Characterization Of The FHL Protein Family In Striated Muscle
Funder
National Health and Medical Research Council
Funding Amount
$500,750.00
Summary
This grant examines the role of a family of muscle proteins, called FHL proteins, in skeletal and heart muscle. Inherited muscular disorders such as muscular dystrophy and myopathies, cause muscle weakness, which may be profound and lead to premature death due to respiratory muscle failure, or cause mild weakness later in life. The proteins which are defective in these muscular dystrophies are structural muscle proteins, which link and stabilize the contractile fibres in muscle and protect the m ....This grant examines the role of a family of muscle proteins, called FHL proteins, in skeletal and heart muscle. Inherited muscular disorders such as muscular dystrophy and myopathies, cause muscle weakness, which may be profound and lead to premature death due to respiratory muscle failure, or cause mild weakness later in life. The proteins which are defective in these muscular dystrophies are structural muscle proteins, which link and stabilize the contractile fibres in muscle and protect the muscle from the stresses and damage resulting from repeated muscular contraction. We have identified that the FHL proteins, which are the focus of this grant application, bind to and potentially regulate muscle proteins, which have been shown to cause forms of muscular dystrophy and cardiomyopathy. Examination of these interactions will provide insights into the biological mechanism of these muscle disorders. Furthermore, one of these proteins, FHL1 is significantly increased in hypertrophic cardiomyopathy, heart muscle thickening, a major cause of sudden cardiac death in young adults. We are creating transgenic mice, which make increased levels of FHL1 protein in their heart muscle, to determine whether increased FHL1, by itself is sufficient to promote heart muscle thickening. These studies should lead to further understanding of the development of diseases of heart and skeletal muscle, which may lead to novel treatments in the future.Read moreRead less
The Interactions Of Dengue Virus RNA Dependent RNA Polymerase (NS5) With Other Viral And Host Factors.
Funder
National Health and Medical Research Council
Funding Amount
$170,165.00
Summary
Dengue fever is a mosquito-borne disease that is prevalent in tropical countries. It is estimated that 40% of the global population is at risk of dengue infection. Classical dengue fever is not life threatening. However, the more serious disease, dengue haemorrhagic fever-shock syndrome requires intensive medical attention to prevent fatality. A significant number of deaths are recorded each year especially in the underdeveloped countries. Dengue is periodically also a problem in northern Austra ....Dengue fever is a mosquito-borne disease that is prevalent in tropical countries. It is estimated that 40% of the global population is at risk of dengue infection. Classical dengue fever is not life threatening. However, the more serious disease, dengue haemorrhagic fever-shock syndrome requires intensive medical attention to prevent fatality. A significant number of deaths are recorded each year especially in the underdeveloped countries. Dengue is periodically also a problem in northern Australia. There is no cure for dengue fever. The present research aims to use a knowledge-based approach to develop novel antiviral strategies based on preventing the critical protein interactions required for the normal virus life cycle. Two of the most important proteins involved in dengue virus replication are called the NS3 and NS5 proteins. The protein-protein interaction (contact) that occurs between NS5 and NS3 is crucial for the replication of the virus. Little is known about this interaction at present, and the studies we propose will directly address this issue. We have previously shown that a 37 amino acid in the middle of NS5 contains a nuclear localisation signal that can target the normally cytoplasmic protein to the nucleus of the infected cell. What the function of this protein is in the nucleus is not known. We will use a technique called the yeast two-hybrid test to address the question of dengue virus protein interactions in the common bakers yeast. This method is very sensitive and powerful and will provide important insights that will contribute to the development of a rapid high-throughput test to screen the extensive extract collection from Australia's marine biodiversity, held by the Australian Institute of Marine Sciences, to discover suitable inhibitors of NS3-NS5 interaction.Read moreRead less