This program application seeks to draw on the skills of a world leading group of Australian researchers to bring novel HIV vaccine designs to clinical trials, improve vaccine design and create new opportunities for commercialisation. The Chief Investigators, Prof David Cooper, Prof Peter Doherty (Nobel Prize winner), A-Prof Stephen Kent and Prof Ian Ramshaw, have achieved major scientific developments including: innovative collaborative clinical trials, cutting edge research in T cell immunology ....This program application seeks to draw on the skills of a world leading group of Australian researchers to bring novel HIV vaccine designs to clinical trials, improve vaccine design and create new opportunities for commercialisation. The Chief Investigators, Prof David Cooper, Prof Peter Doherty (Nobel Prize winner), A-Prof Stephen Kent and Prof Ian Ramshaw, have achieved major scientific developments including: innovative collaborative clinical trials, cutting edge research in T cell immunology, the establishment of the only PC3-level nonhuman primate facility in the Southern hemisphere, T cell immunogenicity of the DNA-viral vector prime-boost vaccine regimens and ground-breaking research on cytokine co-expressing viral vector vaccines. The Principle Investigators also have a record of substantial achievement in relation to HIV and T cell biology as well as novel vaccination technologies. There is a strong history of successful collaboration among this group leading to the award of major NIH funding.Read moreRead less
The development of vaccines and better treatments for HIV-AIDS and Hepatitis C are urgent global health priorities. This Program will undertake studies to better understand effective immunity against HIV and hepatitis C, allowing the rational design and testing of novel vaccines and treatments. The Program brings together a team of researchers with skills in basic virology and immunology with those providing expertise in translating findings in the laboratory into human clinical trials.
While current influenza vaccines blunt winter epidemics, they must be updated frequently to keep up with virus mutation and they do not protect against pandemics caused by new flu viruses (such as bird flu). This program will define how flu virus interacts with the immune system to generate immunity mediated particularly by “killer” T cells. We will use this knowledge to develop and evaluate vaccines that induce long-lasting T-cell immunity that can protect against both seasonal and pandemic flu ....While current influenza vaccines blunt winter epidemics, they must be updated frequently to keep up with virus mutation and they do not protect against pandemics caused by new flu viruses (such as bird flu). This program will define how flu virus interacts with the immune system to generate immunity mediated particularly by “killer” T cells. We will use this knowledge to develop and evaluate vaccines that induce long-lasting T-cell immunity that can protect against both seasonal and pandemic flu.Read moreRead less
Regulation Of Gene Expression: Biomolecular Interactions In Cellular Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$2,998,713.00
Summary
This team consists of three of Australia�s younger researchers Merlin Crossley, Joel Mackay and Jacqui Matthews (as Chief Investigators), who are recognized as authorities in the areas of gene regulation and the structural and functional analysis of proteins. They are joined by Mitchell Weiss, a world authority on blood development and clinical disorders,and Alexis Verger, a molecular and cell biologist recruited from France, both as Principal Investigators. Crossley, Mackay and Matthews have wo ....This team consists of three of Australia�s younger researchers Merlin Crossley, Joel Mackay and Jacqui Matthews (as Chief Investigators), who are recognized as authorities in the areas of gene regulation and the structural and functional analysis of proteins. They are joined by Mitchell Weiss, a world authority on blood development and clinical disorders,and Alexis Verger, a molecular and cell biologist recruited from France, both as Principal Investigators. Crossley, Mackay and Matthews have worked as a team for around six years to date, have published together in high-quality international journals, and have received anumber of accolades for their contributions to Australian science. For example, Crossley has won a number of national awards, including the Gottschalk Medal of the Australian Academy of Science; Mackay was recently awarded the Prime Minister�s Prize for Life Scientist of the Year, and Matthews won the only Charles and Sylvia Viertel Medical Research Fellowship to be awarded in 2003. The members of this team have collaborated extensively on the world stage and Crossley, Mackay and Matthews have also taken leadership roles in the Australian scientific community. Mitchell Weiss has been an important collaborator, exchanging reagents and advice, since he and Crossley trained together as postdocs in Stu Orkin�s lab at Harvard in the early 90s. Most recently Weiss, in collaboration with Mackay, has made important discoveries on a-globin production, which has led to several highly significant publications including a seminal paper in Cell in 2004.The program of research put forward in this proposal centres around understanding the mechanisms through which genes are switched on and off, using blood development as a model system, that is also fundamental to human life. The regulation of gene output is essential both during the development of an organism and throughout the course of its life. Problems with this regulation can result in many different disease states, most notably cancer, which includes the many different types of leukemias. At one level, gene output is controlled by networks of specific proteins known as transcription factors that interact both with each other and with DNA. Currently, however, the details surrounding which complexes regulate which genes and the processes that control the making and breaking up of the complexes are not well understood. Knowledge of how these interactions take place will put us in a position to control the output of chosen genes for therapeutic purposes. We propose to use a combination of cell biological, biochemical, and structural approaches to firstly shed light on these complexes and secondly develop reagents that can be used to manipulate the activity of specific genes.Read moreRead less
Control Of Proteases In Infectious, Degenerative And Cardiovascular Disease
Funder
National Health and Medical Research Council
Funding Amount
$11,668,789.00
Summary
Proteases are enzymes that control key processes in humans. The research in this program will result in major discoveries in the field of proteases and their inhibitors, with a focus on inflammatory, cardiovascular and degenerative disease. The knowledge gained from this strong foundation of fundamental research will underpin the translational outcomes necessary to combat the debilitating effects of immunological dysfunction, conformational and cardiovascular disease.
Molecular And Functional Characterisation Of Cell Surface Microdomains
Funder
National Health and Medical Research Council
Funding Amount
$4,803,731.00
Summary
This research program aims to gain a detailed understanding of the organisation of the cell surface at the molecular level. The cell surface is organised into domains with distinct functions. Visualisation of these domains, identifying their important components, and understanding how they form and function will have huge importance for therapeutic strategies aimed at combating the changes associated with cell transformation in cancer and in other human diseases such as muscular dystrophy.
Insult, Injury And Recovery In Brain Disease: From Molecules To Therapeutic Outcome
Funder
National Health and Medical Research Council
Funding Amount
$8,215,611.00
Summary
When nerve cells are damaged, destroyed or injured, through disease or trauma, common pathological processes are set in train. Even though there are many factors that might trigger disease, these inevitably lead to common processes that end in cell death or initiate protective processes. One theme involves the factors that surround these responses to nerve injury and stress, and the consequent protective and regenerative responses that ensue. Another theme, closely integrates with the first, is ....When nerve cells are damaged, destroyed or injured, through disease or trauma, common pathological processes are set in train. Even though there are many factors that might trigger disease, these inevitably lead to common processes that end in cell death or initiate protective processes. One theme involves the factors that surround these responses to nerve injury and stress, and the consequent protective and regenerative responses that ensue. Another theme, closely integrates with the first, is to exploit basic biological mechanisms with the aim of identifying and developing therapeutic targets for the management of a wider range of neurological conditions.Read moreRead less
Structural Biology Of Cytokine Receptor Signalling
Funder
National Health and Medical Research Council
Funding Amount
$3,988,996.00
Summary
This Program will be focused on a group of protein hormones and their receptors, implicated in blood cell cancers and inflammatory diseases and for which current treatments are inadequate. We will determine the mechanism of receptor activation and in particular will seek to link different forms of receptor assembly to different functions. This information will help us develop new drugs with more specificity for certain hormone functions and thus less side-effects.
Colon Cancer: Receptors, Signalling And Therapeutics
Funder
National Health and Medical Research Council
Funding Amount
$7,115,542.00
Summary
This program aims to understand the biochemical and biological basis of colorectal cancer, a major cause of cancer deaths in Australia. The Chief Investigators have extensive experience in the analysis of the molecular defects in colorectal cancer cells and have already developed new drugs to treat successfully experimental colon tumours in animals. During this research program, we will explore these systems further, concentrating on the identification of novel inhibitors of colon cancer cell gr ....This program aims to understand the biochemical and biological basis of colorectal cancer, a major cause of cancer deaths in Australia. The Chief Investigators have extensive experience in the analysis of the molecular defects in colorectal cancer cells and have already developed new drugs to treat successfully experimental colon tumours in animals. During this research program, we will explore these systems further, concentrating on the identification of novel inhibitors of colon cancer cell growth, survival and movement. Newly developed instruments and techniques will allow us to identify and detect the critical steps during the development of colorectal cancer and to design potent drugs to fight the disease. We have experience in conducting novel clinical trials in colon cancer and have developed imaging techniques for monitoring the effectiveness and safety of new anti-cancer drugs. Our collective scientific experience and ability to work in the clinic provides a unique opportunity for developing more effective treatments for colorectal cancer patients.Read moreRead less