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PurposeTo investigate in vivo the adaptations of satellite cell induced by exercise performed in acute or chronic hypoxic conditions and their contribution to muscle remodeling and hypertrophy.MethodsSearch terms related to exercise, hypoxia and satellite cells were entered on Embase, PubMed and Scopus. Studies were selected for their relevance in terms of regulation of satellite cells by in vivo exercise and muscle contraction in hypoxic conditions.ResultsSatellite cell activation and proliferation seem to be enabled after acute hypoxic exercise via regulations induced by myogenic regulatory factors. Several studies reported also a role of the inflammatory pathway nuclear factor-kappa B and angiogenic factors such as vascular endothelial growth factor, both known to upregulate myogenesis. By stimulating angiogenesis, repeated exercise performed in acute hypoxia might contribute to satellite cell activation. Contrary to such exercise conditions, chronic exposure to hypoxia downregulates myogenesis despite the maintenance of physical activity. This impaired myogenesis might be induced by excessive oxidative stress and proteolysis.ConclusionIn vivo studies suggest that, in comparison to exercise or hypoxia alone, exercise performed in a hypoxic environment, may improve or impair muscle remodeling induced by contractile activity depending upon the duration of hypoxia. Satellite cells seem to be major actors in these dichotomous adaptations. Further research on the role of angiogenesis, types of contraction and autophagy is needed for a better understanding of their respective role in hypoxic exercise-induced modulations of satellite cell activity in human.

The purpose of this study was to investigate whether toll-like receptor 4 (TLR4) is implicated in the development of endoplasmic reticulum stress (ER stress) observed after a high-fat diet (HFD) in liver, skeletal muscle and adipose tissue. TLR4(-/-) and C57BL/6J wild-type mice (WT) were fed with chow or HFD (45% calories from fat) during 18 weeks. An oral glucose tolerance-test was performed. The animals were sacrificed in a fasted state and the tissues were removed. TLR4 deletion protected from body weight gain and glucose intolerance induced by HFD whereas energy intake was higher in transgenic mice suggesting larger energy expenditure. HFD induced an ER stress in skeletal muscle, liver and adipose tissue of WT mice as assessed by BiP, CHOP, spliced and unspliced XBP1 and phospho-eIF2α. TLR4(-/-) mice were protected against HFD-induced ER stress. Then, we investigated the main signaling downstream of TLR4 namely the NF-κB pathway, expecting to identify the mechanism by which TLR4 is able to activate ER stress. The mRNA levels of cytokines regulated by NF-κB namely TNFα, IL-1β and IL-6, were not changed after HFD and phospho-IκB-α (ser 32) was not changed. Our results indicate that TLR4 is essential for the development of ER stress related to HFD. Nevertheless, the NFκ-B pathway does not seem to be directly implicated. The reduced fat storage in TLR4(-/-) mice could explain the absence of an ER stress after HFD.

The aim of this study was to compare the adaptive responses to repeated sprint training in heat (RSHT) on exercise performance under temperate conditions between males and females. Active males and females completed 7 weeks of repeated sprint training twice a week in temperate (CON, 20°C, 55% relative humidity (RH), males: n = 12, females: n = 13) or hot (HEAT, 30°C, 60% RH, males: n = 12, females: n = 14) conditions. Before and after training, a repeated sprint ability test (RSA) was performed (10‐s cycle sprints with 20‐s recovery between sprints, until exhaustion), and aerobic and anaerobic qualities were evaluated in temperate conditions. Thermoregulatory responses were measured on Training 1 and 12 (TR1 and TR12). Sprint number during RSA increased after HEAT from 15 to 21 in males and from 8 to 13 in females (p < 0.001), without significant changes after CON. VO2peak during an incremental exercise test (+3 ± 1 mL·kg−1·min−1, p = 0.032) and mean power output during a Wingate test (+0.41 ± 0.15 W·kg−1, p = 0.007) increased in all groups. No changes were observed in hematological parameters. In HEAT group only, the change in core temperature (−0.16 ± 0.07°C, p = 0.015), but not skin, and thermal sensation (−1 ± 0, p < 0.001) were lower at TR12 than TR1 in both sexes. No changes were observed in sweat rate or whole‐body sweat sodium concentration. Seven weeks of RSHT induced partial heat acclimation and increased the number of repeated sprints performed under temperate conditions in females, to the same extent as in males. Highlights The effects of a repeated sprint training in heat on repeated sprint ability in temperate conditions and sex differences in training responses remain unexplored in the literature. In the current study, 7 weeks of repeated sprint training in heat (30°C and 60% relative humidity) twice weekly improved repeated sprint ability and induced partial heat acclimation similarly in males and females. We suggest that this time efficient training method can be incorporated into a regular training schedule for enhancing repeated sprint ability under temperate conditions in recreationally active females. However, it is important to adjust training settings based on lean body mass rather than total body mass.

Background The control of muscle size is an essential feature of health. Indeed, skeletal muscle atrophy leads to reduced strength, poor quality of life, and metabolic disturbances. Consequently, strategies aiming to attenuate muscle wasting and to promote muscle growth during various (pathological) physiological states like sarcopenia, immobilization, malnutrition, or cachexia are needed to address this extensive health issue. In this study, we tested the effects of urolithin B, an ellagitannin‐derived metabolite, on skeletal muscle growth. Methods C2C12 myotubes were treated with 15 μM of urolithin B for 24 h. For in vivo experiments, mice were implanted with mini‐osmotic pumps delivering continuously 10 μg/day of urolithin B during 28 days. Muscle atrophy was studied in mice with a sciatic nerve denervation receiving urolithin B by the same way. Results Our experiments reveal that urolithin B enhances the growth and differentiation of C2C12 myotubes by increasing protein synthesis and repressing the ubiquitin–proteasome pathway. Genetic and pharmacological arguments support an implication of the androgen receptor. Signalling analyses suggest a crosstalk between the androgen receptor and the mTORC1 pathway, possibly via AMPK. In vivo experiments confirm that urolithin B induces muscle hypertrophy in mice and reduces muscle atrophy after the sciatic nerve section. Conclusions This study highlights the potential usefulness of urolithin B for the treatment of muscle mass loss associated with various (pathological) physiological states.

This study was designed to better understand the molecular mechanisms involved in the anabolic resistance observed in elderly people. Nine young (22 ± 0.1 years) and 10 older (69 ± 1.7 years) volunteers performed a one-leg extension exercise consisting of 10 × 10 repetitions at 70% of their 3-RM, immediately after which they ingested 30 g of whey protein. Muscle biopsies were taken from the vastus lateralis at rest in the fasted state and 30 min after protein ingestion in the non-exercised (Pro) and exercised (Pro+ex) legs. Plasma insulin levels were determined at the same time points. No age difference was measured in fasting insulin levels but the older subjects had a 50% higher concentration than the young subjects in the fed state (p < 0.05). While no difference was observed in the fasted state, in response to exercise and protein ingestion, the phosphorylation state of PKB (p < 0.05 in Pro and Pro+ex) and S6K1 (p = 0.059 in Pro; p = 0.066 in Pro+ex) was lower in the older subjects compared with the young subjects. After Pro+ex, REDD1 expression tended to be higher (p = 0.087) in the older group while AMPK phosphorylation was not modified by any condition. In conclusion, we show that the activation of the mTORC1 pathway is reduced in skeletal muscle of older subjects after resistance exercise and protein ingestion compared with young subjects, which could be partially due to an increased expression of REDD1 and an impaired anabolic sensitivity.

Anabolic resistance is the inability to increase protein synthesis in response to an increase in amino acids following a meal. One potential mediator of anabolic resistance is endoplasmic reticulum (ER) stress. The purpose of the present study was to test whether ER stress impairs the response to growth factors and leucine in muscle cells. Muscle cells were incubated overnight with tunicamycin or thapsigargin to induce ER stress and the activation of the unfolded protein response, mTORC1 activity at baseline and following insulin and amino acids, as well as amino acid transport were determined. ER stress decreased basal phosphorylation of PKB and S6K1 in a dose-dependent manner. In spite of the decrease in basal PKB phosphorylation, insulin (10-50 nM) could still activate both PKB and S6K1. The leucine (2.5-5 mM)-induced phosphorylation of S6K1 on the other hand was repressed by low concentrations of both tunicamycin and thapsigargin. To determine the mechanism underlying this anabolic resistance, several inhibitors of mTORC1 activation were measured. Tunicamycin and thapsigargin did not change the phosphorylation or content of either AMPK or JNK, both increased TRB3 mRNA expression and thapsigargin increased REDD1 mRNA. Tunicamycin and thapsigargin both decreased the basal phosphorylation state of PRAS40. Neither tunicamycin nor thapsigargin prevented phosphorylation of PRAS40 by insulin. However, since PKB is not activated by amino acids, PRAS40 phosphorylation remained low following the addition of leucine. Blocking PKB using a specific inhibitor had the same effect on both PRAS40 and leucine-induced phosphorylation of S6K1. ER stress induces anabolic resistance in muscle cells through a PKB/PRAS40-induced blockade of mTORC1.

During the course of life, muscle mass undergoes many changes in terms of quantity and quality. Skeletal muscle is a dynamic tissue able to hypertrophy or atrophy according to growth, ageing, physical activity, nutrition and health state. The purpose of the present review is to present the mechanisms by which exercise can induce changes in human skeletal muscle mass by modulating protein balance and regulating the fate of satellite cells. Exercise is known to exert transcriptional, translational and post-translational regulations as well as to induce epigenetic modifications and to control messenger RNA stability, which all contribute to the regulation of protein synthesis. Exercise also regulates the autophagy–lysosomal and the ubiquitin–proteasome pathways, the two main proteolytic systems in skeletal muscle, indicating that exercise participates to the regulation of the quality control mechanisms of cellular components and, therefore, to muscle health. Finally, activation, proliferation and differentiation of satellite cells can be enhanced by exercise to induce muscle remodelling and hypertrophy. Each of these mechanisms can potentially impact skeletal muscle mass, depending on the intensity, duration and frequency with which the signal appears.

Background: Benefits of sprint interval training performed in hypoxia (SIH) compared to normoxia (SIN) have been assessed by studies mostly conducted around 3000 m of simulated altitude. The present study aims to determine whether SIH at an altitude as high as 4000 m can elicit greater adaptations than the same training at 2000 m, 3000 m or sea-level. Methods: Thirty well-trained endurance male athletes (18–35 years old) participated in a six-week repeated sprint interval training program (30 s all-out sprint, 4 min 30 s recovery; 4–9 repetitions, 2 sessions/week) at sea-level (SL, n = 8), 2000 m (FiO2 16.7%, n = 8), 3000 m (FiO2 14.5%, n = 7) or 4000 m (FiO2 13.0%, n = 7). Aerobic and anaerobic exercise components were evaluated by an incremental exercise test, a 600 kJ time trial and a Wingate test before and after the training program. Results: After training, peak power output (PPO) during the incremental exercise test increased (~6%) without differences between groups. The lactate threshold assessed by Dmax increased at 2000 m (+14 ± 12 W) and 4000 m (+12 ± 11 W) but did not change at SL and 3000 m. Mean power during the Wingate test increased at SL, 2000 m and 4000 m, although peak power increased only at 4000 m (+38 ± 38 W). Conclusions: The present study indicates that SIH using 30 s sprints is as efficient as SIN for improving aerobic and anaerobic qualities. Additional benefits such as lactate-related adaptations were found only in SIH and Wingate peak power only increased at 4000 m. This finding is of particular interest for disciplines requiring high power output, such as in very explosive sports.

Systemic inflammatory state found in obesity increases the risk of developing numerous diseases. While endurance training seems effective to reduce this inflammation, the underlying mechanisms are not fully understood. Among those, extracellular vesicles (EVs) have been proposed to be actors in the anti‐inflammatory intercellular crosstalk induced by exercise training. This study aimed to investigate how endurance training modulates the EV proteome in the context of an inflammatory state in adults with obesity. Thirteen lean sedentary adults and 10 sedentary adults with obesity participated in a 12‐week endurance training programme. Skeletal muscle, abdominal subcutaneous adipose tissue and venous blood samples were taken prior to and after the training period. The systemic and adipose tissue inflammatory states were assessed, and plasma EVs were isolated by size exclusion chromatography. EV content was analysed by mass spectrometry. EVs isolated from the medium of myotubes stimulated by electrical pulse stimulation in vitro were quantified, and their content was analysed by western blot. After the endurance training, C‐reactive protein (CRP) levels decreased in participants with obesity. In abdominal subcutaneous adipose tissue, the phosphorylation state of nuclear factor‐kappa B (NF‐κB) was not affected by training, but interleukin (IL)‐6 and IL‐1β protein levels were reduced after the 12 weeks in both groups. Conversely, interferon gamma (IFNγ) level reduction was exclusively found in the obesity group. Despite no changes in EV abundance, EV proteome was modified by training. Among the modified proteins in participants with obesity, the antioxidant enzyme peroxiredoxin (PRDX) 1 abundance was increased after training. Additionally, the PRDX1 content of EVs isolated from stimulated myotubes was increased compared to control conditions. In conclusion, our results suggest that the anti‐inflammatory effects of exercise training are not directly mediated by EV anti‐inflammatory proteome changes. However, exercise training increases circulating EV antioxidant content, possibly through contractile activity of skeletal muscle during repeated exercise.

A common nonsense polymorphism in the ACTN3 gene results in the absence of α-actinin-3 in XX individuals. The wild type allele has been associated with power athlete status and an increased force output in numeral studies, though the mechanisms by which these effects occur are unclear. Recent findings in the Actn3(-/-) (KO) mouse suggest a shift towards 'slow' metabolic and contractile characteristics of fast muscle fibers lacking α-actinin-3. Skinned single fibers from the quadriceps muscle of three men with spinal cord injury (SCI) were tested regarding peak force, unloaded shortening velocity, force-velocity relationship, passive tension and calcium sensitivity. The SCI condition induces an 'equal environment condition' what makes these subjects ideal to study the role of α-actinin-3 on fiber type expression and single muscle fiber contractile properties. Genotyping for ACTN3 revealed that the three subjects were XX, RX and RR carriers, respectively. The XX carrier's biopsy was the only one that presented type I fibers with a complete lack of type II(x) fibers. Properties of hybrid type II(a)/II(x) fibers were compared between the three subjects. Absence of α-actinin-3 resulted in less stiff type II(a)/II(x) fibers. The heterozygote (RX) exhibited the highest fiber diameter (0.121±0.005 mm) and CSA (0.012±0.001 mm(2)) and, as a consequence, the highest peak force (2.11±0.14 mN). Normalized peak force was similar in all three subjects (P = 0.75). Unloaded shortening velocity was highest in R-allele carriers (P<0.001). No difference was found in calcium sensitivity. The preservation of type I fibers and the absence of type II(x) fibers in the XX individual indicate a restricted transformation of the muscle fiber composition to type II fibers in response to long-term muscle disuse. Lack of α-actinin-3 may decrease unloaded shortening velocity and increase fiber elasticity.