It was a challenge unlike any other the chef-turned-graduate student had faced: Vayu Maini Rekdal had to create a menu in which every ingredient could be eaten either raw or cooked. No pickling was allowed, nor fermented toppings such as soy sauce or miso. Nothing could be processed, so things such as tofu were out. And the more sweet potatoes he could serve up, the better.
“It was extremely challenging,” said Rekdal, a chemistry graduate student at Harvard.
Rising to the occasion, Rekdal concocted chia seed breakfast puddings that could be cooked or chilled. He made raw and cooked pea-sweet potato-tahini patties. And for three days, eight volunteers dined on the menu, providing stool samples to aid in research that could eventually help illuminate the evolution of the human microbiome.
The work was led by Rachel Carmody, a professor of human evolution at Harvard, and Peter Turnbaugh, a professor of microbiology at the University of California, San Francisco. They were studying the gut microbiome, the collection of microbes that live in our intestines and influence our immune system and various other parts of our biology, as well as help us digest food.
They had discovered that mice, eating a diet of starchy foods such as sweet potatoes, developed vastly different microbiomes, depending on whether their food had been cooked or served raw. A switch from one to the other provoked a rapid shift in their guts’ microbial inhabitants.
Now, they wanted to see whether the same was true with humans.
Human study
The results of the experiment appear in Nature Microbiology. Although the sample size was small, and the effect was not as strong as in mice, people’s microbiomes do seem to shift on a raw diet, and rapidly. The human study, though short, raises questions about whether starting to eat cooked food, aeons ago, shaped the evolution of the organisms that live inside us, and whether our bugs may have helped us survive times of scarcity.
Cooking alters the structure of many molecules, making more energy available to the mice
As a graduate student, Prof Carmody found that mice fed cooked diets quickly grew plump. Cooking alters the structure of many molecules, making more energy available to the mice. But she was also interested in the microbial community living in the mouse gut, which helps digest food and interacts with its host’s biology in a variety of ways.
In the new paper, she and her collaborators found that feeding mice meat that was raw or cooked changed little about their microbiomes. But with sweet potatoes, meant to stand in for tubers that early humans might have eaten, it was a different story.
Cooking produced significant changes, affecting the kinds of microbes that thrived and which genes they used.
The ability of the gut's microbial residents to shift themselves so drastically even in the short term may have had other benefits for their hosts
The scientists traced the effect to the sweet potato’s starches, which are difficult for mammals to digest raw but become more easily digestible once cooked. Depending on which kind of starch molecules arrive in the large intestine, different groups of microbes might take on the disposal job and subsequently surge in numbers. “Like any ecosystem, if you dramatically change foodstuffs coming into it, some species will thrive over others,” Prof Carmody said.
Ecology of the gut
If cooking, at least of starches, can alter the ecology of the gut, then have humans been shaping our microbiomes ever since we learned to put prehistoric tubers in the fire? If our ancestors did eat these kinds of foods, and switched to cooking them, it may be that some tasks that used to be handled by gut microbes were no longer necessary, said Stephanie Schnorr, a biological anthropologist at the University of Nevada, Las Vegas, who was not involved in the study. As a result, the bacteria might have lost the related genes or gained new roles.
The ability of the gut’s microbial residents to shift themselves so drastically even in the short term may have had other benefits for their hosts. If microbiomes can retool themselves on little notice to handle changes in diet, they may have helped early humans cope with lean days when tubers were the only foods or times when only meat was on the menu. “The microbiome could essentially help us, within 24 hours, maximise our ability to digest nutrients even on a low-quality diet,” Prof Carmody said.
Longer term
The interaction between host and microbes is complex, and longer studies with more people would be necessary to probe how such a dietary change affects the microbiome and its host in the longer term.
People actually did enjoy the menu, Rekdal said. He sees the study as helping advance our understanding of cooking, a particularly ancient kind of applied chemistry. “It’s a form of science,” he said, “that humans have been practising for thousands and thousands of years”. – New York Times