Treadmill training effect on the myokines content in skeletal muscles of mice with a metabolic disorder model

The effect of treadmill training loads on the content of cytokines in mice skeletal muscles with metabolic disorders induced by a 16 week high fat diet (HFD) was studied. The study included accounting the age and biorhythmological aspects. In the experiment, mice were used at the age of 4 and 32 weeks, by the end of the experiment—respectively 20 and 48 weeks. HFD feeding lasted 16 weeks. Treadmill training were carried out for last 4 weeks six times a week, the duration 60 min and the speed from 15 to 18 m/min. Three modes of loading were applied. The first subgroup was subjected to stress in the morning hours (light phase); the second subgroup was subjected to stress in the evening hours (dark phase); the third subgroup was subjected to loads in the shift mode (the first- and third-weeks treadmill training was used in the morning hours, the second and fourth treadmill training was used in the evening hours). In 20-weekold animals, the exercise effect does not depend on the training regime, however, in 48-week-old animals, the decrease in body weight in mice with the shift training regime was more profound. HFD affected muscle myokine levels. The content of all myokines, except for LIF, decreased, while the concentration of CLCX1 decreased only in young animals in response to HFD. The treadmill training caused multidirectional changes in the concentration of myokines in muscle tissue. The IL-6 content changed most profoundly. These changes were observed in all groups of animals. The changes depended to the greatest extent on the training time scheme. The effect of physical activity on the content of IL-15 in the skeletal muscle tissue was observed mostly in 48-week-old mice. In 20-week-old animals, physical activity led to an increase in the concentration of LIF in muscle tissue when applied under the training during the dark phase or shift training scheme. In the HFD group, this effect was significantly more pronounced. The content of CXCL1 did not change with the use of treadmill training in almost all groups of animals. Physical activity, introduced considering circadian rhythms, is a promising way of influencing metabolic processes both at the cellular and systemic levels, which is important for the search for new ways of correcting metabolic disorders

Comparative profiling of skeletal muscle models reveals heterogeneity of transcriptome and metabolism

We acknowledge the Beta Cell in-vivo Imaging/Extracellular Flux Analysis core facility, supported by the Strategic Research Program (SRP) in Diabetes, for the use of the Seahorse flux analyzer. AUTHOR CONTRIBUTIONS A.M.A. and N.J.P. conceived and designed research; A.M.A., L.S.P., J.A.B.S., B.M.G., M.S., L.D., A.V.C., and N.J.P. performed experiments; A.M.A., L.S.P., J.A.B.S., B.M.G., M.S., L.D., A.V.C., and N.J.P. analyzed data; A.M.A., L.S.P., J.A.B.S., B.M.G., M.S., L.D., A.V.C., A.K., J.R.Z., and N.J.P. interpreted results of experiments; A.M.A. and N.J.P. prepared figures; A.M.A. and N.J.P. drafted manuscript; A.M.A., L.S.P., J.A.B.S., B.M.G., M.S., L.D., A.V.C., A.K., J.R.Z., and N.J.P. edited and revised manuscript; A.M.A., L.S.P., J.A.B.S., B.M.G., M.S., L.D., A.V.C., A.K., J.R.Z., and N.J.P. approved final version of manuscript.Peer reviewedPublisher PD

Kinetics of GLUT4 Trafficking in Rat and Human Skeletal Muscle

OBJECTIVE—In skeletal muscle, insulin stimulates glucose transport activity three- to fourfold, and a large part of this stimulation is associated with a net translocation of GLUT4 from an intracellular compartment to the cell surface. We examined the extent to which insulin or the AMP-activated protein kinase activator AICAR can lead to a stimulation of the exocytosis limb of the GLUT4 translocation pathway and thereby account for the net increase in glucose transport activity. RESEARCH DESIGN AND METHODS—Using a biotinylated photoaffinity label, we tagged endogenous GLUT4 and studied the kinetics of exocytosis of the tagged protein in rat and human skeletal muscle in response to insulin or AICAR. Isolated ep-itrochlearis muscles were obtained from male Wistar rats. Vastus lateralis skeletal muscle strips were prepared from open muscle biopsies obtained from six healthy men (age 39 11 years an

Chronic Nicotine Modifies Skeletal Muscle Na,K-ATPase Activity through Its Interaction with the Nicotinic Acetylcholine Receptor and Phospholemman

Our previous finding that the muscle nicotinic acetylcholine receptor (nAChR) and the Na,K-ATPase interact as a regulatory complex to modulate Na,K-ATPase activity suggested that chronic, circulating nicotine may alter this interaction, with long-term changes in the membrane potential. To test this hypothesis, we chronically exposed rats to nicotine delivered orally for 21–31 days. Chronic nicotine produced a steady membrane depolarization of ∼3 mV in the diaphragm muscle, which resulted from a net change in electrogenic transport by the Na,K-ATPase α2 and α1 isoforms. Electrogenic transport by the α2 isoform increased (+1.8 mV) while the activity of the α1 isoform decreased (−4.4 mV). Protein expression of Na,K-ATPase α1 or α2 isoforms and the nAChR did not change; however, the content of α2 subunit in the plasma membrane decreased by 25%, indicating that its stimulated electrogenic transport is due to an increase in specific activity. The physical association between the nAChR, the Na,K-ATPase α1 or α2 subunits, and the regulatory subunit of the Na,K-ATPase, phospholemman (PLM), measured by co-immuno precipitation, was stable and unchanged. Chronic nicotine treatment activated PKCα/β2 and PKCδ and was accompanied by parallel increases in PLM phosphorylation at Ser63 and Ser68. Collectively, these results demonstrate that nicotine at chronic doses, acting through the nAChR-Na,K-ATPase complex, is able to modulate Na,K-ATPase activity in an isoform-specific manner and that the regulatory range includes both stimulation and inhibition of enzyme activity. Cholinergic modulation of Na,K-ATPase activity is achieved, in part, through activation of PKC and phosphorylation of PLM

Exercise-induced phosphorylation of novel akt substances AS160 and filamin A in human skeletal muscle

Skeletal muscle contraction stimulates multiple signaling cascades that govern a variety of metabolic and transcriptional events. Akt/protein kinase B regulates metabolism and growth/muscle hypertrophy, but contraction effects on this target and its substrates are varied and may depend on the mode of the contractile stimulus. Accordingly, we determined the effects of endurance or resistance exercise on phosphorylation of Akt and downstream substrates in six trained cyclists who performed a single bout of endurance or resistance exercise separated by approximately 7 days. Muscle biopsies were taken from the vastus lateralis at rest and immediately after exercise. Akt Ser(473) phosphorylation was increased (1.8-fold; P=0.011) after endurance but was unchanged after resistance exercise. Conversely, Akt Thr(308) phosphorylation was unaltered after either bout of exercise. Several exercise-responsive phosphoproteins were detected by immunoblot analysis with a phospho-Akt substrate antibody. pp160 and pp300 were identified as AS160 and filamin A, respectively, with increased phosphorylation (2.0- and 4.9-fold, respectively; P<0.05) after endurance but not resistance exercise. In conclusion, AS160 and filamin A may provide an important link to mediate endurance exercise-induced bioeffects in skeletal muscle

Mice experimental model of diabetes mellitus type ii based on high fat diet

An experimental model of the obesity and type II diabetes mellitus formation in C57BL/6 mice using a high fat diet was developed and tested. In the study, it was shown that mice feeding high-fat diet had a significant body weight gain during the 3rd week. By the end of the experiment, body weight has more than doubled. In mice that feed chow diet, body weight increased by 50%, by the end of the experiment It was shown that high fat diet also induced glucose tolerance, and the insulin concentration tripled. The data obtained confirm the adequacy of the experimental model of diabetes mellitus type II in mice

Transcriptomic changes in C2C12 myotubes triggered by electrical stimulation: Role of Ca2+i-mediated and Ca2+i-independent signaling and elevated [Na+]i/[K+]i ratio

Elevation of Ca2+i and AMP-activated protein kinase (AMPK) are considered as major signals triggering transcriptomic changes in exercising skeletal muscle. Electrical pulse stimulation (EPS) of cultured myotubes is widely employed as an in vitro model of muscle contraction. This study examines the impact of Ca2+i-mediated and Ca2+i-independent signaling in transcriptomic changes in EPS-treated C2C12 myotubes. Electrical pulse stimulation (40 V, 1 Hz, 10 ms, 2 h) resulted in [Ca2+]i oscillations, gain of Na+i, loss of K+i, and differential expression of 3215 transcripts. Additions of 10 μM nicardipine abolished [Ca2+]i oscillations but did not affect elevation of the [Na+]i/[K+]i ratio seen in EPS-treated myotubes. Differential expression of 1018 transcripts was preserved in the presence of nicardipine, indicating a Ca2+i-independent mechanism of excitation–transcription coupling. Among nicardipine-resistant transcripts, we noted 113 transcripts whose expression was also affected by partial Na+,K+-ATPase inhibition with 30 μM ouabain providing the same elevation of the [Na+]i/[K+]i ratio as in EPS-treated cells. Electrical pulse stimulation increased phosphorylation of CREB, ATF-1, Akt, ERK, and p38 MAPK without any impact on phosphorylation of acetyl-CoA carboxylase and Unc-51 like autophagy activating kinase-1, i.e. downstream markers of AMPK activation. Unlike CREB, ATF-1, and MAPKs, an increment in Akt phosphorylation was abolished by nicardipine. Thus, our results show that Ca2+i-independent signaling plays a key role in altered expression of 30% of studied genes in EPS-treated myotubes. This signaling pathway is at least partially triggered by dissipation of transmembrane gradients of monovalent cations

Transcriptomic changes in C2C12 myotubes triggered by electrical stimulation: Role of Ca2+i-mediated and Ca2+i-independent signaling and elevated [Na+]i/[K+]i ratio

Elevation of Ca2+i and AMP-activated protein kinase (AMPK) are considered as major signals triggering transcriptomic changes in exercising skeletal muscle. Electrical pulse stimulation (EPS) of cultured myotubes is widely employed as an in vitro model of muscle contraction. This study examines the impact of Ca2+i-mediated and Ca2+i-independent signaling in transcriptomic changes in EPS-treated C2C12 myotubes. Electrical pulse stimulation (40 V, 1 Hz, 10 ms, 2 h) resulted in [Ca2+]i oscillations, gain of Na+i, loss of K+i, and differential expression of 3215 transcripts. Additions of 10 μM nicardipine abolished [Ca2+]i oscillations but did not affect elevation of the [Na+]i/[K+]i ratio seen in EPS-treated myotubes. Differential expression of 1018 transcripts was preserved in the presence of nicardipine, indicating a Ca2+i-independent mechanism of excitation–transcription coupling. Among nicardipine-resistant transcripts, we noted 113 transcripts whose expression was also affected by partial Na+,K+-ATPase inhibition with 30 μM ouabain providing the same elevation of the [Na+]i/[K+]i ratio as in EPS-treated cells. Electrical pulse stimulation increased phosphorylation of CREB, ATF-1, Akt, ERK, and p38 MAPK without any impact on phosphorylation of acetyl-CoA carboxylase and Unc-51 like autophagy activating kinase-1, i.e. downstream markers of AMPK activation. Unlike CREB, ATF-1, and MAPKs, an increment in Akt phosphorylation was abolished by nicardipine. Thus, our results show that Ca2+i-independent signaling plays a key role in altered expression of 30% of studied genes in EPS-treated myotubes. This signaling pathway is at least partially triggered by dissipation of transmembrane gradients of monovalent cations