Loss of insulin-producing beta cells leads to type 1 diabetes and rejection of allogeneic islet transplants. The aim of this program is to discover ways of protecting beta cells from damage. We will do this by investigating whether blocking crucial regulators of cell death can protect mouse and human beta cells from destruction in vitro and in vivo. In doing so, we aim to prevent diabetes in mice and potentially improve the survival of islet grafts after transplantation.
In type 1 diabetes the body becomes deficient in insulin production from pancreatic b cells because the immune system mistakenly attacks and destroys b cells as if they were an invading infection. Recurrence of autoimmune destruction of b cells also occurs following transplantation of whole pancreas or islet cells and may occur in the future when other engineered insulin producing cells are transplanted. The focus of this program is to better understand how b cells are killed by the immune syste ....In type 1 diabetes the body becomes deficient in insulin production from pancreatic b cells because the immune system mistakenly attacks and destroys b cells as if they were an invading infection. Recurrence of autoimmune destruction of b cells also occurs following transplantation of whole pancreas or islet cells and may occur in the future when other engineered insulin producing cells are transplanted. The focus of this program is to better understand how b cells are killed by the immune system and to test ways of protecting beta cells from these mechanisms. Because of the inaccessibility of the pancreas to study (particularly biopsy) in humans with diabetes, much of the proposed work will be carried out in b cells derived from non-obese diabetic (NOD) mice, the best available mouse model of type 1 diabetes. It is clear from the literature that a molecule called perforin found in cytoxic T lymphocytes (CTL) is a major, if not the major, mechanism the immune system uses against b cells. For this reason we will try to better understand the interaction between b cells and perforin and ultimately design ways of them from perforin-mediated cell death. It is equally clear that there are other mechanisms besides perforin that can cause b cell death and the program will also address discovery of these mechanisms and new ways to block them. Beta cells in NOD mice will be protected from perforin or other mechanisms by the addition of protective genes or removal of harmful genes using transgenic knockout technology. Addition or removal of genes involved in cell death can be done systematically and each protocol tested using NOD mouse model. The process of cell death that b cell undergo in type 1 diabetes is called apoptosis. Apoptosis is a general mechanism by which cells of all types die. Experts in the biology of apoptosis and perforin are important members of the program, providing the opportunity to translate the latest advances in cell death research to diabetes. This research addresses several of the specific research areas of interest to JDRF. It focuses on the prevention of b cell death in individuals with type 1 diabetes receiving islet transplants. It may be applicable in the future to protection of stem or precursor cells that have been differentiated into b cells or even to devising strategies to prevent the development of diabetes.Read moreRead less
Gene Based Treatment Strategies For Diabetic Retinopathy
Funder
National Health and Medical Research Council
Funding Amount
$2,630,000.00
Summary
Diabetic retinopathy is the leading cause of blindness in the working population of developed countries and it is an increasing problem in the developing world. Present therapy involves extensive laser destruction of the light-detecting part of he retina. In addition, it is not only effective when administered at an appropriate stage in the disease process. Consequently, there is an urgent need for the development of better, prophylactic, easily administrable and cheaper therapies. This project ....Diabetic retinopathy is the leading cause of blindness in the working population of developed countries and it is an increasing problem in the developing world. Present therapy involves extensive laser destruction of the light-detecting part of he retina. In addition, it is not only effective when administered at an appropriate stage in the disease process. Consequently, there is an urgent need for the development of better, prophylactic, easily administrable and cheaper therapies. This project aims to develop a potentially permanent solution to alleviate diabetes-related blindness in the world. The project combines several very recent scientific advances into one strategy to combat diabetic retinopathy at a molecular level. Vision is our most important sensory organ that cannot be replaced. Thus, human trials can only be conducted following extensive animal safety and efficacy trials. To date the development of new therapies has been seriously hampered by the lack of appropriate, easy to reproduce animal models for different stages of diabetic retinopathy. In addition, it aims to identify new therapeutic agents from molecules that are naturally produced by the retina while fighting the disease. Finally, tested and evaluated in the animal models. The most successful therapeutic candidates will then be further developed for human trials.If successful, our approach will potentially have a major impact on the treatment of diabetic retinopathy and possibly on all diabetic vascular diseases. A single injection might only be necessary to prevent the development of diabetic retinopathy, which would represent a significant weapon in the management of patients. In addition, successful application of secretion gene therapy in the eye might open up the possibility to introduce the same concept for the treatment of larger organs undergoing microvascular changes as a result of diabetes.Read moreRead less