Characterising The Mechanisms That Control Blood Cell Development
Funder
National Health and Medical Research Council
Funding Amount
$335,616.00
Summary
Hematopoiesis is a tightly regulated process that provides the body with a constant supply of all the cells of the blood system. My studies aim to characterize the molecular mechanisms that regulate the expansion and differentiation of hematopoietic stem cells (HSCs) into each cell lineage. These studies will be key to the effective use of cellular transplantation therapeutic strategies and aim to provide a greater understanding of the mechanisms that underpin proliferative disorders such as can ....Hematopoiesis is a tightly regulated process that provides the body with a constant supply of all the cells of the blood system. My studies aim to characterize the molecular mechanisms that regulate the expansion and differentiation of hematopoietic stem cells (HSCs) into each cell lineage. These studies will be key to the effective use of cellular transplantation therapeutic strategies and aim to provide a greater understanding of the mechanisms that underpin proliferative disorders such as cancer.Read moreRead less
Tapping The Power Of Pluripotency: The Role Of HMGA1 In Stem Cell Self-renewal And Cell Fate Transitions
Funder
National Health and Medical Research Council
Funding Amount
$520,314.00
Summary
Stem-cell-based therapies have great potential as new treatments for degenerative and genetic diseases. However, to ensure we move in the right direction, we need a detailed understanding of stem cell properties. We have recently identified a novel mechanism for controlling stem-cell-like properties in both normal and cancer stem cells. In this project, we will further investigate this new means of controlling stem cells, which could revolutionise future therapeutic strategies for many diseases.
Revealing How The Mammalian Preimplantation Embryo Undergoes Compaction
Funder
National Health and Medical Research Council
Funding Amount
$705,102.00
Summary
The first morphological process critical for mammalian development is embryo compaction. During compaction, cells change their morphology from rounded to wedge-like. The mechanisms controlling embryo compaction remain unclear. We recently discovered that during compaction, cells extend long membrane protrusions on top of each other. In this Project we will establish the role of these protrusion in controlling embryo compaction and reveal the mechanisms underlying their formation.
The Role Of Sidt2 In Cell Proliferation And Tumour Suppression
Funder
National Health and Medical Research Council
Funding Amount
$531,053.00
Summary
This project seeks to understand the function of a gene known as Sidt2. Our preliminary results suggest that Sidt2 not only controls how normal cells divide but also prevents cancer cell growth. We have now engineered mice that lack Sidt2, and will study the cellular and molecular pathways that are disrupted following loss of Sidt2. This work should provide important insights into how both normal and cancer cells grow, and will hopefully identify new targets for anti-cancer treatment.
Cell death by a specialised process known apoptosis is a way of deleting unwanted and harmful cells from the body. As such, aberrant apoptosis is associated with a wide array of diseases including cancer. For example, abnormal levels of proteins that suppress apoptosis or enhance cell survival can result in cancer and often produce resistance to chemotherapy. To understand and treat cancers that result from aberrant apoptosis we need to know at a molecular level how apoptosis is regulated. Centr ....Cell death by a specialised process known apoptosis is a way of deleting unwanted and harmful cells from the body. As such, aberrant apoptosis is associated with a wide array of diseases including cancer. For example, abnormal levels of proteins that suppress apoptosis or enhance cell survival can result in cancer and often produce resistance to chemotherapy. To understand and treat cancers that result from aberrant apoptosis we need to know at a molecular level how apoptosis is regulated. Central to the apoptosis execution are a group of enzymes called caspases that target many cellular proteins for specific cleavage. In this proposal, we will investigate the function of one of the caspases (called caspase-2), in order to better understand its potential role in the apoptosis of cancer cells. A number of recent reports suggest that caspase-2 levels are reduced in many cancer cells. The human caspase-2 gene localizes to a chromosomal region frequently affected- deleted in leukaemia, and caspase-2 levels have been proposed to be predictors of remission and survival in patients with some types of leukaemia. We will study if loss of caspase-2 in cancer cells makes them resistant to killing by drugs and if mice lacking caspase-2 have an increased potential to develop cancer. Understanding caspase-2 function and its regulation is likely to provide new therapeutic opportunities and potential targets for cancer therapy.Read moreRead less
Defining The Molecular Regulators Of Apoptotic Cell Disassembly And Their Role In Cell Clearance And Lupus-like Autoimmune Disease
Funder
National Health and Medical Research Council
Funding Amount
$773,848.00
Summary
In humans, billions of cells will die daily as part of normal turnover in various organs. It is vital that dying cells are rapidly removed as their accumulation has been linked to autoimmunity and inflammation. To aid efficient removal of dead cells, dying cells can disassemble into smaller fragments for neighbouring cells to engulf. We aim to understand the machinery that controls how dying cells can disassemble into smaller pieces and their function in cell clearance and autoimmunity.
Elucidating The Mechanism And Function Of Cell Disassembly During Apoptosis
Funder
National Health and Medical Research Council
Funding Amount
$425,048.00
Summary
In humans, billions of cells will die daily in various organs as part of normal turnover and disease progression. During cell death, dying cells can disassembly in to smaller fragments, a process that could facilitate their removal, as well as mediate communication with other healthy cells. I aim to understand the machinery that control how dying cells can disassemble into smaller pieces and their function in influenza A infection.
The Role Of The Asymmetric Cell Division Regulator GPSM2 In Mammary Gland Development And Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$647,539.00
Summary
Tissues are built by small populations of progenitor cells which divide unequally to generate different cell types. Recent studies suggest defective progenitor cells are founders of some breast cancers and that progenitor-like cancer cells resist therapy to regenerate tumours. We have shown a progenitor division regulator called GPSM2 controls these cells and inhibits breast cancer. Examination of this new anti-tumour pathway promises to identify therapeutic targets for breast cancer recurrence.
Deciphering The Role Of Scribble In Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$628,789.00
Summary
Scribble is a protein that controls the orientation and organization of all cells within our body. Mutations in the Scribble gene are found in many cancers and also in some patients with spina bifida, however how these mutations cause these diseases is not understood. Here we propose experiments that can be used to link Scribble mutations to specific cellular functions. This information will help us design new therapies to treat diseases driven by tissue disorganization such as cancer.
Apoptosis And Autophagy In Developmentally Programmed Cell Death
Funder
National Health and Medical Research Council
Funding Amount
$502,437.00
Summary
Cell death is essential for sculpting tissues and organs in developing foetus and deregulated cell death results in many diseases. To treat disorders that result from aberrant cell death, we need to understand the control of cell death during development. We will use a vinegar fly model to study cell death modalities in development. By doing this we hope to uncover new knowledge important for human biology and identify new molecules that may be important for understanding and treating disease.