Inherited Muscle Disorders - Gene Discovery, Pathobiology And Therapy.
Funder
National Health and Medical Research Council
Funding Amount
$1,750,277.00
Summary
The project proposed by Professors Nigel Laing and Kathryn North and Dr Kristen Nowak is based upon the results of their successful identification of disease genes for genetic muscle diseases. The project is divided into three parts. In the first part of the project, the research team will identify further novel disease genes, some of which they are already close to finding. In the second part of the project the team will determine how the mutations they have identified in the disease genes actu ....The project proposed by Professors Nigel Laing and Kathryn North and Dr Kristen Nowak is based upon the results of their successful identification of disease genes for genetic muscle diseases. The project is divided into three parts. In the first part of the project, the research team will identify further novel disease genes, some of which they are already close to finding. In the second part of the project the team will determine how the mutations they have identified in the disease genes actually cause the diseases. The aim of this work is to discover targets that may ultimately lead to new therapies for these muscle diseases. In the third and final part of the project, the team will pursue one possible therapeutic approach, which is based upon the understanding of the diseases the researchers have gained from their previous studies. There are currently no cures for these muscle diseases, though symptoms can be treated. The team will determine whether heart actin can replace muscle actin in skeletal muscle and thus might treat the muscle disease.Read moreRead less
Hormonal Control Of Serotli Cell Maturation And Function
Funder
National Health and Medical Research Council
Funding Amount
$512,898.00
Summary
This project will determine the key roles of androgen in the Sertoli cell, a unique highly specialised cell that provides essential nutritional and structural support for sperm production. Androgen acts via the androgen receptor (AR), which is vital for initiating and maintaining sperm development. In current NHMRC-funded research we successfully established new mouse models designed to study AR, in particular its regulation of gene expression, in the Sertoli cell. We revealed that genomic AR ac ....This project will determine the key roles of androgen in the Sertoli cell, a unique highly specialised cell that provides essential nutritional and structural support for sperm production. Androgen acts via the androgen receptor (AR), which is vital for initiating and maintaining sperm development. In current NHMRC-funded research we successfully established new mouse models designed to study AR, in particular its regulation of gene expression, in the Sertoli cell. We revealed that genomic AR activity within Sertoli cells is essential for 'induction' of complete sperm development. Ongoing work will develop unique 'inducible' transgenic models that will allow, for the first time, selective analysis of Sertoli AR in both 'developing' and 'adult' testes. Our innovative models will allow AR function to be switched on or off at any stage of development, providing unique opportunity to determine the key AR-regulated factors and pathways controlling induction, maintenance or restoration of sperm production. In past NHMRC research we created a novel transgenic model to study another major reproductive hormone, FSH. Using the hormone-deficient background of 'hpg' mice, we found that androgen and FSH act synergistically in the developing 'meiotic' germ cells that form sperm. Using the latest microarray gene technology we generated datasets of androgen-regulated genes with or without FSH activity, which combined with our unique transgenic AR and FSH models, will be used to identify key pathways, including those enhanced by androgen-FSH synergism, in the early testicular response. Our research will provide new knowledge of the precise roles and pathways of testicular AR actions, to ultimately identify key genetic and regulatory factors as targets for significantly improved therapy for male infertility, gonadal tumours, or contraception.Read moreRead less
The Sertoli Cell: Master Regulator Of Hormone-induced Spermatogenic Development
Funder
National Health and Medical Research Council
Funding Amount
$563,536.00
Summary
This project will determine the key roles of major hormones (testosterone, follicle-stimulating hormone, Vitamin A) in Sertoli cells, unique highly specialised cells found in the testis that provide essential nutritional and structural support for sperm production. This research will provide new understanding of the biological pathways controlling sperm development, leading to new molecular targets for infertility or cancer treatment or diagnosis, or new contraceptive strategies for men.
Mechanisms Of Insulin Resistance And Diabetes Susceptibility
Funder
National Health and Medical Research Council
Funding Amount
$633,783.00
Summary
The two main forms of diabetes - types 1 (T1D) and 2 (T2D) - pose a major problem. It is difficult to identify what causes diabetes. Recently, people at risk of T1D were found to have insulin resistance, a condition thought typical only of T2D. Excitingly, we discovered that the best T1D animal model also shows insulin resistance, and we used it to map important genes. We will now identify these genes. This will help us understand the disease process and to develop better treatments for it.
Building a death-defying islet beta cell Type I diabetes results when the cells that produce insulin (the islet beta cells) are killed by the immune system. The beta cell, like any other cell in the body, can be induced to die by activation of a process that leads to cell suicide. During this process, enzymes dismantle the structure of the cell and the remains are eaten by neighboring cells. In diabetes, the stimulus for beta cell suicide is provided by a number of agents most of which are made ....Building a death-defying islet beta cell Type I diabetes results when the cells that produce insulin (the islet beta cells) are killed by the immune system. The beta cell, like any other cell in the body, can be induced to die by activation of a process that leads to cell suicide. During this process, enzymes dismantle the structure of the cell and the remains are eaten by neighboring cells. In diabetes, the stimulus for beta cell suicide is provided by a number of agents most of which are made by the T cells of the immune system. Our aim is to interfere with this cell suicide process and engineer a beta cell that can resist T cell attack. Because genetically manipulated mice provide the flexibility we need to add and subtract genes from the beta cell we will use them as a model to build a death-defying beta cell. We will investigate three strategies. Firstly, cells will be engineered to express a molecule (CD30 ligand) which recognizes a protein on the surface of the attacking T cells and in so doing, sends a signal to the T cells to stop proliferating. Secondly, we will remove proteins (CD95, TNFRI) from the surface of the beta cell, that attacking T cells use to set in motion the cell suicide process. Thirdly, we will engineer beta cells that express inside themselves, cell death inhibitor proteins (Bcl-2, CrmA, p35) that can prevent the automatic process of cell suicide. It is our hope that studies with death-defying beta cells will find a new way to manipulate islet tissue for transplantation. In patients with diabetes, the beta cells have all been destroyed but the attacking T cells still remain. As a result, transplants of new beta cells are rapidly damaged. Beta cells that can resist ongoing immune attack may survive well enough to reverse the symptoms of diabetes. The success of this research could have an impact on a cure for diabetes.Read moreRead less
Type 2 diabetes is caused by multiple genetic defects, resulting in high blood sugar levels. These high sugar levels are primarily due to a decrease in the concentration of insulin, a hormone produced by the pancreas. A number of recent studies have aimed to identify which genes are regulated under conditions that mimic diabetes. One gene shown to have altered expression levels under these conditions is an enzyme called fructose-1,6-bisphosphatase (or FBPase). This enzyme is involved in the meta ....Type 2 diabetes is caused by multiple genetic defects, resulting in high blood sugar levels. These high sugar levels are primarily due to a decrease in the concentration of insulin, a hormone produced by the pancreas. A number of recent studies have aimed to identify which genes are regulated under conditions that mimic diabetes. One gene shown to have altered expression levels under these conditions is an enzyme called fructose-1,6-bisphosphatase (or FBPase). This enzyme is involved in the metabolism of sugar and is usually expressed at undetectable levels in the pancreas, but when blood sugar levels are high, the amount of FBPase in the pancreas increases considerably. We hypothesise that this increase in FBPase may contribute to the decrease in insulin secretion by the pancreas, seen in the diabetic state. The aim of this proposal therefore is to study mice that we have modified to express increased FBPase specifically in the pancreas, in order to determine whether this will lead to a decrease in insulin release and to diabetes. If this is the case, then FBPase could be targeted for the development of drugs that would improve the control of blood sugar levels in diabetes.Read moreRead less
Biological Role And Partners Of The LIM Domain Protein LMO4 In Breast Epithelium
Funder
National Health and Medical Research Council
Funding Amount
$120,181.00
Summary
Breast cancer is the most common cancer affecting women, with 1 in 14 developing this disease. Although treatment of breast cancer has substantially improved over the last few years, 30% of women diagnosed with this cancer will die from it. One major focus of cancer research is the identification of genes involved in tumour development and definition of their precise role in cancer cells. The design of effective therapeutic inhibitors of cancer requires an understanding of the basic molecular an ....Breast cancer is the most common cancer affecting women, with 1 in 14 developing this disease. Although treatment of breast cancer has substantially improved over the last few years, 30% of women diagnosed with this cancer will die from it. One major focus of cancer research is the identification of genes involved in tumour development and definition of their precise role in cancer cells. The design of effective therapeutic inhibitors of cancer requires an understanding of the basic molecular and cellular biology behind the genetic changes thought to contribute to cancer. The focus of our research is to understand normal cellular mechanisms that drive growth and differentiation of breast tissue, and those changes that lead to breast cancer. Nuclear regulatory proteins have been implicated in many different types of cancers and leukaemias. We aim to identify the key regulators in breast tissue, characterising both their structural properties and biological roles, with the ultimate view of understanding how they divert a normal cell to a cancerous cell.Read moreRead less
The Translocator Protein (TSPO) As A Novel Target For The Treatment Of Alzheimers Disease
Funder
National Health and Medical Research Council
Funding Amount
$629,260.00
Summary
Alzheimer's disease (AD) is the most prevalent dementia, characterized by progressive loss of memory. An estimated 230,000 Australians currently suffer from AD, causing a huge impact on their families and carers, as well as on national finances. The present therapies are very limited, and there is no cure. Thus, there is a need for novel treatment strategies. We have developed novel drugs that represent an innovative approach to the treatment of AD.