Study Gives Insight into Diet, Gut Bacteria and Chronic Diarrhea

ARS scientists Danielle Lemay (right) and Zeynep Alkan review microscope images and data from SAMSA2 software. ( USDA-ARS )

A new Agricultural Research Service (ARS) study reveals, for the first time, how diet and bacteria may interact to prolong chronic diarrhea in monkeys.

 

Gut bacteria and nutrition are inseparable, said molecular biologist Danielle Lemay, with ARS’s Western Human Nutrition Research Center in Davis, California. Gut bacteria aid nutrient absorption while nutrition influences which gut bacteria live and die. Together, they promote health or disease.

 

Like humans, rhesus macaques—a well-known species of Old-World monkeys—suffer from gastrointestinal diseases of unknown cause. Medical treatments such as antibiotics have not been able to solve this problem, and no single causative pathogen has been identified. This disease shares many similarities with ulcerative colitis in humans, which affects the large intestine.

 

Unlike humans in a hospital, monkeys who arrive in a medical wing are all on the same diet as their healthy counterparts. This makes it easier to study how gut microbes differently respond to the same diet in health and disease, said Lemay, who began her research on idiopathic chronic diarrhea in monkeys while working at the University of California-Davis. Collaborating with UC-Davis pathobiologist and veterinarian Amir Ardeshir and others, she used a new method called SAMSA2, developed by her research team, to observe all genes expressed by all organisms—bacteria, fungi, protists, etc.—in fecal samples from healthy monkeys and monkeys with chronic diarrhea.

 

The study, published recently in Microbiome, showed how two bacteria interact to produce a bad outcome. Lemay found that bacteria believed to be "good" were cross-feeding fucose—a sugar—to bacteria that may not be so good.

 

This would not be detectable with standard culture-based systems, whose limited testing look only for one bacterium as the culprit in a syndrome or disease, she said. With the team’s SAMSA2 software, they were able to identify which genes were being expressed in the colon of diseased and healthy monkeys.

 

Even though healthy monkeys and those that developed diarrhea were consuming the same foods, this study showed that the "diet" of their gut microbes was not the same, Lemay said. Gut microbes can consume carbohydrates from food we eat or from carbohydrates produced by intestinal cells. The study showed that gut microbes in diseased animals were expressing more genes that enabled them to consume more of the carbohydrates produced by intestinal cells. That was a problem, because those carbohydrates—the mucus layer—also protect intestinal cells and too much degradation of the layer enables microbes to cross the intestinal barrier.

 

Another critical discovery was that the identity of a particular bacterium is not as important as what it is doing in the gut. For example, the pathogen Campylobacter was found in both groups, but in animals with disease, the pathogen expressed a gene that allowed it to attach to the mucin layer. In healthy animals, Campylobacter may just be passing through, Lemay said.

 

The study showed that chronic diarrhea in rhesus macaques is associated with increased gene expression by pathogens, increased mucin degradation and altered fucose utilization, Lemay said. These findings could have implications for chronic gastrointestinal disease, such as ulcerative colitis, that affect humans.

 

 

For more on the role of the microbiome’s role in animal health, see these articles from BovineVetOnline:

Endomicrobial Ecology Could Harness Diversity of Cattle Microbiome

MSU Scientists Study Microbiome Role in Antibiotic-Resistant Bacteria

Encourage the “Good Bugs”

Bugs in the Airway

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