The Role Of Copper In Ubiquitin-dependent Protein Degradation In Alzheimer's Disease
Funder
National Health and Medical Research Council
Funding Amount
$588,622.00
Summary
Ubiquitin’s are small proteins that tag other proteins in a process known as “Ubiquitination”. Often this is to target them for degradation once they are no longer needed i.e. to take out the rubbish. This process is disrupted in Alzheimer’s disease (AD), which may contribute to the disease. This project aims to find out if copper, an essential metal for life, is required for this process. Drugs that are designed to deliver copper to brain cells have been effective in small AD clinical trials.
Protein Networks Mediating Copper Balance And Their Break-down In Disease.
Funder
National Health and Medical Research Council
Funding Amount
$540,075.00
Summary
Neurological disorders (eg. Alzheimer s, Parkinson s and prion diseases) impose a growing health burden on society. Exciting new therapeutic possibilities stem from the discovery that copper (Cu) plays a central role in the disease process. Our research will help foster a holistic understanding of the protein network regulating copper balance, particularly in the brain, and where it breaks down in disease. Clinical benefits include new targets for diagnosis and treatment of Cu-related diseases.
Regulation Of The Nedd4 Family Of Ubiquitin Ligases By Adaptor And Accessory Proteins In Normal Physiology And In Disease
Funder
National Health and Medical Research Council
Funding Amount
$609,424.00
Summary
In part this proposal is to understand how the body controls iron uptake through iron transporters DMT1 and Nramp1. We will study the regulation of these transporters by proteins called Ndfip1, Ndfip2 and arrestins. We will also study the functions of these proteins in controlling ubiquitination, a fundamental process required for cellular homeostasis. The results from this study may ultimately contribute to the development of novel therapies for certain human diseases.
Genotypes And Phenotypes Of Human Primary Non-congenital Antibody Deficiency
Funder
National Health and Medical Research Council
Funding Amount
$544,692.00
Summary
Antibodies represent a key component of the immune system, and a particularly important in defence against bacterial and viral infections. In some individuals, antibody production fails, rendering them more susceptible to infection. In most cases, the mechanism of antibody failure is unknown. This project seeks to determine the genetic and cellular mechanisms of antibody failure. This could improve diagnosis for immune deficiency, and improve our overall understanding of the immune system.
Molecular Analysis Of Alpha-1-Antitrypsin Misfolding: A Cause Of Alpha-1-antitrypsin Deficiency
Funder
National Health and Medical Research Council
Funding Amount
$255,837.00
Summary
Antitrypsin deficiency occurs in approximately 1 in 1800 live births. It is the most common genetic cause of liver disease in children and the debilitating lung disease emphysema in adults. Antitrypsin is produced in the liver and secreted into the circulation. Its primary role is to inhibit the degradative enzyme elastase which attacks the tissues of the lung. A deficiency in Antitrypsin leads to uncontrolled elastase activity which destroys the lung tissue so causing emphysema. The deficiency ....Antitrypsin deficiency occurs in approximately 1 in 1800 live births. It is the most common genetic cause of liver disease in children and the debilitating lung disease emphysema in adults. Antitrypsin is produced in the liver and secreted into the circulation. Its primary role is to inhibit the degradative enzyme elastase which attacks the tissues of the lung. A deficiency in Antitrypsin leads to uncontrolled elastase activity which destroys the lung tissue so causing emphysema. The deficiency is commonly caused by Antitrypsin being unable to enter the circulation. This is due to mutations within the Antitrypsin molecule which cause the protein to adopt an incorrect three-dimensional structure. This causes the protein to form long chains within the liver, which in turn damage the liver cell. There are no specific treatments for Antitrypsin deficiency, this partly reflects our lack of understanding of the molecular basis of the disease. This project examines the effects of the mutations upon the folding of Antitrypsin so that we can understand how these long protein chains form. Using a range of biochemical techniques we will monitor structural changes within the normal and abnormal proteins as they fold to determine how the mutations disrupt the process. These data will allow us to begin to rationally design inhibitors which will prevent the formation of the long chains, which we hope will aid in the treatment of patients with Antitrypsin deficiency. This increased understanding of Antitrypsin deficiency may also benefit other disease processes where similar protein misfolding occurs such as amyloid and prion diseases.Read moreRead less
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
Roles Of Ndfip1 And Ndfip2 As Adaptors For The Nedd4 Family Of Ubiquitin Ligases
Funder
National Health and Medical Research Council
Funding Amount
$656,395.00
Summary
Part of this proposal is to understand how the body controls iron uptake through one of the iron transporters (DMT1). We will also study how proteins called Ndfip1 and Ndfip2 that regulate DMT1, also control other cellular processes, such as protection against brain damage following trauma. The results from this study should ultimately contribute to the development of therapies for certain human pathologies.
Elucidation Of Trafficking Of The Menkes (MNK;ATP7A) Copper-transporting ATPase In Epthelial Cells
Funder
National Health and Medical Research Council
Funding Amount
$457,267.00
Summary
Copper is an essential trace element for all organisms. Copper is needed for many processes including energy metabolism, the making and maintenance of strong bones and arteries with sufficient elasticity, the synthesis of chemical transmitters in the brain and for the reactions which remove toxic free radicals. Copper is also used by the proteins involved in important neurological diseases including Alzheimers disease and mad cow disease. Menkes disease is an inherited and usually lethal copper ....Copper is an essential trace element for all organisms. Copper is needed for many processes including energy metabolism, the making and maintenance of strong bones and arteries with sufficient elasticity, the synthesis of chemical transmitters in the brain and for the reactions which remove toxic free radicals. Copper is also used by the proteins involved in important neurological diseases including Alzheimers disease and mad cow disease. Menkes disease is an inherited and usually lethal copper deficiency disorder in humans, and the diverse and detrimental symptoms of this disease related to organs and tissues described above is a stark indicator of the essentiality of copper. We have carried out extensive research on Menkes disease and in particular the Menkes protein which in normal individuals plays a major role in maintaining the copper balance in cells, i.e. enough copper to satisfy nutritional needs of cells but not too much which causes toxicity. The normal Menkes protein catalyses the transport of copper across membranes of cells to the areas where it is needed by copper-dependent enzymes and is essential for copper absorption into the body from the gut. The normal Menkes protein functions as a molecular pump. We have discovered that this protein can sense copper concentrations in the cell and when these reach potentially toxic levels it can move (traffic) via small vesicles to the plasma membrane which surrounds cells. There it pumps the excess copper out of the cell and returns to its original location. Our studies are directed to understanding the molecular mechanisms which permit this remarkable protein to achieve a copper balance in living cells. The findings will be of major significance in understanding and treating acquired and inherited diseases involving copper deficiency or copper toxicity including osteoporosis, cardiovascular disease, and Alzheimer's disease.Read moreRead less
Molecular And Cellular Studies Of The Copper-transporting ATPases Affected In Menkes And Wilson Diseases
Funder
National Health and Medical Research Council
Funding Amount
$558,300.00
Summary
Copper is an element that is essential for life but is highly toxic in excess. Because of this, the regulation of copper uptake, distribution in the body and excretion of excess is a very tightly regulated process. Until recently little was known about the molecular basis of this process. Two genetic disorders that show these two aspects of copper are Menkes disease (deficiency) and Wilson disease (toxicity). Both diseases are caused by mutations in similar copper pumping proteins. Our research ....Copper is an element that is essential for life but is highly toxic in excess. Because of this, the regulation of copper uptake, distribution in the body and excretion of excess is a very tightly regulated process. Until recently little was known about the molecular basis of this process. Two genetic disorders that show these two aspects of copper are Menkes disease (deficiency) and Wilson disease (toxicity). Both diseases are caused by mutations in similar copper pumping proteins. Our research is trying to establish the molecular mechanisms used in the body to control copper metabolism. We made a major breakthrough in 1993 with the isolation of the gene affected in Menkes disease, and we continue to be one of the leading groups in the world in studying the molecular mechanisms that handle copper, and the importance of these mechanisms in health and disease. Research into the biology of copper has become much more important following the recent discoveries of the involvement of the metal in such important neurodegenerative conditions such as Alzheimer's, Mad Cow, and Parkinson's diseases. Health effects from the lack of copper may be widespread also, copper deficiency is suspected to contribute to some common diseases, such as cardiovascular problems and osteoporosis. Our research is providing information about copper transport mechanisms that are necessary for the understanding of, and may lead to better treatment and diagnosis of common and important diseases. In this grant we propose to continue our studies into the molecular signals that control the copper pumps, that make the regulation of copper metabolism possible. We also will use various test systems for studying the effect of mutations on the activity of these proteins and relate these effects to the type of disease produced in patients.Read moreRead less