Regulation Of Ca2+/calmodulin Dependent Protein Kinase Kinase-2 By Phosphorylation
Funder
National Health and Medical Research Council
Funding Amount
$570,334.00
Summary
This project will study the regulation of an enzyme called CaMKK2, which plays a pivotal role in controlling a number of important biological functions including brain development, regulation of appetite, energy metabolism and blood pressure. Understanding how this enzyme is regulated may open new avenues for treating Type 2 diabetes, obesity, and cardiovascular disease.
Skeletal Muscle Signal Transduction Related To Exercise, Metabolic Disease And Human Health
Funder
National Health and Medical Research Council
Funding Amount
$557,298.00
Summary
Exercise is one of the best prevention and treatment strategies for all major human diseases. Despite these well documented advantages, we still do not know exactly how exercise produces these benefits at the molecular level. A comprehensive understanding of this will lead to new avenues to treat many diseases. This project will monitor thousands of molecular changes that occur in human muscle biopsies following exercise and create the world’s first molecular blueprint of exercise.
Biochemical And Molecular Dissection Of The Mechanisms Controlling Ribosome Biogenesis By The PI3K/AKT/mTOR/MYC Network
Funder
National Health and Medical Research Council
Funding Amount
$545,180.00
Summary
Ribosome synthesis and function are critical for normal cell growth and division and hence this process is exquisitely regulated. Conversely, de-regulated cell growth can lead to cancer. We have identified new roles for the AKT and SGK families of kinases in controlling this process. This proposal aims to establish the mechanisms by which these enzymes control ribosome synthesis to better understand growth control and to provide insight for targeting these pathways in growth driven cancers.
Dissecting Rapamycin Sensitive And Insensitive Effects Of MTOR
Funder
National Health and Medical Research Council
Funding Amount
$1,183,241.00
Summary
All cells possess machinery that can sense nutrient availability and trigger cell growth and nutrient storage pathways. However, nutrient oversupply is detrimental to health. Recently, it was shown that drugs that inhibit the nutrient sensors have life extending effects. Our laboratory has discovered a novel mechanism by which these drugs might be mediating these beneficial effects that could change the way we think about the beneficial effects of these drugs and their mode of action
Role Of Oxidative Stress In Activating ATM To Protect Against Neurodegeneration
Funder
National Health and Medical Research Council
Funding Amount
$570,334.00
Summary
ATM is the protein defective in the human genetic disorder ataxia-telangiectasia (A-T). This project is designed to investigate how this protein is activated by oxidative stress. The study is largely a mechanistic one, to investigate changes occurring in ATM as part of the activation process. There is evidence that ATM exists in the cytoplasm in neuronal cells and understanding its function in these cells may assist in understanding the basis for neurodegeneration in A-T.
Molecular Regulation Of The Serine-Threonine Kinase ULK1 In Autophagy
Funder
National Health and Medical Research Council
Funding Amount
$299,431.00
Summary
Autophagy or self eating is a basic cellular process and can have either beneficial or adverse effects in cancer. It is essential to determine the status of autophagy in patients before considering drugs that block autophagy for therapy. A protein called ULK1 is needed for autophagy and may emerge as a pathological marker for autophagy in cancer as well as a potential drug target. This grant proposal will study ULK1 regulation and will lay the scientific foundation for its medical application.
New Insights Into Mechanisms That Coordinate Kinase Signalling And Molecular Motors In Mitosis: A Novel Role For The Protein Scaffold WD-repeat Protein 62 (WDR62).
Funder
National Health and Medical Research Council
Funding Amount
$529,122.00
Summary
Proteins perform all functions within a cell. Commonly, different proteins are assembled into large complexes to carry out processes, such as cell division, with significant implications for human health. Scaffold proteins facilitate the proper assembly of large complexes but are a poorly understood protein class. We will perform molecular analysis of a newly discovered scaffold, WDR62, to define how it drives cell division and reveal how this can be exploited to develop new anti-cancer drugs.
Dissecting The Role Of Selective Insulin Resistance In Type 2 Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$980,624.00
Summary
Insulin resistance is a clinical condition where insulin, secreted from the pancreas in response to meals, is unable to fulfill its normal function. It is intimately linked to obesity and associated diseases - type 2 diabetes, cancer and cardiovascular disease. This proposal examines mechanisms contributing to insulin resistance and how insulin resistance leads to disease. We will identify drug targets with improved specificity and lead to novel insight into the risks of current treatments.
An AMPK Myristoyl Switch Controls AMP Mediated Metabolic Stress Signaling
Funder
National Health and Medical Research Council
Funding Amount
$524,820.00
Summary
This project is investigating an enzyme called AMP-activated protein kinase that plays a pivotal role in controlling how our bodies regulate energy metabolism in response to exercise and diet. Improved understanding of how this enzyme is regulated may provide new therapeutic methods for mimicking the beneficial effects of diet and exercise to treat multiple metabolic diseases including obesity, Type 2 diabetes and cardiovascular disease.
C-Jun N-terminal Kinase Regulation Of Microtubule Destabilizer, Stathmin - A Novel Cytoprotective Pathway
Funder
National Health and Medical Research Council
Funding Amount
$550,230.00
Summary
The loss of heart muscle cells during heart attack and heart failure worsens the severity of heart disease. We will study how to protect heart muscle cells by identifying the molecules involved in controlling survival responses. We will use this knowledge to prevent heart muscle cells from dying when exposed to a range of normally harmful conditions. Our study has the potential to prevent heart muscle cell loss, improve heart function and prevent muscle damage in heart disease.