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
Role Of PAK1 In Colorectal Cancer Growth And Metastasis Regulated By Gastrins
Funder
National Health and Medical Research Council
Funding Amount
$460,070.00
Summary
Increased level of PAK1(a protein kinase) was associated with the progression of colorectal (large bowel) cancer (CRC). Gastrin peptides are growth factors responsible for CRC development. The objective of this project is to determine the role of PAK1 in the regulation of CRC growth and metastasis by gastrin peptides. We will use cell culture, animal models and clinical samples in the program. A successful outcome will lead to the development of new CRC therapies such as inhibitors of PAK1.
The Interaction Between CD46 And PSD-95/Dlg-4: Roles In Cell Polarisation And CD46 Signalling.
Funder
National Health and Medical Research Council
Funding Amount
$70,000.00
Summary
Immune defence against pathogens is primarily achieved by the activities of a range of blood cells, including T cells. T cells have specialised functions involving direct killing of the pathogen, and recruitment and activation of other immune cells. Many of these functions require the lymphocyte to become polarised, or asymmetric, in order to concentrate the appropriate cellular machinery towards the site of activity. Examples of polarisation in lymphocytes includes (i) the formation of a single ....Immune defence against pathogens is primarily achieved by the activities of a range of blood cells, including T cells. T cells have specialised functions involving direct killing of the pathogen, and recruitment and activation of other immune cells. Many of these functions require the lymphocyte to become polarised, or asymmetric, in order to concentrate the appropriate cellular machinery towards the site of activity. Examples of polarisation in lymphocytes includes (i) the formation of a single protrusion, or uropod, that forms the basis for cell-cell interactions, (ii) the formation of an immune synapse which allows a T cell to recognise a pathogen, and (iii) the direction of the cellular killing machinery towards the target. The process of cell polarisation is best characterised in neurons and epithelial cells, both of which are asymmetric. In each cell type, a major mechanism of regulating polarisation is the expression and targeting of a family of proteins containing regions called PDZ domains. PDZ domains mediate protein-protein interactions and so allow the assembly of large molecular scaffolds which hold proteins in specific cell sites. The loss of cell polarity in some cells is thought to cause uncontrolled proliferation and tumour progression, and some of the PDZ-containing proteins are tumour suppressors. We have identified a PDZ-containing protein that is polarised in T cells, and have evidence that this protein interacts with and controls the polarisation of a cell surface receptor whose functions include the regulation of T cell function and proliferation. The aim of this proposal is to determine the mechanisms and functional consequences of polarisation of these two proteins in T cells, and to determine whether their interaction or polarisation is important for T cell proliferation.Read moreRead less
Immune defence against pathogens is primarily achieved by the activities of a range of blood cells, including T cells. T cells have specialised functions involving direct killing of the pathogen, and recruitment and activation of other immune cells. Many of these functions require the lymphocyte to become polarised, or asymmetric, in order to concentrate the appropriate cellular machinery towards the site of activity. Examples of polarisation in lymphocytes includes (i) the formation of a single ....Immune defence against pathogens is primarily achieved by the activities of a range of blood cells, including T cells. T cells have specialised functions involving direct killing of the pathogen, and recruitment and activation of other immune cells. Many of these functions require the lymphocyte to become polarised, or asymmetric, in order to concentrate the appropriate cellular machinery towards the site of activity. Examples of polarisation in lymphocytes includes (i) the formation of a single protrusion, or uropod, that forms the basis for cell-cell interactions, (ii) the formation of an immune synapse which allows a T cell to recognise a pathogen, and (iii) the direction of the cellular killing machinery towards the target. The process of cell polarisation is best characterised in neurons and epithelial cells, both of which are asymmetric. In each cell type, a major mechanism of regulating polarisation is the expression and targeting of a family of proteins containing regions called PDZ domains. PDZ domains mediate protein-protein interactions and so allow the assembly of large molecular scaffolds which hold proteins in specific cell sites. The loss of cell polarity in some cells is thought to cause uncontrolled proliferation and tumour progression, and some of the PDZ-containing proteins are tumour suppressors. We have identified a PDZ-containing protein that is polarised in T cells, and have evidence that this protein interacts with and controls the polarisation of a cell surface receptor whose functions include the regulation of T cell function and proliferation. The aim of this proposal is to determine the mechanisms and functional consequences of polarisation of these two proteins in T cells, and to determine whether their interaction or polarisation is important for T cell proliferation.Read moreRead less