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.
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.
Elucidating The Mechanism Of IL-2 Cytokine/antibody Mediated Transplantation Tolerance
Funder
National Health and Medical Research Council
Funding Amount
$624,429.00
Summary
Organ transplantation is a life-saving treatment for end-stage organ failure. However, patients must take immunosuppressive drugs to prevent rejection, a lifetime of which increases the risk of infection and cancer. An alternative to drugs is to manipulate the immune system from within. We discovered a way to boost the immune ‘regulators’ so that they stifle the graft-destroying response. We are optimising this approach with the aim of transplanting organs without long-term immunosuppression.
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.
Deciphering The Role Of Scribble In Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$628,789.00
Summary
Scribble is a protein that controls the orientation and organization of all cells within our body. Mutations in the Scribble gene are found in many cancers and also in some patients with spina bifida, however how these mutations cause these diseases is not understood. Here we propose experiments that can be used to link Scribble mutations to specific cellular functions. This information will help us design new therapies to treat diseases driven by tissue disorganization such as cancer.
Diabetes is a major health epidemic; and both type 1 and type 2 diabetes can lead to the development of diabetic complications - the major cause of morbidity and mortality from diabetes. Loss of islet function is a key factor in diabetes and my testable hypothesis is that islet inflammation contributes to this process. We will investigate how genes effect islet inflammation. New understanding could lead to biomarkers for determining who is susceptible & new treatment opportunities.
Functional And Molecular Characterization Of A Novel Regulator Of Angiogenesis
Funder
National Health and Medical Research Council
Funding Amount
$474,907.00
Summary
All cells in the body require blood vessels for the provision of nutrients and waste-removal. A deficiency of vessels prevents proper healing whereas an overabundance is a hallmark of diseases such as cancer and macular degeneration. This research will investigate a novel gene that is essential for new vessel growth. The project aims to understand the mechanism of how this gene functions. Ultimately, the research aims to inform therapeutic development for stimulating or inhibiting vessel growth.
Interleukin Signalling In CD4+ T Cell Differentiation
Funder
National Health and Medical Research Council
Funding Amount
$663,919.00
Summary
Our bodies rely on the production of antibodies to fight infection. The cytokine IL-21 is produced by immune cells called T follicular helper (Tfh) cells that help B cells make antibodies. Tfh cells, in turn, are controlled by regulatory (Tfr) cells. Our findings demonstrate that IL-21 supports Tfh cells and limits Tfr cells, thus favoring antibody production and long term immunity. Using genomic and cellular approaches, the mechanism(s) underlying these observations will be explored.
Investigating The Contribution Of Distinct Mitochondrial Cell Death Pathways To Platelet Survival And Function
Funder
National Health and Medical Research Council
Funding Amount
$635,247.00
Summary
Platelets are small blood cells that form clots to stop bleeding. We have found new and unexpected roles for 2 distinct pathways that regulate cell death in the process of blood clot formation. We will study the precise role of these pathways in blood clot formation, and determine whether they may also regulate the survival of platelets stored by the blood bank for transfusion. These studies will provide new insight into the role of cell death pathways in blood clot formation, and may help to im ....Platelets are small blood cells that form clots to stop bleeding. We have found new and unexpected roles for 2 distinct pathways that regulate cell death in the process of blood clot formation. We will study the precise role of these pathways in blood clot formation, and determine whether they may also regulate the survival of platelets stored by the blood bank for transfusion. These studies will provide new insight into the role of cell death pathways in blood clot formation, and may help to improve current protocols for storing plateletsRead moreRead less
The Role Of The Polarity Protein, Par3, In Haematopoiesis And Leukaemogenesis
Funder
National Health and Medical Research Council
Funding Amount
$589,777.00
Summary
Understanding the factors regulating blood production is critical to understanding how blood cancers occur and for the development of new therapies. Evidence is emerging of a vital role for the evolutionary conserved ‘polarity’ proteins in blood production and leukaemia This project will elucidate the role of the polarity protein, Par3, in normal and malignant blood cells, providing valuable insight into how Par3 regulates blood formation and the onset and severity of leukaemia.