Microenvironmental Impact In The Treatment Of Acute Lymphoblastic Leukemia
Funder
National Health and Medical Research Council
Funding Amount
$621,458.00
Summary
Acute lymphoblastic leukemia remains one of the leading causes of death in children and outcomes for adults with this disease remain poor. This project examines how manipulation of the environment where leukemia arises can be used to therpaeutic advancage. Acute lymphoblastic leukemia cells are highly dependent on the support provided by bone marrow cells but the mechanisms are not well understood. Disrupting signals from the bone marrow cells has potential as a therapeutic strategy.
A Clinical Trial Of Partially HLA-matched Unrelated Donor Microtransplantation For Prevention Of Relapse In Patients With Acute Myeloid Leukaemia Ineligible For Standard Haemopoietic Stem Cell Transplantation
Funder
National Health and Medical Research Council
Funding Amount
$154,828.00
Summary
Acute myeloid leukaemia has a poor prognosis in patients unable to undergo bone marrow transplant, in particular in the elderly. No proven therapy improves their poor outcome. There is an urgent need to identify clinically applicable, non-toxic therapies for this group of patients. We will perform a clinical trial of "microtransplantation" using unrelated stem cell donors in combination with chemotherapy to try to reduce the relapse rate in these patients without the toxic effects of standard st ....Acute myeloid leukaemia has a poor prognosis in patients unable to undergo bone marrow transplant, in particular in the elderly. No proven therapy improves their poor outcome. There is an urgent need to identify clinically applicable, non-toxic therapies for this group of patients. We will perform a clinical trial of "microtransplantation" using unrelated stem cell donors in combination with chemotherapy to try to reduce the relapse rate in these patients without the toxic effects of standard stem cell transplantation.Read moreRead less
Niche Regulation Of Normal And Malignant Stem Cells
Funder
National Health and Medical Research Council
Funding Amount
$622,655.00
Summary
Hematopoietic stem cells (HSC) reside in the bone marrow (BM) and make all the cells of the blood system. We study molecules in the BM regulating normal HSC to helping them survive chemotherapy. This means cancer patients should suffer less side-effects from their therapy. Some of these molecule also help leukaemia stem cells (LSC) resist chemotherapy. Inhibitors may a) reduce patient mortality caused by chemotherapy and b) sensitise LSC to chemotherapy enabling long-term cure.
Improving Patient Outcomes In Leukaemia By Targeting Cancer Stem Cells
Funder
National Health and Medical Research Council
Funding Amount
$294,763.00
Summary
Blood cancers such as acute myeloid leukaemia (AML) are among the most deadly types of cancer and new treatments are desperately needed to improve patient’s survival in these diseases. AML cancer-causing stem cells survive by turning on immortalization programs and we hope to specifically kill these AML stem cells by blocking these crucial pathways. This includes things that control the way the cells divide and the way they respond to genetic damage as well as other novel pathways.
Understanding Autophagy In Haematopoiesis And Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$500,813.00
Summary
Blood cancers such as leukaemia are among the most deadly types of cancer and new treatments are desperately needed to improve survival. We have identified a new pathway that is activated when cells undergo stress. This pathway controls the survival of normal blood cells and also appears to be very important in the way cancer cells respond to chemotherapy. We will characterize this pathway in normal blood cells and use this information to develop new treatments to target and eliminate the leukae ....Blood cancers such as leukaemia are among the most deadly types of cancer and new treatments are desperately needed to improve survival. We have identified a new pathway that is activated when cells undergo stress. This pathway controls the survival of normal blood cells and also appears to be very important in the way cancer cells respond to chemotherapy. We will characterize this pathway in normal blood cells and use this information to develop new treatments to target and eliminate the leukaemia cells.Read moreRead less
Modern chemotherapies are designed to exert maximal effect on tumour cells while having minimal side-effects on normal cells. Remarkable advances in our understanding of the molecular biology of cancer has provided possible avenues for more successful targeted cancer treatments. Several crucial interactions between cancer-specific proteins called oncoproteins , occur largely in tumour cells and thus provide ideal targets for intervention. The proposed project is to develop a model system for a t ....Modern chemotherapies are designed to exert maximal effect on tumour cells while having minimal side-effects on normal cells. Remarkable advances in our understanding of the molecular biology of cancer has provided possible avenues for more successful targeted cancer treatments. Several crucial interactions between cancer-specific proteins called oncoproteins , occur largely in tumour cells and thus provide ideal targets for intervention. The proposed project is to develop a model system for a target specific therapy of leukaemia cells by blocking the interactions between oncoproteins. Moreover, the ability to isolate specific blockers of particular protein-protein interactions provides an opportunity to unravel complex genetic pathways in mammalian systems, which are relatively intractable by other analyses. The dissection of pathways using specific blockers may also provide a useful avenue for identifying new drug targets. We have chosen to target particular interactions involving one known oncoprotein in the search for specific inhibitors. A genetic selection will be used to identify random, constrained peptide sequences which are capable of blocking these interactions and which do not interfere with other interactions involving the oncoprotein. This technique allows one to select for or against specific blockers of known interactions from a library containing millions of candidate drug leads in baker's yeast cells. This procedure will be most suitable for high through-put drug screening projects. The validity of this approach to the identification of new peptide drug leads will be finally established in vivo using transgenic models of oncoprotein-dependent cancer in mice.Read moreRead less
Is Hypoxia Inducible Factor 2 The Trigger Of The Angiogenic Switch And A Driver Of Disease Progression In Myeloma?
Funder
National Health and Medical Research Council
Funding Amount
$605,096.00
Summary
Multiple myeloma (MM) is a fatal cancer of plasma cells (PC). PC migrate to the bone marrow, which compared with other organs is low in oxygen (hypoxic). In response to this hypoxia, the cancer cells turn on the expression of genes called hypoxia-inducible factors (HIF). HIFs activate the expression of genes that encourage blood vessel formation, which in turn stimulates greater tumour growth and disease progression. This proposal will investigate the role of HIFs in the progression of MM.
Determining The Transcriptional Programme Of A Leukaemogenic Transcription Factor In Normal And Leukaemic Cells
Funder
National Health and Medical Research Council
Funding Amount
$643,958.00
Summary
Leukaemic (blood cancer) cells develop from immature blood cells by inappropriate expression of genes. These genes are also those that are required for normal blood production in the embryo. Gene expression during normal blood development is tightly controlled. However in leukaemia, these genes are expressed at inappropriate stages of blood development. We will investigate whether leukaemic cells adopt features of embryonic blood stem cells to express genes that convert normal cells into abnorma ....Leukaemic (blood cancer) cells develop from immature blood cells by inappropriate expression of genes. These genes are also those that are required for normal blood production in the embryo. Gene expression during normal blood development is tightly controlled. However in leukaemia, these genes are expressed at inappropriate stages of blood development. We will investigate whether leukaemic cells adopt features of embryonic blood stem cells to express genes that convert normal cells into abnormal cells.Read moreRead less
Klf5 Function In Normal And Leukaemic Haemopoiesis
Funder
National Health and Medical Research Council
Funding Amount
$609,924.00
Summary
Acute Myeloid Leukaemia (AML) is a devastating disease that affects both children and adults. New treatments that target particular genetic abnormalities are urgently needed. We have identified KLF5 as a gene that may control blood cell maturation. In AML patient samples we have found alterations of the KLF5 gene that may suppress its activity and contribute to the formation of leukaemia. These leukaemias may be good candidates for treatment with new drugs called methyltransferase inhibitors.