Type 2 diabetes is a health crisis in Australia. In this project, we will investigate the mechanisms whereby high glucose and fat impair pancreatic beta-cell function leading to type 2 diabetes. We will establish how endoplasmic reticulum stress and the protein Id1 are linked with loss of beta-cell gene expression and function. The information gained will further our understanding of the basic mechanisms regulating insulin secretion and provide new therapeutic targets for diabetes treatment.
Investigating The Novel Role Of SEPS1 In The Prevention Of Islet Beta Cell Failure And Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$535,804.00
Summary
SEPS1 is an important glucose-regulated protein whose function is to protect tissues from oxidative stress. Inhibition of SEPS1 by hyperglycaemia, is a mechanism for progression of Type 1 and Type 2 diabetes once hyperglycaemia supervenes. The overall aim of the project is to investigate the function of the novel SEPS1, using transgenic and knockout approaches.
New Molecular Mechanisms Of Islet Protection Against Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$673,259.00
Summary
Type 2 diabetes is an enormous health and economic burden. The mechanisms of ?-cell compensation for insulin resistance and of ?-cell failure in type 2 diabetes are unclear. This proposal will test the novel hypothesis that the adaptation of endoplasmic reticulum (ER) capacity mediates ?-cell compensation, and that the failure of ?-cell adaptation to ER stress causes diabetes. The studies will show that targeting ER capacity is an important novel strategy for type 2 diabetes therapy.
Reversal Of Diabetes In A Humanised Mouse Using A Clinically Applicable Vector System
Funder
National Health and Medical Research Council
Funding Amount
$842,173.00
Summary
Somatic gene therapy is one of the strategies that is being considered to cure Type I diabetes. Specifically, we wish to engineer liver cells to replace beta cell function. The aim of this project is to design a clinically-applicable protocol for the reversal of diabetes using a recombinant adeno-associated vector that delivers genes to human livers with high efficiency showing long term expression without pathogenicity and immunogenicity following a simple intra-peritoneal injection.
Can Vitamin D Prevent Diabetes By Improving Insulin Sensitivity And Secreation In Overweight Humans?
Funder
National Health and Medical Research Council
Funding Amount
$715,371.00
Summary
Vitamin D is mainly produced by the action of sunlight on skin. Low levels of vitamin D are becoming more common, as we work more indoors and avoid the sun and have been associated with type 2 diabetes. In proposed study, healthy overweight people, with low vitamin D, will be given vitamin D for 16 weeks to optimise blood levels of this vitamin. We will examine the changes in sugar metabolism. This study should provide important evidence on how vitamin D protects against diabetes and will suppor ....Vitamin D is mainly produced by the action of sunlight on skin. Low levels of vitamin D are becoming more common, as we work more indoors and avoid the sun and have been associated with type 2 diabetes. In proposed study, healthy overweight people, with low vitamin D, will be given vitamin D for 16 weeks to optimise blood levels of this vitamin. We will examine the changes in sugar metabolism. This study should provide important evidence on how vitamin D protects against diabetes and will support novel approaches to diabetes prevention.Read moreRead less
Role Of The Adaptive Unfolded Protein Response In Beta-cell Compensation
Funder
National Health and Medical Research Council
Funding Amount
$581,715.00
Summary
Obesity is a strong risk factor for type 2 diabetes. Obese subjects with “robust” pancreatic beta-cells can sustain a compensatory response. Type 2 diabetes arises in subjects with beta-cells that are “susceptible” to dysfunction and death. We will investigate the role of the adaptive unfolded protein response in beta-cell compensation for obesity-associated insulin resistance. Findings will help explain why some individuals but not others develop type 2 diabetes.
Role Of Lysosomal Acid Lipase In Regulating Insulin Secretion
Funder
National Health and Medical Research Council
Funding Amount
$570,928.00
Summary
Type 2 diabetes (T2D) affects 7% of Australians and is a major cause of morbidity and mortality. A failure of insulin secretion contributes to T2D, and this is linked to the inability of insulin producing ?-cells to use lipids appropriately (lipotoxicity). Here we will study the role of a cellular body called the lysosome to regulate ?-cell lipid metabolism and insulin secretion. This work will greatly increase the understanding of ?-cell failure in T2D.
Targeting Insulin Hypersecretion To Prevent Type 1 And Type 2 Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$834,596.00
Summary
Diabetes develops when islet beta-cells fail to secrete insulin. While major differences exist in the mechanisms by which type 1 and type 2 diabetes develop, there is overlap in beta-cell susceptibility factors. We will investigate whether an islet 'overwork' response to excess nutrient loads underlies beta-cell susceptibility to failure in both types of diabetes. We will also develop novel pharmacological approaches to reduce islet 'overwork' to prevent and treat type 1 and 2 diabetes.
Control Of Insulin Secretion By Y1 Receptor Signalling
Funder
National Health and Medical Research Council
Funding Amount
$675,582.00
Summary
Diabetes is the most common metabolic disease worldwide. Impaired insulin secretion and beta cell function is one of its major causes. We have recently discovered a key signaling pathway that we believe hold the secret to inhibiting insulin secretion in beta cells and blocking it leads to significant insulin release. This proposal focuses on this pathway and its regulation using innovative and unique tools. This will provide a novel treatment option for diabetes as well as islet transplantation.
The proposal focuses on a novel angle explaining how pancreatic beta cells normally match their insulin synthesis, storage and secretion in response to an enhanced demand as occurs during obesity, and how this fails in the progression to Type 2 diabetes. In particular we will expand our discovery that glucose rapidly enhances the synthesis of a novel factor regulating gene transcription. This will generate basic knowledge that will potentially help design of novel therapies for Type 2 diabetes.