Is the gut microbiota bacterial abundance and composition associated with intestinal epithelial injury, systemic inflammatory profile, and gastrointestinal symptoms in response to exertional-heat stress?

Christie J Bennett; Rebekah Henry; Rhiannon M J Snipe; Ricardo J S Costa

doi:10.1016/j.jsams.2020.06.002

Is the gut microbiota bacterial abundance and composition associated with intestinal epithelial injury, systemic inflammatory profile, and gastrointestinal symptoms in response to exertional-heat stress?

J Sci Med Sport. 2020 Dec;23(12):1141-1153. doi: 10.1016/j.jsams.2020.06.002. Epub 2020 Jun 23.

Authors

Christie J Bennett¹, Rebekah Henry², Rhiannon M J Snipe³, Ricardo J S Costa⁴

Affiliations

¹ Monash University, Department of Nutrition Dietetics & Food, Australia.
² Monash University, Department of Civil Engineering, Australia.
³ Deakin University, Centre for Sport Research, Australia.
⁴ Monash University, Department of Nutrition Dietetics & Food, Australia. Electronic address: ricardo.costa@monash.edu.

PMID: 32620352
DOI: 10.1016/j.jsams.2020.06.002

Abstract

Objectives: The study aimed to examine if the α-diversity and relative abundance of the gastrointestinal bacterial taxa is associated with the response magnitude of markers characteristic of exercise-induced gastrointestinal syndrome in response to exertional-heat stress.

Design: Cross-sectional.

Methods: Twenty-two endurance-trained athletes completed 2h running at 60% V.O_2max in hot ambient conditions (35.2°C, 25% relative humidity). Faecal samples were collected pre-exercise to determine bacterial taxonomy by 16S rRNA amplicon sequencing (Illumina MiSeq platform). Data were processed using the QIIME2 pipeline (v2019.1) establishing taxonomic classification with >95% confidence using SILVA. Pre- and post-exercise blood samples were used to determine plasma I-FABP and cortisol concentrations, and systemic inflammatory response profile. Markers of physiological and thermoregulatory strain, and gastrointestinal symptoms were measured every 10min during exercise. Associations were determined by partial correlation controlled for body mass variables.

Results: Positive associations between Tenericutes (r₍₁₈₎=0.446, p=0.049) and Verrucomicrobia (r₍₁₈₎=0.450, p=0.046) phylum, Akkermansiaceae (r₍₁₈₎=0.486, p=0.030) and Ruminococcaceae (r₍₁₈₎=0.449, p=0.047) family and aligned genus groups with I-FABP were observed. Whilst, associations between Faecalibacterium (r₍₁₂₎=0.668, p=0.009) and Ruminoclostridium-9 (r₍₁₂₎=-0.577, p=0.031) genus with systemic inflammatory profile were observed. Association between bacterial phyla, family, and genus groups were also observed for gastrointestinal symptoms and markers of thermoregulatory strain (r₍₁₈₎ >0.400, p<0.05).

Conclusions: The relative abundance of several commensal bacterial groups showed modest favourable (i.e., low perturbations) or detrimental associations with the magnitude of gastrointestinal integrity perturbations and symptoms, and potentially influences body temperature change, in response to exertional-heat stress.

Keywords: Cytokine; Endurance; Gastrointestinal symptoms; I-FABP; Thermoregulation; α-Diversity.

MeSH terms

Adolescent
Adult
Base Sequence
Body Temperature Regulation
Cross-Sectional Studies
Cytokines / blood
Exercise / physiology*
Fatty Acid-Binding Proteins / blood
Feces / microbiology
Female
Gastrointestinal Microbiome*
Heat-Shock Response / physiology*
Humans
Inflammation / physiopathology
Intestinal Mucosa / physiopathology*
Male
Middle Aged
Peptide Fragments / blood
Physical Exertion / physiology*
Young Adult

Substances

Cytokines
Fatty Acid-Binding Proteins
Peptide Fragments
intestinal fatty acid-binding protein (1-19), human