Analysis Of The C-terminal Hypervariable Region Of Ras Proteins
Funder
National Health and Medical Research Council
Funding Amount
$419,241.00
Summary
In human cancers one or more of the signaling pathways leading from growth factor receptors at the cell surface to the nucleus where cell division is initiated are subverted. For example, a protein called Ras, that regulates one major signaling pathway, is mutated in 90% of pancreatic cancers, 50% of colon cancers and 30% of acute leukaemias. This leaves Ras and the signaling pathway permanently switched on causing uncontrolled cell proliferation. The clinical impact of drugs that could neutrali ....In human cancers one or more of the signaling pathways leading from growth factor receptors at the cell surface to the nucleus where cell division is initiated are subverted. For example, a protein called Ras, that regulates one major signaling pathway, is mutated in 90% of pancreatic cancers, 50% of colon cancers and 30% of acute leukaemias. This leaves Ras and the signaling pathway permanently switched on causing uncontrolled cell proliferation. The clinical impact of drugs that could neutralise Ras function in these tumours is potentially enormous. Our previous work demonstrated that Ras must be attached to the inner surface of the cell membrane in order to function properly. This project now seeks to understand exactly how Ras gets to and attaches to the cell membrane. Once we understand this mechanism drugs can be designed to block Ras getting to the membrane. Such drugs should neutralize the effect of Ras in tumours and control cell proliferation. In fact, our previous study has already led to the identification of the first generation of anti-Ras drugs that work on this principle.Read moreRead less
I am interested in determining the molecular basis of immune recognition of foreign and self-antigens in the context of viral, tumor and auto-immunity as well as transplantation. In addition to fundamental observations this knowledge is also applied in va
Molecular Identification Of Causative Genetic And Epigenetic Alterations That Induce And Promote Colorectal Cancer
Funder
National Health and Medical Research Council
Funding Amount
$381,821.00
Summary
The majority of mouse models currently employed to study colorectal cancer have two failings. The first is that they tend to focus on small intestinal cancers rather than colorectal cancers. It is important to note that small intestinal cancers are in the minority of gastrointestinal cancers in humans. The second problem is that the genetic lesions introduced into mice are mostly in all cells throughout development. This is a poor representation of the random nature of genetic changes that under ....The majority of mouse models currently employed to study colorectal cancer have two failings. The first is that they tend to focus on small intestinal cancers rather than colorectal cancers. It is important to note that small intestinal cancers are in the minority of gastrointestinal cancers in humans. The second problem is that the genetic lesions introduced into mice are mostly in all cells throughout development. This is a poor representation of the random nature of genetic changes that underpin the probable cause of colon cancer. We therefore propose to genetically engineer unique mouse models that focus on colon cancer to most closely replicate the situation in human disease. These models will then be available to others and us to develop and test therapies to prevent and-or treat colorectal cancer that will ultimately be used in patients.Read moreRead less
The Role Of Seipin In Lipid Metabolism And Adipogenesis
Funder
National Health and Medical Research Council
Funding Amount
$397,749.00
Summary
The prevalence of obesity and its related disorders has reached an alarming level in Australia and other developed countries. Obesity is characterized by accumulation of fully-differentiated adipocytes loaded with lipid droplets (LDs). Therefore, understanding the cellular dynamics of LDs and the molecular mechanisms of adipogenesis (adipocyte differentiation) is of crucial importance in our battle against obesity. Our proposed study will help undertand the mechnisams of obesity.
Elucidating Metabolic Dysregulation In Alzheimer’s Disease: Profiling The Peripheral Immune Cell Lipidome To Unravel Pathological Mechanisms.
Funder
National Health and Medical Research Council
Funding Amount
$645,205.00
Summary
Both the immune system and lipid metabolism have been identified to be important in Alzheimer’s disease (AD). With the failures of all clinical trials attempting to treat AD, we seek to determine a way to both better diagnose individuals with AD and to identify people at increased risk. This project uses a novel profiling technique to characterise the lipid composition of immune cells to diagnose, predict risk, monitor the disease and to identify potential disease modifying therapeutic targets.
Lipoprotein Metabolism And Mutations Of The APOB Gene Causing Familial Hypobetalipoproteinaemia
Funder
National Health and Medical Research Council
Funding Amount
$396,179.00
Summary
Cardiovascular disease is an increasing problem in Australia, however, the cause of atherosclerosis is incompletely understood. A protein, known as apolipoprotein (apo) B, plays a central role in lipoprotein metabolism. Elevated levels of apoB are characteristic of many forms of hypercholestrolaemia. Familial combined hyperlipidaemia and polygenic hypercholesterolaemia are two common inherited disorders of lipoprotein metabolism that are characterised by elevated apoB levels in the blood and ear ....Cardiovascular disease is an increasing problem in Australia, however, the cause of atherosclerosis is incompletely understood. A protein, known as apolipoprotein (apo) B, plays a central role in lipoprotein metabolism. Elevated levels of apoB are characteristic of many forms of hypercholestrolaemia. Familial combined hyperlipidaemia and polygenic hypercholesterolaemia are two common inherited disorders of lipoprotein metabolism that are characterised by elevated apoB levels in the blood and early atherosclerosis. In contrast, familial hypobetalipoproteinemia is a rare inherited disorder of lipoprotein metabolism characterised by very low levels of cholesterol and apoB in the blood and resistance to atherosclerosis and cardiovascular disease. The focus of this research project is to explore the regulation of apoB metabolism using individuals from unique families with familial hypobetalipoproteinaemia. First, we will determine and characterise the alterations in the APOB gene causing the low cholesterol levels in families with familial hypobetalipoproteinaemia. Second, we will determine if these apoB alterations affect the production and-or clearance of blood fats, or lipoproteins in affected individuals, when compared to controls, by performing metabolic studies. The proposed human in vivo metabolic studies will lead to a better understanding of the mechanism(s) involved in the assembly, secretion, transport, and clearance of plasma apoB-containing lipoproteins. Furthermore, these studies may reveal new protective mechanisms and potentially aid in the development of strategies to suppress over-production of apoB-containing lipoproteins in reciprocal conditions such as familial combined hyperlipidaemia or polygenic hypercholesterolaemia.Read moreRead less
I am a lipid biochemist-cell biologist determining the molecular mechanisms of disorders of lipid metabolism and developing treatments for such disorders. The diseases where lipid metabolism plays a key role include cardiovascular diseases (such as coronary artery disease), metabolic disorders (such as diabetes), some infectious diseases (such as HIV) and neurological disorders (such as Alzheimer disease).
Deciphering Posttranslational Codes Of The Dioxin Receptor
Funder
National Health and Medical Research Council
Funding Amount
$540,083.00
Summary
The dioxin receptor (DR) is a protein which protects human cells by binding xenobiotics, ie foreign or anti-nutritional chemicals found in food sources and the general environment. When these chemicals bind the DR, it becomes an active gene regulatory protein, turning on genes that are involved in breakdown and excretion of the xenobiotics. Recently it has been found that the DR performs other important functions which are unrelated to xenobiotic breakdown. These include blood vessel development ....The dioxin receptor (DR) is a protein which protects human cells by binding xenobiotics, ie foreign or anti-nutritional chemicals found in food sources and the general environment. When these chemicals bind the DR, it becomes an active gene regulatory protein, turning on genes that are involved in breakdown and excretion of the xenobiotics. Recently it has been found that the DR performs other important functions which are unrelated to xenobiotic breakdown. These include blood vessel development in the embryonic liver and hormone production during the estrous cycle. These observations imply that natural physiological mechanisms also exist for activating the DR, providing it with a separate code to perform these innate functions. A number of man-made chemicals, such as dioxins and PCBs, are especially good at activating the DR. However, they have chlorinated chemical structures, which are not broken down by the protective system. This creates a wide range of severe toxic responses. It has been established that toxicities result from persistent hyperactivation of the DR, but how this hyperactivation induces the toxic outcomes is not known. As the DR has roles in early development and estrogen production, this project will investigate how the DR becomes activated to perform these functions. Our initial experiments have shown that the DR can be activated by normal cell signalling systems, which induce distinct modifications (a distinct code) to the protein. We are comparing this code of modifications to those induced by xenobiotics which are able to be broken down, and dioxins which are resistant to breakdown. We hypothesise that dioxins will give an excessive code of activating modifications, resulting in uncontrolled regulation of genes used in both the developmental and xenobiotic breakdown pathways. We will explore the hypothesis that this gross loss of gene regulatory control underpins the multifarious toxicities of dioxin poisoning.Read moreRead less