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They aim to create insulin-secreting B cells by identifying their progenitor cells and the moleculaes normally required for their development, in order to restore B-cell function in the people with type 1 diabetes. Mouse and human multipotent embryonic stem (ES) cells and fetal mouse panceas and adult pancreas duct cells will be used as sources of progenitor B cells. Comparative studies will provide a more complete picture of human B-cell ontogeny. Culture systems developed for ES cells-embryoid ....They aim to create insulin-secreting B cells by identifying their progenitor cells and the moleculaes normally required for their development, in order to restore B-cell function in the people with type 1 diabetes. Mouse and human multipotent embryonic stem (ES) cells and fetal mouse panceas and adult pancreas duct cells will be used as sources of progenitor B cells. Comparative studies will provide a more complete picture of human B-cell ontogeny. Culture systems developed for ES cells-embryoid bodies (EB) - EB-derived cells, fetal pancreas and adult pancreas duct cells, will be employed to screen for and identify novel growth-differentiation factors and to optimise parameters for creating B cells in vitro or (re) generating B cells in vivo. Genetic constructs allowing regulated expression of fluorescently-tagged marker genes and growth-transcription factors will be introduced into cultured cells or transgenic mice to enable progenitor B cells to be tracked and isolated. Progenitor B cells will be typed with panels of known novel markers molecules at the gene and protein level, and gene expression profiles of tissue yielding B cells will be analysed across time to reveal further candidate markers. Molecules and methods effective in mouse systems will be applied to human ES cell-derived or pancreatic duct cells. The capacity to progenitor cells or insulin-secreting cells to ameliorate diabetes when transplanted into the testis, under the kidney capsule or into the pancreas of mouse models would represent proof-of-concept. Functional B cells derived from human ERS cells or pancreas duct cells, or growth factors that regenerate B cells in vivo, could together with appropriate immunotherapy restore B-cell function in people with type 1 diabetes.Read moreRead less
Derivation Of Pancreatic Beta Cells From Embryonic Stem Cells
Funder
National Health and Medical Research Council
Funding Amount
$2,968,050.00
Summary
People with type 1 diabetes require regular insulin injections because the organ that normally makes insulin, the pancreas, no longer functions. The goal of this program is to derive human fetal pancreas tissues from embryonic stem cells. Such tissue could be used to replace the missing insulin producing cells in people with type 1 diabetes. The program brings together expertise in ES cell biology at Monash University and the leading diabetes research at the Walter and Eliza Hall Institute.
Gamma-ray Inactivated Influenza A Virus Vaccine For Cross-protective T Cell Immunity
Funder
National Health and Medical Research Council
Funding Amount
$239,963.00
Summary
Although there are new antiviral drugs that appear to be effective against influenza virus, the far more costeffective and efficient means to combat an influenza pandemic would be by vaccination. Current influenza vaccines employ virus preparations that are inactivated by chemical treatment. The inactivated vaccines, which function mostly by inducing antibody against the virus, have to be reformulated almost every year to take account of the changing virus because the antibodies recognize the vi ....Although there are new antiviral drugs that appear to be effective against influenza virus, the far more costeffective and efficient means to combat an influenza pandemic would be by vaccination. Current influenza vaccines employ virus preparations that are inactivated by chemical treatment. The inactivated vaccines, which function mostly by inducing antibody against the virus, have to be reformulated almost every year to take account of the changing virus because the antibodies recognize the viral surface which is prone to mutation. Accordingly, in terms of the threatening H5N1 avian influenza pandemic, it is not known if an inactivated vaccine based on the circulating H5N1 strain will be effective if the virus mutates to adapt to efficient growth and spread in the human population. In contrast to the antibody response against influenza virus, the cytotoxic T cell response is broadly crossreactive between heterologous influenza virus strains. Live virus infection efficiently induces cytotoxic T cell immunity which plays an important role in reducing disease severity and mortality following infection with a second, heterologous influenza virus, although infection per se is not prevented. Accordingly, vaccination strategies that elicit cytotoxic T cell memory should be given urgent consideration in the preparation against an influenza pandemic. We have found that the use of gamma-irradiation (in contrast to chemical treatment) for the preparation of inactivated experimental vaccines against influenza and other viruses does not destroy the ability of the vaccines to elicit cytotoxic T cell immunity. The gamma-ray inactivated vaccines conferred protection against lethal challenge with heterologous influenza virus strains in mice. This proposal is aimed at extending this novel finding to avian influenza viruses and to uncover the mechanisms involved in the cytotoxic T cell immunogenicity of gamma-ray inactivated vaccines.Read moreRead less
This study will examine cellular immunity to the avian H5 influenza in people who have been previously infected with the currently circulating strains of H1 and H3 influenza, or in those who have been recently vaccinated with current influenza vaccines. This will give us an idea if there is any cross reactive immunity that may assist in developing immunity to pandemic strains of avian influenza, or may provide help in making antibody responses sooner to avian influenza vaccines once they are dev ....This study will examine cellular immunity to the avian H5 influenza in people who have been previously infected with the currently circulating strains of H1 and H3 influenza, or in those who have been recently vaccinated with current influenza vaccines. This will give us an idea if there is any cross reactive immunity that may assist in developing immunity to pandemic strains of avian influenza, or may provide help in making antibody responses sooner to avian influenza vaccines once they are developed. We will also establish assays to determine how immunogenic some new avian influenza vaccines are in mice.Read moreRead less
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
Retroviral Expression Cloning Using An Arrayed Full Length CDNA Gene Set
Funder
National Health and Medical Research Council
Funding Amount
$1,841,500.00
Summary
The sequencing of the human genome has revealed the blueprint for life, but the identities and-or functions of the majority of genes remain unknown. Here we propose to establish a radically modified retroviral expression cloning system that will, in principle, allow identification of all genes that confer a particular dominant phenotype. To do this we will establish an arrayed retroviral library of sequence-verified genes covering the entire human transcriptome. This technology will be used to i ....The sequencing of the human genome has revealed the blueprint for life, but the identities and-or functions of the majority of genes remain unknown. Here we propose to establish a radically modified retroviral expression cloning system that will, in principle, allow identification of all genes that confer a particular dominant phenotype. To do this we will establish an arrayed retroviral library of sequence-verified genes covering the entire human transcriptome. This technology will be used to identify genes involved in a wide range of medically-important biological processes.Read moreRead less