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.
Deciphering The Function Of Caspase-2 In DNA Damage Response And Tumour Suppression
Funder
National Health and Medical Research Council
Funding Amount
$808,007.00
Summary
Aberrant cell death and DNA damage response (DDR) are hallmarks of tumourigenesis. Recently we have discovered that an enzyme, caspase-2, previously implicated in cell death execution, also works in DDR and acts as a tumour suppressor. We now wish to validate these finding in preclinical models of cancer and understand precisely how caspase-2 safeguards against cancer development. These studies will help better understand tumourigenesis and may lead to the discovery of new drug targets.
Investigating The Contribution Of Distinct Mitochondrial Cell Death Pathways To Platelet Survival And Function
Funder
National Health and Medical Research Council
Funding Amount
$635,247.00
Summary
Platelets are small blood cells that form clots to stop bleeding. We have found new and unexpected roles for 2 distinct pathways that regulate cell death in the process of blood clot formation. We will study the precise role of these pathways in blood clot formation, and determine whether they may also regulate the survival of platelets stored by the blood bank for transfusion. These studies will provide new insight into the role of cell death pathways in blood clot formation, and may help to im ....Platelets are small blood cells that form clots to stop bleeding. We have found new and unexpected roles for 2 distinct pathways that regulate cell death in the process of blood clot formation. We will study the precise role of these pathways in blood clot formation, and determine whether they may also regulate the survival of platelets stored by the blood bank for transfusion. These studies will provide new insight into the role of cell death pathways in blood clot formation, and may help to improve current protocols for storing plateletsRead moreRead less
Understanding The Activation Of Pro-apoptotic Bcl-2 Family Proteins For The Development Of Modulators Of Apoptosis
Funder
National Health and Medical Research Council
Funding Amount
$627,805.00
Summary
Programmed cell death is a process by which the body protects against rogue cells, eg cells potentially cancerous or infected by viruses. Dysregulation of the process occurs in cancer and can also lead to degenerative diseases. This work will discover the molecular mechanisms by which key proteins control the life/death switch in cells and will develop compounds capable of regulating their activity, setting the foundation for developing therapeutics aimed at regulating these processes.
Understanding How Bcl-2 Proteins Form The Apoptotic Pores That Kill Cells
Funder
National Health and Medical Research Council
Funding Amount
$893,614.00
Summary
Programmed cell death termed apoptosis is a process our bodies use to remove cells that are a threat to our health, e.g. cancer cells. The proteins that regulate cell death are attractive targets for therapeutics that have become resistant to this defence mechanism. This study will reveal how proteins from the Bcl-2 family regulate cell death at the molecular level. Understanding this process will inform the development of drugs aimed at regulating cell death in cancer and other diseases.
Caspase 8 Apoptotic Signalling Induced By The Inflammasome
Funder
National Health and Medical Research Council
Funding Amount
$603,126.00
Summary
The death of cells of our body can be an active and purposeful process. Programmed death occurs in response to infection or as a defence against cancerous changes. If a virally infected cell can die prior to replication of the virus, this will control the infection. We have investigated cell death in response to DNA found in the cytoplasm of cells, which can be an indication of infection. The novel cell death pathway we are characterising is relevant to defence against infection and tumours.
Structural Investigations Of The Bcl-2 Family Cell Death Apparatus
Funder
National Health and Medical Research Council
Funding Amount
$612,652.00
Summary
Programmed Cell Death is a process by which dangerous cells are removed from the body. Sometimes it goes wrong and causes disease, e.g. cancer cells stay alive when they should die. This project will study a group of proteins that regulate cell death, the Bcl-2 family of proteins, in order to understand the mechanism by which they control the balance of cell life and death. The findings will inform the development of new drugs aimed at regulating cell death in a variety of disease states.
The Role Of Apoptotic Caspases In Regulating Type I Interferon Production
Funder
National Health and Medical Research Council
Funding Amount
$791,746.00
Summary
Type I interferons (IFNs) are potent anti-viral cytokines. Dysregulated type I IFN responses result in major pathologies, e.g., embryonic lethality and defects in tissue homeostasis. We have identified a novel molecular mechanism regulating IFN production that relies on the host’s own apoptotic caspases. We hypothesize that apoptotic caspases critically regulate IFN responses during the process of cell death, with implications for tissue homeostasis and host responses to infection.
Understanding How BH3-only Proteins Initiate Apoptosis In Response To Chemotherapy
Funder
National Health and Medical Research Council
Funding Amount
$481,124.00
Summary
Failure to initiate cell death is a hallmark in the development of the majority of cancers and killing all tumour cells is essential for effective cancer treatment. A group of proteins termed the BH3-only proteins normally sense cell stress to trigger cell death. Their dysregulation contributes to cancer and failure to respond to chemotherapy. Understanding how these proteins function to induce cell death will allow the design of drugs that mimic this activity for improved cancer therapy.
New Drug Combinations To Enhance Elimination Of Hepatitis B Infection
Funder
National Health and Medical Research Council
Funding Amount
$888,304.00
Summary
We have developed a therapy that kills hepatitis B virus infected cells and promotes elimination of infection. We are now testing novel drugs that can be used to maximise the efficacy of our new treatment to promote better outcomes that may be translated to other infections.