Four men in a boat: Ultra-endurance exercise alters the gut microbiome
| Autor: | Paul D. Cotter, Fergus Shanahan, Ronan Whiston, Trevor Woods, Michael G. Molloy, Patrick O'Connor, Owen Cronin, Sean Underwood, David Keohane, Orla O'Sullivan |
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| Rok vydání: | 2019 |
| Předmět: |
Adult
Male Rowing Physiology Physical Therapy Sports Therapy and Rehabilitation Biology Feces 03 medical and health sciences 0302 clinical medicine Abundance (ecology) Endurance training Humans Orthopedics and Sports Medicine Prospective Studies 030212 general & internal medicine Exertion Relative species abundance Water Sports Bacteria Cardiorespiratory fitness Biodiversity 030229 sport sciences Gastrointestinal Microbiome Athletes Metagenomics Physical Endurance Metaproteomics |
| Zdroj: | Journal of Science and Medicine in Sport. 22:1059-1064 |
| ISSN: | 1440-2440 |
| DOI: | 10.1016/j.jsams.2019.04.004 |
| Popis: | Objectives Compositional and functional adaptions occur in the gut microbiome in response to habitual physical activity. The response of the gut microbiome to sustained, intense exercise in previously active individuals, however, is unknown. This study aimed to prospectively explore the gut microbiome response of four well-trained male athletes to prolonged, high intensity trans-oceanic rowing, describing changes in microbial diversity, abundance and metabolic capacity. Design A prospective, repeated-measures, within-subject report. Methods Serial stool samples were obtained from four male athletes for metagenomic whole-genome shotgun sequencing to record microbial community structure and relevant functional gene profiles before, during and after a continuous, unsupported 33-day, 5000 km transoceanic rowing race. Calorific intake and macronutrient composition were recorded by validated food frequency questionnaire and anthropometry was determined by body composition analysis and cardiorespiratory testing. Results Microbial diversity increased throughout the ultra-endurance event. Variations in taxonomic composition included increased abundance of butyrate producing species and species associated with improved metabolic health, including improved insulin sensitivity. The functional potential of bacterial species involved in specific amino and fatty acid biosynthesis also increased. Many of the adaptions in microbial community structure and metaproteomics persisted at three months follow up. Conclusions These findings demonstrate that prolonged, intense exercise positively influences gut microbial diversity, increases the relative abundance of some bacterial species and up-regulates the metabolic potential of specific pathways expressing microbial gene products. These adaptions may play a compensatory role in controlling the physiological stress associated with sustained exertion as well as negating the deleterious consequences accompanying endurance exercise. |
| Databáze: | OpenAIRE |
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