06:37am Thursday 15 November 2018

The complicated biology of garlic

Researchers today generally agree that eating garlic, used for thousands of years to treat human disease, can reduce the risk of developing certain kinds of cancers, cardiovascular disease, and type 2 diabetes, but exactly how it does this is a still a mystery that needs more research.

In a review led by the University of Nottingham, published April 26 in the journal Trends in Pharmacological Sciences, researchers argue that explaining exactly how garlic affects human health—and getting consistent results during clinical trials—is more complex, because of the vast array of compounds garlic produces.

Dr Peter Rose, a biochemist at the University of Nottingham has led the review and says: “Garlic isn’t a magic bullet as it can often be portrayed, I don’t think there is one individual plant species that is a cure-all, but there are certainly plant species that are strongly associated with reducing disease risk within humans and Garlic is one of these. Variety is the spice of life, but understanding the chemistry of some of your spices is probably a very advantageous thing to do.”

Garlic’s unique flavour comes from sulfur compounds. Like other members of the allium family, the plant absorbs sulfate from the soil and incorporates it into amino acids and sulfur storage molecules. These sulfur storage molecules can then be broken down into approximately 50 different sulfur-containing compounds when the garlic is prepared and eaten.  Dr Rose continues: “The different molecules that make up Garlic give the plants an ecological advantage when they’re growing out in the wild. As it happens, they’re also biologically active within mammalian cells and tissues.”

Preparation affects molecules

These compounds are well studied in garlic, and there is research to suggest that they are important in producing the health effects for which garlic is renowned. Understanding how they produce those effects is less clear, however, in part because how we prepare garlic affects which sulfur compounds we end up consuming. Chopping fresh garlic, fermenting garlic in alcohol, and pressing garlic for oil, for example, all yield different sulfur compounds. “Each of these preparative forms could have a different effect within mammalian systems. And that’s what makes this research so complex, because we don’t really understand how these compounds are metabolized in humans and it’s very difficult to identify common mechanisms of action for these molecules,” Dr Rose says.

While there’s no right or wrong way to prepare your garlic, this quirk of garlic’s biochemistry could explain why studies of the plant’s effects on humans have had such mixed results. “When it comes to human intervention studies, there’s been quite a lot of disparity. Sometimes the consumption of and exposure to these compounds has biological effects, and other times, it does nothing. I think it needs reinvestigating, just because of the sheer complexity of the diversity of these sorts of compounds and the different distribution of them between different garlic products,” he says.

Rose and his colleagues are particularly interested in how these sulfur compounds might affect gaseous signaling molecules like nitric oxide and hydrogen sulfide, which are naturally produced by our bodies. Gaseous signaling molecules play an important role in cell communication and maintaining homeostasis, and altered levels of them are present in many diseases. A number of pre-clinical studies linked the kinds of sulphur compounds we get from garlic to increased production of these molecules, suggesting that this might be the common mechanism by which the different sulfur compounds affect the human body.

More research needed

There’s still a lot of research to be done, but Rose believes that someday we might be able to identify other plants that stimulate the production of these gases or modify garlic, onions, and other alliums to be more efficient at producing them once ingested. “There is a lot of possibility within this area for finding approaches that could reduce the risk of diseases and improve human health, but it all comes back to those fundamental questions of what actually happens to these compounds when we metabolize them. There’s a whole spectrum of human work that still needs to be done to further explore some of these weird and wonderful sulfur compounds that we find within our diets,” he says.

Story credits

For more information, contact Dr Pete Rose on peter.rose@nottingham.ac.uk or 0115 9516098

The University of Nottingham

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