Advanced Glycation End Products As Risk Factors For Type 1 Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$80,040.00
Summary
There is no cure for type 1 diabetes which manifests in children and adolescents resulting in the need for 5 injections of insulin each day. During this scholarship period, we aim to discover new genetic and blood biomarkers for disease onset in children for use in new born and childhood screening. In addition we will determine if specific environmental factors called advanced glycation end products can contribute to type 1 diabetes via interactions with a specific gene, RAGE.
Alterations In Secretion And Gene Expression In Pancreatic Beta Cells Exposed To Lipid.
Funder
National Health and Medical Research Council
Funding Amount
$425,250.00
Summary
The project is aimed at a better understanding of the way in which fats control gene expression in the pancreatic beta cells of the islets of Langerhans. Because changes in gene expression are to likely to explain why exposure of these cells to fat disrupts their ability to release insulin, identification of these genes could explain why only some obese people develop Type 2 diabetes.
Correlative Structure-function Studies Of Cis- And Trans-Golgi Membrane Traffic In Mammalian Cells
Funder
National Health and Medical Research Council
Funding Amount
$649,531.00
Summary
This project combines imaging by light and electron microscopy with additional techniques for studying protein function at the molecular level, to elucidate how changes in the 3D organisation of cellular machinery can lead to fundamental changes in the function and health of mammalian cells. Although this work includes detailed investigation of the 'insulin factory', it has the potential to modify established concepts on membrane traffic and protein secretion well beyond the field of diabetes.
Metabolic Wiring In Adipocytes - Unique Role In Maintaining Long-term Health
Funder
National Health and Medical Research Council
Funding Amount
$1,077,886.00
Summary
Fat cell metabolism is wired to optimize the cell’s ability to make and store lipid while programming the cell to fulfil its function in whole body metabolism. We will: 1) map fat cell metabolism under optimal and insulin resistant conditions; 2) explore the role of 3 nodes in his metabolic circuit predicted as control points; 3) use a novel genetically engineered mouse model to explore the functional significance of fat cell metabolism in whole body insulin sensitivity.
Most common diseases of ageing like diabetes and cancer have proven intractable because much of our knowledge is limited to individual molecules. This proposal takes a global approach to complex diseases, utilising quantitative high-resolution methods and computational modelling. This research will lead to a completely new way of thinking about complex diseases providing a range of completely novel treatment options.
Transcription-based Identification Of Insulin Resistance Subtypes
Funder
National Health and Medical Research Council
Funding Amount
$341,883.00
Summary
A key feature of type 2 diabetes is the failure of metabolic tissues such as muscle and fat to respond to normal levels of insulin. This 'insulin resistance' is caused by a number of mechanisms. We will use cutting-edge technology to identify small sets of genes that define each variety of insulin resistance. These gene sets will be used to diagnose sub-types of insulin resistance and will facilitate the development of personalised therapies to effectively treat individuals with type 2 diabetes.
Ciliary Neurotrophic Factor: A Novel Theraputic Agent For The Prevention Of Muscle Insulin Resistance
Funder
National Health and Medical Research Council
Funding Amount
$602,673.00
Summary
In 1995 leptin was discovered and scientists world-wide hoped that this was the great panacea in the treatment of obesity related disorders. Alas, from 1995-1997 the identification of a novel cytokine inducible compound termed suppressor of cytokine signaling (SOCS) that negatively regulated leptin signalling and lead to leptin resistance, quashing hopes for a viable anti-obesogenic drug. Recently, however, work from our group has demonstrated that the neuropoietic cytokine, ciliary neurotrophic ....In 1995 leptin was discovered and scientists world-wide hoped that this was the great panacea in the treatment of obesity related disorders. Alas, from 1995-1997 the identification of a novel cytokine inducible compound termed suppressor of cytokine signaling (SOCS) that negatively regulated leptin signalling and lead to leptin resistance, quashing hopes for a viable anti-obesogenic drug. Recently, however, work from our group has demonstrated that the neuropoietic cytokine, ciliary neurotrophic factor (CNTF), can act in an anti-obesogenic fashion in a manner similar to leptin. However, unlike leptin, when we place rodents on a high fat diet, the effects of CNTF persist and override induction SOCS proteins. This project will examine the biochemical pathways that allow the actions of CNTF to persist in the presence of diet-induced obesity. This is of major significance because in completing this work, the potential for the development of peripheral tissue drug targets for the treatment of obesity related diseases are both tangible and realistic.Read moreRead less
I am a cell biologist-whole body physiologist determining the cellular and molecular mechanisms that lead to insulin resistance in insulin sensitive tissues such as skeletal muscle, liver and adipose tissue. My work primarily focuses on the role of inflam