I am a molecular geneticist dissecting the regulation of hematopoiesis. My lab is primarily concerned with the development and function of the megakaryocytic lineage, from hematopoietic stem cells, through to committed progenitors, megakaryocytes and thei
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
STUDIES OF NF-E4, A NOVEL FETAL/ERYTHROID SPECIFIC FACTOR INVOLVED IN FETAL GLOBIN GENE REGULATION
Funder
National Health and Medical Research Council
Funding Amount
$753,810.00
Summary
Sickle cell anemia and thalassemia are the commonest genetic disorders worldwide. Those affected suffer devastating clinical sequelae and mortality in the first twenty years of life remains high. A cure for these diseases is dependent on the replacement of the affected or absent hemoglobin protein chains with normally functioning hemoglobins. This is evident in rare patients who co-inherit a natural mutation which elevates fetal hemoglobin (HbF), as these patients have a dramatically ameliorated ....Sickle cell anemia and thalassemia are the commonest genetic disorders worldwide. Those affected suffer devastating clinical sequelae and mortality in the first twenty years of life remains high. A cure for these diseases is dependent on the replacement of the affected or absent hemoglobin protein chains with normally functioning hemoglobins. This is evident in rare patients who co-inherit a natural mutation which elevates fetal hemoglobin (HbF), as these patients have a dramatically ameliorated clinical course. Therefore, treatment strategies which could reactivate fetal globin gene expression after birth should be explored for these diseases. To achieve this goal we must further our understanding of the normal mechanisms of developmental regulation of globin gene expression. To this end we have recently identified a novel gene which is critical for fetal globin expression. The studies we propose here will further define the function of this gene and assess its potential for gene therapy for sickle cell disease and thalassemia.Read moreRead less
An Analysis Of The Lyn Tyrosine Kinase In The Regulation Of Hematopoiesis And Tumourigenesis.
Funder
National Health and Medical Research Council
Funding Amount
$381,000.00
Summary
The Lyn kinase is an enzyme that is involved in relaying information across the cell membrane. It is a member of a family of genes that have been implicated in tumour development. Lyn is expressed in blood cells and it is involved in a variety of immunological responses. To further our understanding of the role of this enzyme in the context of the whole animal, we have generated two strains of mice, one that is unable to make Lyn protein (Lyn-deficient mice) and one that expresses an activated f ....The Lyn kinase is an enzyme that is involved in relaying information across the cell membrane. It is a member of a family of genes that have been implicated in tumour development. Lyn is expressed in blood cells and it is involved in a variety of immunological responses. To further our understanding of the role of this enzyme in the context of the whole animal, we have generated two strains of mice, one that is unable to make Lyn protein (Lyn-deficient mice) and one that expresses an activated form of the Lyn enzyme (Lyn-up mice). Our previous studies have shown that Lyn-deficient mice have enhanced blood cell formation (hematopoiesis) and develop white blood cell tumours with age, whereas Lyn-up mice show no propensity to develop tumours. In this study we will examine in detail the role that Lyn plays in blood cell formation and tumourigenesis, and we will identify the pathways that underlie the phenotypes in Lyn-deficient mice. On completion of these studies we will have catalogued the molecules and pathways regulated by Lyn, and have an understanding of how Lyn functions in regulating development of specific populations of blood cells, and in suppressing or promoting tumour development.Read moreRead less
The Characterization Of A Novel Pseudokinase Regulator Of Platelet Formation
Funder
National Health and Medical Research Council
Funding Amount
$372,965.00
Summary
Mammalian cells contain a complex switchboard, which directs the cell to grow, die, multiply or move in response to external cues. When communication breaks down within the cell, diseases arise. Our studies are directed towards identifying the molecules that comprise the switchboard which directs blood cell formation. A detailed understanding of the regulators of blood cell formation will equip us with a sound starting point for designing drugs to ameliorate blood diseases.
Mature red cells develop from hemopoietic stem cells in the adult bone marrow. The production of red blood cells is primarily controlled by the hormone erythropoietin (Epo). Previously we had identified that the protein Lyn must be present inside primitive red blood cells for Epo to stimulate them to become mature functional cells. We will determine the role of several molecules that interact with Lyn including Cbp, Liar and LACM, towards apects of red blood cell development.
CXCR4 Antagonists In Acute Lymphoblastic Leukemias In NOD/SCID Mice
Funder
National Health and Medical Research Council
Funding Amount
$505,500.00
Summary
Acute lymphoblastic leukemia (ALL) is the most common form of childhood cancer and a major cause of death in children. Although ALL is usually responsive to chemotherapy, about 25% of children and 65% of adults with ALL develop a relapse of their disease. The majority of these patients will die of leukemia. New approaches to the treatment of ALL are necessary to obtain cures for these patients. We have identified stromal-derived factor (SDF)-1 as a major regulator of ALL cell growth and survival ....Acute lymphoblastic leukemia (ALL) is the most common form of childhood cancer and a major cause of death in children. Although ALL is usually responsive to chemotherapy, about 25% of children and 65% of adults with ALL develop a relapse of their disease. The majority of these patients will die of leukemia. New approaches to the treatment of ALL are necessary to obtain cures for these patients. We have identified stromal-derived factor (SDF)-1 as a major regulator of ALL cell growth and survival. It is currently the only known factor that significantly stimulates the growth-survival of cells from the majority of patients with ALL. Specific antagonists of the SDF-1 receptor, CXCR4, are available. Depriving ALL cells of SDF-1 by the use of these antagonists provides a radically new approach for the treatment of ALL. CXCR4 antagonists also increase the susceptibility of ALL cells to cytotoxic drugs. The mechanisms by which SDF-1 promotes ALL cell growth and survival are not known but appear to be largely due to synergistic interactions with other molecules that have little or no effect on their own. Knowledge of the underlying mechanisms of action of SDF-1 and the factors with which it synergises will facilitate for the further development of this approach. This project will examine the modulation of the expression of proteins that regulate ALL cell growth and survival by CXCR4 antagonists, providing insights into how CXCR4 antagonists work. This project will also extend our encouraging data obtained using tissue culture to an animal model of leukemia. The antagonists will be tested in isolation and in combination with currently used chemotherapy agents. It is expected that CXCR4 antagonists will inhibit the growth of ALL cells and increase their sensitivity to chemotherapy agents in the animal model as we have seen in laboratory culture. The addition of CXCR4 antagonists to current treatment protocols is expected to significantly improve the outcome for patients.Read moreRead less