Therapeutic Targeting Of A New Growth Factor In Mesothelioma
Funder
National Health and Medical Research Council
Funding Amount
$317,775.00
Summary
Malignant mesothelioma is an aggressive and incurable cancer. This study will build on our recent data showing a protein termed FGF-9, not previously linked with mesothelioma, could significantly stimulate mesothelioma growth. This project will examine the biologic activities of FGF-9 and its receptors in mesothelioma, and the therapeutic benefits of antagonizing FGF-9 in mesothelioma in vivo.
Identification Of Novel Biomarkers And Risk Factors For Cardiovascular Disease
Funder
National Health and Medical Research Council
Funding Amount
$425,048.00
Summary
Heart disease is the leading cause of death in Australia. In this fellowship, I will investigate different markers in the blood and risk factors that can help to identify people at an increased risk of developing heart disease. The ultimate aim of this project is to identify blood markers or factors that can be used to identify and treat people at the early stages of heart disease, thus reducing the death rate and associated economic burden of the disease.
Does Enhanced Vitamin D Activity In Bone Heal The Skeleton In Disorders Of FGF23 Excess?
Funder
National Health and Medical Research Council
Funding Amount
$855,925.00
Summary
X-linked hypophosphatemia (XLH) is a genetic disorder which results in phosphate wasting and rickets. This severe disorder has no effective treatment. We have compelling new evidence that the rickets in XLH is not primarily a disorder of low blood phosphate, but rather specific issue of low cellular levels and activity of vitamin D (1,25D) within bone. This proposal is designed to specifically demonstrate this new concept and outline a new paradigm for a new XLH treatment.
Analysis Of FGF Receptor Signalling Involved In Lens Cell Proliferation And Differentiation
Funder
National Health and Medical Research Council
Funding Amount
$343,028.00
Summary
Cataract, the loss of transparency of the eye lens, is the leading cause of blindness in the world. An eventual cure for cataract depends on a better understanding of the basic molecular processes in the normal and cataractous lens. Our research has focussed on identifying the molecules that control the formation and maintenance of the lens. Growth factors are important regulators of cell behaviour and our studies have provided compelling evidence that members of the FGF growth factor family pla ....Cataract, the loss of transparency of the eye lens, is the leading cause of blindness in the world. An eventual cure for cataract depends on a better understanding of the basic molecular processes in the normal and cataractous lens. Our research has focussed on identifying the molecules that control the formation and maintenance of the lens. Growth factors are important regulators of cell behaviour and our studies have provided compelling evidence that members of the FGF growth factor family play pivotal roles in lens developmental biology by influencing lens cell proliferation and differentiation. An important finding from our laboratory is that FGF induces lens epithelial cell proliferation and differentiation at different concentrations. The FGFs elicit intracellular responses upon binding to and activating cell surface FGF receptors (FGFRs). The FGFRs are membrane bound tyrosine kinases which upon activation, activate specific signalling pathways leading to a specific cellular response. To understand how FGFs mediate and regulate different responses in lens cells, namely cell proliferation and fibre differentiation, we plan to examine the role of FGFRs in normal lens development using genetically altered FGFRs that will be expressed specifically in lenses of transgenic mice. While it is known that four different FGF receptor genes are expressed by the normal developing lens, it is unknown what role each of these play in the process of lens cell proliferation and differentiation. In addition, as we can reproduce a specific FGF-induced lens cellular response in vitro, we will use our lens explant culture system to dissect the signalling pathway(s) downstream from specific receptor activation and correlate this with a specific cellular response. By identifying the molecules and mechanisms that control the cellular processes essential for normal lens development, we can better understand how disruptions of these processes lead to cataract formation.Read moreRead less
Obesity is becoming more common in Australian adults and children, and is a major contributor to a number of diseases including type 2 diabetes, cardiovascular disease and some cancers. Current weight loss strategies using either lifestyle modification (diet and exercise) or drugs are relatively ineffective in the majority of obese individuals. This is partly due to the fact that we have an incomplete knowledge of the factors that regulate weight in humans. In laboratory studies we have shown th ....Obesity is becoming more common in Australian adults and children, and is a major contributor to a number of diseases including type 2 diabetes, cardiovascular disease and some cancers. Current weight loss strategies using either lifestyle modification (diet and exercise) or drugs are relatively ineffective in the majority of obese individuals. This is partly due to the fact that we have an incomplete knowledge of the factors that regulate weight in humans. In laboratory studies we have shown that human fat cell development can be dramatically accelerated by fibroblast growth factor-1 (FGF-1). This growth factor is produced by human endothelial cells, which are cells that line the blood vessels in fat tissue. When human fat cell precursors (preadipocytes) are cultured in the presence of FGF-1 the preadipocytes divide much more rapidly than normal and, additionally, then develop into mature fat cells much more rapidly than normal. These processes involved in development of new fat cells form the basis of fat tissue expansion in the body. The effect of FGF-1 on human fat cell development is far greater in magnitude than that of other known factors that promote fat cell growth. The aim of this project is to determine the actual biochemical pathways that mediate the effect of FGF-1 in promoting fat cell growth and development. Results obtained will provide insight into the cellular and molecular mechanisms regulating expansion of fat tissue mass in humans. Research aimed at identifying these underlying mechanisms, or at potentially contributing or exacerbating factors, is critically important in development of novel and more effective approaches to prevention and treatment of obesity.Read moreRead less