Posts tagged resveratrol
Articles and news from the latest research reports.
Natural Compound Mitigates Effects of Methamphetamine Abuse
Studies have shown that resveratrol, a natural compound found in colored vegetables, fruits and especially grapes, may minimize the impact of Parkinson’s disease, stroke and Alzheimer’s disease in those who maintain healthy diets or who regularly take resveratrol supplements. Now, researchers at the University of Missouri have found that resveratrol may also block the effects of the highly addictive drug, methamphetamine.
(Image: Wikipedia)
Dennis Miller, associate professor in the Department of Psychological Sciences in the College of Arts & Science and an investigator with the Bond Life Sciences Center, and researchers in the Center for Translational Neuroscience at MU, study therapies for drug addiction and neurodegenerative disorders. Their research targets treatments for methamphetamine abuse and has focused on the role of the neurotransmitter dopamine in drug addiction. Dopamine levels in the brain surge after methamphetamine use; this increase is associated with the motivation to continue using the drug, despite its adverse consequences. However, with repeated methamphetamine use, dopamine neurons may degenerate causing neurological and behavioral impairments, similar to those observed in people with Parkinson’s disease.
“Dopamine is critical to the development of methamphetamine addiction—the transition from using a drug because one likes or enjoys it to using the drug because one craves or compulsively uses it,” Miller said. “Resveratrol has been shown to regulate these dopamine neurons and to be protective in Parkinson’s disease, a disorder where dopamine neurons degenerate; therefore, we sought to determine if resveratrol could affect methamphetamine-induced changes in the brain.”
Using procedures established by Parkinson’s and Alzheimer’s disease research, rats received resveratrol once a day for seven days in about the same concentration as a human would receive from a healthy diet. After a week of resveratrol, researchers measured how much dopamine was released by methamphetamine. Researchers found that resveratrol significantly diminished methamphetamine’s ability to increase dopamine levels in the brain. Furthermore, resveratrol diminished methamphetamine’s ability to increase activity in mice, a behavior that models the hyperactivity observed in people that use the stimulant.
“People are encouraged by physicians and dieticians to include resveratrol-containing products in their diet and protection against methamphetamine’s harmful effects may be an added bonus,” Miller said. “Additionally, there are no consistently effective treatments to help people who are dependent on methamphetamine. Our initial research suggests that resveratrol could be included in a treatment regimen for those addicted to methamphetamine and it has potential to decrease the craving and desire for the drug. Resveratrol is found in good, colorful foods, and has few side effects. We all ought to consume resveratrol for good brain health; our research suggests it may also prevent the changes in the brain that occur with the development of drug addiction.”
(Source: munews.missouri.edu)
Major Alzheimer’s Risk Factor Linked to Red Wine Target
Buck Institute study provides insight for new therapeutics that target the interaction between ApoE4 and a Sirtuin protein
The major genetic risk factor for Alzheimer’s disease (AD), present in about two-thirds of people who develop the disease, is ApoE4, the cholesterol-carrying protein that about a quarter of us are born with. But one of the unsolved mysteries of AD is how ApoE4 causes the risk for the incurable, neurodegenerative disease. In research published this week in The Proceedings of the National Academy of Sciences, researchers at the Buck Institute found a link between ApoE4 and SirT1, an “anti-aging protein” that is targeted by resveratrol, present in red wine.
The Buck researchers found that ApoE4 causes a dramatic reduction in SirT1, which is one of seven human Sirtuins. Lead scientists Rammohan Rao, PhD, and Dale Bredesen, MD, founding CEO of the Buck Institute, say the reduction was found both in cultured neural cells and in brain samples from patients with ApoE4 and AD. “The biochemical mechanisms that link ApoE4 to Alzheimer’s disease have been something of a black box. However, recent work from a number of labs, including our own, has begun to open the box,” said Bredesen.
The Buck group also found that the abnormalities associated with ApoE4 and AD, such as the creation of phospho-tau and amyloid-beta, could be prevented by increasing SirT1. They have identified drug candidates that exert the same effect. “This research offers a new type of screen for Alzheimer’s prevention and treatment,” said Rammohan V. Rao, PhD, co-author of the study, and an Associate Research Professor at the Buck. “One of our goals is to identify a safe, non-toxic treatment that could be given to anyone who carries the ApoE4 gene to prevent the development of AD.”
In particular, the researchers discovered that the reduction in SirT1 was associated with a change in the way the amyloid precursor protein (APP) is processed. Rao said that ApoE4 favored the formation of the amyloid-beta peptide that is associated with the sticky plaques that are one of the hallmarks of the disease. He said with ApoE3 (which confers no increased risk of AD), there was a higher ratio of the anti-Alzheimer’s peptide, sAPP alpha, produced, in comparison to the pro-Alzheimer’s amyloid-beta peptide. This finding fits very well with the reduction in SirT1, since overexpressing SirT1 has previously been shown to increase ADAM10, the protease that cleaves APP to produce sAPP alpha and prevent amyloid-beta.
AD affects over 5 million Americans – there are no treatments that are known to cure, or even halt the progression of symptoms that include loss of memory and language. Preventive treatments are particularly needed for the 2.5% of the population that carry two genes for ApoE4, which puts them at an approximate 10-fold higher risk of developing AD, as well as for the 25% of the population with a single copy of the gene. The group hopes that the current work will identify simple, safe therapeutics that can be given to ApoE4 carriers to prevent the development of Alzheimer’s disease.
(Source: buckinstitute.org)
New Study Validates Longevity Pathway
A new study demonstrates what researchers consider conclusive evidence that the red wine compound resveratrol directly activates a protein that promotes health and longevity in animal models.
What’s more, the researchers have uncovered the molecular mechanism for this interaction, and show that a class of more potent drugs currently in clinical trials act in a similar fashion. Pharmaceutical compounds similar to resveratrol may potentially treat and prevent diseases related to aging in people, the authors contend.
These findings are published in the March 8 issue of Science.
For the last decade, the science of aging has increasingly focused on sirtuins, a group of genes that are believed to protect many organisms, including mammals, against diseases of aging. Mounting evidence has demonstrated that resveratrol, a compound found in the skin of grapes as well as in peanuts and berries, increases the activity of a specific sirtuin, SIRT1, that protects the body from diseases by revving up the mitochondria, a kind of cellular battery that slowly runs down as we age. By recharging the batteries, SIRT1 can have profound effects on health.
Mice on resveratrol have twice the endurance and are relatively immune from effects of obesity and aging. In experiments with yeast, nematodes, bees, flies and mice, lifespan has been extended.
“In the history of pharmaceuticals, there has never been a drug that binds to a protein to make it run faster in the way that resveratrol activates SIRT1,” said David Sinclair, Harvard Medical School professor of genetics and senior author on the paper. “Almost all drugs either slow or block them.”
In 2006, Sinclair’s group published a study showing that resveratrol could extend the lifespan of mice, and the company Sirtris Pharmaceuticals, which was started by HMS researchers, was founded to make drugs more potent than resveratrol. (Sinclair is a co-founder of Sirtris, a GlaxoSmithKline company, and remains a scientific advisor. Sirtris currently has a number of sirtuin-activating compounds in clinical trials.)
But while numerous studies, from Sinclair’s lab and elsewhere, underscored a direct causal link between resveratrol and SIRT1, some scientists claimed the studies were flawed.
The contention lay in the way SIRT1 was studied in vitro, using a specific chemical group attached to the targets of SIRT1 that fluoresces more brightly as SIRT1 activity increases. This chemical group, however, is synthetic and does not exist in cells or in nature, and without it the experiments did not work. As a response to this, a paper published in 2010 surmised that resveratrol’s activation of SIRT1 was an experimental artifact, one that existed in the lab, but not in an actual animal. SIRT1 activity in mice was, the paper claimed, at best an indirect result of resveratrol, and perhaps even a sheer coincidence.
As a result, a debate erupted over the particular pathway that resveratrol and similar compounds affected. Does resveratrol directly activate SIRT1 or is the effect indirect? “We had six years of work telling us that this was most definitely not an artifact,” said Sinclair. “Still, we needed to figure out precisely how resveratrol works. The answer was extremely elegant.”
Sinclair and Basil Hubbard, then a doctoral student in the lab, teamed up with a group of researchers from both the National Institutes of Health and Sirtris Pharmaceuticals to address this question.
First, the team addressed the problem of the fluorescent chemical group. Why was it required for resveratrol to rev up SIRT1 in the test tube? Instead of dismissing the result as an artifact, the researchers surmised that the chemical might be mimicking molecules found naturally in the cell. These turned out to be a specific class of amino acid, the building blocks of proteins. In nature, there are three amino acids that resemble the fluorescent chemical group, one of which is tryptophan, a molecule abundant in turkey and notable for inducing drowsiness. When researchers repeated the experiment, swapping the fluorescing chemical group on the substrate with a tryptophan residue, resveratrol and similar molecules were once again able to activate SIRT1.
“We discovered a signature for activation that is in fact found in the cell and doesn’t require these other synthetic groups,” said Hubbard, first author of the study. “This was a critical result, which allowed us to bridge the gap between our biochemical and physiological findings.
“Next, we needed to identify precisely how resveratrol presses on SIRT1’s accelerator,” said Sinclair. The team tested approximately 2,000 mutants of the SIRT1 gene, eventually identifying one mutant that completely blocked resveratrol’s effect. The particular mutation resulted in the substitution of a single amino acid residue, out of the 747 that make up SIRT1. The researchers also tested hundreds of other molecules from the Sirtris library, many of which are far more powerful than resveratrol, against this mutant SIRT1. All failed to activate it.
The authors propose a model for how resveratrol works: When the molecule binds, a hinge flips, and SIRT1 becomes hyperactive.
Although these experiments occurred in a test tube, once the researchers identified the precise location of the accelerator pedal on SIRT1—and how to break it—they could test their ideas in a cell. They replaced the normal SIRT1 gene in muscle and skin cells with the accelerator-dead mutant. Now they could test precisely whether resveratrol and the drugs in development work by tweaking SIRT1 (in which case they would not work) or one of the thousands of other proteins in a cell (in which they would work). While resveratrol and the drugs tested revved up mitochondria in normal cells (an effect caused activating by SIRT1), the mutant cells were completely immune.
“This was the killer experiment,” said Sinclair. “There is no rational alternative explanation other than resveratrol directly activates SIRT1 in cells. Now that we know the exact location on SIRT1 where and how resveratrol works, we can engineer even better molecules that more precisely and effectively trigger the effects of resveratrol.”
The researchers plan on continuing academic-industry collaborations with the goal of bringing to fruition drugs that treat diseases associated with aging.
Green tea and red wine extracts interrupt Alzheimer’s disease pathway in cells
Natural chemicals found in green tea and red wine may disrupt a key step of the Alzheimer’s disease pathway, according to new research from the University of Leeds.
In early-stage laboratory experiments, the researchers identified the process which allows harmful clumps of protein to latch on to brain cells, causing them to die. They were able to interrupt this pathway using the purified extracts of EGCG from green tea and resveratrol from red wine.
The findings, published in the Journal of Biological Chemistry, offer potential new targets for developing drugs to treat Alzheimer’s disease, which affects some 800,000 people in the UK alone, and for which there is currently no cure.
"This is an important step in increasing our understanding of the cause and progression of Alzheimer’s disease," says lead researcher Professor Nigel Hooper of the University’s Faculty of Biological Sciences. "It’s a misconception that Alzheimer’s is a natural part of ageing; it’s a disease that we believe can ultimately be cured through finding new opportunities for drug targets like this."
Alzheimer’s disease is characterised by a distinct build-up of amyloid protein in the brain, which clumps together to form toxic, sticky balls of varying shapes. These amyloid balls latch on to the surface of nerve cells in the brain by attaching to proteins on the cell surface called prions, causing the nerve cells to malfunction and eventually die.
"We wanted to investigate whether the precise shape of the amyloid balls is essential for them to attach to the prion receptors, like the way a baseball fits snugly into its glove," says co-author Dr Jo Rushworth. "And if so, we wanted to see if we could prevent the amyloid balls binding to prion by altering their shape, as this would stop the cells from dying."
The team formed amyloid balls in a test tube and added them to human and animal brain cells. Professor Hooper said: “When we added the extracts from red wine and green tea, which recent research has shown to re-shape amyloid proteins, the amyloid balls no longer harmed the nerve cells. We saw that this was because their shape was distorted, so they could no longer bind to prion and disrupt cell function.
"We also showed, for the first time, that when amyloid balls stick to prion, it triggers the production of even more amyloid, in a deadly vicious cycle," he added.
Professor Hooper says that the team’s next steps are to understand exactly how the amyloid-prion interaction kills off neurons.
"I’m certain that this will increase our understanding of Alzheimer’s disease even further, with the potential to reveal yet more drug targets," he said.
Dr Simon Ridley, Head of Research at Alzheimer’s Research UK, the UK’s leading dementia research charity, which part-funded the study, said: “Understanding the causes of Alzheimer’s is vital if we are to find a way of stopping the disease in its tracks. While these early-stage results should not be a signal for people to stock up on green tea and red wine, they could provide an important new lead in the search for new and effective treatments. With half a million people affected by Alzheimer’s in the UK, we urgently need treatments that can halt the disease – that means it’s crucial to invest in research to take results like these from the lab bench to the clinic.”
Scientists Map Initial Anti-Aging Formula
A new study indicates that scientists have found a new way of delaying the aging process in mice, and they hope to replicate the finding in people.
The scientists published their findings in the journal Cell Metabolism. The research was built upon an earlier study that shed light on progeria, a rare genetic disease that prematurely ages one in four million babies.
A mutation was found in the Lamin A protein, which lines the nucleus in human cells, disrupting the repair process and accelerating aging. They also found that normal and healthy Lamin A binds to and activates the gene SIRT1, which has been long associated with longevity. If scientists can develop drugs that mimic Lamin A or increase the binding between Lamin A and SIRT1, this may lead to anti-aging drugs.
The team also examined if the binding efficiency was boosted with resveratrol, a compound found in the skin of red grapes. Mice fed with concentrated resveratrol fared significantly better than healthy mice that weren’t given it and the onset of aging was delayed and the life expectancy was extended. Mice with progeria lived 30% longer when fed with resveratrol compared with progerial mice not given the compound.