Vitamin D Activity To Regulate Bone Remodelling And Promote Bone Strength
Funder
National Health and Medical Research Council
Funding Amount
$497,001.00
Summary
While vitamin D and calcium supplementation is well known to protect against osteoporosis and hip fracture, the mechanisms by which this occur are not fully understood. Thus, this project aims to establish the cellular basis for the importance of direct action of vitamin D and calcium within the bone. This information is necessary to develop public health nutritional recommendations for improving skeletal health and reducing the incidence of hip factures in the elderly.
Identification Of The Molecular Mechanisms By Which Mutations In FHL1 Lead To Protein Misfolding And Skeletal Muscle Disease
Funder
National Health and Medical Research Council
Funding Amount
$609,424.00
Summary
Skeletal muscle diseases result in debilitating muscle loss and may result from an error (mutation) within a gene. Mutations in FHL1 were identified as the cause of four different muscle diseases. Using purified FHL1, skeletal muscle cells and animal models we will investigate how FHL1 mutations cause muscle wasting, and loss of muscle strength.
Gene Therapy For The Treatment Of Retinal Dystrophy In The RPE65 Knockout Mouse Using RAAV Virus Mediated Gene Therapy.
Funder
National Health and Medical Research Council
Funding Amount
$211,527.00
Summary
RPE65 is a gene that is found exclusively within the retina. At the moment the exact role of RPE65 is not known, however recent research has shown that mutations in the RPE65 gene have been found in a number of inherited retinal dystrophies (these dystrophies include Leber congenital amaurosis and autosomal recessive retinitis pigmentosa). It therefore appears that a functional, non-mutated RPE65 gene is essential for normal vision. A mouse model of RPE65-related retinal dystrophies has been rec ....RPE65 is a gene that is found exclusively within the retina. At the moment the exact role of RPE65 is not known, however recent research has shown that mutations in the RPE65 gene have been found in a number of inherited retinal dystrophies (these dystrophies include Leber congenital amaurosis and autosomal recessive retinitis pigmentosa). It therefore appears that a functional, non-mutated RPE65 gene is essential for normal vision. A mouse model of RPE65-related retinal dystrophies has been recently developed, by producing a RPE65 knockout mouse breed in which the mouse's RPE65 gene has been mutated into an inactive form. Research on these mice have shown that they develop retinal dystrophies very similar to those seen in patients with mutated RPE65 genes. We propose to use these RPE65 knockout mice to test potential methods for treating the RPE65-related retinal dystrophies in patients. In particular, we will study the potential of using gene therapy to treat these diseases. The project will involve delivering a new, functional RPE65 gene to the retinas of the RPE65 knockout mice. The new, functional RPE65 gene will then replace the inactive, mutated RPE65 gene within the mouse retinas, an action that we predict will be able to stop these mice developing retinal dystrophy. Performing such a study will allow us to improve our understanding of the RPE65-related retinal dystrophies, and provide an indication of whether they can be treated with gene therapy.Read moreRead less
Genomic And Functional Analyses Of A Novel Gene Implicated In Type 1 Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$732,439.00
Summary
We have recently discovered a novel gene that contributes to the development of juvenile diabetes. Unfortunately, very little is known about the function of this gene. To better understand how this gene affects the immune system and contributes to disease, we have generated a unique mouse strain that has a dysfunctional copy of this gene. These mice will enable us to characterise this gene and potentially establish a new area of research in diabetes prevention.
In Vivo Role Of LMO4 And Isolation Of An LMO4-containing Proteosome In Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$455,250.00
Summary
Breast cancer is the most common cancer to affect women, with one in 10 developing the disease. Although treatment of breast cancer has substantially improved over the last few years, 25% of women diagnosed with this cancer will die from the disease. A major objective of cancer research is the identification of genes involved in tumour development and definition of their precise role in both normal and cancer cells. The design of effective therapeutic inhibitors of cancer requires an understandi ....Breast cancer is the most common cancer to affect women, with one in 10 developing the disease. Although treatment of breast cancer has substantially improved over the last few years, 25% of women diagnosed with this cancer will die from the disease. A major objective of cancer research is the identification of genes involved in tumour development and definition of their precise role in both normal and 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. This proposal centres on the characterisation of a specific regulatory molecule which we recently demonstrated to be overexpressed in 56% of human primary breast cancers and in 38% of pre-invasive ductal carcinoma in situ. These studies will include defining its normal biologic function and identification of the proteins that this regulator associates with in breast cancer cells.Read moreRead less
Transcriptional Targets Of The MEN1 Tumour Suppressor In Endocrine Cancer
Funder
National Health and Medical Research Council
Funding Amount
$454,500.00
Summary
We have developed mouse models of a human cancer syndrome called multiple endocrine neoplasia type 1 (MEN 1) by inactivating the tumour suppressor gene responsible. These mice devlop tumours of a wide variety of different tissues, including the pancreas, pituitary, parathyroids and gonads. The data obtained from this project will be the first major step towards determining the mechanism by which the Men1 gene functions as a tumour suppressor and should shed light on its role in normal cell cycle ....We have developed mouse models of a human cancer syndrome called multiple endocrine neoplasia type 1 (MEN 1) by inactivating the tumour suppressor gene responsible. These mice devlop tumours of a wide variety of different tissues, including the pancreas, pituitary, parathyroids and gonads. The data obtained from this project will be the first major step towards determining the mechanism by which the Men1 gene functions as a tumour suppressor and should shed light on its role in normal cell cycle regulation. Findings from murine models of endocrine cancer will lead to a better understanding of MEN 1 in particular, and also of carcinogenesis in general. Defining the cellular pathways normally disrupted by loss of the MEN 1 gene will be useful in designing therapeutic approaches to control endocrine tumours and some other types of cancer.Read moreRead less
Convergence Of Activated C-myb And Wnt Pathways In Colon Cancer
Funder
National Health and Medical Research Council
Funding Amount
$256,320.00
Summary
c-myb is essential for the normal biology of the blood system and the colon. It is involved in regulating the balance between the production of new cells and their timely removal once they have completed their assigned tasks. Another group of factors that make up theWnt pathway also contribute to the normal biology of the colon in man and mouse. Defects that lead to too much c-myb and ineffective control of the Wnt pathway appear to work together to increase the risk and severity of colon cancer ....c-myb is essential for the normal biology of the blood system and the colon. It is involved in regulating the balance between the production of new cells and their timely removal once they have completed their assigned tasks. Another group of factors that make up theWnt pathway also contribute to the normal biology of the colon in man and mouse. Defects that lead to too much c-myb and ineffective control of the Wnt pathway appear to work together to increase the risk and severity of colon cancer. This project is designed to specifically test this observation in animals. In addition it examines in fine detail how c-myb levels increase in colon cancer and how it combines with the Wnt pathway to regulate other genes in colon cancer.Read moreRead less
Epilepsy is an important human disease because it causes physical trauma and sudden death in addition to immense social and economic hardship. The genetic basis of a number of epilepsy syndromes has been identified but the precise mechanism whereby mutations produce seizures is unknown. Several mutations in the alpha4 neuronal nicotinic receptor (a4 nAChR) gene have been identified in Autosomal Dominant Nocturnal Frontal Lobe Epilepsy (ADNFLE). This is a rare form of inherited epilepsy character ....Epilepsy is an important human disease because it causes physical trauma and sudden death in addition to immense social and economic hardship. The genetic basis of a number of epilepsy syndromes has been identified but the precise mechanism whereby mutations produce seizures is unknown. Several mutations in the alpha4 neuronal nicotinic receptor (a4 nAChR) gene have been identified in Autosomal Dominant Nocturnal Frontal Lobe Epilepsy (ADNFLE). This is a rare form of inherited epilepsy characterized by the presence of seizures during light sleep. In vitro studies using the human mutated DNA (i.e. DNA containing the genetic defect) have suggested that this mutation results in reduced activity of the receptor. Therefore a mouse in which this gene is destroyed would be relevant in understanding the human disease. We have generated an a4 nAChR knockout (KO) mouse and plan to use the mouse to test the idea that loss of function of the a4 nAChR in vivo is associated with enhanced seizure activity. The KO mice do not have unprovoked seizures but appear to have an increased number of major motor seizures in response to pentylenetetrazole, an agent which is known to cause seizures by blocking the effects of the brain inhibitory molecule GABA. Interestingly, a4 nAChRs are known to control the release of GABA. We therefore propose that our knockout mice have seizures because they tend to under produce GABA. We will also make and analyse a mouse line with the same genetic mutation as patients with ADNFLE. The experiments are aimed at understanding the way that seizures are generated and spread in the brain in these rare forms of epilepsy. The hope is that understanding these mechanisms will help us better understand and therefore treat common forms of epilepsy.Read moreRead less