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Gut microbiome altered by surgery improves metabolism independent of weight loss and other metabolic factors

Researchers at the University of Toronto (U of T), Canada, and its partner hospitals, have reported that changes in gut microbiota after bariatric surgery can directly improve metabolism, independent of food intake, weight loss and other metabolic factors. The preclinical findings add to evidence that microbiome-based therapies such as probiotics and faecal matter transplants have the potential to improve metabolic health, and may one day reduce the need for weight-loss surgery.

“We know the microbiome contributes to metabolic improvements after bariatric surgery, but have known very little about how,” said Johane Allard, a professor at U of T’s Temerty Faculty of Medicine and a clinician-scientist at University Health Network. “Here, we show that with no other changes, the altered microbiome influences that outcome, and we identify potential mechanisms.”


Bariatric surgery releases gut hormones that improve insulin sensitivity and reduce appetite, and it alters the make-up and function of gut microbiota. Researchers have sought to understand, how and how much, these additional biochemical changes contribute to metabolic improvements and weight loss, with an eye to new treatments. But studies of microbiota-related changes that could be harnessed as broadly effective therapies have been stymied by vast differences in gut microbiota among individuals.


The current study paired faecal matter transplants. The Toronto team transferred faecal matter from four people to mice — both before and after they had bariatric surgery. The team fed both groups of mice the same high-fat, Western diet in a germ-free facility, then observed the effects over several weeks.


Mice receiving the post-surgery transplant showed much better blood-sugar control and insulin sensitivity than the pre-surgery recipients, suggesting a strong role for the microbiome in improved metabolism, despite no change in body weight. The human study participants also became more sensitive to insulin and lost weight, as expected.


Less expected, however, was an increase in mass and energy expenditure in brown fat among mice that received the post-surgery transplant.


“We were very surprised by the data in brown adipose tissue,” said Dana Philpott, a co-principal investigator on the study and professor of immunology at Temerty Medicine. “We thought if we looked at regular [white fat] adipose tissue, we might see decreased fat or an ability to metabolise better, but the finding was very specific to brown fat.”


Heat was an early clue that something of interest was happening in brown fat.


“When we first put the post-surgery transplant mice in the metabolic cages, we noticed they generated more heat,” said Jitender Yadav, a postdoctoral fellow in the Philpott lab and one of three first-authors on the study. “We also noticed in some of the literature that bariatric surgery in mice increases brown adipose tissue and energy expenditure, and in our study we were able to see the similar effect just by transferring the post-surgery microbiome.”


As well, the team found biochemical and transcriptional markers of reduced inflammation in the white fat of post-surgery mice — another sign of improved metabolic health. To look for microbiota-related changes that could explain all these metabolic improvements, the researchers studied and compared metabolites in stool samples from pre- and post-surgery mice.


They found increases in tryptophan metabolites, short-chain fatty acids and acylcarnitines, and decreases in amino acids, organic acid and lactic acid, all correlated with improved metabolic health. Those changes in metabolites were consistent across the post-surgery mice, despite variations in the constituents of their microbiota and in the microbiota of the four patients.


“The bacterial make-up of the microbiota wasn’t significant,” Yadav said. “We now think that microbiome-based therapies that induce the right mix of metabolites, such as pre- and probiotics, dietary changes and fecal matter transplants, could be an effective therapy for improved metabolism and weight loss.”


Co-principal investigator Herbert Gaisano, a professor in the department of medicine at U of T and a clinician-scientist at Toronto General Hospital Research Institute, recently received funding to study how these metabolites work. Gaisano and his team, including co-first authors on the current study Tao Liang and Tairan Qin, will analyse the metabolites in human tissue samples of fat and liver, obtained during bariatric surgery.


The Philpott lab also continues to study the metabolites, in the offspring of the study mice, and they hope to replicate their results with a larger number of patients at some point.


More broadly, Yadav said the study should help nudge the field of microbiome research away from a long-standing focus on bacteria. “One take-away is that the amount and type of bacteria don’t always matter,” he said. “It’s the metabolites they produce, and which get absorbed downstream, that can influence health.”


Several other researchers participated in the study. They include bariatric Professors Allan Okrainec and Tim Jackson, both of U of T’s department of surgery and University Health Network, and Professors Daniel Winer,Susy Hota, Susan Poutanen and Hoon-Ki Sung, and their lab groups.

Funding for the study came from the Canadian Institutes of Health Research, and the Banting and Best Diabetes Centre at U of T.


The findings were reported in the study, ‘Gut microbiome modified by bariatric surgery improves insulin sensitivity and correlates with increased brown fat activity and energy expenditure’, published in the journal Cell Reports Medicine.


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