This program of research is firmly focussed on the basic mechanisms involved in normal functioning of cells and tissues, followed by a step by step process to understand the abnormal or the diseased. The disease states we are investigating involve the blood and blood vessels, and when there is malfunction it may contribute to conditions as diverse as atherosclerosis, thrombosis, inflammation and cancer. The program thus addresses the fundamentals of diseases which are responsible for most deaths ....This program of research is firmly focussed on the basic mechanisms involved in normal functioning of cells and tissues, followed by a step by step process to understand the abnormal or the diseased. The disease states we are investigating involve the blood and blood vessels, and when there is malfunction it may contribute to conditions as diverse as atherosclerosis, thrombosis, inflammation and cancer. The program thus addresses the fundamentals of diseases which are responsible for most deaths in our society. We will use technology which is proven to provide precise information, the molecular and biochemical processes responsible for cell function (or malfunction). However in each individual project there will be a clear path to a clinical use, diagnostic or therapeutic. Indeed in a number of the components of the program there are already potential treatments and diagnostics in development and trial.Read moreRead less
The Chief Investigators have worked as a team for 20 years as part of a successful NHMRC Program Grant that was renewed on three successive occasions and subsequently under a NHMRC Block Grant to QIMR. Their combined expertise covers the whole spectrum from the bedside to the bench with respect to clinical studies and fundamental molecular studies of iron homeostasis. The common theme of iron homeostasis and iron overload pervades virtually all the research of the team. The team�s research has l ....The Chief Investigators have worked as a team for 20 years as part of a successful NHMRC Program Grant that was renewed on three successive occasions and subsequently under a NHMRC Block Grant to QIMR. Their combined expertise covers the whole spectrum from the bedside to the bench with respect to clinical studies and fundamental molecular studies of iron homeostasis. The common theme of iron homeostasis and iron overload pervades virtually all the research of the team. The team�s research has led to fundamental observations of iron regulation and homeostasis and the development of guidelines for the management of, and screening for, haemochromatosis, recognized as the most common inherited disorder of Caucasian populations. The proposed research encompasses molecular studies aimed at deciphering the mechanisms of iron absorption and transport; how these processes are regulated; and clinical studies on patients diagnosed with haemochromatosis. The findings are particularly pertinent to the diagnosis, management and prevention of clinical haemochromatosis.Read moreRead less
Genetic And Bioinformatic Analysis Of Complex Human Diseases
Funder
National Health and Medical Research Council
Funding Amount
$8,752,567.00
Summary
Some human diseases are common in families; examples include prostate cancer, blood cancers, epilepsy and diabetes. Therefore, close relatives of individuals with a disease have an increased risk of being affected by this disease, implying a genetic basis. Finding the cause of these diseases is difficult, we will be developing novel approaches to the identification of genes responsible for these diseases. This is the first step towards the development of treatments for affected individuals.
The immune system plays an important role in protecting the host from viral and bacterial infections, and inhibits cancer onset and progression. Unfortunately the immune system can sometimes lose specificity and attack the host resulting in autoimmune diseases such as diabetes. This research team has played a vital role in characterising the specific activities of immune cells and the associated factors. By understanding these complex processes the team aims to harness the unique therapeutic pro ....The immune system plays an important role in protecting the host from viral and bacterial infections, and inhibits cancer onset and progression. Unfortunately the immune system can sometimes lose specificity and attack the host resulting in autoimmune diseases such as diabetes. This research team has played a vital role in characterising the specific activities of immune cells and the associated factors. By understanding these complex processes the team aims to harness the unique therapeutic properties of our own immune system and translate their findings into the clinic.Read moreRead less
The foot soldiers of the immune system, the white blood cells, constantly march through the body seeking out invaders, but kept in check by the barrier of endothelial cells that lines the inside of blood vessels. When infection occurs, molecular messages are transmitted amongst the white cells and between white cells and edothelium, to activate the immune cells to pass out of the blood vessels and mount a defence. Unfortunatley, the activation system sometimes goes awry, resulting in inflammator ....The foot soldiers of the immune system, the white blood cells, constantly march through the body seeking out invaders, but kept in check by the barrier of endothelial cells that lines the inside of blood vessels. When infection occurs, molecular messages are transmitted amongst the white cells and between white cells and edothelium, to activate the immune cells to pass out of the blood vessels and mount a defence. Unfortunatley, the activation system sometimes goes awry, resulting in inflammatory or allergic disease, such as arthritis or asthma. This team of researchers from the Hanson Institute in Adelaide, combining expertise in molecular and cell biology, protein chemestry, structual biology and animal models, has been working together for over 10 years, investigating the molecular mechanisms involved in controlling the formation and activities of blood vessels and white blood cells. This program seeks to further that understanding, and to develop drugs that have the potential of ameliorating the inflammatory condition.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
Antibodies are made by B-cells and are essential for a functional immune system. B cells circulate in the body, and, when they encounter an invader, they mature into antibody-producing cells (ASC). A small proportion of the cells become “memory” cells with the potential to become ASC should the same infection occur in the future. This is the basis of vaccination. This program aims to understand how a B cell changes into an ASC. We aim eventually to be able to improve vaccines and understand dise ....Antibodies are made by B-cells and are essential for a functional immune system. B cells circulate in the body, and, when they encounter an invader, they mature into antibody-producing cells (ASC). A small proportion of the cells become “memory” cells with the potential to become ASC should the same infection occur in the future. This is the basis of vaccination. This program aims to understand how a B cell changes into an ASC. We aim eventually to be able to improve vaccines and understand diseases such as allergy, lupus, arthritis and leukaemia to develop novel therapies.Read moreRead less