REGULATION OF LIPID METABOLISM IN SKELETAL MUSCLE BY IDOL – A Novel Degrader Of The Very Low Density Lipoprotein Receptor
Funder
National Health and Medical Research Council
Funding Amount
$557,162.00
Summary
More than 1 in 5 Australians are estimated to have increased levels of fats (triglycerides; TGs) in the blood, commonly due to excess dietary intake or genetics. The excess TGs are deposited in skeletal muscle where they can cause insulin resistance, increasing the risk of developing diabetes, the fastest growing chronic condition in Australia. I will examine whether a recently identified protein, IDOL, can reduce accumulation of TGs in skeletal muscle and protect against insulin resistance.
Protein Homeostasis, Protein Aggregation And Amyotrophic Lateral Sclerosis
Funder
National Health and Medical Research Council
Funding Amount
$428,065.00
Summary
There is a desperate need for biomarkers and therapeutics for Motor Neurone Disease (MND). Mutations in a growing list of genes are implicated as a cause of MND, although the way these cause MND remains a mystery. I aim to build a uniquely positioned research team that approaches this problem from a protein centric view and incorporating strategic collaborative efforts to the understanding of the pathogenesis of MND; the longterm goal of which is translation to biomarkers and therapeutics.
The Role Of Copper In Ubiquitin-dependent Protein Degradation In Alzheimer's Disease
Funder
National Health and Medical Research Council
Funding Amount
$588,622.00
Summary
Ubiquitin’s are small proteins that tag other proteins in a process known as “Ubiquitination”. Often this is to target them for degradation once they are no longer needed i.e. to take out the rubbish. This process is disrupted in Alzheimer’s disease (AD), which may contribute to the disease. This project aims to find out if copper, an essential metal for life, is required for this process. Drugs that are designed to deliver copper to brain cells have been effective in small AD clinical trials.
Characterising An Important Control Point In Cholesterol Synthesis Beyond HMG-CoA Reductase
Funder
National Health and Medical Research Council
Funding Amount
$480,739.00
Summary
The statins are the ‘go-to’ drugs for treating heart disease; blocking a very early, highly-controlled step in the pathway producing cholesterol. However, they inhibit the production of other vital molecules which explains why some patients do not tolerate them. We have identified that a later enzyme in this pathway is also highly controlled and here aim to characterise the molecular mechanisms involved. This work could translate into the development of even safer drugs for treating cholesterol- ....The statins are the ‘go-to’ drugs for treating heart disease; blocking a very early, highly-controlled step in the pathway producing cholesterol. However, they inhibit the production of other vital molecules which explains why some patients do not tolerate them. We have identified that a later enzyme in this pathway is also highly controlled and here aim to characterise the molecular mechanisms involved. This work could translate into the development of even safer drugs for treating cholesterol-related diseases.Read moreRead less
The Role Of A Novel Extracellular Matrix Protein, WARP, In Cartilage Development, Function And Pathology
Funder
National Health and Medical Research Council
Funding Amount
$482,500.00
Summary
The environment outside all cells is absolutely essential for normal growth and development. In order to undertand many disease and developmental processes it is critical that we acquire a detailed understanding of the various extracellular matrix components and how they interact to form a functional extracellular matrix. We recently discovered a new extracellular matrix protein which we have named WARP for von Willebrand factor A-domain-related protein. Our experiments demonstrate that WARP is ....The environment outside all cells is absolutely essential for normal growth and development. In order to undertand many disease and developmental processes it is critical that we acquire a detailed understanding of the various extracellular matrix components and how they interact to form a functional extracellular matrix. We recently discovered a new extracellular matrix protein which we have named WARP for von Willebrand factor A-domain-related protein. Our experiments demonstrate that WARP is an important constituent of the three-dimensional structure of the extracellular matrix of the articular surface of cartilage. We can show that WARP forms large-scale structures in tissue culture experiments and in extracts from mouse cartilage, and we have some new data which suggests that WARP interacts specifically with collagen II, a large and quantitatively major component of cartilage. We will explore the function of WARP in cartilage and include in vitro experiments that will reveal information about its distribution, tissue forms, and interactions with other extracellular matrix components (PART 1). To define the in vivo role of WARP we will generate a WARP gene knockout mouse (PART 2). These experiments will provide valuable information about the structure of the cartilage in the joint on the surface of bone and in particular the function of WARP in this structure. Since WARP is at the articular cartilage surface we asked whether WARP is lost in cartilage degeneration. In cartilage tissue grown in vitro under conditions that promote cartilage degradation, WARP is fragmented and released from the cartilage surface. We will explore this further in in vitro and in vivo models of cartilage breakdown (PART 3). Thus, in addition to promoting a new understanding of cartilage structure WARP has the exciting potential to become a specific biomarker for arthritis a major joint degenerative disease with high medical and financial cost to the community.Read moreRead less
Our goal is to discover new mechanisms involved in our cells’ delicate balancing act with respect to cholesterol levels. Understanding how production of cholesterol is controlled in our cells is key to developing new drugs aimed at preventing its excessive accumulation. This will have long-term benefits for health considering that a cellular imbalance in cholesterol is involved in two of the most common conditions threatening the health of Australians, namely heart disease and Alzheimer’s diseas ....Our goal is to discover new mechanisms involved in our cells’ delicate balancing act with respect to cholesterol levels. Understanding how production of cholesterol is controlled in our cells is key to developing new drugs aimed at preventing its excessive accumulation. This will have long-term benefits for health considering that a cellular imbalance in cholesterol is involved in two of the most common conditions threatening the health of Australians, namely heart disease and Alzheimer’s disease.Read moreRead less