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The ins and outs of HIV biology. This project aims to delineate the fundamental mechanisms that regulate the production of HIV and the ability of HIV to cause AIDS in infected patients. It will utilise state-of-the-art technologies to unearth new clues that govern the biology of HIV, with the ultimate goal to develop novel vaccine and treatment strategies against HIV.
Interrogating a novel protein scaffold that coordinates signal transduction and molecular motor function. The inside of a cell is an extremely crowded environment and the precise location of each component is carefully controlled. This project will unravel the protein machinery involved in transporting cargos in cells as they divide and identify new protein targets for the development of next generation anti-cancer drugs.
Tracking DNA repair dynamics in the nuclear landscape of a living cell. This project aims to track DNA repair factor recruitment in the nuclear landscape of a living cell and quantify the role of nucleus architecture in maintenance of genome integrity. By coupling advanced fluorescence microscopy with a novel DNA double strand break inducible cell system, this project expects to uncover how the nucleus spatially coordinates DNA damage detection, assessment and repair in real time. This research ....Tracking DNA repair dynamics in the nuclear landscape of a living cell. This project aims to track DNA repair factor recruitment in the nuclear landscape of a living cell and quantify the role of nucleus architecture in maintenance of genome integrity. By coupling advanced fluorescence microscopy with a novel DNA double strand break inducible cell system, this project expects to uncover how the nucleus spatially coordinates DNA damage detection, assessment and repair in real time. This research is important because DNA damage threatens organism survival and this project has the potential to define how this genomic threat is resolved at the single molecule level. The benefit of this research is a fundamental insight into DNA repair biology and development of imaging technology to quantify genome function.Read moreRead less
Mitochondrial proteases and their contribution to protein homeostasis. This research will examine how a critically important cellular organelle known as the mitochondrion maintains its functional integrity by sensing and signalling protein perturbations. As mitochondrial dysfunction is central to a number of neurodegenerative diseases understanding the molecular biology of this fundamentally important cellular process could, in the future, provide for better health outcomes for an aging Australi ....Mitochondrial proteases and their contribution to protein homeostasis. This research will examine how a critically important cellular organelle known as the mitochondrion maintains its functional integrity by sensing and signalling protein perturbations. As mitochondrial dysfunction is central to a number of neurodegenerative diseases understanding the molecular biology of this fundamentally important cellular process could, in the future, provide for better health outcomes for an aging Australian population. The training of post-graduate students is an integral component of this study and thus will contribute to building national research capacity. International collaborations and new discoveries will also contribute to the recognition of Australian research.Read moreRead less
Transcriptional and epigenetic regulation of terminal lymphocyte differentiation and alterations of the same that lead to leukemia. In the developed world infection diseases are the number three killer behind heart disease and cancer, and huge financial effort is put into treatment and prevention. Despite this, results have often been disappointing. One cause of these poor outcomes is the lack of knowledge of how effective immune responses are generated. This project aims to better understand th ....Transcriptional and epigenetic regulation of terminal lymphocyte differentiation and alterations of the same that lead to leukemia. In the developed world infection diseases are the number three killer behind heart disease and cancer, and huge financial effort is put into treatment and prevention. Despite this, results have often been disappointing. One cause of these poor outcomes is the lack of knowledge of how effective immune responses are generated. This project aims to better understand the processes that control the generation of protective lymphocytes. It will deliver information that may enable a more targeted approach to vaccine-development and treatments of infections. As defective differentiation can also be a cause of leukemia it may also lead to targets of cancer treatment.Read moreRead less
Targeting genes elevated in the athlete's heart to improve function of the failing heart. Cardiovascular disease affects about 3.7 million Australians and heart failure ranks as one of the major killers, representing a huge burden on our health care system and economy. This situation is likely to get worse with an increasing ageing population. Current therapeutics for heart failure patients largely delay disease progression but generally fail in significantly improving heart function and quality ....Targeting genes elevated in the athlete's heart to improve function of the failing heart. Cardiovascular disease affects about 3.7 million Australians and heart failure ranks as one of the major killers, representing a huge burden on our health care system and economy. This situation is likely to get worse with an increasing ageing population. Current therapeutics for heart failure patients largely delay disease progression but generally fail in significantly improving heart function and quality of life. The proposal has focused on targeting the protective effects of 'good' heart growth by identifying genes elevated in the heart in response to exercise. Targeting genes elevated in the athlete's heart to improve function of the failing heart represents a new strategy for the treatment of heart failure.Read moreRead less
The roles of novel pathways in the activation and regulation of the adaptive immune response in health and disease. The immune system is designed to protect us against infection and vaccines exploit this with great success in preventing many infections. However, the immune system can also 'fail' and attack the body in a process called autoimmunity e.g. destroying joints in rheumatoid arthritis. This proposal will define how white blood cells work to make better vaccines against infection and ho ....The roles of novel pathways in the activation and regulation of the adaptive immune response in health and disease. The immune system is designed to protect us against infection and vaccines exploit this with great success in preventing many infections. However, the immune system can also 'fail' and attack the body in a process called autoimmunity e.g. destroying joints in rheumatoid arthritis. This proposal will define how white blood cells work to make better vaccines against infection and how these same immune cells can malfunction to create autoimmune diseases like Crohn's disease.Read moreRead less
Novel tools and nanotechnology to navigate intracellular trafficking. This project aims to investigate how material accesses different compartments inside cells, also known as trafficking. Using immunology, cell biology and nanotechnology, the project will manipulate intracellular trafficking to achieve specific cellular functions. Outcomes will also form the basis of intellectual property development for new products by Australian biotechnology companies. These products will improve veterinary ....Novel tools and nanotechnology to navigate intracellular trafficking. This project aims to investigate how material accesses different compartments inside cells, also known as trafficking. Using immunology, cell biology and nanotechnology, the project will manipulate intracellular trafficking to achieve specific cellular functions. Outcomes will also form the basis of intellectual property development for new products by Australian biotechnology companies. These products will improve veterinary and human health services, leading to increased productivity.Read moreRead less
Molecular signals that regulate the regenerative properties of intestinal epithelial cells. Most cancer deaths are due to the cancer spreading to other organs. Cancer is much more difficult to treat once it has spread to other organs in the body where the cancer cells can exist in a dormant state. Dormant cancer cells evade conventional anticancer treatment and can remain dormant for a very long time before they change back to a 'tumour-growing' state. An understanding of how the cancer initiati ....Molecular signals that regulate the regenerative properties of intestinal epithelial cells. Most cancer deaths are due to the cancer spreading to other organs. Cancer is much more difficult to treat once it has spread to other organs in the body where the cancer cells can exist in a dormant state. Dormant cancer cells evade conventional anticancer treatment and can remain dormant for a very long time before they change back to a 'tumour-growing' state. An understanding of how the cancer initiating (stem cell) property of tumour cells is maintained offers potential novel avenues to eliminate persistent cancer cells. This knowledge will ultimately lead to better management and treatment of cancer, and increase survival. An understanding of stem cell behaviour is also central to the control of degenerative conditions.Read moreRead less
Polarity in lymphocytes: Regulation of immune function and cancer. The Fellow will elucidate the mechanisms and consequences of a fundamental new phenomenon in immunology. This is likely to profoundly impact upon approaches to detecting and treating immune-related diseases such as autoimmunity, transplantation, vaccination and immunodeficiencies. The ongoing project and the work that led to our discovery involves interdisciplinary collaborations between physicists and biologists to apply frontie ....Polarity in lymphocytes: Regulation of immune function and cancer. The Fellow will elucidate the mechanisms and consequences of a fundamental new phenomenon in immunology. This is likely to profoundly impact upon approaches to detecting and treating immune-related diseases such as autoimmunity, transplantation, vaccination and immunodeficiencies. The ongoing project and the work that led to our discovery involves interdisciplinary collaborations between physicists and biologists to apply frontier laser technologies to biological studies. These technologies will not only facilitate our elucidation of immune development and function, but will also be made available to other research in Australia and overseas.Read moreRead less