De-differentiation Of Committed Cells Into Haematopoietic Stem Cells By The Instructive Role Of The Transcription Factor HOXB4
Funder
National Health and Medical Research Council
Funding Amount
$683,040.00
Summary
Blood stem cells are long-lived and can give rise to every cell type of the blood system and due to these properties they are currently used in the clinics. Despite their importance, our knowledge of the mechanisms the control the multiplication of these rare cells is very scarce. This proposal aims to identify key factors that have the potential to convert mature, easy available blood cells into stem cells. This knowledge has to potential to lead to novel system that allow the expansion of stem ....Blood stem cells are long-lived and can give rise to every cell type of the blood system and due to these properties they are currently used in the clinics. Despite their importance, our knowledge of the mechanisms the control the multiplication of these rare cells is very scarce. This proposal aims to identify key factors that have the potential to convert mature, easy available blood cells into stem cells. This knowledge has to potential to lead to novel system that allow the expansion of stem cells for transplantations in the future.Read moreRead less
Revealing How Transcription Factors Search The DNA To Control Preimplantation Development In Mammals
Funder
National Health and Medical Research Council
Funding Amount
$605,251.00
Summary
The development of mammalian embryos relies on proteins that bind to DNA to activate different genes. While several proteins regulating genes during embryonic development have been identified, it remains unknown how these proteins find their specific DNA targets. We will apply new non-invasive methods to analyse the movement of DNA–binding proteins in intact mouse embryos undergoing normal development, and will determine the molecular mechanisms that control DNA–protein interactions.
Regulation Of TNF Expression In Inflammation And Cancer
Funder
National Health and Medical Research Council
Funding Amount
$728,447.00
Summary
By studying a spontaneous mutation in mice, we have found an error in the TNF gene (a major factor in many inflammatory diseases) that causes severe arthritis, heart valve disease and gut inflammation. We have also identified new regulators of TNF expression, which might be useful therapeutic targets to limit inflammation. We intend to study the role of these regulators in controlling the expression of TNF, and the link between chronic inflammation and the development of cancer.
The Role Of MOZ In The Development Of The Hematopoietic System, Spleen And Thymus
Funder
National Health and Medical Research Council
Funding Amount
$324,375.00
Summary
Current treatment of leukaemia in adults is unsatisfactory with the majority of patients dying. In the past most treatments for cancer have been empirical, that is a particular drug has been found to be effective by trial and error rather than a process of rational design. In order to improve the rate at which effective treatments for leukaemia are found it is necessary to understand how hematopoiesis is regulated and what the critical points are where things can go wrong, leading to cancer. Som ....Current treatment of leukaemia in adults is unsatisfactory with the majority of patients dying. In the past most treatments for cancer have been empirical, that is a particular drug has been found to be effective by trial and error rather than a process of rational design. In order to improve the rate at which effective treatments for leukaemia are found it is necessary to understand how hematopoiesis is regulated and what the critical points are where things can go wrong, leading to cancer. Some genes are commonly found to be mutated in leukaemia. Clearly these genes are involved in some key aspect of regulation of hematopoiesis. We are studying one of these genes, MOZ, which is mutated in acute myeloid leukaemia. The purpose of this grant is to determine what the normal function of this gene is. One of the most promising new treatments for leukaemia is directly targeting the regulation of gene expression inside the cell. MOZ is one of the proteins, which regulates gene expression in hematopoiesis and controls the differentiation of different types of blood cells. One of the possible effects of these new types of anticancer drugs is to accentuate the normal function of MOZ. However, at the moment we don't know what the normal function of MOZ is so it is impossible to test this prediction. If we know which pathways controlling blood formation MOZ is acting in it may be possible, in the future, to use this information to improve on the current anti cancer drugs in a more directed way than has been possible in the past.Read moreRead less
Defining The Role Of VEGF And Vascular Formation In Craniofacial Development
Funder
National Health and Medical Research Council
Funding Amount
$636,417.00
Summary
Aberrant neural crest cell development gives rise to common congenital malformations such as cleft lip and/or palate and cardiac outflow tract defects that effect over 1% of all births. As the aetiology of these disorders are largely unknown it is critical to understand the cell and molecular mechanisms coordinating NCC development such that alternative therapies may be devised to target the underlying pathological defects and to provide definitive diagnostic / prognostic tools.
The Role Of Necroptosis In Inflammatory Skin Diseases
Funder
National Health and Medical Research Council
Funding Amount
$548,690.00
Summary
Diseases associated with exaggerated inflammation account for a large toll of human disease. We have recently described how mice with a mutation in the Sharpin gene, that causes the chronic proliferative dermatitis phenotype (cpdm), can be rescued by crossing these mice to TNF (Tumor Necrosis Factor) knock-out mice. Our findings suggest that TNF induced cell death, rather than TNF induced cytokine production, may be at the root of many inflammatory diseases and we aim to test this hypothesis in ....Diseases associated with exaggerated inflammation account for a large toll of human disease. We have recently described how mice with a mutation in the Sharpin gene, that causes the chronic proliferative dermatitis phenotype (cpdm), can be rescued by crossing these mice to TNF (Tumor Necrosis Factor) knock-out mice. Our findings suggest that TNF induced cell death, rather than TNF induced cytokine production, may be at the root of many inflammatory diseases and we aim to test this hypothesis in this proposal.Read moreRead less
Blimp-1: A Master Regulator Of B-lymphocyte Terminal Differentiation?
Funder
National Health and Medical Research Council
Funding Amount
$154,250.00
Summary
B lymphocytes are the antibody-producing cells of the immune system. They are formed in the bone marrow, and are exported to the body to circulate, searching for signs of infection. These circulating cells are not fully mature, but when they encounter an invader, with the help of other immune cells, they change. Most become antibody-producing cells, the final, operational cells of the B cell lineage. A few cells are set aside as memory cells that can rapidly become antibody-producing cells shoul ....B lymphocytes are the antibody-producing cells of the immune system. They are formed in the bone marrow, and are exported to the body to circulate, searching for signs of infection. These circulating cells are not fully mature, but when they encounter an invader, with the help of other immune cells, they change. Most become antibody-producing cells, the final, operational cells of the B cell lineage. A few cells are set aside as memory cells that can rapidly become antibody-producing cells should the same infection occur again. This is the basis of vaccination. The secretion of antibodies into the serum (that can bind to and eliminate an invader anywhere in the body) is the main function of B lymphocytes. This project will study the genes that allow B cells to become antibody-secreting cells (called ASC). We will focus on the gene for Blimp-1, the B lymphocyte-induced maturation protein, which has been called the master regulator of ASC formation. This claim is based largely on circumstantial evidence, and has not been directly tested genetically. We have made a mouse in which the Blimp-1 gene has been altered so that we can disable it in carefully controlled way. Using this knockout mouse, we can directly test the requirement for Blimp-1 in ASC and in other cell types. We will study these animals, using many tests that can accurately measure the behaviour of isolated cells, or the immune responses of the animals. We will examine other genes that are thought to be required for ASC to form or to perform their work, to see if loss of Blimp-1 (a known gene silencer) has impacted on these other genes. In this way, we expect to identify the genetic program that drives a B cell to become a mature ASC. Using this knowledge, we hope eventually to be able to study diseases of ASC in humans (as occur in allergy, asthma, rheumatoid arthritis and leukaemia). This information may also be used to improve the outcome of vaccination.Read moreRead less
Genetic Analysis Of Cell Death Pathways, Drug Resistance And Oncogenic Co-operativity In IL-3 Dependent Cell Lines
Funder
National Health and Medical Research Council
Funding Amount
$445,270.00
Summary
The ultimate fate of most of our cells is to die by committing suicide, because they are no longer required, are no longer functioning, or are potentially harmful. This normal physiological process is termed apoptosis . Inappropriate apoptosis can contribute to cell loss following heart attacks, stroke or neurodegenerative diseases, such as Alzheimer s or Parkinson s disease. Conversely, when cell death fails to occur, abnormal cells can accumulate and lead to cancer. In addition, because drugs ....The ultimate fate of most of our cells is to die by committing suicide, because they are no longer required, are no longer functioning, or are potentially harmful. This normal physiological process is termed apoptosis . Inappropriate apoptosis can contribute to cell loss following heart attacks, stroke or neurodegenerative diseases, such as Alzheimer s or Parkinson s disease. Conversely, when cell death fails to occur, abnormal cells can accumulate and lead to cancer. In addition, because drugs that are used to treat cancer may exert their effect by inducing apoptosis, a failure of this suicide response may cause resistance to chemotherapy. The genes of the apoptosis pathway function either to promote or inhibit cell death. We have found that some genes in the apoptosis pathway allow apoptosis to proceed rapidly, but do not decide the fate of the cell. Other genes are required for a cell to commit to die. If these genes are mutated then apoptosis does not occur and a functional cell may survive. The distinction between cells that decide fate and those that do not is crucial because it is only the genes that decide cell fate that can act as cancer genes, and are valid targets for therapy. We use a model in which apoptosis is caused by removal of a growth factor, using cell lines derived from mice that lack particular genes in the cell death pathway. These cells proliferate normally in the presence of growth factor, and allow us to determine the role of the genes when growth factor is withdrawn. Because these cells are sensitive to chemotherapeutic drugs, we can also determine the contribution these genes make to cancer drug sensitivity. Using this system, we have discovered that Puma, a gene known to be required for apoptosis in response to radiation, is also a critical activator of apoptosis following growth factor withdrawal. We will determine the manner in which Puma is regulated by growth factors, as well as identify and characterise other key components.Read moreRead less
Determining The Role Of Rel/NF-kB Transcription Factors In Myeloid Differentiation
Funder
National Health and Medical Research Council
Funding Amount
$500,944.00
Summary
Different types of mature blood cells arise from stem cells in a process involving changes in gene expression that dictate which types of blood cells ultimately develop. A family of gene regulatory proteins called NF-kB transcription factors has been found to control the pattern of gene expression in a particular blood cell precursor called a granulocyte macrophage precursor (GMP) that normally generates two types of mature blood cells called macrophages and neutrophils. In the absence of NF-kB ....Different types of mature blood cells arise from stem cells in a process involving changes in gene expression that dictate which types of blood cells ultimately develop. A family of gene regulatory proteins called NF-kB transcription factors has been found to control the pattern of gene expression in a particular blood cell precursor called a granulocyte macrophage precursor (GMP) that normally generates two types of mature blood cells called macrophages and neutrophils. In the absence of NF-kB proteins, a change in the pattern of gene expression in GMPs leads to an imbalance in production of these two blood cell types that now favours the generation of neutrophils. This work will provide insight into the molecular mechanisms of blood cell development regulated by NF-kB. With disturbances in the balance of blood cell formation representing a hallmark of leukemia, understanding how this process is normally controlled may have important implications for developing therapeutic strategies to combat various types of leukemias.Read moreRead less