Effects of probiotics and commensals on intestinal epithelial physiology: implications for nutrient handling
SC Resta - The Journal of physiology, 2009 - Wiley Online Library
SC Resta
The Journal of physiology, 2009•Wiley Online LibraryEukaryotes and prokaryotes have developed mutually beneficial relationships over
millennia of evolutionary adaptation. Bacteria in our gut rely on our diet and the protected
environment of our bodies just as our health depends on byproducts of microbial
metabolism. Microorganisms of the gut microbiota ferment carbohydrates into short‐chain
fatty acids, convert dietary and endogenous nitrogenous compounds into ammonia and
microbial protein, and synthesize and activate B vitamins and vitamin K. The benefit from …
millennia of evolutionary adaptation. Bacteria in our gut rely on our diet and the protected
environment of our bodies just as our health depends on byproducts of microbial
metabolism. Microorganisms of the gut microbiota ferment carbohydrates into short‐chain
fatty acids, convert dietary and endogenous nitrogenous compounds into ammonia and
microbial protein, and synthesize and activate B vitamins and vitamin K. The benefit from …
Eukaryotes and prokaryotes have developed mutually beneficial relationships over millennia of evolutionary adaptation. Bacteria in our gut rely on our diet and the protected environment of our bodies just as our health depends on byproducts of microbial metabolism. Microorganisms of the gut microbiota ferment carbohydrates into short‐chain fatty acids, convert dietary and endogenous nitrogenous compounds into ammonia and microbial protein, and synthesize and activate B vitamins and vitamin K. The benefit from their activity is multiplex and translates into increased energy for the gut epithelial cells, balanced absorption of salt and water, nitrogen recycling, breakdown of complex lipids and cholesterol, and detoxification of waste compounds.
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