Gut-Muscle Axis Exists and May Affect Skeletal Muscle Adaptation to Training
Abstract
:1. Introduction
2. The Link between Diet, Physical Activity, and Microbiota
3. The Effect of Microbiota on Anabolic and Catabolic Processes
4. Bacterial Products and Their Effect on Muscle Function
5. Microbiome and the Availability of Nutrients
6. Glucose Metabolism
7. The Interaction between Microbiota and Mitochondrial Function
8. Microbial Modulation of Neuroactive Molecules
9. Impact of the Microbiome on Exercise Capacity
10. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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References | Study Model | Type of Exercise | Intervention | Beneficial Effect of Intervention on Direct and Indirect Parameters of Sports Performance |
---|---|---|---|---|
Hsu et al. 2015 [119] | Mice | Endurance swimming | Threestudy groups: germ free (GF) vs. Bacteroides fragilis (BF) comparison with no probiotic (specific pathogen-free (SPF) | ↑ activity of serum glutathione peroxidase (GPx) and catalase (Cat) ↑ activity of liver GPx ↑ muscle mass ↑ antioxidant properties ↑ free radical damage protection ↑ muscle mass endurance (extended exercise to exhaustion time) No differences in liver superoxide dismutase (SOD) and Cat activity |
Unsal et al. 2018 [120] | Rats | Exhaustive swimming trial | Fourstudy groups: control, placebo, exercise, exercise+probiotic | ↓ oxidative stress ↑ antioxidative enzymes activity ↑ antioxidative balance |
Study product: multi strain probiotic mixture VSL#3 (Lactobacillus casei, L. plantarum, L. acidophilus, L. delbrueckii subsp. bulgaricus, Bifidobacterium longum, B. breve, and B. infantis, Streptococcus salivarius) | ||||
Scheiman et al. 2019 [97] | Mice | Exhaustive treadmill run | Twostudy groups: control and supplemented | ↑ lactate utilization ↑ blood short-chain fatty acid (SCFA) concentration ↑ extended exercise to exhaustion time (treadmill workout) ↑ Cori cycle efficiency |
Studyproduct: Veilonella, propionic | ||||
Chen et al. 2016 [52] | Mice | grip strength and endurance swimming | Threestudy groups: vehicle, 2.05ˆ108CFU/kg (LP10-1X), and 1.03ˆ109CFU/kg (LP10-5X). | ↑ relative muscle mass and strength ↑ number of type 1 muscle fibers ↑ extended exercise to exhaustion time (swimming trial) ↓ post-workout lactate blood concentration ↓ post-workout ammonia blood concentration ↓ post-workout CK ↓ post-workout ammonia, albumin, creatinine and triglyceride concentration All above changes were dose-dependent |
Study product: Lactobacillus plantarum TWK10 (LP10) | ||||
Hoffman et al. 2019 [123] | Soldiers | vertical jump power, two times 100-m shuttle runs | Twostudy groups: Bacillus coagulans and placebo | ↑ interferon gamma (IFN)-γ and interleukin-10 (IL-10) concentration ↑ mean jump power No effects on 60 s pull-ups, 100-m shuttle run, shuttle run fatigue rate No effects on cortisol and testosterone concentration No effects on CK and pro-inflammatory cytokines concentration |
Studyproduct:Bacillus coagulans | ||||
Jager et al. 2016 [121] | Recreative training man | Damaging exercise bout | Twostudy groups: 20 g of casein consumptionand/or 20 g of casein plus Bacillus consumption | ↑ regeneration perception after damaging workout ↑ sport performance in Wingate Test ↓ soreness perception 24 and 72 h after damaging workout ↓ post-exercise blood CK No effects on muscle strength and thickness |
Study product: Bacillus coagulans GBI-30 | ||||
Roberts et al. 2016 [81] | untrained men and women | triathlon specific stage times (swim, bike, and run) | Three study gorups: probiotics, probiotics +antioxidants and placebo | ↓ blood lipopolysaccharide (LPS) level up to 6 days after workout ↓ race duration |
Study product: mix of Bifidobaterium and Lactobacillus | ||||
Toohey et.al. 2018 [124] | volleyballplayers (women) | squat, deadlift, and bench press, vertical jump, pro-agility and isometric midthigh pull test | Twostudy groups: probiotic and placebo | ↓ fat mass level compared to placebo group No effects on strength or athletic performance. |
Studyproduct:Bacillus Subtilis | ||||
Jager et al. 2016 [78] | resistance-trained men | eccentric exercise of the elbow | Twostudy groups: probiotic and placebo | ↓ IL-6 concentration up 48 h after damaging training ↑ maximal voluntary isometric peak torque at 24 to 72 h following damaging exercises ↑ flexed arm angle after damaging workout No effect on average maximal voluntary isometric peak No clear effect on plasma CK level after damaging exercises |
Study product:Streptococcus thermophilus FP4 Bifidobacterium breve BR03 | ||||
Carbuhn et al. 2018 [122] | Swimmers (women) | aerobic/anaerobic swim time trials and force plate vertical jump | Twostudy groups: probiotic and placebo | ↑ post-training regeneration perception No effects on aerobic and anaerobic swim performance testing No effects onconcentric/eccentric force production No differences in serum IL-1, LPS, and LPS Binding Protein (LBP) concentration |
Studyproduct:Bifidobacterium longum 35624 | ||||
Townsend et al. 2018 [80] | baseball players (men) | Ten-yard sprint test, pro-agility test, standing long jump | Twogroups: probiotics and placebo | ↓ post-workout blood TNF-α concentration No significant effecton IL-10, zonulin, testosterone, cortisol concentration and salivary immunoglobulin A (SIgA) secretion No differences in strength, performance and body composition |
Studyproduct: Bacillus subtilis DE111 | ||||
Huang et al. 2019 [79] | triathletes | triathlon championship | Twostudy groups: Lactobacillus and placebo | ↓ oxidative stress level ↑ antioxidant potential through thioredoxin (TRX) and MPO modulation ↑ post-workout blood BCAA concentration ↑ post-workout regeneration rate ↑ post-workout blood IL-10 concentration ↓ post-workout blood IL-6, IL-8, TNF-α IFN-γ concentration ↓ CK level during recovery period ↑ anaerobic capacity in Wingate Test No significant differences in body composition No effects on CK, myoglobin, lactate dehydrogenase (LDH), ammonia, lactate and FFA after exercise |
Study product: Lactobacillus plantarum PS128 |
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Przewłócka, K.; Folwarski, M.; Kaźmierczak-Siedlecka, K.; Skonieczna-Żydecka, K.; Kaczor, J.J. Gut-Muscle Axis Exists and May Affect Skeletal Muscle Adaptation to Training. Nutrients 2020, 12, 1451. https://doi.org/10.3390/nu12051451
Przewłócka K, Folwarski M, Kaźmierczak-Siedlecka K, Skonieczna-Żydecka K, Kaczor JJ. Gut-Muscle Axis Exists and May Affect Skeletal Muscle Adaptation to Training. Nutrients. 2020; 12(5):1451. https://doi.org/10.3390/nu12051451
Chicago/Turabian StylePrzewłócka, Katarzyna, Marcin Folwarski, Karolina Kaźmierczak-Siedlecka, Karolina Skonieczna-Żydecka, and Jan Jacek Kaczor. 2020. "Gut-Muscle Axis Exists and May Affect Skeletal Muscle Adaptation to Training" Nutrients 12, no. 5: 1451. https://doi.org/10.3390/nu12051451
APA StylePrzewłócka, K., Folwarski, M., Kaźmierczak-Siedlecka, K., Skonieczna-Żydecka, K., & Kaczor, J. J. (2020). Gut-Muscle Axis Exists and May Affect Skeletal Muscle Adaptation to Training. Nutrients, 12(5), 1451. https://doi.org/10.3390/nu12051451