POSTED BY LISA HOWARD-UC DAVIS
Do sugar-free candy and gum give you gas? Researchers think they know why.
They have identified changes in the gut microbiome that can result in an inability to digest sorbitol.
Sorbitol, a sugar alcohol, is used in sugar-free gum, mints, candy, and other products. It is also found naturally in apricots, apples, pears, avocados, and other foods. At high levels, sorbitol can cause bloating, cramps, and diarrhea. For some people, even a small amount causes digestive upset, a condition known as sorbitol intolerance.
A new study with mice found that taking antibiotics, combined with a high-fat diet, reduced the number of Clostridia gut microbes, which can break down sorbitol.
The findings appear in the journal Cell.
“Our research suggests that microbial sorbitol degradation normally protects the host against sorbitol intolerance. However, an impairment in the microbial ability to break down sorbitol causes sorbitol intolerance,” says Jee-Yon Lee, first author of the study. Lee is an assistant project scientist in the University of California, Davis medical microbiology and immunology department.
The researchers used metagenomic analysis to identify which gut bacteria have genes that make the enzyme that breaks down sorbitol. They also identified which of those gut bacteria were plentiful before—but not after—antibiotic treatment.
This analysis allowed them to zero in on gut microbes belonging to the class Clostridium. Clostridium are anaerobic, meaning they don’t like environments with oxygen.
The researchers found that after the mice were given antibiotics and fed a diet high in saturated fat, the cells lining the gut used less oxygen. This created a higher level of oxygen in the gut, decreasing Clostridia. Without enough Clostridia, sorbitol was not broken down in the gut.
The researchers performed several experiments to try to restore the gut bacteria so it could break down sorbitol again.
In one, they fed the mice Anaerostipes caccae, a gut bacterium that produces butyrate. Butyrate is a short-chain fatty acid produced as part of the normal fermentation process in the gut. It enhances oxygen usage by the cells that line the gut, the epithelial lining, which reduces oxygen levels in the large intestine.
Regulating the oxygen level with Anaerostipes caccae restored the normal levels of Clostridia, which protected the mice from sorbitol-induced diarrhea, even after the butyrate-producing bacteria had been cleared from the mouse’s digestive system.
The researchers suggest that a drug used to treat ulcerative colitis, Crohn’s disease, and other inflammatory bowel diseases, mesalazine (5-aminosalicylate), may be a treatment for sorbitol intolerance in humans. Mesalazine, also known as mesalamine, functions similarly to the butyrate-producing bacteria, restoring the low oxygen levels in the intestine preferred by Clostridia.
“This discovery is crucial, given the prevalent use of sorbitol and similar sugar alcohols in the production of keto-friendly diet foods that are high in fat content,” Lee says.
“It also highlights the importance of oxygen consumption by the epithelial lining in the intestines in maintaining a healthy balance of gut bacteria, especially Clostridia, for proper digestion of certain sugars.”
An important limitation of the study is that mice can tolerate much higher sorbitol levels than humans. Mice possess a cecum—a pouch in their digestive system that slows the flow of intestinal contents and helps digest carbohydrates, which may contribute to being able to better tolerate sorbitol. Clinical studies will be needed to test the hypothesis that mesalazine could treat sorbitol intolerance in humans.
“Our study provides a completely new starting point for approaches to diagnose, prevent, and treat sorbitol intolerance,” says Andreas Bäumler, senior author of the study. Bäumler is a distinguished professor and vice chair of research in the UC Davis medical microbiology and immunology department.
Additional coauthors are from UC Davis, Lawrence Berkeley National Laboratory, Kitasato University in Japan, UC San Francisco, and Chan Zuckerberg Biohub.
Support for this work came from the Kenneth Rainin Foundation and the 2020 Tri-Institutional Partnership in Microbiome Research Initiative. It was also funded by UCSF, UC Davis, and the National Microbiome Data Collaborative.
Source: UC Davis
Original Study DOI: 10.1016/j.cell.2024.01.029
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