Dietary Fatty Acids Sustain the Growth of the Human Gut Microbiota

While a substantial amount of dietary fats escape absorption in the human small intestine and reach the colon, the ability of resident microbiota to utilize these dietary fats for growth has not been investigated in detail. In this study, we used an multivessel simulator system of the human colon to...

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Veröffentlicht in:	Applied and environmental microbiology 2018-11, Vol.84 (21)
Hauptverfasser:	Agans, Richard, Gordon, Alex, Kramer, Denise Lynette, Perez-Burillo, Sergio, Rufián-Henares, José A, Paliy, Oleg
Format:	Artikel
Sprache:	eng
Schlagworte:	Anaerobic microorganisms Antioxidants Biodegradation Carbohydrates Colon Diet Digestive system Fats Fatty acids Gastrointestinal tract Genes Glycan High fat diet Intestinal microflora Microbial Ecology Microbiota Microorganisms Proteins Reductases Small intestine Spotlight
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creator	Agans, Richard Gordon, Alex Kramer, Denise Lynette Perez-Burillo, Sergio Rufián-Henares, José A Paliy, Oleg
description	While a substantial amount of dietary fats escape absorption in the human small intestine and reach the colon, the ability of resident microbiota to utilize these dietary fats for growth has not been investigated in detail. In this study, we used an multivessel simulator system of the human colon to reveal that the human gut microbiota is able to utilize typically consumed dietary fatty acids to sustain growth. Gut microbiota adapted quickly to a macronutrient switch from a balanced Western diet-type medium to its variant lacking carbohydrates and proteins. We defined specific genera that increased in their abundances on the fats-only medium, including , , and several genera of the class In contrast, the abundances of well-known glycan and protein degraders, including , , and spp., were reduced under such conditions. The predicted prevalences of microbial genes coding for fatty acid degradation enzymes and anaerobic respiratory reductases were significantly increased in the fats-only environment, whereas the abundance of glycan degradation genes was diminished. These changes also resulted in lower microbial production of short-chain fatty acids and antioxidants. Our findings provide justification for the previously observed alterations in gut microbiota observed in human and animal studies of high-fat diets. Increased intake of fats in many developed countries has raised awareness of potentially harmful and beneficial effects of high fat consumption on human health. Some dietary fats escape digestion in the small intestine and reach the colon where they can be metabolized by gut microbiota. We show that human gut microbes are able to maintain a complex community when supplied with dietary fatty acids as the only nutrient and carbon sources. Such fatty acid-based growth leads to lower production of short-chain fatty acids and antioxidants by community members, which potentially have negative health consequences on the host.
doi_str_mv	10.1128/AEM.01525-18
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In this study, we used an multivessel simulator system of the human colon to reveal that the human gut microbiota is able to utilize typically consumed dietary fatty acids to sustain growth. Gut microbiota adapted quickly to a macronutrient switch from a balanced Western diet-type medium to its variant lacking carbohydrates and proteins. We defined specific genera that increased in their abundances on the fats-only medium, including , , and several genera of the class In contrast, the abundances of well-known glycan and protein degraders, including , , and spp., were reduced under such conditions. The predicted prevalences of microbial genes coding for fatty acid degradation enzymes and anaerobic respiratory reductases were significantly increased in the fats-only environment, whereas the abundance of glycan degradation genes was diminished. These changes also resulted in lower microbial production of short-chain fatty acids and antioxidants. Our findings provide justification for the previously observed alterations in gut microbiota observed in human and animal studies of high-fat diets. Increased intake of fats in many developed countries has raised awareness of potentially harmful and beneficial effects of high fat consumption on human health. Some dietary fats escape digestion in the small intestine and reach the colon where they can be metabolized by gut microbiota. We show that human gut microbes are able to maintain a complex community when supplied with dietary fatty acids as the only nutrient and carbon sources. 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subjects	Anaerobic microorganisms Antioxidants Biodegradation Carbohydrates Colon Diet Digestive system Fats Fatty acids Gastrointestinal tract Genes Glycan High fat diet Intestinal microflora Microbial Ecology Microbiota Microorganisms Proteins Reductases Small intestine Spotlight
title	Dietary Fatty Acids Sustain the Growth of the Human Gut Microbiota
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