The majority of stroke results from focal brain infarction, followed by substantial secondary excitotoxic damage in the surrounding areas. Tau has been shown to contribute to excitotoxicity and neurodegeneration in mouse models of Alzheimer’s disease (AD). Preliminary data show that tau reduction also protects against excitotoxic damage after experimental stroke. We aim to dissect the molecular mechanisms of stroke using a tau-deficient mouse model.
Vitamin D Synthesis Within Osteoblasts Increases Bone Mineral By Regulating Remodelling: Is This The Link Between Vitamin D Status And Fractures?
Funder
National Health and Medical Research Council
Funding Amount
$627,082.00
Summary
This project will contribute to understanding mechanism of vitamin D action within bone to modulate bone resorption and offers the exciting prospect of identifying the mechanism by which an adequate vitamin D status can reduce the risk of osteoporotic hip fractures. Thus, this project has great potential to improve community health by being able to recommend vitamin D supplementation made on the basis of maintaining normal bone cell function with psarticular reference to modulating bone resorpti ....This project will contribute to understanding mechanism of vitamin D action within bone to modulate bone resorption and offers the exciting prospect of identifying the mechanism by which an adequate vitamin D status can reduce the risk of osteoporotic hip fractures. Thus, this project has great potential to improve community health by being able to recommend vitamin D supplementation made on the basis of maintaining normal bone cell function with psarticular reference to modulating bone resorption.Read moreRead less
Elucidating The Role Of MiR-196 In Formation Of The Axial Skeleton
Funder
National Health and Medical Research Council
Funding Amount
$520,087.00
Summary
Exquisite regulation of gene expression is a fundamental principle underlying growth and development of an embryo as well as homeostasis in the adult. Following the identification of hundreds of microRNAs within the genome which act to modulate gene expression, the challenge and the goal of these studies, is to identify individual microRNAs which contribute significantly to bone formation in the developing embryo.
This study aims to elucidate central pathways which can be manipulated to drive the storage of excess energy away from fat and instead directing it into the production of bone mass. Having identified leptin-responsive NPY neurons as important in the control of energy partitioning, we will focus on manipulating these neurons in the hypothalamus using innovative technology to alter body composition. This research has the potential to result in novel treatments for obesity and osteoporosis.
Molecular Characterization Of V-ATPase V0 Domain Subunits E1 And E2 In Osteoclast
Funder
National Health and Medical Research Council
Funding Amount
$558,909.00
Summary
Osteoporotic fractures in the elderly are often linked to increased mortality rates. Excess bone resorption is a major contributor to the onset of the disease. The proposed project focuses on the investigation of the molecular mechanisms of acid secretion that is required for the bone degradation in body. The project will examine the role of the proton pump in bone resorption and seek potential targets for the treatment of osteoporosis.
Epigenetic Regulation Of L1 Retrotransposition In Mouse Models Of Abnormal Human Neurobiology
Funder
National Health and Medical Research Council
Funding Amount
$417,812.00
Summary
Retrotransposons are mobile genes that copy-and-paste themselves to spread in DNA. Until very recently, they were thought to only be active in sperm and egg. In our recent work, we demonstrated that they also move in the brain. In the current study, we will use cutting-edge technologies to determine how retrotransposons change the genetic makeup of neurons in neurodevelopmentally impaired mice to predict whether these mutations would also be present in human brain disorders.
Deciphering The Overlapping Roles Of SSB1 And SSB2 In The Regulation Of Haematopoiesis And Intestinal Homeostasis
Funder
National Health and Medical Research Council
Funding Amount
$996,631.00
Summary
Our work centres on elucidating the role of two newly identified and related single-stranded DNA binding protein (Ssb1 and Ssb2) in development of blood and gut system. When both genes are deleted mice die with 8 days of knockdown due to bone marrow failure and intestinal atrophy. Our double knockout model parallels the consequences of radiation damage on blood and gut system. Toxicity to these systems is a significant hindrance in delivering anti-tumor therapy.
Problems in learning, memory and other complex mental processes are common to many brain disorders. This project will study the impact of mutations on a family of genes reported in autism and schizophrenia, on complex cognitive behaviours using novel behavioural technologies. This will not only shed fundamental insights into the specific mental processes regulated by these genes and their role in disease, but importantly provide novel targets for the development of therapies.