Generating Tumour-Specific Dendritic Cells For Cancer Therapy
Funder
National Health and Medical Research Council
Funding Amount
$288,210.00
Summary
Therapies using the immune system are showing promise for cancer treatment, particularly for melanoma, but complete durable responses are few and improvements are needed. We believe that such immunotherapies, in their current form, fail to sufficiently mimic a natural immune reaction to disease, and therefore fall short of effectively controling cancer. In particular, an alarm (danger signal) is not produced within tumour as it would be when the body is challenged by infectious agents. Such dang ....Therapies using the immune system are showing promise for cancer treatment, particularly for melanoma, but complete durable responses are few and improvements are needed. We believe that such immunotherapies, in their current form, fail to sufficiently mimic a natural immune reaction to disease, and therefore fall short of effectively controling cancer. In particular, an alarm (danger signal) is not produced within tumour as it would be when the body is challenged by infectious agents. Such danger signals are critical for the immune system to respond effectively and for white blood cells of the immune system to find their way to the disease organism and eliminate it. The strongest danger signals are produced by a type of white blood cell known as a dendritic cell (DC). These cells detect infectious agents and produce biochemical alarm molecules that alert the entire immune system to the danger resulting in powerful action against the disease. However, tumours are really just a part of our own body and no danger signal is produced. It is our aim to use genetic modification to make DC see tumours as a threat and produce danger signals. These gene-modified DC either alone, or in combination with other immunotherapies, may lead to destruction of tumours.Read moreRead less
Impaired Bone Remodelling Leads To Failure Of Orthopaedic Prostheses
Funder
National Health and Medical Research Council
Funding Amount
$515,917.00
Summary
The failure of bone prostheses is becoming a major health problem. More than 26,000 hip, and an equal number of knee, replacements were performed in Australia in 2002 with the number increasing between 5%-10% each year for the previous 10 years. Disturbingly, the incidence of revision hip surgery in Australia is now more than 15%, meaning that, despite the impressive success of joint replacement surgery, a significant number of arthroplasties fail. It is becoming more common for young, active in ....The failure of bone prostheses is becoming a major health problem. More than 26,000 hip, and an equal number of knee, replacements were performed in Australia in 2002 with the number increasing between 5%-10% each year for the previous 10 years. Disturbingly, the incidence of revision hip surgery in Australia is now more than 15%, meaning that, despite the impressive success of joint replacement surgery, a significant number of arthroplasties fail. It is becoming more common for young, active individuals to receive joint replacement surgery to improve their quality of life. This, combined with increasing life expectancy, and the known higher rate of failure of joint replacements in younger patients, means that the morbidity of a failed replacement, and the mobidity and associated mortality of revision surgery, will become an increasingly important health issue, with a major impact upon health budgets. The overwhelming majority of hip and knee prostheses have metal or ceramic on polyethylene bearing surfaces. It is now apparent that most implants fail due to bone loss around them leading to loosening, and evidence is accumulating that polyethylene wear particles are a major contributing factor to this process. It is therefore vital that we obtain better understanding of the causes of implant failure in order to extend the life of these implants and this project is designed to do so.Read moreRead less
LPS-regulated SNAREs And Control Of Cytokine Secretion In Macrophages.
Funder
National Health and Medical Research Council
Funding Amount
$470,750.00
Summary
TNF(tumour necrosis factor alpha) is a potent proinflammatory cytokine secreted by immune activated macrophages. TNF has essential roles in host defense, tumour killing and energy metabolism. Excessive secretion of TNF in acute and chronic inflammatory conditions, such as septic shock, Crohn s disease, rheumatoid arthritis and in cancer has many severe, even fatal, consequences. Improved anti-TNF therapeutics are needed for clinical management in all of these conditions. Our studies are focused ....TNF(tumour necrosis factor alpha) is a potent proinflammatory cytokine secreted by immune activated macrophages. TNF has essential roles in host defense, tumour killing and energy metabolism. Excessive secretion of TNF in acute and chronic inflammatory conditions, such as septic shock, Crohn s disease, rheumatoid arthritis and in cancer has many severe, even fatal, consequences. Improved anti-TNF therapeutics are needed for clinical management in all of these conditions. Our studies are focused on investigating how macrophages synthesize and secrete TNF, with the ultimate goal of characterizing the molecules and vesicles in the TNF secretory pathway. Our recent findings show the expression of SNARE proteins, part of the vesicle docking and fusion machinery, is regulated in concert with cytokine secretion and other trafficking changes in activated macrophages. We identified the proteins Syntaxin4, Munc-18c and SNAP-23 as the specific t-SNARE complex that regulates TNF delivery to the cell surface. In the proposed studies we will investigate how SNAREs are regulated during macrophage activation by studying their gene expression and protein modifications. We have developed a single-cell assay to measure TNF trafficking in macrophages; this allows the identification of molecules with roles in TNF secretion and it will be used in a series of experiments to identify the specific v-SNARE proteins that partner the t-SNARE for TNF delivery. Finally we will use live cell imaging to investigate how and where TNF is delivered to the macrophage cell surface and membrane fractionation to examine a role for membrane microdomains in organizing SNARE-mediated TNF secretion. Manipulation of SNAREs, using data generated by these studies, holds potential for the development of new anti-TNF therapies.Read moreRead less
What drives the pain associated with inflammation is unknown as is the relationship between pain and the extent of tissue damage associated with disease, for example, arthritis. Our laboratory has shown that a particular protein is a key mediator of inflammatory pain. The project is to understand how this particular protein promotes pain, including how it sensitzes neurons.
Proatherogenic CD4 NKT Cells And Atherosclerosis: Molecular Mechanisms And Therapeutic Strategies For Suppression
Funder
National Health and Medical Research Council
Funding Amount
$504,348.00
Summary
Immune cells called CD4+ iNKT cells are known to be activated by lipids which initiate development of atherosclerosis, a disorder of blood vessels which is responsible for most heart attacks and strokes. We aim to investigate how these cells contribute to the development of this important blood vessel disoder and examine potential ways of inhibiting their activation to prevent heart attacks and strokes.
Developmental-associated Dysregulation Of Innate Anti-microbial Immunity In Early Life As A Determinant Of Susceptibility To Atopic Asthma
Funder
National Health and Medical Research Council
Funding Amount
$570,334.00
Summary
Previous NHMRC-sponsored research from the applicants has demonstrated that one of the strongest risk factors for subsequent development of asthma is having chest infections during infancy that are so severe that they trigger symptoms of fever and wheeze. It is not known what predisposes susceptible infants to these severe infections, and this project will attempt to define the mechanisms of susceptibility.
Monomeric C-reactive Protein As Pathogenic Factor And Therapeutic Target In Athero-thrombotic Disease.
Funder
National Health and Medical Research Council
Funding Amount
$86,570.00
Summary
Vascular disease of the heart, brain and limbs affects many people in Australia and throughout the world. Current treatments assist in slowing the development and progression of established disease, but new developments are required. This project will investigate the role of C-reactive protein in vascular disease and evaluate its potential as a new therapeutic target in the future.
THE ROLE OF THE HEPATOCYTE HEDGEHOG PATHWAY IN PROGRESSIVE LIVER INJURY
Funder
National Health and Medical Research Council
Funding Amount
$570,876.00
Summary
This research plan investigates the role of a pathway, known as the Hedgehog pathway, in the development of liver disease which can result in end-stage scarring known as cirrhosis and even lead to liver cancer (known as Hepatocellular carcinoma). Hepatocellular carcinoma is the globally the third most common cause of cancer death and our research will help to better understand how liver injury develops and how this then leads to liver cancer.
Discovery And Characterisation Of Novel Tick Evasins As Inhibitors Of Chemokine-mediated Inflammation
Funder
National Health and Medical Research Council
Funding Amount
$654,847.00
Summary
An important aspect of inflammatory diseases is the migration of white blood cells into the affected tissues. This is controlled by a group of proteins called chemokines. Ticks, which live on mammalian hosts, produce proteins called evasins, which interact with host chemokines and thereby prevent inflammatory responses. This project will discover new tick evasins, study their chemokine interactions and investigate their ability to block inflammation in allergic asthma.
Determining The Synergistic Effects Of Complementary Medicines On Pro-inflammatory Cytokines,
Funder
National Health and Medical Research Council
Funding Amount
$290,412.00
Summary
Diseases like influenza, commonly called ‘the flu’, produce symptoms such as fever, headaches, lethargy and lack of appetite. What most people don’t realise is that it is not the influenza virus that produces these symptoms, but the body’s immune response to the influenza virus. This immune response comes about because the influenza virus stimulates cells to produce molecules called cytokines, and cytokines have many effects in the body, including causing fever and a lack of appetite. In severe ....Diseases like influenza, commonly called ‘the flu’, produce symptoms such as fever, headaches, lethargy and lack of appetite. What most people don’t realise is that it is not the influenza virus that produces these symptoms, but the body’s immune response to the influenza virus. This immune response comes about because the influenza virus stimulates cells to produce molecules called cytokines, and cytokines have many effects in the body, including causing fever and a lack of appetite. In severe infections like those caused by the influenza virus responsible for the pandemic of 1918, and during “bird ‘flu” (H5N1) infections, people die because the immune response becomes overwhelming. Cytokines produced during these sorts of responses are actually very harmful, even though in small amounts they help to kill the virus and cure the infection. Researchers working in this field have likened these severe responses to a “cytokine storm”. This project focusses on finding alternative therapies such as those used in Chinese medicine to prevent a cytokine storm happening, so that if an influenza pandemic occurs these treatments could be quickly made available to everyone. Examples are the Chinese herbs Angelica sinensis and Salvia miltiorrhiza. Recent laboratory studies in New York have shown that both of these herbs have potent cytokine effects, decreasing levels of an inflammatory cytokine known to be associated with death in both malaria and sepsis. Our study aims to closely examine the effects of these Chinese herbs, as well as other commercially available herbal extracts, and traditional combinations of herbs, to find synergies between them that could be used to treat severe influenza infections.Read moreRead less