Resveratrol Helps The Heart Says New University Study
Resveratrol Keeps Hearts Young
June 4, 2008
Resveratrol, A natural compound found in red wine, may protect the heart against the effects of the aging process, researchers said on Tuesday.
In their study, mice were given a diet supplemented with the compound known as resveratrol starting at their equivalent of middle age until old age. These mice experienced changes in their gene activity related to aging in a way very similar to mice that were placed on a so-called calorie restriction diet that slows the aging process by greatly cutting dietary energy intake. Most striking was how the resveratrol, like calorie restriction, blocked the decline in heart function typically associated with aging, according to Tomas Prolla, a University of Wisconsin professor of genetics who helped lead the study. Much as Spaniard Juan Ponce de Leon once searched for the mythical fountain of youth, researchers now are seeking ways to extend the quality and length of human life. In some studies, animals given a diet with greatly reduced caloric intake have lived longer than animals with normal diets. But perpetual hunger is a steep price to pay for greater longevity, some researchers say. Resveratrol, found in abundance in grapes and in red wine, has drawn a lot of interest from scientists and some companies, including GlaxoSmithKline, which in April said it would pay $720 million to buy Sirtris Pharmaceuticals Inc, a company that is developing drugs that mimic the effects of resveratrol. Some studies have shown that in high doses, resveratrol extended the life span of fruit flies and worms and prevented early death in mice fed a high-fat diet. In this study, mice were given relatively low doses compared to the earlier research, and still experienced important aging-related benefits, the researchers said. The researchers began giving the resveratrol diet to the mice when they were 14 months old — their middle age — and followed the animals until they were about 30 months old. The researchers then conducted tests on cardiac function and on gene activity related to aging. “”Resveratrol at low doses can retard some aspects of the aging process, including heart aging, and it may do so by mimicking some of the effects of caloric restriction, which is known to retard aging in several tissues and extend life span,”" added Prolla, whose study was published in the scientific journal PLoS ONE. Using a method that permits simultaneous analysis of thousands of genes at the same time, the researchers found a huge overlap in the genes whose activity were changed by resveratrol and caloric restriction. They looked at the heart, brain and muscles, and said that the effect of resveratrol was strongest in the heart but did prevent some aging-related changes in the other tissues. Just because mice had these benefits does not mean people also would, although Prolla said, “”I think there’s a high likelihood that our findings are applicable to humans.”" He said he expected to see a lot of studies in the coming years on the effects of resveratrol supplementation in people.
Scientists Learning More Why Aging Cells Fail to Repair Themselves
Why Aging Cells Lose Ability to Repair Themselves Study finds defect that could lead to new treatments for disease
FRIDAY, Sept. 5 (HealthWire) — A defect in the body’s self-defense mechanism against age-related genetic mutations has been identified by researchers at the University of Texas Medical Branch at Galveston.
The finding may help explain why the aging human body can’t defend itself against DNA damage in the mitochondria, the power plants that fuel the growth and activity of cells.
Finding ways to help aging cells repair their own damaged DNA could possibly lead to ways to prevent or treat cancer, Alzheimer’s disease, Parkinson’s disease and other health problems caused by genetic defects.
As cells age, they experience continuous genetic mutations, some of which are caused by the harmful byproducts of the oxygen we inhale. But the body’s repair mechanism is constantly at work fixing this DNA damage. However, this repair activity becomes less efficient as cells age.
In this study, the researchers analyzed why this DNA repair activity becomes less effective in the mitochondria as cells age. They found a biochemical “”roadblock”" that prevents much of the repair enzyme activity from reaching the site of the DNA damage in the mitochondria of aging cells.
In old cells, about half of the repair enzyme activity can’t reach the mitochondria DNA to repair it.
The study was published online this week in the Proceedings of the National Academy of Sciences.
Science Begins to Add Weight to CLA
The flurry of activity in CLA applications is being backed by a growing body of research to support the ingredient, particularly for its effects on weight loss. A review published in this month’s Journal of Nutrition supports conjugated linoleic acid’s action on weight management, concluding that it is at least in part due to regulation of glucose and fatty acid uptake and metabolism.
Conjugated linoleic acid is the common name of a group of fatty acids found in dairy products and meat. CLA isomers have been studied for their action on an impressive range of diseases, including cancer, atherosclerosis, obesity, and immune function. However as scientists begin to reveal their effects on reduction of body fat, food makers are increasingly looking at the ingredient for the valuable slimming market.
In Canada, where many of the patents for CLA are held, the dairy industry has long been studying the production of high-CLA milk. In Europe, a research centre in Ireland is studying the compound which could add significant value to its dairy industry, while in Italy, Techno Foods introduced a strawberry flavoured yoghurt naturally rich in CLA (conjugated linoleic acid) and omega-3 fatty acids this summer.
Specific CLA isomers have been shown to prevent the development of obesity in certain rodent and pig models and this has been attributed mainly to trans-10, cis-12 CLA, both in vivo and in vitro, write the University of North Carolina researchers in the review. However, CLA’s ability to modulate human obesity remains controversial because data from clinical trials using mixed isomers are conflicting.
In vitro studies by the team demonstrated that while trans-10, cis-12 CLA prevents triglyceride accumulation in human cells, cis-9, trans-11 CLA increases triglyceride content. The team concluded that the isomers’ regulation of glucose and metabolism must partly explain its mechanism on human fat.
The news is also good for supplement marketers who recently learned of research carried out by Cognis backing the long-term safety of its Tonalin CLA.
Acetyl L-Carntine vs. L-Carnitine
The Essential Difference Between the Carnitines
Do you lack energy, or feel tired and physically or mentally unprepared to take on the tasks of the day? This is not unusual, especially as we age, and today’s topic may help explain some of the reasons for this energy deficit.
Two natural compounds produced by our tissues, L-carnitine and acetyl-L-carnitine (ALC), are similar in that both have identical chemical core structures. However, one (ALC) contains an extra component, an acetic acid bound to the core molecule (in what is known as an ester linkage). It turns out that this extra chemical piece makes a significant difference in how this molecule behaves in our body relative to its non-acetylated cousin, L-carnitine. These differences are described below, but first a brief summary of how these molecules normally function in our body.
L-carnitine functions as a vehicle to ferry fat constituents (fatty acids) across a membrane barrier into the cell’s energy-producing machine, the mitochondria, where the fat is converted to energy. Equally important, L-carnitine works in the reverse direction, too. It ferries toxic products produced during fat metabolism out of the mitochondria. This latter step helps maintain the mitochondria as clean-burning, energy-efficient machines.
We are all aware of the fact that as we age, our energy level diminishes. This decrease in energy parallels a decrease in the plasma level of L-carnitine. L-carnitine also decreases under conditions of stress, both psychological and physical. Consequently, it is described as a conditionally essential nutrient. This simply means that when our bodies cannot produce enough of it to meet demand, we need to increase the intake of this nutrient.
Acetyl-L-carnitine is just as active as L-carnitine in transporting fatty acids into the mitochondria. However, as described below, that extra acetyl group confers additional properties to this form of L-carnitine, which make it superior to its non-acetylated cousin. Both compounds increase energy Acetyl L-Carnitine or ALC Physical Energy Fat Metabolism Brain Protection Neurotransmission
Experiments with rats show a dramatic decrease (between 50-70%) in the activity level of old rats as compared to the young animal. Old rats, too, get tired with age! This decrease, as mentioned above, parallels a decrease in the amount of L-carnitine present in the animal’s tissues and blood.
This observation led researchers to investigate whether the old energy-deficient animals could be transformed into more energetic, youthful animals by feeding them a diet enriched with L-carnitine. Supplying L-carnitine to the diet increased the ambulatory activity of the old rats almost two-fold. The experiment was repeated with ALC, and it too increased the animals’ activity level to about an equal degree. So both compounds worked equally well in improving the old rats’ energy levels. ALC protects the brain
One of the two cousins, ALC, stands out with respect to its effects on the brain and nervous system. First, ALC is more effectively transported into the central nervous system. It more readily traverses the blood-brain barrier