FOXO Proteins And Protection From Cardiac Ischaemic Injury
Funder
National Health and Medical Research Council
Funding Amount
$354,375.00
Summary
Reduced blood supply to the heart can initiate a heart attack that results in damage to the heart muscle. Loss of muscle tissue under these conditions initiates pathological growth of the heart and can eventually lead to the development of heart failure, a major cause of death and disability in western countries. Treatment with growth factors can prevent the acute damage and loss of cells, but these cause detrimental effects on other tissues. For these reasons, it is necessary to establish ways ....Reduced blood supply to the heart can initiate a heart attack that results in damage to the heart muscle. Loss of muscle tissue under these conditions initiates pathological growth of the heart and can eventually lead to the development of heart failure, a major cause of death and disability in western countries. Treatment with growth factors can prevent the acute damage and loss of cells, but these cause detrimental effects on other tissues. For these reasons, it is necessary to establish ways to activate protective pathways in the heart without causing unwanted effects on other tissues. To this end, we have identified for the first time in the heart members of a newly described family of gene regulators that can cause cell death by increasing expression of cytotoxic factors. We showed that these FKHRor FOXO family members are regulated in the heart and that they are active in generating cytotoxic factors. We now plan to establish whether FOXO proteins are involved in causing cell death during heart attack and whether manipulating their activities can be cardioprotective.Read moreRead less
The Regulation And Role Of Puma And P53 In IL-3 Withdrawal Induced Cell Death
Funder
National Health and Medical Research Council
Funding Amount
$527,683.00
Summary
It is the ultimate fate of most of our cells 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 . When cell death fails to occur, abnormal cells can accumulate and lead to cancer. Signalling from growth-factors is required for many cell types to survive. When these signals are lost, the cells activate their cell death pathways. It is a hallmark of cancer cells that they ha ....It is the ultimate fate of most of our cells 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 . When cell death fails to occur, abnormal cells can accumulate and lead to cancer. Signalling from growth-factors is required for many cell types to survive. When these signals are lost, the cells activate their cell death pathways. It is a hallmark of cancer cells that they harbour mutations in cell death genes and their dependence on growth factors for survival is diminished or lost. The genes of the apoptosis pathway function either to promote or inhibit cell death. 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, and if they are mutated then a functional cell, that is capable of proliferating, survives. This is a crucial distinction because it is only the genes that decide cell fate that can act as cancer genes, and are valid targets for therapy. We have identified one particular gene, Puma, as an important regulator of cell survival. Without this gene, cells survive longer without growth-factor and, importantly, can proliferate when growth factor is restored. Understanding how this gene functions and is regulated will contribute to our understanding of the gene mutations that lead to cancer and may identify valid targets for cancer therapy. In our model we use growth factor dependent cell lines derived from mice lacking particular genes in the cell death pathway, including Puma. These cells proliferate in the presence of growth factor, and allow us to determine the role of the genes when growth factor is withdrawn. Using this system, we will determine how Puma is able to induce cell death, what other genes are required to regulate this process and how loss of Puma function may contribute to cancer development.Read moreRead less
Mitochondria: Molecular And Cellular Insights Into Their Diverse Contributions To Neuronal Injury
Funder
National Health and Medical Research Council
Funding Amount
$747,927.00
Summary
Mitochondria are components of cells normally providing energy for essential functions and in the energy demanding brain, under stress conditions, mitochondria acts as controllers of cellular decision-making processes leading to neuronal death. Our goal is to understand mitochondrial mechanisms determining how neurones die after various stresses and injury. Using pathological insults relevant to neurological conditions, we shall analyse death molecules and how neurones adapt when threatened.
Negative Regulators Of Nuclear Import; Potential Links To Cancer
Funder
National Health and Medical Research Council
Funding Amount
$495,829.00
Summary
Trafficking of proteins into the nucleus is critical to mammalian cell function, relating strongly to developmental processes and cancer. We have identified a new class of molecule - negative regulators of nuclear import - that function to prevent entry into the nucleus of key regulators of the cell cycle-apoptosis, and have a potential link thereby to cancer. We propose to determine their mechanism of action, modulation by cellular signals, and how important this is to cell function-cancer.
The Role Of Hox Genes In Myeloid Cell Development And Myeloid Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$591,286.00
Summary
The transformation of normal white blood cells into leukaemic cells occurs as a result of changes to the genes of those cells. These changes are often characteristic of particular cancers and carry diagnostic and prognostic significance. This work will determine how critical some of the typical genetic changes of leukaemia are to the occurrence and persistence of cancer. Importantly, we will determine whether targeting these changes can provide new and effective approaches to treatment.