Tuesday, October 26, 2021

 

Green tea catechins promote oxidative stress

green tea
Credit: Unsplash/CC0 Public Domain

Green tea is seen as healthy and promotes a longer life, supposedly due to its high level of antioxidants. Researchers at ETH Zurich have now cast doubt on previous assumptions about how these ingredients work.

Green tea has long been known to have health benefits. In particular, it contains catechins called ECG and EGCG that are said to prolong life. These two substances belong to the group of polyphenols. They are considered antioxidants, which means they counteract or prevent oxidative stress in the body caused by aggressive free radicals of oxygen.

Until now, research has assumed that the catechins neutralize these free radicals and thus prevent damage to cells or DNA. One source of oxygen free radicals is metabolism; for example, when the mitochondria—the powerhouses of the cell—are working to produce energy.

ETH researchers led by Michael Ristow, Professor of Energy Metabolism at the Department of Health Sciences and Technology at ETH Zurich, together with colleagues from the University of Jena, have now taken a closer look at how catechins act in the nematode worm C. elegans. And they have come to a different, seemingly paradoxical conclusion: Rather than suppressing oxidative stress, the catechins in green tea promote it.

Temporary increase in oxidative stress

In a study just published in the journal Aging, Ristow's team shows that these polyphenols from green tea initially increase oxidative stress in the short term, but that this has the subsequent effect of increasing the defensive capabilities of the cells and the organism. As a result, the catechins in green tea led to  and greater fitness in nematodes that were fed them.

"That means green tea polyphenols, or catechins, aren't, in fact, antioxidants, but rather pro-oxidants that improve the organism's ability to defend itself, similar to a vaccination," explains study leader Ristow.

However, this increase in defensive capability manifests not through the , but rather by activating genes that produce certain enzymes such as superoxide dismutase (SOD) and catalase (CTL). It is these enzymes that inactivate the free radicals in the nematode; they are essentially endogenous antioxidants.

Sport and calorie reduction have a similar effect

Ristow isn't surprised to see this kind of mechanism at work. His research group showed back in 2009 that the reason sport promotes health is because sporting activities increase  in the short term, thus improving the body's defenses. Consuming fewer calories has the same effect, as has been shown several times in animals. Mice fed a reduced-calorie diet live longer than those fed a normal, high-calorie diet. "So it made sense to me that the catechins in green tea would work in a similar way," Ristow explains.

He goes on to say that the findings from this study translate well to humans. The basic biochemical processes by which organisms neutralize oxygen free radicals are conserved in evolutionary history and are present in everything from unicellular yeast to humans.

Green tea yes, concentrates no

Ristow himself drinks green tea every day, a practice he recommends. But he advises against taking green tea extracts or concentrates. "At a certain concentration, it becomes toxic," he says. High-dose catechins inhibit mitochondria to such an extent that cell death ensues, which can be particularly dangerous in the liver. Anyone consuming these polyphenols in excessive doses risks damaging their organs.

While the most catechins are to be found in Japanese varieties of green tea, other green teas also contain sufficient amounts of these polyphenols. Black tea, on the other hand, contains a much lower level of catechins, since these are largely destroyed by the fermentation process. "That's why  is preferable to black tea," Ristow says.

Is green tea a fad or a real health boost?

More information: Jing Tian et al, Green tea catechins EGCG and ECG enhance the fitness and lifespan of Caenorhabditis elegans by complex I inhibition, Aging (2021). DOI: 10.18632/aging.203597
Provided by ETH Zurich 

No comments:

Post a Comment