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Manipulation Of Haematopoietic Stem Cell Niches To Improve Their Clinical Use
Funder
National Health and Medical Research Council
Funding Amount
$434,883.00
Summary
Haematopoietic stem cells (HSC) reside in adult bone marrow (BM) and make all blood and immune cells. HSCs can be damaged by chemotherapy leading to blood and BM failure. We have identified an adhesion molecule in the BM which regulates HSC behaviour. We anticipate that inhibiting this molecule will i) help minimise HSC damage during chemotherapy and ii) enhance the success of BM transplantation.
Macrophages are a key component of the immune system; thier functions include killing of pathogens as well as cancerous cells. Macrophage lineage cells are derived from stem cells within the bone marrow and thier differentiation, proliferation and survival is mediated by a particular growth factor termed colony stimulating factor-1 (CSF-1). The understanding of how macrophage lineage cells develop will help us to treat many diseases including certain cancers (such as leukemia), arthritis and inf ....Macrophages are a key component of the immune system; thier functions include killing of pathogens as well as cancerous cells. Macrophage lineage cells are derived from stem cells within the bone marrow and thier differentiation, proliferation and survival is mediated by a particular growth factor termed colony stimulating factor-1 (CSF-1). The understanding of how macrophage lineage cells develop will help us to treat many diseases including certain cancers (such as leukemia), arthritis and inflammation, and disorders of the immune system. The action of CSF-1 is mediated by the CSF-1 receptor (CSF-1R) which, when activated, controls gene regulation. In this proposal we will study CSF-1R activation and identify the genes regulated by CSF-1 with a view to characterize genes critical for macrophage development. These genes may provide potential targets for new pharmacological agents.Read moreRead less
Characterisation Of Human Embryonic Stem Cell Differentiation To Haematopoietic Progenitors And Stem Cells
Funder
National Health and Medical Research Council
Funding Amount
$638,856.00
Summary
Blood stem cells, which are found in the bone marrow, are currently used for treating human blood disorders including leukemia and lymphoma. However, for the majority of bone marrow transplant candidates, suitable donors cannot be found. Using embryonic stem cells, this project aims to define the conditions required to generate blood stem cells in the laboratory. The aim of the work is to provide a new source of blood stem cells that could be used in place of donor derived bone marrow.
Gene Therapy, Stress Haematopoiesis And The Risk Of Malignancy
Funder
National Health and Medical Research Council
Funding Amount
$617,354.00
Summary
The immense potential of gene therapy has been confirmed by the successful treatment of immune deficiencies disorders. A key issue that has emerged however is the need to avoid potentially cancer-causing genetic damage to cells undergoing repair. Some of this risk can be linked to the gene repair technology used, but we have identified and propose to investigate another potentially important mechanism involving the unusually high levels of replication imposed on cells during disease correction.
The Developmental Hierarchy Of Haemopoietic Lineage Relationships
Funder
National Health and Medical Research Council
Funding Amount
$192,000.00
Summary
The blood cells are all the progeny of a very rare stem cell, that is thought to reside in the bone marrow. The stem cell maintains itself throughout the life span of the individual as well as generating the billions of more mature cell types required in the blood. However the processes and stages that immature cells pass through from the stem cell to ultimately a mature functional blood cell such as a lymphocyte remain disputed. This study aims to determine to relationship of the various blood ....The blood cells are all the progeny of a very rare stem cell, that is thought to reside in the bone marrow. The stem cell maintains itself throughout the life span of the individual as well as generating the billions of more mature cell types required in the blood. However the processes and stages that immature cells pass through from the stem cell to ultimately a mature functional blood cell such as a lymphocyte remain disputed. This study aims to determine to relationship of the various blood cell progeny with each other and thus to provide a lineage map of the system. To do this we will isolate precursors at various stages along the developmental pathways and determine their capabilities to produce the normal range of progeny. We will then use a number of genetically altered mouse strains to assess the genes involved in this process. These studies will help provide an underlying scientific basis to the attempts to development a number of stem cell therapies that are aimed at boosting or directing stem cell production in procedures such as bone marrow transplantation for leukemia and immune deficiency. In addition a number of characterized human blood malignancies seem to have developed along aberrant pathways indicating that inappropriate lineage specification may be a factor in cancer.Read moreRead less
Approaches To Allogeneic Chimerism For The Induction Of Transplantation Tolerance
Funder
National Health and Medical Research Council
Funding Amount
$212,036.00
Summary
All patients with organ failure who receive a transplant require lifelong immunosuppressive medications to prevent the body from rejecting the foreign tissue. Indefinite immunosuppressive therapy is associated with significant side-effects which include infections and cancers. In addition, long-term loss of the transplants due to slow rejection (chronic rejection) remains high. Achieving a state of immunological tolerance in which transplanted tissue is regarded as self, but reactivity to all ot ....All patients with organ failure who receive a transplant require lifelong immunosuppressive medications to prevent the body from rejecting the foreign tissue. Indefinite immunosuppressive therapy is associated with significant side-effects which include infections and cancers. In addition, long-term loss of the transplants due to slow rejection (chronic rejection) remains high. Achieving a state of immunological tolerance in which transplanted tissue is regarded as self, but reactivity to all other foreign tissues (e.g. harmful viruses, bacteria) remain normal, would solve all these problems. Tolerance would eliminate the need for immunosuppressive medications and prevent rejection of transplanted organs. The production of mixed bone marrow chimerism is a potent method of inducing tolerance. Chimerism is a state in which bone marrow tissue from two genetically different individuals coexists in one person. This can be achieved by bone marrow transplantation from a specific donor, and if chimerism is achieved, the recipient will accept all tissues from the bone marrow donor without the need for ongoing immunosuppressive therapy. This study will attempt to examine the use of different therapeutic reagents (e.g. antibodies alone or antibodies linked to idarubicin, a drug which prevent cells dividing) to develop safe protocols for the production of bone marrow chimerism and tolerance for routine clinical use in humans. The study will also examine different cellular components of the donor bone marrow which may induce tolerance.Read moreRead less
All cells in the blood are the descendants of a single cell type, the stem cell. Stem cells are found in the bone marrow and throughout life have the unique ability to generate more of themselves (termed self-renewal) as well as to produce the functional cell types of the blood, ie. red and white blood cells. This project concentrates on the processes by which these stem cells can achieve these two functions. What are the genes that enable a stem cell to have this self-renewal characteristic and ....All cells in the blood are the descendants of a single cell type, the stem cell. Stem cells are found in the bone marrow and throughout life have the unique ability to generate more of themselves (termed self-renewal) as well as to produce the functional cell types of the blood, ie. red and white blood cells. This project concentrates on the processes by which these stem cells can achieve these two functions. What are the genes that enable a stem cell to have this self-renewal characteristic and conversely what are the genes that are activated when a cell becomes committed to become, for example, a white blood cell ? We have identified a gene, Pax5, which is essential in the process whereby a stem cell commits to become a lymphocyte . Our aim is to understand the function of Pax5 as a model for understanding how the commitment process as a whole works in the blood. These studies, as well as having an underlying fundamental scientific importance, are relevant to the clinical development of a number of stem cell therapies which rely on boosting stem cell production in procedures such as bone marrow transplantation for leukaemia and immune deficiency. In addition a number of characterised human blood malignancies indicate that inappropriate lineage commitment may be a factor in cancer.Read moreRead less
The Molecular Mechanisms Controlling Maintenance Of Osteogenic Precursor Cells And Skeletal Tissue Regeneration
Funder
National Health and Medical Research Council
Funding Amount
$234,750.00
Summary
Within human bone marrow there exists a rare population of bone marrow stromal stem cells (BMSSCs) able to develop into the different cell types that form haematopoietic supportive stroma and surrounding skeletal tissue. There has been alot of interest of late in the potential of BMSSCs as a cellular based therapy to treat and manage bone fractures or bone loss caused by disease. Increasing evidence suggests that decreased bone mass due to osteoporosis dos not purely result in an increase of bon ....Within human bone marrow there exists a rare population of bone marrow stromal stem cells (BMSSCs) able to develop into the different cell types that form haematopoietic supportive stroma and surrounding skeletal tissue. There has been alot of interest of late in the potential of BMSSCs as a cellular based therapy to treat and manage bone fractures or bone loss caused by disease. Increasing evidence suggests that decreased bone mass due to osteoporosis dos not purely result in an increase of bone resorption by osteoclasts, but may also occur through a decline in the number of bone forming cells called osteoblasts or their progenitors. Fracture non-union, prosthetic loosening and the replacement of large defects in bone are common and difficult problems. The use of autologous bone cells generated from isolated BMSSCs in combination with bio-compatible implant materials would provide a novel solution for the treatment of these problems, avoiding the use of autografts and allografts of bone with all their associated difficulties. However, large numbers of ex vivo expanded BMSSCs are currently required to heal even small bone defects in animal models. This is compounded by the decline in proliferation rates and bone forming capacity of BMSSCs during prolonged expansion in culture. An improved understanding of the genes that regulate the proliferation and differentiation of BMSSCs in vitro is therefore an essential prerequisite for the effective management of bone fracture and bone loss. We propose to genetically manipulate the expression of genes in BMSSCs, that are known to regulate cellular growth and development inorder to maintain the growth of stem cell populations in vitro and to extend their capacity to form bone when transplanted in vivo.Read moreRead less
The Role Of TWIST Family Basic Helix-Loop-Helix Transcription Factors In Bone Cell Commitment, Function And Repair
Funder
National Health and Medical Research Council
Funding Amount
$485,928.00
Summary
In developed countries, projected estimates predict an alarming trend of a two to three fold increase in the number of fractures that require surgical intervention and rehabilitation therapy in the coming decades as a consequence of an aging population. Fracture healing is a complex physiological process that involves the coordinated participation of different bone marrow cells, immune cells and skeletal progenitor cells. Multiple factors regulate interactions between these cell types that influ ....In developed countries, projected estimates predict an alarming trend of a two to three fold increase in the number of fractures that require surgical intervention and rehabilitation therapy in the coming decades as a consequence of an aging population. Fracture healing is a complex physiological process that involves the coordinated participation of different bone marrow cells, immune cells and skeletal progenitor cells. Multiple factors regulate interactions between these cell types that influence the capacity of bone cell progenitors to develop into functional bone forming cells known as osteoblasts. An understanding of the fracture healing is critical for the future advancement of fracture treatment, and for identifying the mechanisms of skeletal growth and repair as well as the causes of aging and disease. This proposal seeks to identify critical regulatory molecules that act to mediate bone cell progenitor recruitment and development during bone fracture repair.Read moreRead less