Novel Interplay Of Oestrogen And Growth Hormone In Regulating Lipid Metabolism
Funder
National Health and Medical Research Council
Funding Amount
$673,045.00
Summary
These studies provide insights into the mechanisms and role of oestrogen in regulating whole body and liver fat metabolism. Oestrogen-related medications that modify the action or tissue availability of oestrogen are widely used therapeutics and can predispose to obesity and fat accumulation in the liver. Whether the effect is direct or through interplay with other metabolic hormones is unknown. This proposal examines their metabolic consequences and impact on obesity and liver health.
Novel Metabolic Actions Of HDL With Therapeutic Potential For Type 2 Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$559,471.00
Summary
Our proposal investigates a novel approach to treat type 2 (late onset) diabetes. We have identified an important link between HDL (good) cholesterol and glucose metabolism. The current proposal is to conduct studies in humans to determine whether therapies which increase HDL result in sustained reduction of blood glucose. Given the escalating global prevalence of obesity and type 2 diabetes, this work is potentially of great significance.
Brown fat protects animals against obesity and diabetes. Humans with abundant brown fat are metabolically healthy. Identification of medication that boosts brown fat function may lead to novel treatment of metabolic disorders. This proposal will examine the role of such a medication, which is modeled on a factor (called FGF21) released from brown fat. The project will also search for other factors released by human brown fat, which may become future targets of obesity treatment.
Understanding Sphingolipid Mediators Of Insulin Resistance
Funder
National Health and Medical Research Council
Funding Amount
$643,447.00
Summary
Sphingolipids are a class of lipid metabolites that have a variety of functions within cells. It has been known for some time that an accumulation of excess lipid, including certain sphingolipids, can adversely impact insulin action and glucose metabolism in cells. In this project we will a combination of strategies to test the hypothesis that the sphingolipid profile can be manipulated to have favourable effects on metabolism.
Short-term Effects Of Overfeeding On Metabolic Risk In Humans
Funder
National Health and Medical Research Council
Funding Amount
$417,196.00
Summary
The prevalence of obesity is rapidly increasing in Australia and other parts of the world. Obesity is closely associated with insulin resistance and plays a role in the development of type 2 diabetes. However, the effects of short-term periods of over nutrition in humans remain unclear. In the proposed study, we will investigate the effects of short-term weight gain by high fat feeding in lean subjects, in subjects who are overweight and in subjects who are genetically more likely to develop dia ....The prevalence of obesity is rapidly increasing in Australia and other parts of the world. Obesity is closely associated with insulin resistance and plays a role in the development of type 2 diabetes. However, the effects of short-term periods of over nutrition in humans remain unclear. In the proposed study, we will investigate the effects of short-term weight gain by high fat feeding in lean subjects, in subjects who are overweight and in subjects who are genetically more likely to develop diabetes (due to strong family history). The aims are to distinguish physiological and endocrine characteristics of individuals who store more fat in response to overfeeding. We will identify differences between these individuals and whether they have defects in upregulating machinery involved in fat oxidation and energy production in skeletal muscle that may help them adapt during to energy excess. We will look for changes in type 2 diabetes risk and we will have the potential to identify defects in factors that are involved in this response. We will also re-examine indivudals again after calorie restriction and weight loss. We also plan to confirm the role of the candidate genes involved in fat oxidation that have been identifieid in human studies by in vivo gene transfer technology in rodents. This study will determine whether overweight and lean subjects behave similarly when faced with an overfeeding challenge. We expect that individuals with a genetic predisposition for T2DM will become more IR, due to metabolic inflexibility and a decreased ability to upregulate machinery involved in fatty acid oxidation and mitochondrial function. By characterising the physiological and endocrine responses to overfeeding, we will establish quantifiable markers allowing us to distinguish those at risk and identify new targets for pharmacological or lifestyle intervention.Read moreRead less
Investigation Of The Roles Of Protein Kinase C Epsilon In Insulin Secretion And Insulin Clearance
Funder
National Health and Medical Research Council
Funding Amount
$627,148.00
Summary
The rise in blood insulin levels after a meal normally reduces blood sugar levels by increasing glucose uptake and storage in certain tissues, especially muscle. Type 2 diabetes is characterized in part by a failure of the pancreas to produce adequate insulin in response to increases in blood sugar. This loss of insulin secretion has been strongly linked to increases in the availability of fat, although the reasons for this are not clear. We have recently found that mice lacking a specific enzym ....The rise in blood insulin levels after a meal normally reduces blood sugar levels by increasing glucose uptake and storage in certain tissues, especially muscle. Type 2 diabetes is characterized in part by a failure of the pancreas to produce adequate insulin in response to increases in blood sugar. This loss of insulin secretion has been strongly linked to increases in the availability of fat, although the reasons for this are not clear. We have recently found that mice lacking a specific enzyme (protein kinase C epsilon) are much less susceptible to the problems in dealing with blood sugar that are caused by a high fat diet. We showed that this is due partly to improved insulin secretion, and also to a slower breakdown of insulin by the liver, which increases its availability to target tissues. The aim of this project is to investigate the mechanisms occurring in the liver and in the pancreas by which this enzyme contributes to improved insulin action. Firstly, we will examine insulin uptake in liver cells, to investigate how the enzyme controls this process. Secondly, we will determine the mechanism through which the activation of the enzyme, upon increased fat supply to pancreatic beta-cells, reduces insulin secretion in response to glucose. Finally, will assess the relative importance of these two actions of the enzyme in improving the control of blood sugar levels. This work will lead to a better understanding of the mechanisms by which fat oversupply, and hence obesity, can play a role in the development of Type 2 diabetes, so that they can be targeted both for the development of new and more effective treatments for the disorder and for prevention of its onset.Read moreRead less
Targeting Ceramide Metabolism To Improve Lipid-induced Insulin Resistance
Funder
National Health and Medical Research Council
Funding Amount
$604,327.00
Summary
We have shown that the buildup of ceramide in muscle plays a key role in the inhibition of normal insulin action when the body is exposed to excessive amounts of fat, which leads to poor control of blood sugar levels and Type 2 diabetes. Using mass spectrometry we will now measure different ceramide types, to investigate which contribute to defects in insulin action. We will also examine whether enzymes involved in ceramide formation or degradation can be targeted to improve insulin responses.
Therapeutic Strategies And Screening Methods For PKC Epsilon Antagonists In The Treatment Of Type 2 Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$157,375.00
Summary
Type 2 diabetes is a chronic disease affecting over a million Australians and hundreds of millions of people worldwide. Its prevalence is rising due to several factors such as an increase in caloric intake, the aging of the population, and the common sedentary lifestyle of Western civilization. Type 2 diabetes occurs when the pancreas is unable to produce enough insulin for the body to cope with rising blood glucose levels after a meal, and has been strongly linked to obesity. We have now shown ....Type 2 diabetes is a chronic disease affecting over a million Australians and hundreds of millions of people worldwide. Its prevalence is rising due to several factors such as an increase in caloric intake, the aging of the population, and the common sedentary lifestyle of Western civilization. Type 2 diabetes occurs when the pancreas is unable to produce enough insulin for the body to cope with rising blood glucose levels after a meal, and has been strongly linked to obesity. We have now shown that an enzyme found in the pancreas becomes inappropriately activated under conditions of fat oversupply, and plays an important role in the development of defects in insulin release from the pancreas in response to glucose. Excitingly, we have also shown that inhibition of this enzyme can partly reverse these defects once they have been established. We now intend to further validate this enzyme as a drug target by determining the optimum dosing regimen for the treatment of type 2 diabetes in a mouse model, and testing whether this approach can be used in conjunction with previously-developed drugs which promote insulin action, to improve bood glucose handling better than either treatment alone. This would promote the enzyme as a therapeutic strategy in the treatment of Type 2 diabetes. We also plan to develop a high throuhput screen to identify novel inhibitors of the enzyme, which will further increase the attractiveness of the project to pharmaceutical companies, who are better able to implent full commercialization of our findings.Read moreRead less