The Structure And Composition Of The T-cell Receptor-CD3 Complex
Funder
National Health and Medical Research Council
Funding Amount
$434,644.00
Summary
Our research will provide a fundamental advance in our understanding of how foreign viruses and pathogens trigger the immune system. Gaining a greater understanding of these central events will facilitate the design of novel therapies to treat immune associated disorders such as transplant rejection, autoimmune disease and some cancers.
The Structure And Composition Of The T-Cell Receptor-CD3 Complex
Funder
National Health and Medical Research Council
Funding Amount
$419,180.00
Summary
My research will use cutting edge imaging techniques to provide a fundamental advance in our understanding of how foreign viruses and pathogens trigger the immune system. Gaining a greater understanding of these central events will facilitate the design of novel therapies to treat immune associated disorders such as transplant rejection, autoimmune disease and some cancers.
Macrophage Polarisation And Control Of Pulmonary Inflammation.
Funder
National Health and Medical Research Council
Funding Amount
$895,494.00
Summary
As key immune cells, macrophages are polarised to phenotypes that turn inflammation on or off. In cystic fibrosis, defective macrophage polarisation enhances inflammation and prevents lung repair. We are defining the molecules and cellular pathways that control this process and identifying targets for existing drugs that can be used to reprogram macrophages and restore lung repair to improve patient outcomes.
Mineralocortioid Receptor-Mediated Injury In Progressive Kidney Disease
Funder
National Health and Medical Research Council
Funding Amount
$707,008.00
Summary
Diabetes is the major cause of kidney failure. Activation of a hormone receptor (the mineralocorticoid receptor-MR) can promote kidney injury. Current drugs blocking MR can suppress diabetic kidney disease but are limited by their poor specificity and harmful side effects. Our study will help improve strategies for blocking MR by identifying the cell types responsible for MR-mediated injury and by examining whether a new class of drug targeting MR is a superior therapy to current MR inhibitors.
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.
Cells of the immune system need to recognise characteristic viral and bacterial molecules, in order to identify infection. Some immune cells can detect the presence of viral and bacterial DNA. The cells respond by making a number of anti-viral or anti-bacterial molecules, as well as activating other cells to fight the infection. The effect of bacterial DNA can be mimicked by certain short synthetic pieces of DNA. The potent activity of this synthetic DNA (termed CpG DNA ) is being exploited in a ....Cells of the immune system need to recognise characteristic viral and bacterial molecules, in order to identify infection. Some immune cells can detect the presence of viral and bacterial DNA. The cells respond by making a number of anti-viral or anti-bacterial molecules, as well as activating other cells to fight the infection. The effect of bacterial DNA can be mimicked by certain short synthetic pieces of DNA. The potent activity of this synthetic DNA (termed CpG DNA ) is being exploited in a number of clinical trials for treatment of cancer and allergy, as well as to improve vaccinations. Despite the rapid advance towards clinical application, there is still much basic information to learn about how CpG DNA acts on cells. The molecule to which DNA binds in order to activate the cells is called TLR9. TLR9 is not on the surface of cells, but within cells. In a bacterial infection, cells called macrophages engulf and digest bacteria and release the bacterial DNA within the cell, where it binds to TLR9. In other cases, including when CpG DNA is used therapeutically, the DNA needs to be taken up into the cell. Evidence shows that there is a receptor on the cell surface which binds DNA, and takes it into the cell. In this project we propose to identify this DNA uptake receptor. Apart from the use of CpG DNA, there are a number of other proposals for the therapeutic use of DNA. Although it is known that DNA enters into cells, the route for this has not been established. Whilst CpG DNA can activate immune cells, some other distinct DNA molecules can prevent the activation. We will examine whether these inhibitory DNA molecules bind more effectively to TLR9 than the CpG DNA, but do not activate the cell. These inhibitory molecules are proposed as a therapy for the autoimmune disease lupus, which involves inappropriate responses to DNA, and is thought to involve TLR9. In order to develop therapies, a detailed knowledge of how they work is essential.Read moreRead less
Role Of The Growth Hormone Binding Protein As A Transcriptional Activator
Funder
National Health and Medical Research Council
Funding Amount
$387,226.00
Summary
Growth hormone is an important hormone therapeutic for treating dwarfism. Recently, many new therapeutic applications for growth hormone have been discovered, particularly in relation to its role as an anabolic agent. These include post surgery recovery, enhanced bone fracture healing, Crohns disease, dilated cardiomyopathy, infertility and of course, ageing. This proposal examines a novel way that GH could work, that is by sending the extracellular part of its receptor (GHBP) to the nucleus, wh ....Growth hormone is an important hormone therapeutic for treating dwarfism. Recently, many new therapeutic applications for growth hormone have been discovered, particularly in relation to its role as an anabolic agent. These include post surgery recovery, enhanced bone fracture healing, Crohns disease, dilated cardiomyopathy, infertility and of course, ageing. This proposal examines a novel way that GH could work, that is by sending the extracellular part of its receptor (GHBP) to the nucleus, where it can directly activate gene readout. This would have the effect of augmenting the normal action of GH to regulate gene readout. We have exciting preliminary data which makes us think this may be a new mechanism for hormone activation of genes. The level of GHBP in the nucleus is regulated, and if a defect in export of the GHBP occurred, this would lead to accumulation of nuclear GHBP and stimulate cell proliferation. This may be important in cancer cell proliferation, since we find nuclear GHBP in cancers.Read moreRead less
Mechanisms Of Macrophage Activation By Immunostimulatory DNA
Funder
National Health and Medical Research Council
Funding Amount
$230,728.00
Summary
This project is based upon the observation that the mammalian immune system can distinguish between its own genetic material (DNA) and the genes of infectious agents such as bacteria. This fact has implications for understanding how the immune system copes with infection, and also for design of new therapies and vaccines. Our central aim is to define exactly how this recognition system works. The cells that respond most vigorously to foreign DNA are large white blood cells called macrophages. We ....This project is based upon the observation that the mammalian immune system can distinguish between its own genetic material (DNA) and the genes of infectious agents such as bacteria. This fact has implications for understanding how the immune system copes with infection, and also for design of new therapies and vaccines. Our central aim is to define exactly how this recognition system works. The cells that respond most vigorously to foreign DNA are large white blood cells called macrophages. We aim to find the macrophage protein which binds to foreign DNA and triggers the activation of the immune system. The type of immune responses initiated by foreign DNA may be useful in treatment of allergies and cancer and for improving vaccinations.Read moreRead less
Understanding Selective Drug Signaling At G Protein-coupled Receptors
Funder
National Health and Medical Research Council
Funding Amount
$362,206.00
Summary
The maintenance of optimum health and function living cells, and consequently that of the whole organism, depends on how cells respond to a multitude of physical and chemical stimuli that continually bombard them. The majority of the chemical stimuli such as hormones and neurotransmitters impart their actions not by directly entering the cell, but instead, by binding to a specific reciever protein at the cell surface called receptor. In one class of such receptors called G protein-coupled recept ....The maintenance of optimum health and function living cells, and consequently that of the whole organism, depends on how cells respond to a multitude of physical and chemical stimuli that continually bombard them. The majority of the chemical stimuli such as hormones and neurotransmitters impart their actions not by directly entering the cell, but instead, by binding to a specific reciever protein at the cell surface called receptor. In one class of such receptors called G protein-coupled receptors, the transmission of the message to the interior of the cell involves yet another protein called G protein. These receptors are the most abundant type of cell surface receptors and form the targets for nearly 50% of currently used therapeutic drugs. It is, therefore, extremely important to unravel how each of these components works, and in particular to know how they work in living cells. This project utilizes state-of-the-art methodologies to examine interactions between receptors and their cognate G proteins, in living cells and in real-time. The work will answer fundamental questions about the nature of G protein-coupled receptor signaling, in particular whether new classes of drugs can be identified that more selectively activate signaling pathways or factors that attenuate signaling. This work has potential for future development of more effective therapeutic agents.Read moreRead less