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The Role And Function Of Macrophages In Cellular Xenograft Rejection
Funder
National Health and Medical Research Council
Funding Amount
$323,250.00
Summary
The long term objective of this project is to develop pig insulin secreting tissue as a treatment for type 1 diabetes. At present the main barrier to this is rejection. In paricular a type of white blood cell called macophages has an important role in causing the rejection seen in xenotransplantation (the transplantation of pig tissue into humans). Our reseach group has made novel observations which show that the way macrophages respond to a xenotransplant is different to the way it behaves to t ....The long term objective of this project is to develop pig insulin secreting tissue as a treatment for type 1 diabetes. At present the main barrier to this is rejection. In paricular a type of white blood cell called macophages has an important role in causing the rejection seen in xenotransplantation (the transplantation of pig tissue into humans). Our reseach group has made novel observations which show that the way macrophages respond to a xenotransplant is different to the way it behaves to the transplant of an organ from the same species. In the rejection of pig insulin secreting tissue, macrophages are able to respond in the absence of ongoing signals from T cells. This project aims to identify the receptors on macrophages that are responsible for this response. In particular those receptors that are important for facilitating the migration of macrophages to the transplant site and the receptors that allow macrophages to distinguish self from non-self will be analysed. Hopefully these receptors will be used as targets for new therapeutic agents that could be used to prevent the strong rejection response that occurs when pig insulin secreting tissue is transplanted into humans.Read moreRead less
Functional Suicide Of Selected Dendritic Cells By Cytochrome C: An In Vivo Model Lacking Cross-presentation
Funder
National Health and Medical Research Council
Funding Amount
$597,476.00
Summary
Certain white blood cells (dendritic cells) activate the immune system, especially its T cells. Infection of such cells elicits killer T cell responses. However not all infections infect dendritic cells. In such cases, the infectious material is eaten by dendritic cells and moved to certain areas within the cell. This process is called cross-presentation and how important it is during various diseases remains moot. We now have a model of testing this by eliminating these cross-presenting cells.
The current treatment for diabetes involves diet, drugs and insulin treatment. While these are satisfactory for some adult onset diabetes, it is clear that in juvenile diabetes, the disease can progress in the presence of careful insulin dosage. It is apparent that the whole islet as a functional unit is likely to give the best control of diabetes, as when patients are transplanted with whole or segments of pancreas from human donors, as not only is there an improvement in their diabetic status, ....The current treatment for diabetes involves diet, drugs and insulin treatment. While these are satisfactory for some adult onset diabetes, it is clear that in juvenile diabetes, the disease can progress in the presence of careful insulin dosage. It is apparent that the whole islet as a functional unit is likely to give the best control of diabetes, as when patients are transplanted with whole or segments of pancreas from human donors, as not only is there an improvement in their diabetic status, the vessel lesions improve. Transplantation therefore offers a new therapy to diabetic patients for reversal of their disease and improvement in the serious side affects found in the eye, kidney and blood vessels. However, transplantation introduces a problem in that there is simply not sufficient human islets available for organ or islet transplantation, and in this light, animals are being examined as a possible source of islets. This is called xenografting or xenotransplantation. Of all the animal species, the pig is the most suitable donor for a variety of reasons, for example similar control of blood sugar to humans. The ultimate aims of the study are to examine possible genetic modifications that would allow the production of transgenic pig islets for transplantation to humans for the treatment of diabetes. The focus of the proposed studies is to elucidate the optimal combinations using mouse models. Importantly this study will establish the proof of principle and provide information on the genes that will be useful to finally genetically modify pigs for clinical use.Read moreRead less
The Role Of T-cell Apoptosis In Transplantation Tolerance
Funder
National Health and Medical Research Council
Funding Amount
$173,380.00
Summary
Organ transplantation is the treatment of choice for patients with end-stage heart, lung, liver or kidney failure and there have been spectacular improvements in the early success of these procedures. However the 10 year graft survival rate has not changed much in the past 15 years. One way of overcoming this problem is to manipulate the immune system so that the transplant is accepted indefinitely. This is called tolerance and it works by giving intense immunosuppression for a short period so t ....Organ transplantation is the treatment of choice for patients with end-stage heart, lung, liver or kidney failure and there have been spectacular improvements in the early success of these procedures. However the 10 year graft survival rate has not changed much in the past 15 years. One way of overcoming this problem is to manipulate the immune system so that the transplant is accepted indefinitely. This is called tolerance and it works by giving intense immunosuppression for a short period so that the transplant is accepted indefinitely without the need for long term immunosuppression. The immune mechanism responsible for this phenomenon is complex and is poorly understood. This project aims to study the early events in the immune system that leads to transplantation tolerance. In particular, factors involved in programmed cell death in white blood cells will be studied. Specially bred mice that have blocks in the cell death mechanisms will used to determine what effects these blocks have on the ability to induce tolerance. Other mice that have been genetically altered to allow their white cells to be tracked will be used to study the fate of these cells. If the mechanisms involved in tolerance induction are better understood, then it will be possible to design specific immunosuppressive drugs that will be used to produce tolerance in transplant patients.Read moreRead less
Determining The Potential For Porcine Foetal Islet Xenotransplantation.
Funder
National Health and Medical Research Council
Funding Amount
$351,660.00
Summary
Tight glucose control by insulin injection minimises diabetic complications but restricts lifestyle. An alternative, pancreatic islet transplantation, is limited by donor shortage. With genetic technology, pig donor tissue is a feasible donor source. This project will use an inbred pig colony to assess long term foetal pig islet function in the absence of an immune response. It will outline the genetic characteristics of this pig colony and carefully catalogue the type, number and distribution o ....Tight glucose control by insulin injection minimises diabetic complications but restricts lifestyle. An alternative, pancreatic islet transplantation, is limited by donor shortage. With genetic technology, pig donor tissue is a feasible donor source. This project will use an inbred pig colony to assess long term foetal pig islet function in the absence of an immune response. It will outline the genetic characteristics of this pig colony and carefully catalogue the type, number and distribution of endogenous retroviruses within pig genes. It may provide a basis from which new strategies can be developed to overcome rejection. Ultimately a unique Australian resource will be developed which may provide unlimited islets for safe, large-scale transplantation of diabetics before they develop debilitating complications.Read moreRead less
Xenotransplantation Of Encapsulated Insulin-producing Pig Cells
Funder
National Health and Medical Research Council
Funding Amount
$763,316.00
Summary
The ideal treatment for insulin-dependent diabetes is the replacement of insulin-producing cells. Currently, this is carried out using a whole pancreas or experimentally with cells isolated from the pancreas of donor humans. Despite the success of these procedures, demand for human organs far exceeds supply, thus driving the search for suitable alternatives. Pigs are physiologically similar to humans, and insulin-producing cells can be easily isolated from the fetal pig pancreas as islet-like ce ....The ideal treatment for insulin-dependent diabetes is the replacement of insulin-producing cells. Currently, this is carried out using a whole pancreas or experimentally with cells isolated from the pancreas of donor humans. Despite the success of these procedures, demand for human organs far exceeds supply, thus driving the search for suitable alternatives. Pigs are physiologically similar to humans, and insulin-producing cells can be easily isolated from the fetal pig pancreas as islet-like cell clusters; 8% of the cells in the cluster produce insulin and the remaining cells develop this capability after transplantation. Transplantation requires chronic immunosuppression with drugs which increase the risk of infection and cancer. To many people with diabetes, the side effects will be greater than the potential benefit. Placing cells inside microcapsules made of a biologically inert material may prevent graft rejection without chronic immunosuppression. The Investigators have demonstrated that encapsulated insulin-producing pig cells survive and function when transplanted into diabetic immunodeficient mice, but not when xenografted into immunocompetent mice. It is hypothesised that this is due to an immunological or inflammatory response by the host in response to the shedding of molecules by the encapsulated pig cells. A pre-clinical model to test the efficacy of encapsulated insulin-producing pig cells is the humanized mouse. It is hypothesized that transient administration of anti-rejection drugs will be needed to allow the survival of pig cells xenografted into these mice and normalization of BGL once diabetes has been induced. The aims of this study are: 1. To assess the nature of the host response when encapsulated insulin-producing fetal pig cells are transplanted into diabetic BALB-c mice. 2. To normalize blood glucose levels (BGL) in diabetic humanized mice transplanted with encapsulated insulin-producing fetal pig cells.Read moreRead less
Expansion, Differentiation And Functional Analysis Of In Vitro Derived Pdx1+ Pancreatic Progenitors
Funder
National Health and Medical Research Council
Funding Amount
$540,075.00
Summary
Type 1 diabetes is a condition that arises when the body's immune system destroys insulin-producing beta cells within the pancreas. Recent studies have shown that normal glucose control can be restored by replacing the missing beta cells by transplantation of cells from deceased donors. However, the demand for transplant material outweighs supply. The work described in this application seeks to define how insulin-producing beta cells can be derived in the laboratory from embryonic stem cells .
NON IMMUNOLOGICAL BARRIERS TO SUCCESSFUL TREATMENT OF DIABETES BY XENOTRANSPLANTATION
Funder
National Health and Medical Research Council
Funding Amount
$310,500.00
Summary
Tragically patients whom suffer from diabetes mellitus develop major secondary complications such as renal failure, even with today's tight glucose control. Insulin injections minimise diabetic complications but restricts lifestyle and an alternative, pancreatic islet cell transplantation, is limited by donor shortage. With genetic technology, pig donor tissue is a feasible donor source. This project will use an inbred pig colony to assess long term pig fetal and neonatal islet cell function in ....Tragically patients whom suffer from diabetes mellitus develop major secondary complications such as renal failure, even with today's tight glucose control. Insulin injections minimise diabetic complications but restricts lifestyle and an alternative, pancreatic islet cell transplantation, is limited by donor shortage. With genetic technology, pig donor tissue is a feasible donor source. This project will use an inbred pig colony to assess long term pig fetal and neonatal islet cell function in combination with a kidney graft in the absence of an immune response. Using this specifically inbred pig colony we will carefully catalogue the type, number and distribution of endogenous retroviruses within pig genes. Using new and novel techniques we will develop a new strategy by which we can block and overcome this major concern of xenotransplantation. Ultimately a unique Australian resource will be developed which may provide unlimited islets for safe, large-scale transplantation of diabetics before they develop debilitating secondary complications from their diabetes and provide an alternative to the only current method of curing endstage renal failure with a combined pancreas and kidney transplant.Read moreRead less
Apoptotic Pathways In Pancreatic Beta Cells Leading To Type 1 Diabetes And Transplant Rejection
Funder
National Health and Medical Research Council
Funding Amount
$535,333.00
Summary
The destruction of insulin-producing beta cells in the pancreas by immune cells leads to the need for daily insulin injections in patients with type 1 diabetes. This project aims to understand how beta cells are destroyed. A knowledge of the process by which this occurs will indicate ways we can protect these cells. Our previous work has suggested strategies that may protect beta cells, and we aim to test these. Such protection may eventually allow beta cell replacement by transplantation.
Optimising Islet Transplantation With Vascularized Tissue Engineering Chambers
Funder
National Health and Medical Research Council
Funding Amount
$451,651.00
Summary
Diabetics have high blood sugar levels because cells in the pancreas known as islets produce too little of the hormone insulin. Most diabetics need daily insulin injections to maintain normal blood sugar levels. Transplanting islets is the most promising way to treat type 1 diabetes, but, apart from the obvious difficulty of rejection of foreign islets, several major problems remain: (1) there are insufficient pancreata (and therefore islets) for transplantation; and (2) the efficiency of delive ....Diabetics have high blood sugar levels because cells in the pancreas known as islets produce too little of the hormone insulin. Most diabetics need daily insulin injections to maintain normal blood sugar levels. Transplanting islets is the most promising way to treat type 1 diabetes, but, apart from the obvious difficulty of rejection of foreign islets, several major problems remain: (1) there are insufficient pancreata (and therefore islets) for transplantation; and (2) the efficiency of delivery of surviving islet transplants is too low. In pilot studies we have grown a new living pancreatic organ in mice by inserting islets from genetically-related mice together with a structural protein matrix, growth factors and blood vessels inside a plastic chamber. The blood vessels maintain nutrition to the islet cells and simultaneously allow insulin to be released into the bloodstream, thus normalising the high blood sugar in diabetics. In Aim 1 of these experiments we will find the optimal way to grow mature islets in blood vessel-containing chambers in diabetic mice, focusing on (a) the best time to add islets to the chamber - 0, 1 or 2 weeks after establishment, (b) the minimum number of islets to effectively normalise blood sugar and (c) how long we can keep islets alive and functional in chambers, examining periods up to 12 months. In Aim 2 we will test the ability of islet stem cells (provided by our co-investigators at Walter and Eliza Hall Institute, Melbourne) to survive in the chambers and to produce sufficient insulin to effectively lower blood sugar levels to normal in diabetic mice. In Aim 3 we will grow human islets in chambers in special diabetic mice that do not reject foreign tissue, in order to confirm similar behaviour of human islets in this controlled environment. Using this data, we hope to create a research model of functioning islets, that is accessible, retrievable and manipulable, for the further study of diabetes and transplantation.Read moreRead less