The athletic gut microbiota

Mohr, Alex E.; Jäger, Ralf; Carpenter, Katie C; Kerksick, Chad M.; Purpura, Martin; Townsend, Jeremy R.; West, Nicholas P.; Black, Katherine; Gleeson, Michael; Pyne, David B.; Wells, Shawn; Arent, Shawn M.; Kreider, Richard B.; Campbell, Bill; Bannock, Laurent; Scheiman, Jonathan; Wissent, Craig J.; Pane, Marco; Kalman, Douglas; Pugh, Jamie N.; Ortega‐Santos, Carmen P.; Haar, Jessica A. ter; Arciero, Paul J.; António, José

doi:10.1186/s12970-020-00353-w

Cited by 178 publications

(167 citation statements)

References 241 publications

(349 reference statements)

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“…Commonly used probiotic strains for the application of exercise include Lactobacillus , Bifidobacterium , and Bacillus genera, however, new microbiome research and technological advances are identifying potential next-generation probiotic candidates [ 4 ]. In the context of exercise, and especially athletes, the present body of literature suggests their microbiota has several key differences in comparison with other populations, likely driven, in part, by exercise and diet [ 5 ▪ ]. These characteristics may influence the effects of probiotics on the resident microbiome and host physiology, as well as consideration for probiotic application.…”

Section: Introductionmentioning

confidence: 99%

“…However, the recent positive findings noted above are promising and investigators are encouraged to continue this line of research for both macro and micronutrients. It may be that the exercise associated gut microbiota may be more receptive to improved nutrient utilization as it appears to possess a functional capacity that is primed for tissue repair and a greater ability to harness energy from the diet with increased capacity for carbohydrate, cell structure, and nucleotide biosynthesis [ 5 ▪ ].…”

Section: Introductionmentioning

confidence: 99%

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Recent advances in clinical probiotic research for sport

Jäger¹,

Mohr

Pugh³

2020

Current Opinion in Clinical Nutrition &Amp; Metabolic Care

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Purpose of review This is a review of the most up-to-date research on the effectiveness of probiotic supplementation for outcomes related to athletes and physical activity. The focus is on clinical research incorporating exercise and/or physically active participants on the nutritional effectiveness of single and multistrain preparations. Recent findings Findings of the included clinical studies support the notion that certain probiotics could play important roles in maintaining normal physiology and energy production during exercise which may lead to performance-improvement and antifatigue effects, improve exercise-induced gastrointestinal symptoms and permeability, stimulate/modulate of the immune system, and improve the ability to digest, absorb, and metabolize macro and micronutrients important to exercise performance and recovery/health status of those physically active. Summary The current body of literature highlights the specificity of probiotic strain/dose and potential mechanisms of action for application in sport. These novel findings open new areas research, potential use for human health, and reinforce the potential role for probiotic's in exercise performance. While encouraging, more well designed studies of probiotic supplementation in various sport applications are warranted.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Recent advances in clinical probiotic research for sport

Jäger¹,

Mohr

Pugh³

2020

Current Opinion in Clinical Nutrition &Amp; Metabolic Care

Self Cite

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“…Bioinformatics studies have quantitively illustrated how stress can reduce intestinal barrier integrity, altering gut microbiota composition, which in turn modulates immunoregulatory responses in the host (9,40,41). A compromised gut microbiota profile introduces disruption in the uptake of fluids, electrolytes, and vital nutrients, exerting negative impacts on exercise performance and recovery (42)(43)(44). Host-gut microbiota interactions are also implicated in the nervous system control of glucose, impacting another aspect of host metabolic efficiency (45).…”

Section: Downloaded Frommentioning

confidence: 99%

“…The gut microbiome is highly dynamic and correlated with multiple factors including diet, genetic makeup, stress, socioeconomic status, interactions between social and physical environments (42), and exercise (43). It fluctuates over time (13) and varies biogeographically across different sections of the gut (14).…”

Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

Biomimetic Gut Model Systems for Development of Targeted Microbial Solutions for Enhancing Warfighter Health and Performance

et al. 2020

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The human gut microbiome plays a vital role in both health and disease states and as a mediator of cognitive and physical performance. Despite major advances in our understanding of the role of gut microbes in host physiology, mechanisms underlying human-microbiome dynamics have yet to be fully elucidated. This knowledge gap represents a major hurdle to the development of targeted gut microbiome solutions influencing human health and performance outcomes. The microbiome as it relates to warfighter health and performance is of interest to the Department of Defense (DoD) with the development of interventions impacting gut microbiome resiliency among its top research priorities. While technological advancements are enabling the development of experimental model systems that facilitate mechanistic insights underpinning human health, disease, and performance, translatability to human outcomes is still questionable. This review discusses some of the drivers influencing the DoD’s interest in the warfighter gut microbiome and describes current in vitro gut model systems supporting direct microbial-host interactions.

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“…Recent research has revealed that the gut microbiota impacts the host physiology and human health [2]. Indeed, the data obtained on earth argue to preserve an optimized gut microbiota composition, as its disruption/deregulation of these bacteria communities referred to as dysbiosis, is associated with health disorders [3] and/or altered physical performance [4][5][6][7][8]. As a modulator of the immune system, the gut microbiota contributes to intestinal homeostasis and integrity (permeability and in ammation) and exerts a nutritional role via its bacteria-derived metabolites [4].…”

Section: Introductionmentioning

confidence: 99%

Does simulated microgravity induce significant changes in human gut microbiota? New answers with dry immersion, an innovative ground-based model.

Jollet¹,

Goustard²,

Mariadassou³

et al. 2020

Preprint

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Background A new problematic on the gut microbiota of the astronauts and the effects of microgravity emerged recently as that bacteria community is sensitive to physical (in)activity which could be hampered during spaceflights. Therefore, the objective of our study was thus to determine the effects of dry immersion, an innovative ground-based human model of simulated microgravity, on human gut microbiota composition. We collected stools from 14 healthy men before and after 5 days of Dry Immersion to determine taxonomic profiles by 16S metagenomic.Results Our analyses show preservation of α–diversity through Observed, Chao1, Shannon and InvSimpson indices. β–diversity is also not impacted by Dry Immersion as represented by PCoA plots with Jaccard, Bray-Curtis and UniFrac indices. Phyla abundances for OTUs associated to BacteroidetesP, FirmicutesP, ProteobacteriaP and ActinobacteriaP are also preserved. Interestingly, metagenomics analysis of the 32 families and 44 associated genera underscored that OTUs associated to ClostridialesO order and LachnospiraceaeF family are increased (p < 0.01) belonging to FirmicutesP phylum.Conclusion The diversity and global composition of the gut microbiome remained unaltered in response to Dry Immersion confirming the robustness of gut microbiota. However, it’s sufficient to led to several significant changes at the lower taxonomy levels. This suggests that the human gut microbiota, with its known strong impact on human health and performance, is a potential biological target of microgravity and underscores the need to investigate further this new field of research on gut microbiota – microgravity.Trial registration: ClinicalTrials.gov Identifier NCT03915457- Registered 16 April 2019 - Retrospectively registered - https://clinicaltrials.gov/ct2/show/NCT03915457.

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The athletic gut microbiota

Cited by 178 publications

References 241 publications

Recent advances in clinical probiotic research for sport

Recent advances in clinical probiotic research for sport

Biomimetic Gut Model Systems for Development of Targeted Microbial Solutions for Enhancing Warfighter Health and Performance

Does simulated microgravity induce significant changes in human gut microbiota? New answers with dry immersion, an innovative ground-based model.

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