Neuronal Copper Homeostasis And The Role Of The Alzheimer Amyloid-Beta Precursor Protein (APP)
Funder
National Health and Medical Research Council
Funding Amount
$287,321.00
Summary
Alzheimer’s disease (AD) is creating a growing burden upon Australian medical resources. Copper plays an important role in the development of AD and drugs designed to adjust brain copper levels are being tested for AD treatment and show therapeutic benefits. This project will determine how copper is involved in AD so that more effective drugs can be developed. Focus will primarily be on copper-binding proteins central to AD and establishing their role in AD development and progression.
Identification And Characterisation Of Novel Copper Homeostasis Genes And Proteins
Funder
National Health and Medical Research Council
Funding Amount
$70,307.00
Summary
Copper is an essential nutrient that is also toxic when in excess. Specific mechanisms exist to regulate copper levels and these are conserved across many species. Disrupted copper regulation contributes to many diseases including: cardiovascular disease, osteoporosis and Alzheimer’s. I aim to identify and characterise novel copper regulatory proteins using the model organism Drosophila (vinegar fly) together with human cultured cells as a foundation for work to prevent or treat these diseases.
The Role Of Presenilin In Metal Homeostasis And Alzheimers Disease
Funder
National Health and Medical Research Council
Funding Amount
$86,335.00
Summary
Presenilin, a protein involved in Alzheimer’s disease (AD), may regulate copper and zinc levels. Copper and zinc are essential nutrients however a deficiency or excess can cause disease. Promising metal-altering AD drugs, are in various stages of clinical trial. I aim to characterize the interaction of Presenilin and metals using both mouse and cultured human cell models that are deficient in Presenilin. Understanding this interaction should lead to better drug design and treatment of AD.
Copper is an essential trace element with the potential for toxicity. Copper deficiency can be fatal to developing animals due to the multiple organ abnormalities caused by the reduced activity of important copper containing enzymes. Dietary copper deficiency can cause iron unresponsive anaemia in children and may contribute to heart disease and connective tissue defects in adults. A variant form of a copper containing protein is thought to contribute to Alzheimer's disease and the affected prot ....Copper is an essential trace element with the potential for toxicity. Copper deficiency can be fatal to developing animals due to the multiple organ abnormalities caused by the reduced activity of important copper containing enzymes. Dietary copper deficiency can cause iron unresponsive anaemia in children and may contribute to heart disease and connective tissue defects in adults. A variant form of a copper containing protein is thought to contribute to Alzheimer's disease and the affected protein in mad cow disease may normally play a role in copper biology of the brain. Given the importance of copper for normal health and the potential for toxicity, the levels of copper in the body are tightly regulated. There are two main sites for this regulation: the uptake of dietary copper across the intestine and the excretion of excess copper into the bile. This proposal addresses the molecular control of copper uptake in the intestine. Much of our understanding about the regulation of the uptake of copper from dietary sources was obtained prior to the era of modern molecular biology. Prof. Mercer's laboratory has recently made significant discoveries into the molecular basis of copper metabolism in human cells. Based on these findings and finding of others about copper metabolism in yeast, we have proposed a model incorporating these newly described molecules to explain how the body might regulate the uptake of copper in the intestine. We propose to investigate this model using cell culture models of the intestine and in mouse models. These studies will extend our knowledge of copper biology and may provide insight for potential treatments of copper related disorders.Read moreRead less
Copper Pathways Are Altered In Parkinson’s Disease: Implications For Cell Vulnerability
Funder
National Health and Medical Research Council
Funding Amount
$341,398.00
Summary
The cause of brain cell death in Parkinson’s disease is unknown but we have shown that copper levels are reduced in the vulnerable brain regions in this disorder. As copper is vital for the normal function of key brain proteins we suggest that reduced copper contributes to cell damage in vulnerable brain regions. This project investigates why brain copper levels are reduced in the Parkinson’s disease brain and the consequences of this change for brain cell function and survival.
Development Of Therapeutic Copper Delivery Agents For Menkes Disease
Funder
National Health and Medical Research Council
Funding Amount
$651,467.00
Summary
Menkes disease does not currently have an effective treatment. The disease is caused by genetic defects that reduce copper transport into the brain and cause mental retardation and death. We have developed drugs that deliver copper into the brain and should cure Menkes disease. We aim to demonstrate that our drugs are effective in mice that have the same genetic defect as patients. Successful results will allow us to begin treating Menkes disease patients to determine if we can cure the disease.