer predisposition and neuronal degeneration. The gene defective in this disorder, ATM, plays a central role in recognising damage to the genetic material and activates a number of different cellular pathways designed to maintain stability of genome and minimise the risk of cancer and other pathologies. In this project we are investigating how the protein is activated from a dormant state to phosphorylat ....The human genetic disorder ataxia-telangiectasia is a rare human disease characterised by cancer predisposition and neuronal degeneration. The gene defective in this disorder, ATM, plays a central role in recognising damage to the genetic material and activates a number of different cellular pathways designed to maintain stability of genome and minimise the risk of cancer and other pathologies. In this project we are investigating how the protein is activated from a dormant state to phosphorylate a series of substrates involved in cellular signaling. Information in this process is very significant since the genetic lesion that activates ATM is a double strand break in DNA which not only is a potentially lethal lesion to the cell but has also the capacity to destabilize the genetic material. Information on this mechanism will also be useful for the design of small molecules that might interfere with ATM activation and in this way make tumour cells more susceptible to radiotherapy.Read moreRead less
Functional Characterisation Of Pendrin: The Anion Transporter Causing Pendred Syndrome
Funder
National Health and Medical Research Council
Funding Amount
$211,527.00
Summary
Mutations in the human pendrin protein cause progressive hearing loss from an early age in Pendred syndrome. Using techniques of molecular and cellular biology, we intend to test the effects of Pendred-causing mutations on the function of pendrin expressed in frog and cultured mammalian cells. Our approach will enable us to determine how pendrin functions in both the normal and diseased states, which is currently unknown. This will allow us to consider ways of correcting the ion channel defect a ....Mutations in the human pendrin protein cause progressive hearing loss from an early age in Pendred syndrome. Using techniques of molecular and cellular biology, we intend to test the effects of Pendred-causing mutations on the function of pendrin expressed in frog and cultured mammalian cells. Our approach will enable us to determine how pendrin functions in both the normal and diseased states, which is currently unknown. This will allow us to consider ways of correcting the ion channel defect associated with the Pendred syndrome.Read moreRead less