Autocrine Vitamin D Metabolism, Activity And Bone Health
Funder
National Health and Medical Research Council
Funding Amount
$459,270.00
Summary
This project will provide the detailed understanding of the activities of vitamin D within the bone microenvironment and offers the exciting prospect of elucidating the mechanistic reasons for maintaining an adequate vitamin D status in relation to the prevention 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.
Vitamin D And Genetic Susceptibility In Multiple Sclerosis
Funder
National Health and Medical Research Council
Funding Amount
$122,714.00
Summary
Vitamin D3 levels appear to predict clinical status in multiple sclerosis. The reasons for this are unclear, but may be linked to the effect of the Vitamin D Receptor (VDR) on a subset of immune cells. This project aims to identify key genes which are regulated by this receptor, by using specific gene sequencing technologies combined with knowledge of the genes which confer risk of developing MS. This may help to identify the molecular pathways underlying MS and potential treatment strategies.
The Regulation Of Vitamin D-Dependent Bone Metabolism
Funder
National Health and Medical Research Council
Funding Amount
$612,535.00
Summary
This project aims to establish the cellular basis for the importance of vitamin D in bone. This information is necessary to develop public health nutritional recommendations for improving in skeletal health and reducing the incidence of hip factures in the elderly. Furthermore our data have the potential to reveal novel activities of vitamin D that could eventuate as pharmacological targets.
Roles Of Vitamin D In Skeletal Muscle And Satellite Cells
Funder
National Health and Medical Research Council
Funding Amount
$380,891.00
Summary
Vitamin D deficiency leads to muscle pain and weakness that are reversible with vitamin D supplementation. However, precise biological effects of vitamin D in skeletal muscle are unclear. In this fellowship, novel mouse models and innovative techniques will be used to examine vitamin D signalling pathways in whole muscle and muscle stem cells. Ultimately, the therapeutic potential of the vitamin D pathway in treatment of muscle disorders and age-related muscle wasting will be explored.
Quantitiative Assessment Of Solar UV Exposure For Vitamin D Synthesis In Australian Adults
Funder
National Health and Medical Research Council
Funding Amount
$1,162,536.00
Summary
This research program will add significantly to our current scientific understanding of the dual health outcomes of UV exposure (Vitamin D and skin cancer) . This project is in line with Australia's R and D Priorities, in that it will result in direct and indirect social and economic benefits to Australia by applying the scientific knowledge gained through this research to develop public health initiatives to improve some of Australia's most significant and costly health problems.
The Effect Of High-dose Vitamin-D Supplementation On Mental Health In A Randomised, Controlled Trial Of 1500 Older Women
Funder
National Health and Medical Research Council
Funding Amount
$81,965.00
Summary
Vitamin D is commonly deficient in Western populations, more so in the winter months and in the elderly. A link between depression and vitamin D insufficiency may exist. This study aims to see if vitamin-D supplementation is a practical health intervention for depressive symptoms and may define a public health strategy. In this study participants receive a dose of vitamin D3 or placebo annually for three years. Self-rated psychiatric assessments are administered.
Physiological Function Of The Novel Vitamin D Receptor Isoform
Funder
National Health and Medical Research Council
Funding Amount
$465,750.00
Summary
Vitamin D regulates a wide range of physiological systems including those involved in control of calcium blood level and bone health as well as regulation of the immune system and of cell growth. Vitamin D action is mediated through the vitamin D receptor (VDR), a member of a large family of proteins that regulate the activity of specific target genes that control numerous biological functions. A novel, larger form of the human VDR has recently been described in our laboratory. This novel form s ....Vitamin D regulates a wide range of physiological systems including those involved in control of calcium blood level and bone health as well as regulation of the immune system and of cell growth. Vitamin D action is mediated through the vitamin D receptor (VDR), a member of a large family of proteins that regulate the activity of specific target genes that control numerous biological functions. A novel, larger form of the human VDR has recently been described in our laboratory. This novel form shows differences in activity from the shorter VDR form (VDRA) and also has an unusual distribution within the nucleus of the cell that may relate to its function. The present project focuses on further analysis of the relevance of this novel VDR isoform to normal physiology. We hypothesise that the larger VDR isoform has unique characteristics that may modify how vitamin D works in different cells and tissues, on specific target genes and in response to different active forms of vitamin D. These differences depend on this novel isoform s interaction with specific nuclear proteins that regulate the actions of other hormone receptors. The specific aims of this project are to study the functions of the novel VDR isoform in comparison to VDRA: * On different target genes that are either activated or inhibited in response to vitamin D, and on different cell lines from tissues where vitamin D has important roles, like intestine, kidney and bone * In their response to natural and synthetic vitamin D compounds, because of their possible therapeutic applications * In their interactions with intranuclear regulatory proteins, to understand the underlying mechanisms The study of these two forms of the VDR will help to clarify their potentially different cellular roles and their contribution to the wide range of physiological processes regulated by the vitamin D endocrine system. This understanding may open new paths for treatments of human bone and calcium-related diseases.Read moreRead less