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.
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.
Type 2 diabetes (T2D) is threatening the health of this nation and if unchecked will cripple our health care system. There are several problems: (1) The incidence of T2D is growing and we do not fully know why; (2) T2D involves defective insulin action but how insulin works normally is still unclear; (3) much research in this area is performed in laboratory cells or animals and the translation of this research to the human disease is yet to be fully realised; and (4) current therapies and diagno ....Type 2 diabetes (T2D) is threatening the health of this nation and if unchecked will cripple our health care system. There are several problems: (1) The incidence of T2D is growing and we do not fully know why; (2) T2D involves defective insulin action but how insulin works normally is still unclear; (3) much research in this area is performed in laboratory cells or animals and the translation of this research to the human disease is yet to be fully realised; and (4) current therapies and diagnostic markers for early disease prediction are inadequate. Our goal is to make progress in each of these areas.Read moreRead less
Atherosclerosis: Lipoproteins, Cell Biology And Vascular Physiology
Funder
National Health and Medical Research Council
Funding Amount
$10,461,682.00
Summary
The world is confronting a major new epidemic of premature heart disease that is being driven by a global increase in obesity. There are several factors that contribute to the increased risk of heart disease in overweight and obese people. One is a low blood level of the “good” HDL cholesterol that normally protects against heart disease. Another relates to a decreased ability to remove cholesterol from the walls of arteries where it builds up to cause heart disease. A third is the fact that obe ....The world is confronting a major new epidemic of premature heart disease that is being driven by a global increase in obesity. There are several factors that contribute to the increased risk of heart disease in overweight and obese people. One is a low blood level of the “good” HDL cholesterol that normally protects against heart disease. Another relates to a decreased ability to remove cholesterol from the walls of arteries where it builds up to cause heart disease. A third is the fact that obesity is associated with a state of chronic inflammation of the blood vessels. This inflammation not only accelerates the development of heart disease but also makes people who have cholesterol accumulated in their arteries more likely to actually have a heart attack. And a fourth is the fact that the lining of blood vessels does not function normally in overweight and obese people. This loss of normal function is a very early sign of future heart disease. These factors are closely inter-related, with the “good” HDL playing a central role in removing cholesterol from arteries, inhibiting arterial inflammation and promoting normal function and repair of the lining of blood vessels. HDL is complex, consisting of a mixture of several subpopulations of particles that vary in shape, size and composition. Furthermore, these HDL subpopulations are continually remodelled as they circulate in blood in reactions promoted by a number of blood factors that change their size and composition. A major component of the research to be conducted in this program relates to understanding how the HDL subpopulations in human blood are regulated and how they protect against heart disease. The applicants have already made major contributions to understanding the functions of the “good” HDLs, how they take cholesterol out of cells in the artery wall, how they inhibit inflammation of the arteries and how they improve the function of the artery lining. We propose to extend these studies to establish how these protective functions can be enhanced, to find out which of the HDL subpopulations are most protective, and to identify how to increase the most protective HDLs in people at risk of heart disease.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
Improved Respiratory Support And Outcomes For Very Preterm Babies
Funder
National Health and Medical Research Council
Funding Amount
$9,185,907.00
Summary
Premature babies are born with lungs that are not developed enough to sustain their breathing needs after birth. As a result, they need intensive care which is the most costly and challenging problem in newborn medicine as these infants can suffer life-long diseases because of their early birth. This programs study will help to understand the causes of lung disease in premature babies and develop better ways of caring for them to improve their chances of survival without ongoing illness and disa ....Premature babies are born with lungs that are not developed enough to sustain their breathing needs after birth. As a result, they need intensive care which is the most costly and challenging problem in newborn medicine as these infants can suffer life-long diseases because of their early birth. This programs study will help to understand the causes of lung disease in premature babies and develop better ways of caring for them to improve their chances of survival without ongoing illness and disabilityRead moreRead less
The goal of the proposed Program is to improve treatments forpain, especially persistent pain, which remains a poorly managed global health burden. Our pre-eminent team integrates a unique set of complementary research skills in using peptides derived from venomous invertebrates to dissect the pharmacology of pain pathways in persistent pain states, and develop these novel peptides to the point where they can be considered for pre-clinical development in collaboration with commercial partners.
A major obstacle to the development of safer and more effective pain treatments is the poorly defined nature of the different pathways involved in chronic pain. The applicant team bring together a unique set of research expertise in using neurotoxins to define, at the molecular level, how the nervous system functions. The applicants also share a common interest in understanding and improving treatments for pain, especially chronic pain which continues to remain poorly managed Through a focus on ....A major obstacle to the development of safer and more effective pain treatments is the poorly defined nature of the different pathways involved in chronic pain. The applicant team bring together a unique set of research expertise in using neurotoxins to define, at the molecular level, how the nervous system functions. The applicants also share a common interest in understanding and improving treatments for pain, especially chronic pain which continues to remain poorly managed Through a focus on pain research, the Program will significantly enhance the scope of existing multidisciplinary collaborations between the Cis Lewis Alewood, Adams and Christie, which have already made a considerable impact in the fields of pharmacology and neuroscience. The CIs also have considerable experience in the development of pain therapeutics, having discovered two conopeptides now under commercial development with AMRAD (AM336) and Xenome Ltd (Xen2174). This Program will discover and use highly selective conopeptides such as these to dissect the pharmacology of peripheral pain pathways and their projections into the central nervous system, and to identify and characterise new targets amenable to drug intervention. The long-term goal of the Program is to discover new targets in pain pathways and develop conopeptides that act on these targets in animal models of chronic pain. These molecules will be optimised within the Program to the point where they can be considered for pre-clinical development in collaboration with commercial partners.Read moreRead less
This Program Grant investigates a number of important reproductive problems that affect the fertility of men, prostate cancer and the way the mother nurtures and protects the baby during pregnancy. The successful development of sperm requires the proper function of a number of biological processes. This grant investigates the way in which sperm are produced, the genes that are needed to control their development, and the way sperm propel themselves and fertilize the egg. The research also invest ....This Program Grant investigates a number of important reproductive problems that affect the fertility of men, prostate cancer and the way the mother nurtures and protects the baby during pregnancy. The successful development of sperm requires the proper function of a number of biological processes. This grant investigates the way in which sperm are produced, the genes that are needed to control their development, and the way sperm propel themselves and fertilize the egg. The research also investigates how sperm are protected during their development from infection and immunological rejection, achieved in part by a special environment within the tubes in the testis where they grow. It appears that the general mechanisms that the body uses to combat infections are modified within the testis and the way in which this occurs may provide clues that could be applied to prevent the rejection of transplanted organs in general. Some of the substances that control these processes appear to play an important role in the body�s defense against infection. The grant also investigates the processes that are involved in the development of prostate cancer. These changes can occur over many years and the grant will study some substances that appear to be involved. The work will provide new knowledge that may assist in new tests to identify whether a cancer is slow or fast growing, thereby helping each man to decide the most sensible form of treatment. The grant will investigate how a group of proteins, that also are involved in the control of processes discussed above, assist the mother in protecting her baby during pregnancy. The outcomes will assist in the management of disturbances of pregnancy that may put the fetus at risk of survival.Read moreRead less
Understanding G Protein-Coupled Receptors (GPCRs): Accelerating Discovery From Concept To Clinic.
Funder
National Health and Medical Research Council
Funding Amount
$6,871,789.00
Summary
G Protein-Coupled Receptors (GPCRs) form the largest family of receptors (and thus drug targets) in living organisms. Currently, the major reason that new drugs fail to reach the clinic is lack of appropriate drug effect (approx. 30%). Thus, we need a better understanding of how GPCRs work and how this relates to disease. Our Program addresses this knowledge gap, using GPCR models that are relevant to treatment of metabolic, cardiovascular and central nervous system disease.