In cancer cells the normal process of cell death (called apoptosis) is defective, helping abnormal cells to grow and multiply unchecked. The Bak protein is a member of the Bcl-2 family of apoptosis regulators, and plays a pivotal role in mediating cell death. By defining each step in Bak-mediated apoptosis, we aim to better understand how cancer cells accumulate, and how targeting the Bcl-2 family may lead to effective anti-cancer therapeutics.
Role Of Bak And Bax Membrane Anchors In Targeting And Apoptotic Pore Formation.
Funder
National Health and Medical Research Council
Funding Amount
$352,319.00
Summary
In cancer cells the normal process of cell death (called apoptosis) is defective, helping abnormal cells to grow and multiply unchecked. The Bak and Bax proteins are members of the Bcl-2 family of apoptosis regulators, and play a pivotal role in mediating cell death. By defining how these proteins form a pore in mitochondria, the point of no return in cell death, will help the development of novel anti-cancer agents that target the Bcl-2 family in general, and Bak and Bax in particular.
Roles Of Impaired Apoptosis And Differentiation In Tumourigenesis And Therapy
Funder
National Health and Medical Research Council
Funding Amount
$21,656,910.00
Summary
The ten scientific laboratories in this program have joined forces to investigate two ways in which tumours develop. Both are of particular interest, because they suggest new ways in which cancer might be overcome. Most of our tissues are continually renewed throughout life by production of new cells. Therefore many of the old cells in each tissue must die off to maintain the proper cell numbers. To eliminate cells that are no longer needed or have become damaged, the body has developed a remark ....The ten scientific laboratories in this program have joined forces to investigate two ways in which tumours develop. Both are of particular interest, because they suggest new ways in which cancer might be overcome. Most of our tissues are continually renewed throughout life by production of new cells. Therefore many of the old cells in each tissue must die off to maintain the proper cell numbers. To eliminate cells that are no longer needed or have become damaged, the body has developed a remarkable cell suicide process termed apoptosis. Unfortunately, however, occasionally a random accident to the genes in one of our cells prevents the machinery for apoptosis from being turned on. In that case, the cell will not die when it should and, by continually dividing, it may eventually give rise to a cancer. Since most cancer cells still retain most of the machinery for apoptosis, however, a drug that could switch on this natural cell death machinery would provide a promising new approach to cancer therapy. Identifying and developing such drugs is one major long-term goal of this program. The other focus of our program concerns stem cells. These are rare cells with the remarkable ability to generate an entire tissue. For example, one of our laboratories has identified stem cells that can generate all the cells in the breast. The almost unlimited regenerative capacity of stem cells has a built-in danger. If a stem cell acquires the ability to proliferate excessively, it can go on to form a tumour. Indeed, many cancer researchers now suspect that rare stem cells within a tumour cause its inexorable growth. If tumour growth is maintained by stem cells, it will be essential to develop new forms of therapy that target these rare cancer stem cells rather than merely the bulk of the tumour cells. This is another key long-term goal of our program.Read moreRead less
Development Of Small Molecule Modulators Of Apoptosis
Funder
National Health and Medical Research Council
Funding Amount
$621,558.00
Summary
Cancers rely on the deregulation of key cellular pathways. Along with biological and genetic tools, small molecules are powerful probes to understand these mechanisms. During the course of this research program, we will develop new and drug-like molecules that reinstate the cell death process to combat malignancies. This research will bring important advances for potential chemotherapies and create probes to better understand the biology of programmed cell death processes.
Detection and viability of waterborne pathogens using a gut-on-chip. This project aims to resolve a significant problem for water utilities. Microbial pathogens Cryptosporidium, norovirus and adenovirus are the main public health concern for drinking water in developed nations. Water monitoring is limited by the lack of fast, reliable detection methods and viability assays for these pathogens. This project will use a novel gut-on-a-chip to develop for the first time rapid infectivity assays for ....Detection and viability of waterborne pathogens using a gut-on-chip. This project aims to resolve a significant problem for water utilities. Microbial pathogens Cryptosporidium, norovirus and adenovirus are the main public health concern for drinking water in developed nations. Water monitoring is limited by the lack of fast, reliable detection methods and viability assays for these pathogens. This project will use a novel gut-on-a-chip to develop for the first time rapid infectivity assays for Cryptosporidium, norovirus and adenovirus. Significant benefits include improved diagnostics and water disinfection assays, improved water treatment and reduced costs with global impact.Read moreRead less
Epigenetic Therapies As Molecular Probes To Investigate The Molecular Pathogenesis Of Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$937,402.00
Summary
A major limitation to the success of targeted therapies in cancer is the fact that we have few if any tools to study in detail their mechanism of action within cancerous and normal cells. If we were able to visualise these drugs within cells and precisely characterise the proteins, DNA and RNA within a cell that interact with these therapies we will be able to identify strategies that can optimise their efficacy and reduce the side-effects of these treatments.
Transport and innate immune properties of DNA in bacterial nano-sized vesicles. All types of living organisms release nano-sized membrane vesicles or “blebs” which they use for intercellular communication and transport of molecules. This project will determine how bacteria package DNA within these vesicles, how this DNA is transported into host cells and how it triggers immune responses in these cells.
The host specificity of bacterial pathogens. The vast majority of microorganisms that cause diseases in animals are host specific. In other words, they cause disease exclusively in a particular animal species, but are harmless for others. Despite considerable recent advances in our understanding of the mechanisms used by microorganisms in general to cause disease, in most cases the underlying basis of host-specificity is not known. In this project, we will use two animal pathogens, rabbit-spe ....The host specificity of bacterial pathogens. The vast majority of microorganisms that cause diseases in animals are host specific. In other words, they cause disease exclusively in a particular animal species, but are harmless for others. Despite considerable recent advances in our understanding of the mechanisms used by microorganisms in general to cause disease, in most cases the underlying basis of host-specificity is not known. In this project, we will use two animal pathogens, rabbit-specific enteropathogenic E. coli and the closely related bacterium, Citrobacter rodentium, which specifically infect rabbits and mice respectively, to investigate the molecular basis of host specificity.Read moreRead less
Characterization of metabolic networks in a microbial pathogen. New methods are needed to understand complex cellular processes such as metabolism. This proposal will support the development of methods in metabolite profiling and flux analysis that provide a global view of metabolic networks in cells and complement other profiling approaches, such as proteomics and transcriptomics. The development of these approaches (collectively termed Systems Biology) is essential for maintaining Australia sc ....Characterization of metabolic networks in a microbial pathogen. New methods are needed to understand complex cellular processes such as metabolism. This proposal will support the development of methods in metabolite profiling and flux analysis that provide a global view of metabolic networks in cells and complement other profiling approaches, such as proteomics and transcriptomics. The development of these approaches (collectively termed Systems Biology) is essential for maintaining Australia science at the forefront of international efforts (National Research Priority 3; Breakthrough science). This project will also directly contribute to our understanding of metabolism of an important human pathogen and provide training to young Australian scientists.Read moreRead less
Designing effective Gram negative bacterial vaccines. There is a need for the development of novel vaccines for use in animals and humans. This project will to address this need by studying the functions of bacterial 'blebs' as potent inducers of the host immune system and by developing these nano-sized particles for use as safe and cost-effective vaccine candidates.