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Role And Mechanism Of Connective Tissue Growth Factor In Diabetic Cardiomyopathy
Funder
National Health and Medical Research Council
Funding Amount
$382,820.00
Summary
Diabetic cardiomyopathy is a condition where the heart muscle is directly damaged by diabetes. It is being recognised as a prominent cause of both acute and chronic heart failure in diabetes. It is common and occurs in up to 60% of diabetic patients . At present however, no treatments are available to directly treat the cardiomyopathy. This condition can also occur in people with diabetes who have high blood pressure and-or coronary artery disease and may combine with these problems to worsen pa ....Diabetic cardiomyopathy is a condition where the heart muscle is directly damaged by diabetes. It is being recognised as a prominent cause of both acute and chronic heart failure in diabetes. It is common and occurs in up to 60% of diabetic patients . At present however, no treatments are available to directly treat the cardiomyopathy. This condition can also occur in people with diabetes who have high blood pressure and-or coronary artery disease and may combine with these problems to worsen patient outcomes. We have generated data in experimental diabetes in rodents that strongly implicates a heart growth factor in causing diabetic cardiomyopathy. This protein, called connective tissue growth factor (CTGF), is increased in diabetic cardiomyopathy, and is elevated by high glucose and other factors in diabetes. We have published data showing that CTGF causes tissue scarring like that which occurs in cardiomyopathy, by affecting signals in cells called fibroblasts. It increases the laying down of extracellular matrix (ECM) and also inhibits the degradation of ECM by the proteins that break down matrix, known as the MMPand PAI systems. Such accumulation of ECM is thought to be a major factor leading to abnormal muscle function in cardiomyopathy. We now plan to block CTGF in this diabetic heart model to determine if we can prevent diabetic cardiomyopathy. We have generated two methods to inhibit CTGF in the animal model. Echocardiography (a heart ultrasound test), and molecular analysis of the heart tissue will determine if we can prevent the otherwise adverse functional and structural changes of diabetes in the heart. We will also study our baboon model of diabetes to determine if diabetic cardiomyopathy with increased heart CTGF is present in the primates. Cell culture studies from rat heart fibroblasts and myocytes will determine how CTGF has the effect on cells to cause cardiomyopathy and how we might further prevent this condition developing in diabetes.Read moreRead less
Factors Regulating The Temporal And Spatial Assembly Of G-protein Coupled Receptor-mediated Arrestin Complexes
Funder
National Health and Medical Research Council
Funding Amount
$472,770.00
Summary
G-protein coupled receptors are proteins that are present at the surface of most cells in the human body. They recognise and bind to specific molecules, such as hormones, the act of which results in a specific signal being transmitted into the cell. This signal alters the function of the cell and so it is critical that it is appropriate, both in type and duration. G-protein coupled receptors and the molecules that activate them provide an essential function within the human body for communicatin ....G-protein coupled receptors are proteins that are present at the surface of most cells in the human body. They recognise and bind to specific molecules, such as hormones, the act of which results in a specific signal being transmitted into the cell. This signal alters the function of the cell and so it is critical that it is appropriate, both in type and duration. G-protein coupled receptors and the molecules that activate them provide an essential function within the human body for communicating between cells, and consequently between organs. They are a major mechanism by which nerve signals are transmitted and hormones regulate bodily functions. They are therefore an important target for pharmaceuticals, with up to 50% of ethical drugs and many drugs of abuse acting upon them. It is critical to understand how these receptors alter cellular function once they receive an appropriate signal, but it is also essential to know how such responses are switched off. Arrestins are proteins within cells that interact with G-protein coupled receptors to 'arrest' their signalling. They desensitise the cell to continuous stimulation, but also act to resensitise the cell to respond to future, separate signals. Recently, they have also been shown to provide alternative mechanisms of altering cellular activity by interacting with other cellular proteins. These interactions greatly increase the potential ways in which a cell can respond once a G-protein coupled receptor is activated. Understanding the resulting complexity is essential if we are to fully exploit the vast therapeutic potential of this important receptor family.Read moreRead less