Oxidative stress (glutathionylation) and Na,K-ATPase activity in rat skeletal muscle.

BACKGROUND: Changes in ion distribution across skeletal muscle membranes during muscle activity affect excitability and may impair force development. These changes are counteracted by the Na,K-ATPase. Regulation of the Na,K-ATPase is therefore important for skeletal muscle function. The present study investigated the presence of oxidative stress (glutathionylation) on the Na,K-ATPase in rat skeletal muscle membranes. RESULTS: Immunoprecipitation with an anti-glutathione antibody and subsequent immunodetection of Na,K-ATPase protein subunits demonstrated 9.0±1.3% and 4.1±1.0% glutathionylation of the α isoforms in oxidative and glycolytic skeletal muscle, respectively. In oxidative muscle, 20.0±6.1% of the ß1 units were glutathionylated, whereas 14.8±2.8% of the ß2-subunits appear to be glutathionylated in glycolytic muscle. Treatment with the reducing agent dithiothreitol (DTT, 1 mM) increased the in vitro maximal Na,K-ATPase activity by 19% (P<0.05) in membranes from glycolytic muscle. Oxidized glutathione (GSSG, 0-10 mM) increased the in vitro glutathionylation level detected with antibodies, and decreased the in vitro maximal Na,K-ATPase activity in a dose-dependent manner, and with a larger effect in oxidative compared to glycolytic skeletal muscle. CONCLUSION: This study demonstrates the existence of basal glutathionylation of both the α and the ß units of rat skeletal muscle Na,K-ATPase. In addition, the study suggests a negative correlation between glutathionylation levels and maximal Na,K-ATPase activity. PERSPECTIVE: Glutathionylation likely contributes to the complex regulation of Na,K-ATPase function in skeletal muscle. Especially, glutathionylation induced by oxidative stress may have a role in Na,K-ATPase regulation during prolonged muscle activity.

Purinergic effects on Na,K-ATPase activity differ in rat and human skeletal muscle.

BACKGROUND: P2Y receptor activation may link the effect of purines to increased maximal in vitro activity of the Na,K-ATPase in rat muscle. The hypothesis that a similar mechanism is present in human skeletal muscle was investigated with membranes from rat and human skeletal muscle. RESULTS: Membranes purified from rat and human muscles were used in the Na,K-ATPase assay. Incubation with ADP, the stable ADP analogue MeS-ADP and UDP increased the Na+ dependent Na,K-ATPase activity in rat muscle membranes, whereas similar treatments of human muscle membranes lowered the Na,K-ATPase activity. UTP incubation resulted in unchanged Na,K-ATPase activity in humans, but pre-incubation with the antagonist suramin resulted in inhibition with UTP, suggesting that P2Y receptors are involved. The Na,K-ATPase in membranes from both rat and human could be stimulated by protein kinase A and C activation. Thus, protein kinase A and C activation can increase Na,K-ATPase activity in human muscle but not via P2Y receptor stimulation. CONCLUSION: The inhibitory effects of most purines (with the exception of UTP) in human muscle membranes are probably due to mass law inhibition of ATP hydrolysis. This inhibition could be blurred in rat due to receptor mediated activation of the Na,K-ATPase. The different effects could be related to a high density of ADP sensitive P2Y1 and P2Y13 receptors in rat, whereas the UTP sensitive P2Y11 could be more abundant in human. Alternatively, rat could possesses a mechanism for protein-protein interaction between P2Y receptors and the Na,K-ATPase, and this mechanism could be absent in human skeletal muscle (perhaps with the exception of the UTP sensitive P2Y11 receptor). PERSPECTIVE: Rat muscle is not a reliable model for purinergic effects on Na,K-ATPase in human skeletal muscle.

Exercise-induced increase in maximal in vitro Na-K-ATPase activity in human skeletal muscle.

The present study investigated whether maximal in vitro Na-K-ATPase activity in human skeletal muscle is changed with exercise and whether it was altered by acute hypoxia. Needle biopsies from 14 subjects were obtained from vastus lateralis before and after 4 min of intense muscle activity. In addition, six subjects exercised also in hypoxia (12.5% oxygen). The Na-K-ATPase assay revealed a 19% increase (P < 0.05) in maximal velocity (Vmax) for Na⁺-dependent Na-K-ATPase activity after exercise and a tendency (P < 0.1) toward a decrease in Km for Na⁺ (increased Na⁺ affinity) in both normoxia and hypoxia. In contrast, the in vitro Na-K-ATPase activity determined with the 3-O-MFPase technique was 11-32% lower after exercise in normoxia (P < 0.05) and hypoxia (P < 0.1). Based on the different results obtained with the Na-K-ATPase assay and the 3-O-MFPase technique, it was suggested that the 3-O-MFPase method is insensitive to changes in Na-K-ATPase activity. To test this possibility, changes in Na-K-ATPase activity was induced by protein kinase C activation. The changes quantified with the Na-K-ATPase assay could not be detected with the 3-O-MFPase method. In addition, purines stimulated Na-K-ATPase activity in rat muscle membranes; these changes could not be detected with the 3-O-MFPase method. Therefore, the 3-O-MFPase technique is not sensitive to changes in Na⁺ sensitivity, and the method is not suited to detecting changes in Na-K-ATPase activity with exercise. In conclusion, muscle activity in humans induces an increased in vitro Na⁺-dependent Na-K-ATPase activity, which contributes to the upregulation of the Na-K-ATPase in association with exercise both in normoxia and hypoxia.

Purinergic activation of rat skeletal muscle membranes increases Vmax and Na+ affinity of the Na,K-ATPase and phosphorylates phospholemman and α1 subunits.

Muscle activity is associated with an increase in extracellular purines (ATP, ADP), which are involved in signalling mechanisms. The present study investigates the effect of purines on the function of Na,K-ATPase (Na,K-pump) in rat skeletal muscle. Na,K-ATPase activity was quantified by measuring the release of inorganic phosphate in the presence of ATP and variable Na(+) concentrations. In membranes purified from glycolytic muscle fibres, purinergic stimulation increases V (max) and decreases the K (m) (higher Na(+) affinity) of the Na,K-ATPase. Stimulatory effects were obtained using ATP, ADP, 2-methylthio-ADP and UPT, but not UDP and adenosine. The effect of ADP on V (max) can be inhibited by the non-specific P2Y receptor antagonists, suramin and PPADS. Moreover, the P2Y(13) receptor antagonist MRS 2211 strongly inhibited the response to ADP, whereas the specific P2Y(1) receptor antagonist MRS 2500 had less effect. Based on results from these agonists and antagonists, we conclude that P2Y(13) receptors mediate the main effects observed, that P2Y1 receptors are also involved and that some P2Y(2)/P2Y(4) receptors also appear to be involved. Receptor antagonists had no effect on ADP-induced subunit (phospholemman and α1) phosphorylation and changes in K (m) (Na(+) affinity). Thus, the stimulatory effects of purines are mediated by two independent mechanisms: P2Y receptor-mediated increase in Na,K-ATPase capacity (increased V (max)) and P2Y receptor-independent phosphorylation of Na,K-ATPase phospholemman and α1 subunits, which induce changes in ion affinity. These mechanisms may contribute to up-regulation of Na,K-ATPase during muscle activity.

Na,K-ATPase activity in mouse muscle is regulated by AMPK and PGC-1α.

Na,K-ATPase activity, which is crucial for skeletal muscle function, undergoes acute and long-term regulation in response to muscle activity. The aim of the present study was to test the hypothesis that AMP kinase (AMPK) and the transcriptional coactivator PGC-1α are underlying factors in long-term regulation of Na,K-ATPase isoform (α,ß and PLM) abundance and Na(+) affinity. Repeated treatment of mice with the AMPK activator AICAR decreased total PLM protein content but increased PLM phosphorylation, whereas the number of α- and ß-subunits remained unchanged. The K(m) for Na(+) stimulation of Na,K-ATPase was reduced (higher affinity) after AICAR treatment. PLM abundance was increased in AMPK kinase-dead mice compared with control mice, but PLM phosphorylation and Na,K-ATPase Na(+) affinity remained unchanged. Na,K-ATPase activity and subunit distribution were also measured in mice with different degrees of PGC-1α expression. Protein abundances of α1 and α2 were reduced in PGC-1α +/- and -/- mice, and the ß(1)/ß(2) ratio was increased with PGC-1α overexpression (TG mice). PLM protein abundance was decreased in TG mice, but phosphorylation status was unchanged. Na,K-ATPase V (max) was decreased in PCG-1α TG and KO mice. Experimentally in vitro induced phosphorylation of PLM increased Na,K-ATPase Na(+) affinity, confirming that PLM phosphorylation is important for Na,K-ATPase function. In conclusion, both AMPK and PGC-1α regulate PLM abundance, AMPK regulates PLM phosphorylation and PGC-1α expression influences Na,K-ATPase α(1) and α(2) content and ß(1)/ß(2) isoform ratio. Phosphorylation of the Na,K-ATPase subunit PLM is an important regulatory mechanism.

Exercise-induced regulation of muscular Na+-K+ pump, FXYD1, and NHE1 mRNA and protein expression: importance of training status, intensity, and muscle type.

It is investigated if exercise-induced mRNA changes cause similar protein expression changes of Na(+)-K(+) pump isoforms (α(1), α(2), ß(1), ß(2)), FXYD1, and Na(+)/K(+) exchanger (NHE1) in rat skeletal muscle. Expression was evaluated (n = 8 per group) in soleus and extensor digutorum longus after 1 day, 3 days, and 3 wk (5 sessions/wk) of either sprint (4 × 3-min sprint + 1-min rest) or endurance (20 min) running. Two hours after exercise on day 1, no change in protein expression was apparent in either training group or muscle, whereas sprint exercise increased the mRNA of soleus α(2) (4.9 ± 0.8-fold; P < 0.05), ß(2) (13.2 ± 4.4-fold; P < 0.001), and NHE1 (12.0 ± 3.1-fold; P < 0.01). Two hours after sprint exercise, protein expression normalized to control samples was higher on day 3 than day 1 for soleus α(1) (41 ± 18% increase vs. 15 ± 8% reduction; P < 0.05), α(2) (64 ± 35% increase vs. 37 ± 12% reduction; P < 0.05), ß(1) (17 ± 21% increase vs. 14 ± 29% reduction; P < 0.05), and FXYD1 (35 ± 16% increase vs. 13 ± 10% reduction; P < 0.05). In contrast, on day 3, soleus α(1) (0.1 ± 0.1-fold; P < 0.001), α(2) (0.2 ± 0.1-fold; P < 0.001), ß(1) (0.4 ± 0.1-fold; P < 0.05), and ß(2)-mRNA (2.9 ± 1.7-fold; P < 0.001) expression was lower than after exercise on day 1. After 3 wk of training, no change in protein expression relative to control existed. In conclusion, increased expression of Na(+)-K(+) pump subunits, FXYD1 and NHE1 after 3 days exercise training does not appear to be an effect of increased constitutive mRNA levels. Importantly, sprint exercise can reduce mRNA expression concomitant with increased protein expression.

Na+,K+-ATPase Na+ affinity in rat skeletal muscle fiber types.

Previous studies in expression systems have found different ion activation of the Na(+)/K(+)-ATPase isozymes, which suggest that different muscles have different ion affinities. The rate of ATP hydrolysis was used to quantify Na(+),K(+)-ATPase activity, and the Na(+) affinity of Na(+),K(+)-ATPase was studied in total membranes from rat muscle and purified membranes from muscle with different fiber types. The Na(+) affinity was higher (K(m) lower) in oxidative muscle compared with glycolytic muscle and in purified membranes from oxidative muscle compared with glycolytic muscle. Na(+),K(+)-ATPase isoform analysis implied that heterodimers containing the beta(1) isoform have a higher Na(+) affinity than heterodimers containing the beta(2) isoform. Immunoprecipitation experiments demonstrated that dimers with alpha(1) are responsible for approximately 36% of the total Na,K-ATPase activity. Selective inhibition of the alpha(2) isoform with ouabain suggested that heterodimers containing the alpha(1) isoform have a higher Na(+) affinity than heterodimers containing the alpha(2) isoform. The estimated K(m) values for Na(+) are 4.0, 5.5, 7.5 and 13 mM for alpha(1)beta(1), alpha(2)beta(1), alpha(1)beta(2) and alpha(2)beta(2), respectively. The affinity differences and isoform distributions imply that the degree of activation of Na(+),K(+)-ATPase at physiological Na(+) concentrations differs between muscles (oxidative and glycolytic) and between subcellular membrane domains with different isoform compositions. These differences may have consequences for ion balance across the muscle membrane.

Na+-K+-ATPase in rat skeletal muscle: muscle fiber-specific differences in exercise-induced changes in ion affinity and maximal activity.

It is unclear whether muscle activity reduces or increases Na(+)-K(+)-ATPase maximal in vitro activity in rat skeletal muscle, and it is not known whether muscle activity changes the Na(+)-K(+)-ATPase ion affinity. The present study uses quantification of ATP hydrolysis to characterize muscle fiber type-specific changes in Na(+)-K(+)-ATPase activity in sarcolemmal membranes and in total membranes obtained from control rats and after 30 min of treadmill running. ATPase activity was measured at Na(+) concentrations of 0-80 mM and K(+) concentrations of 0-10 mM. K(m) and V(max) values were obtained from a Hill plot. K(m) for Na(+) was higher (lower affinity) in total membranes of glycolytic muscle (extensor digitorum longus and white vastus lateralis), when compared with oxidative muscle (red gastrocnemius and soleus). Treadmill running induced a significant decrease in K(m) for Na(+) in total membranes of glycolytic muscle, which abolished the fiber-type difference in Na(+) affinity. K(m) for K(+) (in the presence of Na(+)) was not influenced by running. Running only increased the maximal in vitro activity (V(max)) in total membranes from soleus, whereas V(max) remained constant in the three other muscles tested. In conclusion, muscle activity induces fiber type-specific changes both in Na(+) affinity and maximal in vitro activity of the Na(+)-K(+)-ATPase. The underlying mechanisms may involve translocation of subunits and increased association between PLM units and the alphabeta complex. The changes in Na(+)-K(+)-ATPase ion affinity are expected to influence muscle ion balance during muscle contraction.

Na(+)-K (+) pump location and translocation during muscle contraction in rat skeletal muscle.

Muscle contraction may up-regulate the number of Na(+)-K(+) pumps in the plasma membrane by translocation of subunits. Since there is still controversy about where this translocation takes place from and if it takes place at all, the present study used different techniques to characterize the translocation. Electrical stimulation and biotin labeling of rat muscle revealed a 40% and 18% increase in the amounts of the Na(+)-K(+) pump alpha(2) subunit and caveolin-3 (Cav-3), respectively, in the sarcolemma. Exercise induced a 36% and 19% increase in the relative amounts of the alpha(2) subunit and Cav-3, respectively, in an outer-membrane-enriched fraction and a 41% and 17% increase, respectively, in sarcolemma giant vesicles. The Na(+)-K(+) pump activity measured with the 3-O-MFPase assay was increased by 37% in giant vesicles from exercised rats. Immunoprecipitation with Cav-3 antibody showed that 17%, 11% and 14% of the alpha(1) subunits were associated with Cav-3 in soleus, extensor digitorum longus, and mixed muscles, respectively. For the alpha(2), the corresponding values were 17%, 5% and 16%. In conclusion; muscle contraction induces translocation of the alpha subunits, which is suggested to be caused partly by structural changes in caveolae and partly by translocation from an intracellular pool.

Effect of two different intense training regimens on skeletal muscle ion transport proteins and fatigue development.

This study examined the effect of two different intense exercise training regimens on skeletal muscle ion transport systems, performance, and metabolic response to exercise. Thirteen subjects performed either sprint training [ST; 6-s sprints (n = 6)], or speed endurance training [SET; 30-s runs approximately 130% Vo(2 max), n = 7]. Training in the SET group provoked higher (P < 0.05) plasma K(+) levels and muscle lactate/H(+) accumulation. Only in the SET group was the amount of the Na(+)/H(+) exchanger isoform 1 (31%) and Na(+)-K(+)-ATPase isoform alpha(2) (68%) elevated (P < 0.05) after training. Both groups had higher (P < 0.05) levels of Na(+)-K(+)-ATPase beta(1)-isoform and monocarboxylate transporter 1 (MCT1), but no change in MCT4 and Na(+)-K(+)-ATPase alpha(1)-isoform. Both groups had greater (P < 0.05) accumulation of lactate during exhaustive exercise and higher (P < 0.05) rates of muscle lactate decrease after exercise. The ST group improved (P < 0.05) sprint performance, whereas the SET group elevated (P < 0.05) performance during exhaustive continuous treadmill running. Improvement in the Yo-Yo intermittent recovery test was larger (P < 0.05) in the SET than ST group (29% vs. 10%). Only the SET group had a decrease (P < 0.05) in fatigue index during a repeated sprint test. In conclusion, turnover of lactate/H(+) and K(+) in muscle during exercise does affect the adaptations of some but not all related muscle ion transport proteins with training. Adaptations with training do have an effect on the metabolic response to exercise and specific improvement in work capacity.

Training-induced changes in membrane transport proteins of human skeletal muscle.

Training improves human physical performance by inducing structural and cardiovascular changes, metabolic changes, and changes in the density of membrane transport proteins. This review focuses on the training-induced changes in proteins involved in sarcolemmal membrane transport. It is concluded that the same type of training affects many transport proteins, suggesting that all transport proteins increase with training, and that both sprint and endurance training in humans increase the density of most membrane transport proteins. There seems to be an upper limit for these changes: intense training for 6-8 weeks substantially increases the density of membrane proteins, whereas years of training (as performed by athletes) have no further effect. Studies suggest that training-induced changes at the protein level are important functionally. The underlying factors responsible for these changes in transport proteins might include changes in substrate concentration, but the existence of "exercise factors" mediating these responses is more likely. Exercise factors might include Ca(2+), mitogen-activated protein kinases, adenosine monophosphate kinases, other kinases, or interleukin-6. Although the magnitudes of training-induced changes have been investigated at the protein level, the underlying signal mechanisms have not been fully described.

Lactate and force production in skeletal muscle.

Lactic acid accumulation is generally believed to be involved in muscle fatigue. However, one study reported that in rat soleus muscle (in vitro), with force depressed by high external K(+) concentrations a subsequent incubation with lactic acid restores force and thereby protects against fatigue. However, incubation with 20 mm lactic acid reduces the pH gradient across the sarcolemma, whereas the gradient is increased during muscle activity. Furthermore, unlike active muscle the Na(+)-K(+) pump is not activated. We therefore hypothesized that lactic acid does not protect against fatigue in active muscle. Three incubation solutions were used: 20 mM Na-lactate (which acidifies internal pH), 12 mM Na-lactate +8 mm lactic acid (which mimics the pH changes during muscle activity), and 20 mM lactic acid (which acidifies external pH more than internal pH). All three solutions improved force in K(+)-depressed rat soleus muscle. The pH regulation associated with lactate incubation accelerated the Na(+)-K(+) pump. To study whether the protective effect of lactate/lactic acid is a general mechanism, we stimulated muscles to fatigue with and without pre-incubation. None of the incubation solutions improved force development in repetitively stimulated muscle (Na-lactate had a negative effect). It is concluded that although lactate/lactic acid incubation regains force in K(+)-depressed resting muscle, a similar incubation has no or a negative effect on force development in active muscle. It is suggested that the difference between the two situations is that lactate/lactic acid removes the negative consequences of an unusual large depolarization in the K(+)-treated passive muscle, whereas the depolarization is less pronounced in active muscle.

Effects of strength training on muscle lactate release and MCT1 and MCT4 content in healthy and type 2 diabetic humans.

UNLABELLED: Lactate is released from skeletal muscle in proportion to glucose uptake rates, and it leaves the cells via simple diffusion and two monocarboxylate transporter proteins, MCT1 and MCT4. In response to endurance training MCT1 - and possibly MCT4 - content in muscle increases. The MCTs have not previously been measured in patients with type 2 diabetes (Type 2), and the response to strength training is unknown. Ten Type 2 and seven healthy men (Control) strength-trained one leg (T) 3 times a week for 6 weeks while the other leg remained untrained (UT). Each session lasted no more than 30 min. After strength training, muscle biopsies were obtained and an isoglycaemic, hyperinsulinaemic clamp, combined with arterial and femoral venous catheterization of both legs, was carried out. During hyperinsulinaemia lactate release was always increased in T versus UT legs. MCT1 was lower (P<0.05) and MCT4 similar in Type 2 versus Control. With training, MCT1 content always increased, while MCT4 only increased in Control. CONCLUSIONS: MCT1 content in skeletal muscle in Type 2 is lower compared with healthy men. Strength training increases MCT1 content in healthy men and in Type 2, thus normalizing the content in Type 2.

Effect of resistance training on Na,K pump and Na+/H+ exchange protein densities in muscle from control and patients with type 2 diabetes.

Ten patients with type 2 diabetes and seven controls were strength-trained with one leg for 30 min three times per week for 6 weeks. The training-induced changes in the protein densities of the Na,K-pump subunits and the Na+/H+ exchanger protein NHE1 were quantified with Western blotting of needle biopsy material obtained from trained and untrained legs of both groups. Training increased the bench press and knee-extensor force by 77+/-15 and 28+/-1%, respectively, in the control subjects, and by 75+/-7 and 42+/-8%, respectively, in the diabetics. In the control subjects the Na,K-pump isoform alpha1 was increased by 37% (P<0.05) in trained compared to untrained leg, and in the diabetics the alpha1 content was 45% higher (P=0.052) in trained compared to untrained leg. For the alpha2 isoform the corresponding values were 21% and 41% (P<0.05), respectively. The content of the beta1 subunit in the control subjects was 33% higher (P<0.05) in trained compared to untrained leg, and 47% higher (P=0.06) in trained compared to untrained leg in the diabetics. Thus, a limited amount of strength-training is able to increase the Na,K-pump subunit and isoform content both in controls and in patients with type 2 diabetes.

Effects of high-intensity intermittent training on potassium kinetics and performance in human skeletal muscle.

A rise in extracellular potassium concentration in human skeletal muscle may play an important role in development of fatigue during intense exercise. The aim of the present study was to examine the effect of intense intermittent training on muscle interstitial potassium kinetics and its relationship to the density of Na(+),K(+)-ATPase subunits and K(ATP) channels, as well as exercise performance, in human skeletal muscle. Six male subjects performed intense one-legged knee-extensor training for 7 weeks. On separate days the trained leg (TL) and the control leg (CL) performed a 30 min exercise period of 30 W and an incremental test to exhaustion. At frequent intervals during the exercise periods interstitial potassium ([K(+)](I)) was determined by microdialysis, femoral arterial and venous blood samples were drawn and thigh blood flow was measured. Time to fatigue for TL was 28% longer (P < 0.05) than for CL (10.6 +/- 0.7 (mean +/-s.e.m.) versus 8.2 +/- 0.7 min). The amounts of Na(+),K(+)-ATPase alpha(1) and alpha(2) subunits were, respectively, 29.0 +/- 8.4 and 15.1 +/- 2.7% higher (P < 0.05) in TL than in CL, while the amounts of beta(1) subunits and ATP-dependent K(+) (K(ATP)) channels were the same. In CL [K(+)](I) increased more rapidly and was higher (P < 0.05) throughout the 30 W exercise bout, as well at 60 and 70 W, compared to TL, whereas [K(+)](I) was similar at the point of fatigue (9.9 +/- 0.7 and 9.1 +/- 0.5 mmol l(-1), respectively). During the 30 W exercise bouts and at 70 W during the incremental exercise femoral venous potassium concentration ([K(+)](v)) was higher (P < 0.05) in CL than in TL, but identical at exhaustion (6.2 +/- 0.2 mmol l(-1)). Release of potassium to the blood was not different in the two legs. The present data demonstrated that intense intermittent training reduce accumulation of potassium in human skeletal muscle interstitium during exercise, probably through a larger re-uptake of potassium due to greater activity of the muscle Na(+),K(+)-ATPase pumps. The lower accumulation of potassium in muscle interstitium in the trained leg was associated with delayed fatigue during intense exercise, supporting the hypothesis that interstitial potassium accumulation is involved in the development of fatigue.

Formation of hydrogen peroxide and nitric oxide in rat skeletal muscle cells during contractions.

We examined intra- and extracellular H(2)O(2) and NO formation during contractions in primary rat skeletal muscle cell culture. The fluorescent probes DCFH-DA/DCFH (2,7-dichlorofluorescein-diacetate/2,7-dichlorofluorescein) and DAF-2-DA/DAF-2 (4,5-diaminofluorescein-diacetate/4,5-diaminofluorescein) were used to detect H(2)O(2) and NO, respectively. Intense electrical stimulation of muscle cells increased the intra- and extracellular DCF fluorescence by 171% and 105%, respectively, compared with control nonstimulated cells (p <.05). The addition of glutathione (GSH) or Tiron prior to electrical stimulation inhibited the intracellular DCFH oxidation (p <.05), whereas the addition of GSH-PX + GSH inhibited the extracellular DCFH oxidation (p <.05). Intense electrical stimulation also increased (p <.05) the intra- and extracellular DAF-2 fluorescence signal by 56% and 20%, respectively. The addition of N(G)-nitro-L-arginine (L-NA) completely removed the intra- and extracellular DAF-2 fluorescent signal. Our results show that H(2)O(2) and NO are formed in skeletal muscle cells during contractions and suggest that a rapid release of H(2)O(2) and NO may constitute an important defense mechanism against the formation of intracellular (*)OH and (*)ONOO. Furthermore, our data show that DCFH and DAF-2 are suitable probes for the detection of ROS and NO both intra- and extracellularly in skeletal muscle cell cultures.

Localization and function of ATP-sensitive potassium channels in human skeletal muscle.

The present study investigated the localization of ATP-sensitive K+ (KATP) channels in human skeletal muscle and the functional importance of these channels for human muscle K+ distribution at rest and during muscle activity. Membrane fractionation based on the giant vesicle technique or the sucrose-gradient technique in combination with Western blotting demonstrated that the KATP channels are mainly located in the sarcolemma. This localization was confirmed by immunohistochemical measurements. With the microdialysis technique, it was demonstrated that local application of the KATP channel inhibitor glibenclamide reduced (P < 0.05) interstitial K+ at rest from approximately 4.5 to 4.0 mM, whereas the concentration in the control leg remained constant. Glibenclamide had no effect on the interstitial K+ accumulation during knee-extensor exercise at a power output of 60 W. In contrast to in vitro conditions, the present study demonstrated that under in vivo conditions the KATP channels are active at rest and contribute to the accumulation of interstitial K+.