Posts tagged copper
Articles and news from the latest research reports.
Findings point toward one of first therapies for Lou Gehrig’s disease
Researchers have determined that a copper compound known for decades may form the basis for a therapy for amyotrophic lateral sclerosis (ALS), or Lou Gehrig’s disease.
In a new study just published in the Journal of Neuroscience, scientists from Australia, the United States (Oregon), and the United Kingdom showed in laboratory animal tests that oral intake of this compound significantly extended the lifespan and improved the locomotor function of transgenic mice that are genetically engineered to develop this debilitating and terminal disease.
In humans, no therapy for ALS has ever been discovered that could extend lifespan more than a few additional months. Researchers in the Linus Pauling Institute at Oregon State University say this approach has the potential to change that, and may have value against Parkinson’s disease as well.
“We believe that with further improvements, and following necessary human clinical trials for safety and efficacy, this could provide a valuable new therapy for ALS and perhaps Parkinson’s disease,” said Joseph Beckman, a distinguished professor of biochemistry and biophysics in the OSU College of Science.
“I’m very optimistic,” said Beckman, who received the 2012 Discovery Award from the OHSU Medical Research Foundation as the leading medical researcher in Oregon.
ALS was first identified as a progressive and fatal neurodegenerative disease in the late 1800s and gained international recognition in 1939 when it was diagnosed in American baseball legend Lou Gehrig. It’s known to be caused by motor neurons in the spinal cord deteriorating and dying, and has been traced to mutations in copper, zinc superoxide dismutase, or SOD1. Ordinarily, superoxide dismutase is an antioxidant whose proper function is essential to life.
When SOD1 is lacking its metal co-factors, it “unfolds” and becomes toxic, leading to the death of motor neurons. The metals copper and zinc are important in stabilizing this protein, and can help it remain folded more than 200 years.
“The damage from ALS is happening primarily in the spinal cord and that’s also one of the most difficult places in the body to absorb copper,” Beckman said. “Copper itself is necessary but can be toxic, so its levels are tightly controlled in the body. The therapy we’re working toward delivers copper selectively into the cells in the spinal cord that actually need it. Otherwise, the compound keeps copper inert.”
“This is a safe way to deliver a micronutrient like copper exactly where it is needed,” Beckman said.
By restoring a proper balance of copper into the brain and spinal cord, scientists believe they are stabilizing the superoxide dismutase in its mature form, while improving the function of mitochondria. This has already extended the lifespan of affected mice by 26 percent, and with continued research the scientists hope to achieve even more extension.
The compound that does this is called copper (ATSM), has been studied for use in some cancer treatments, and is relatively inexpensive to produce.
“In this case, the result was just the opposite of what one might have expected,” said Blaine Roberts, lead author on the study and a research fellow at the University of Melbourne, who received his doctorate at OSU working with Beckman.
“The treatment increased the amount of mutant SOD, and by accepted dogma this means the animals should get worse,” he said. “But in this case, they got a lot better. This is because we’re making a targeted delivery of copper just to the cells that need it.
“This study opens up a previously neglected avenue for new disease therapies, for ALS and other neurodegenerative disease,” Roberts said.
(Source: oregonstate.edu)
Copper Identified as Culprit in Alzheimer’s Disease
Copper appears to be one of the main environmental factors that trigger the onset and enhance the progression of Alzheimer’s disease by preventing the clearance and accelerating the accumulation of toxic proteins in the brain. That is the conclusion of a study appearing today in the journal Proceedings of the National Academy of Sciences.
“It is clear that, over time, copper’s cumulative effect is to impair the systems by which amyloid beta is removed from the brain,” said Rashid Deane, Ph.D., a research professor in the University of Rochester Medical Center (URMC) Department of Neurosurgery, member of the Center for Translational Neuromedicine, and the lead author of the study. “This impairment is one of the key factors that cause the protein to accumulate in the brain and form the plaques that are the hallmark of Alzheimer’s disease.”
Copper’s presence in the food supply is ubiquitous. It is found in drinking water carried by copper pipes, nutritional supplements, and in certain foods such as red meats, shellfish, nuts, and many fruits and vegetables. The mineral plays an important and beneficial role in nerve conduction, bone growth, the formation of connective tissue, and hormone secretion.
However, the new study shows that copper can also accumulate in the brain and cause the blood brain barrier – the system that controls what enters and exits the brain – to break down, resulting in the toxic accumulation of the protein amyloid beta, a by-product of cellular activity. Using both mice and human brain cells Deane and his colleagues conducted a series of experiments that have pinpointed the molecular mechanisms by which copper accelerates the pathology of Alzheimer’s disease.
Under normal circumstances, amyloid beta is removed from the brain by a protein called lipoprotein receptor-related protein 1 (LRP1). These proteins – which line the capillaries that supply the brain with blood – bind with the amyloid beta found in the brain tissue and escort them into the blood vessels where they are removed from the brain.
The research team“dosed” normal mice with copper over a three month period. The exposure consisted of trace amounts of the metal in drinking water and was one-tenth of the water quality standards for copper established by the Environmental Protection Agency.
“These are very low levels of copper, equivalent to what people would consume in a normal diet.” said Deane.
The researchers found that the copper made its way into the blood system and accumulated in the vessels that feed blood to the brain, specifically in the cellular “walls” of the capillaries. These cells are a critical part of the brain’s defense system and help regulate the passage of molecules to and from brain tissue. In this instance, the capillary cells prevent the copper from entering the brain. However, over time the metal can accumulate in these cells with toxic effect.
The researchers observed that the copper disrupted the function of LRP1 through a process called oxidation which, in turn, inhibited the removal of amyloid beta from the brain. They observed this phenomenon in both mouse and human brain cells.
The researchers then looked at the impact of copper exposure on mouse models of Alzheimer’s disease. In these mice, the cells that form the blood brain barrier have broken down and become “leaky” – a likely combination of aging and the cumulative effect of toxic assaults – allowing elements such as copper to pass unimpeded into the brain tissue. They observed that the copper stimulated activity in neurons that increased the production of amyloid beta. The copper also interacted with amyloid beta in a manner that caused the proteins to bind together in larger complexes creating logjams of the protein that the brain’s waste disposal system cannot clear.
This one-two punch, inhibiting the clearance and stimulating the production of amyloid beta, provides strong evidence that copper is a key player in Alzheimer’s disease. In addition, the researchers observed that copper provoked inflammation of brain tissue which may further promote the breakdown of the blood brain barrier and the accumulation of Alzheimer’s-related toxins.
However, because metal is essential to so many other functions in the body, the researchers say that these results must be interpreted with caution.
“Copper is an essential metal and it is clear that these effects are due to exposure over a long period of time,” said Deane. “The key will be striking the right balance between too little and too much copper consumption. Right now we cannot say what the right level will be, but diet may ultimately play an important role in regulating this process.”
(Source: urmc.rochester.edu)
The value of copper has risen dramatically in the 21st century as many a thief can tell you, but in addition to the thermal and electrical properties that make it such a hot commodity metal, copper has chemical properties that make it essential to a healthy brain. Working at the interface of chemistry and neuroscience, Berkeley Lab chemist Christopher Chang and his research group at UC Berkeley have developed a series of fluorescent probes for molecular imaging of copper in the brain. Speaking at the recent national meeting of the American Chemical Society in New Orleans, he described the challenges of creating and applying live-cell and live-animal copper imaging probes and explained the importance of meeting these challenges.
“The human brain is a unique biological system, possessing unparalleled biological complexity in a compact space,” Chang said. “Although it accounts for only two-percent of total body mass, it consumes 20-percent of the oxygen taken in through respiration. As a consequence of its high demand for oxygen and oxidative metabolism, the brain has among the highest levels of copper, as well as iron and zinc in the body.”
Neuron and glia cells in the brain both require copper for the basic respiratory and antioxidant enzymes cytochrome c oxidase and superoxide dismutase. Copper is also necessary for brain-specific enzymes that control neurotransmitters, such as dopamine, as well as neuropeptides and dietary amines. Disruption of copper oxidation in the brain has been linked to several neurodegenerative diseases, including Alzheimer’s, Parkinson’s, Menkes’ and Wilson’s.
“The complex relationships between copper status and various stages of health and disease have been difficult to determine in part because of a lack of methods for monitoring dynamic changes in copper pools in whole living organisms,” Chang said. “We’ve been designing fluorescent probes that can map the movement of copper in live cells, tissue or even model organisms, such as mice and zebrafish.”
Their first success was Coppersensor-3 (CS3), a small-molecule fluorescent probe that can be used to image labile copper pools in living cells at endogenous, basal levels. They used CS3 in conjunction with synchrotron-based X-ray fluorescence microscopy (XRFM) to discover that neuronal cells move significant pools of copper upon activation and that these copper movements are dependent on calcium signaling.
“This was the first established link between mobile copper and major cell signaling pathways,” Chang said. “Being able to map transient copper movements after neuronal depolarization revealed how neural activity triggers copper mobility, and enabled us to create a model for calcium/copper crosstalk in neurons.”
The CS3 probe was followed by Mitochondrial Coppersensor-1 (Mito-CS1), a fluorescent sensor that can selectively target mitochondria and detect basal and labile copper pools in living cells. Mitochondria, the organelles that generate most of the chemical energy used by cells, are important reservoirs for copper. By allowing direct, real-time visualization of exchangeable mitochondrial copper pools, the Mito-CS1 probe enabled Chang and his colleagues to discover that cells maintain copper homeostasis in mitochondria even in situations of copper deficiency and metabolic malfunctions.
“This work illustrated the importance of regulating copper stores in mitochondria,” Chang said.
The latest copper probe from Chang’s group is Coppersensor 790 (CS790), a fluorescent sensor that features near-infrared excitation and emission capabilities, ideal for penetrating thicker biological specimens. CS790 can be used to monitor fluctuations in exchangeable copper stores under basal conditions, as well as under copper overload or deficiency conditions. Chang and his group are using CS790 to study a mouse model of Wilson’s disease, a genetic disorder characterized by an accumulation of excess copper.
“The in vivo fluorescence detection of copper provided by CS790 and our other fluorescent probes is opening up unique opportunities to explore the roles that copper plays in the healthy physiology of the brain, as well as in the development and progression copper-related diseases,” Chang said.