Structural Studies Of The Jak And Abl Kinases: A Prerequisite For Drug Design
Funder
National Health and Medical Research Council
Funding Amount
$360,965.00
Summary
Protein tyrosine kinases (PTK) are a large, pivotal family of signalling molecules implicated in diseases such as cancer and immune related disorders. This fellowship aims to develop more potent kinase inhibitors of a number of PTKs using Cytopia’s drug discovery capability coupled with the X-ray crystallography expertise within Monash University. This innovative approach will permit a rational structure-based drug discovery platform to be established and will lead to the creation of a portfolio ....Protein tyrosine kinases (PTK) are a large, pivotal family of signalling molecules implicated in diseases such as cancer and immune related disorders. This fellowship aims to develop more potent kinase inhibitors of a number of PTKs using Cytopia’s drug discovery capability coupled with the X-ray crystallography expertise within Monash University. This innovative approach will permit a rational structure-based drug discovery platform to be established and will lead to the creation of a portfolio of phase I therapeutics, which will be of substantial benefit in the medical health area.Read moreRead less
C-Kit Signalling And Cellular Responses In Haemopoietic Cells
Funder
National Health and Medical Research Council
Funding Amount
$731,115.00
Summary
Growth factors acting on cell surface receptors activate multiple intracellular signalling pathways that regulate cellular growth and function. Mutations in the genes that code for these receptors or their downstream signalling pathways contribute to many human cancers. The contributions of different signalling pathways linked to these receptors to the various cellular responses (growth, maturation, functional activation) are not understood. In this project we aim to use cell and molecular biolo ....Growth factors acting on cell surface receptors activate multiple intracellular signalling pathways that regulate cellular growth and function. Mutations in the genes that code for these receptors or their downstream signalling pathways contribute to many human cancers. The contributions of different signalling pathways linked to these receptors to the various cellular responses (growth, maturation, functional activation) are not understood. In this project we aim to use cell and molecular biology approaches to determine the role of different signalling pathways in cellular responses mediated by the growth factor receptor c-Kit. The c-Kit receptor has essential functions in blood cell development, skin and hair pigmentation, gut function and the reproductive system. It is also essential for the development and function of mast cells which trigger allergic responses such as asthma and eczema. Mutant forms of the receptor have been identified in certain leukaemias and colon cancers. Many new drugs that target specific intracellular signalling pathways have recently been developed and are beginning to be evaluated in clinical trials. Better understanding of how individual pathways contribute to the function of c-Kit and other receptors is essential for optimal use of these new drugs. For example, it may enable the choice of drugs to block c-Kit dependent cancer cell growth or allergic reactions without affecting the growth of normal blood cells.Read moreRead less
The Role Of ERK MAPKs In Compensated Cardiac Hypertrophy
Funder
National Health and Medical Research Council
Funding Amount
$241,650.00
Summary
According to recent statistics, heart failure accounts for almost 300 deaths each year in Australia. In fact, heart failure is now a major health problem that is on the rise, despite the reduced incidence of other forms of heart and blood vessel disease. We are now in the situation where the cost of treatment of heart failure exceeds that of treating all cancer patients, and there are more patient days in hospital with heart failure than with any other heart or blood vessel disease. Most often, ....According to recent statistics, heart failure accounts for almost 300 deaths each year in Australia. In fact, heart failure is now a major health problem that is on the rise, despite the reduced incidence of other forms of heart and blood vessel disease. We are now in the situation where the cost of treatment of heart failure exceeds that of treating all cancer patients, and there are more patient days in hospital with heart failure than with any other heart or blood vessel disease. Most often, the heart fails to act as an effective pump following long-term exposure to high blood pressure. The increased work load placed on the heart effectively forces it to increase in size in a process called cardiac hypertrophy. But this initial compensation which is of benefit to the patient commonly deteriorates and many of the heart cells die. The resulting death of heart cells is the failure of the heart, and death of the patient is inevitable. The fundamental changes in the functional protein molecules of the heart cells that accompany hypertrophy and heart failure are likely to be extremely complex. As yet, no research has taken a global and unbiased look into this complexity. However, there are new technologies that allow us to take such a look. We have established a collaborative research team to investigate the fundamental mechanisms underlying cardiac hypertrophy. We are exploiting a novel model in which hypertrophy does not progress to failure. Our combined expertise allows us to use recently developed scientific methodologies to evaluate the biochemical basis for these events in the heart. We have chosen to focus on documenting the changes in proteins that accompany cardiac hypertrophy with the aim to establish important targets for interventions to permit cardiac cells to survive despite hypertrophy. This will have important implications for preventing cardiac failure.Read moreRead less
Mechanisms Of Control Of Cell Growth And Proliferation By The AKT Kinase Family
Funder
National Health and Medical Research Council
Funding Amount
$568,452.00
Summary
Ribosome synthesis and function is critical for normal cell growth and division and hence this process is exquisitely regulated. Conversely, de-regulated cell growth can lead to cancer. We have identified new roles for the AKT and SGK families of kinases in controlling this process. This proposal aims to establish the mechanisms by which these enzymes control ribosome synthesis to better understand growth control and to provide insight for targeting these pathways in growth driven cancers.
Understanding The Role Of Tec In Fcgamma Receptor Mediated Phagocytosis
Funder
National Health and Medical Research Council
Funding Amount
$211,527.00
Summary
The recognition and destruction of bacterial pathogens and other foreign particles by specific immune cells (macrophages) is principally mediated by the Fcgamma class of cell surface antibody receptors. This proposal aims to understand the molecular mechanisms which link receptor activation to the cellular rearrangements required to invaginate or swallow the offending particle. We have used immunofluorescent microscopy and biochemical methods to show that the intracellular tyrosine kinase Tec is ....The recognition and destruction of bacterial pathogens and other foreign particles by specific immune cells (macrophages) is principally mediated by the Fcgamma class of cell surface antibody receptors. This proposal aims to understand the molecular mechanisms which link receptor activation to the cellular rearrangements required to invaginate or swallow the offending particle. We have used immunofluorescent microscopy and biochemical methods to show that the intracellular tyrosine kinase Tec is an important component of the phagocytosis mechanism. Here we plan to use highly selective gene targeting methods to generate a mouse cell culture model system which is devoid of Tec protein. This will allow us to determine whether Tec is essential for Fcgamma-mediated phagocytosis. Reintroduction of mutant versions of the Tec protein into this null background will provide detailed information on the molecular partners of Tec and the individual roles of the various domains within the Tec protein. By studying the molecular mechanism of phagocytosis, we expect to gain an understanding of how to influence the Fcgamma signalling pathway, either to enhance the ability to deal with pathogens, or to restrict the consequences of excessive phagocytosis associated with autoimmune diseases. Tec is an enzyme likely to play an important role between the Fcgamma receptor and actin cytoskeleton rearrangements and therefore is a potentially important drug target.Read moreRead less
The focus of my research is mechanisms of growth factor receptor signal transduction and how they are altered in specific disease states, particularly cancer.