Intracellular Trafficking Of Copper And Platinum-based Chemotherapuetics
Funder
National Health and Medical Research Council
Funding Amount
$268,328.00
Summary
Platinum-based anti cancer drugs such as Cisplatin are effective against a number of cancers of the head, colon, lungs and ovaries. Tumour resistance to these drugs has been closely associated with changes in genes that control the movement of copper in and out of cells. We hypothesize that the same genes regulate distribution of both copper and Cisplatin. By investigating these pathways, we aim to find ways to predict and prevent tumour resistance to this important anti cancer treatment.
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
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
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
Studies On Mechanisms Of Vesicular Trafficking And Catalysis For The Menkes (MNK) Copper-transporting P-type ATPase
Funder
National Health and Medical Research Council
Funding Amount
$363,757.00
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 Ofree radicalsO. Copper is also used by the proteins involved in important neurological diseases including Alzheimers disease and Omad cowO disease. Menkes disease is an inherited and usually lethal cop ....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 Ofree radicalsO. Copper is also used by the proteins involved in important neurological diseases including Alzheimers disease and Omad cowO 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 Cu to satisfy nutritional needs of cells but not too much which causes toxicity. The normal Menkes protein catalyses the transport of Cu across membranes of cells to the areas where it is needed by copper-dependent enzymes which themselves catalyse important chemical reactions. The normal Menkes protein functions as a molecular pump. We have discovered that this protein can OsenseO Cu concentrations in the cell and when these reach potentially toxic levels it can move (traffick) via small vesicles to the plasma membrane which surrounds cells. There it pumps the excess Cu 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.Read moreRead less
This study aims to identify naturally occurring genetic variations between men which modify the impact of testosterone, the major male hormone, on men's health and medical care. This study will examine new factors which determine how much any particular man may gain benefit from testosterone exposure such as in muscle and bone development as well as suffer detrimental effects on cardiovascular and prostate diseases. This may clarify some new aspects of how men's health is determined as well as d ....This study aims to identify naturally occurring genetic variations between men which modify the impact of testosterone, the major male hormone, on men's health and medical care. This study will examine new factors which determine how much any particular man may gain benefit from testosterone exposure such as in muscle and bone development as well as suffer detrimental effects on cardiovascular and prostate diseases. This may clarify some new aspects of how men's health is determined as well as developing new, customized medical treatments for men.Read moreRead less
Amyotrophic lateral sclerosis (ALS) is a rapidly progressive disease of motor neurons that leads to death within 5 years of first symptoms. The only proven causes of ALS are gene mutations. But known ALS genes only account for 2% of cases. We aim to investigate a newly identified gene that encodes a protein (TDP-43) that misfolds in the motor neurons of ALS cases. We have found TDP-43 mutations in ALS patients. This exciting finding offers a unique opportunity to understand how TDP-43 causes ALS
Mucopolysaccharidoses (MPS) are a related group of 11 debilitating genetic disorders affecting children. They result from a reduction or total deficiency of an enzyme required for the removal of carbohydrate structures called glycosaminoglycans (gags). Gag degradation occurs inside the cell in specific organelles termed lysosomes and in the absence of the appropriate enzyme, undegraded gag accumulates in the cell. This leads to a range of clinical symptoms and multiple tissue failure. Symptoms c ....Mucopolysaccharidoses (MPS) are a related group of 11 debilitating genetic disorders affecting children. They result from a reduction or total deficiency of an enzyme required for the removal of carbohydrate structures called glycosaminoglycans (gags). Gag degradation occurs inside the cell in specific organelles termed lysosomes and in the absence of the appropriate enzyme, undegraded gag accumulates in the cell. This leads to a range of clinical symptoms and multiple tissue failure. Symptoms common to more than one MPS type include mental deterioration, blindness, abdominal organ enlargement and bone growth problems leading to short stature and bone loss. My laboratory has had a long-term interest in developing treatment for MPS and our research led to the clinical implementation of enzyme replacement therapy (ERT) for MPS VI in 2005. While providing the first effective, multi-tissue treatment for MPS, our research showed that several tissues were not responsive to ERT. These are the brain, cartilage and cornea, thus children on ERT regimens will still suffer from mental retardation, arthritis and blindness. With the goal of treating these particular tissues we have developed a new approach to MPS therapy called substrate deprivation therapy (SDT). Instead of adding back the missing enzyme, SDT acts by decreasing gag production which in turn reduces the level of accumulated gag in cells. SDT results in the correction of MPS cells in culture and reduces several key clinical symptoms in the mouse model of MPS IIIA. In this proposal we will extend our research to evaluate the effect of SDT on brain and bone-joint pathology. Evaluation of efficacy will take place in the MPS VII mouse which exhibits both brain and bone disease and in a new model of MPS IVA developed specifically for this study which exhibits a joint pathology unique amongst the MPS disorders.Read moreRead less