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The Role Of Grb10 In The Regulation Of Muscle Metabolism
Funder
National Health and Medical Research Council
Funding Amount
$624,960.00
Summary
Obesity increases the risk of metabolic diseases such as type 2 diabetes. Muscle is a key tissue for balancing whether energy is used or stored as fat and as we age, muscle mass normally decreases making maintaining a healthy metabolism even more difficult. We have discovered that removing the Grb10 gene from mice produces bigger muscles. This project will investigate the mechanisms of this effect so that strategies can be developed to regulate muscle mass and improve metabolic health
Role Of Impaired Insulin Signalling In Fatty Acid-induced Muscle Insulin Resistance In Vivo
Funder
National Health and Medical Research Council
Funding Amount
$481,500.00
Summary
Type 2 diabetes represents an escalating global health problem. In Australia 7.5% of the population has diabetes and another 16% insulin resistance (impaired action of insulin in tissues). As well as diabetes, insulin resistance is closely associated with obesity, dyslipidaemia, hypertension and cardiovascular diseases (Syndrome X). While genetic factors play a role, a high caloric intake (particularly with a high fat content) and a sedentary lifestyle are extremely important environmental contr ....Type 2 diabetes represents an escalating global health problem. In Australia 7.5% of the population has diabetes and another 16% insulin resistance (impaired action of insulin in tissues). As well as diabetes, insulin resistance is closely associated with obesity, dyslipidaemia, hypertension and cardiovascular diseases (Syndrome X). While genetic factors play a role, a high caloric intake (particularly with a high fat content) and a sedentary lifestyle are extremely important environmental contributors to Syndrome X and diabetes. From evidence that we and others have obtained over the last few years it is now evident that an important mediator of insulin resistance is the quantity of fat molecules which accumulate in muscle and liver. This project examines mechanisms whereby this fat accumulation can disrupt the signalling mechanism normally causing increased glucose metabolism in response to insulin. While basic experiments in cell systems have identified some candidates, a need exists to demonstrate whether they actually cause the insulin resistance in the whole animal or human, or are merely associated with it. We will combine metabolic-physiological studies with a novel technique we have recently established in our laboratory for introducing DNA into skeletal muscle of laboratory animal models. We now aim to exploit this approach to obtain more definitive data about the importance of insulin signalling changes to insulin resistance. Two major steps in insulin signalling will be investigated, involving the insulin receptor substrate proteins and the kinase Akt-PKB, both strongly implicated in lipid-induced insulin resistance. This knowledge will be invaluable in improving strategies to lessen or prevent lipid-associated insulin resistance, a major contributor to the metabolic derangement in Type 2 diabetes and Syndrome X.Read moreRead less
Characterisation Of Autophagy Deficiency In Skeletal Muscle Homeostasis
Funder
National Health and Medical Research Council
Funding Amount
$956,237.00
Summary
Defects in skeletal muscle are a cause of muscle disease, and also have broad health implications for diabetes, obesity and liver disease. As such, it is important to understand the processes required for healthy muscle and how signals communicate from muscle to the liver and fat, which integrate whole body metabolism. This application examines how the cellular degradation process known as autophagy integrates these important processes by investigating a novel gene regulator of this pathway.
Defining The Insulin-signalling Defect In Human Insulin Resistance And Type 2 Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$94,280.00
Summary
Problems with the way insulin removes glucose from the circulation contribute to developing type 2 diabetes. Despite research to date, controversy remains regarding the nature of known defects in insulin action and their relevance to humans. We plan to measure molecules involved in insulin action in muscle of people with insulin resistance, which is linked to diabetes. These studies will define new defects that cause insulin resistance and type 2 diabetes in humans.
Dilinoleoyl Phosphatidic Acid As A Novel Mediator Of Insulin Resistance In Muscle
Funder
National Health and Medical Research Council
Funding Amount
$504,097.00
Summary
We have identified a novel fat molecule in muscle which may play an important role in causing insulin resistance during obesity, a major factor in the development of Type 2 diabetes. We will now examine whether depletion of this molecule, dilinoleoyl-phosphatidic acid, can improve insulin action in muscles and in obese mice, and investigate the mechanisms by which it may act. This work may indicate new strategies for the treatment of diabetes.
Role Of Sphingolipid Signalling In Hepatic Insulin Resistance And Its Application In Prediction Of Risk For Type 2 Diabetes And Prediabetes
Funder
National Health and Medical Research Council
Funding Amount
$563,305.00
Summary
Type 2 diabetes is expected to reach epidemic proportions in the coming decades. Prediabetes is usually unrecognized and constitutes a major public health concern that needs earlier interventions, because the majority of prediabetic subjects proceed to T2D. We have identified an enzyme that plays an important role in insulin signalling. The possibility is that the level or activity of this enzyme is a potential biomarker of the prediabetes state and could be also used as a target
Conologues: Ultra-fast-acting Therapeutic Insulins Based On Cone Snail Venom Insulin Principles
Funder
National Health and Medical Research Council
Funding Amount
$1,082,866.00
Summary
The increasing prevalence of Type 1 and Type 2 diabetes demands better treatments. Our Project is based on a fascinating discovery by our international team of CIs of a new type of insulin within marine organisms that could form the basis of a novel diabetes therapeutic. Within our Project we will exploit this discovery to develop a new class of ultra-rapid-acting therapeutic insulins.
Metabolic Wiring In Adipocytes - Unique Role In Maintaining Long-term Health
Funder
National Health and Medical Research Council
Funding Amount
$1,077,886.00
Summary
Fat cell metabolism is wired to optimize the cell’s ability to make and store lipid while programming the cell to fulfil its function in whole body metabolism. We will: 1) map fat cell metabolism under optimal and insulin resistant conditions; 2) explore the role of 3 nodes in his metabolic circuit predicted as control points; 3) use a novel genetically engineered mouse model to explore the functional significance of fat cell metabolism in whole body insulin sensitivity.
Type 2 diabetes represents an escalating global health problem. In Australia 7.2% of the population has diabetes but an additional 16% have difficulty handling glucose, a problem which frequently precedes the development of diabetes. Resistance of tissues to the action of insulin is an essential pre-requisite for type 2 diabetes but is also closely associated with the syndrome of obesity, dyslipidaemia, hypertension and cardiovascular diseases (Syndrome X). Genetic factors combined with a high c ....Type 2 diabetes represents an escalating global health problem. In Australia 7.2% of the population has diabetes but an additional 16% have difficulty handling glucose, a problem which frequently precedes the development of diabetes. Resistance of tissues to the action of insulin is an essential pre-requisite for type 2 diabetes but is also closely associated with the syndrome of obesity, dyslipidaemia, hypertension and cardiovascular diseases (Syndrome X). Genetic factors combined with a high caloric intake and a sedentary lifestyle are together responsible for the development of insulin resistance. From evidence that we and others have obtained in recent years it is evident that an important mediator of insulin resistance is the amount of fat which accumulates in muscle and liver. One way in which this abnormality seems to cause insulin resistance is through interference with the normal signalling mechanism which causes increased glucose metabolism in response to insulin. While experiments in cell systems have identified some candidate molecules that may be involved, a need exists to demonstrate whether their dysregulation actually causes the insulin resistance in the whole animal or human, or are merely associated with it. We will use novel techniques to manipulate the levels of one of these candidate genes, protein kinase B-Akt, and its regulators in the muscle of rodents. We will then examine the effects of these manipulations on insulin resistance using a combination of metabolic and molecular tests. Building upon earlier work we will also determine how important different subtypes of this molecule are for both normal and abnormal insulin-glucose metabolism, and whether these molecules or others in the pathway are more important in insulin resistance. This knowledge will be invaluable in tailoring specific novel treatment strategies or drugs for prevention or treatment of insulin resistance, and thus reducing the burden of type 2 diabetes and Syndrome X.Read moreRead less