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+.     

Sarcolemmal ATP-sensitive potassium channels modulate skeletal muscle function under low-intensity workloads

ATP-sensitive potassium (K_ATP) channels have the unique ability to adjust membrane excitability and functions in accordance with the metabolic status of the cell. Skeletal muscles are primary sites of activity-related energy consumption and have K_ATP channels expressed in very high density. Previously, we demonstrated that transgenic mice with skeletal muscle–specific disruption of K_ATP channel function consume more energy than wild-type littermates. However, how K_ATP channel activation modulates skeletal muscle resting and action potentials under physiological conditions, particularly low-intensity workloads, and how this can be translated to muscle energy expenditure are yet to be determined. Here, we developed a technique that allows evaluation of skeletal muscle excitability in situ, with minimal disruption of the physiological environment. Isometric twitching of the tibialis anterior muscle at 1 Hz was used as a model of low-intensity physical activity in mice with normal and genetically disrupted K_ATP channel function. This workload was sufficient to induce K_ATP channel opening, resulting in membrane hyperpolarization as well as reduction in action potential overshoot and duration. Loss of K_ATP channel function resulted in increased calcium release and aggravated activity-induced heat production. Thus, this study identifies low-intensity workload as a trigger for opening skeletal muscle K_ATP channels and establishes that this coupling is important for regulation of myocyte function and thermogenesis. These mechanisms may provide a foundation for novel strategies to combat metabolic derangements when energy conservation or dissipation is required.     

Acetylcholine-induced ionic channels in rat skeletal muscle.

This paper briefly reviews the evidence for ionic channels mediating the conductance increase caused by acetylcholine application to the end-plate of skeletal muscle fibers. "Membrane noise" observed during application of constant low concentrations of acetylcholine to an end-plate is thought to arise from the random superposition of many elementary events corresponding to the opening and closing of discrete ion channels. Statistical analysis of acetylcholine-induced noise reveals an elementary conductance event of of 34 pS (1 S = 1 omega-1) amplitude and 1 msec duration at room temperature in rat muscle fibers. Both size and duration of the elementary event are temperature dependent. Analysis of currents induced by application of acetylcholine to the extrasynaptic membrane of chronically denervated fibers shows that the elementary conductance has a similar size but is of much longer duration. Direct recording of square pulse-like currents by a patch clamp method confirms some of the conclusions drawn from fluctuation analysis.     

N-bromoacetamide removes a calcium-dependent component of channel opening from calcium-activated potassium channels in rat skeletal muscle

Calcium-activated potassium channels from cultured rat skeletal muscle were treated with the protein-modifying reagent N-bromoacetamide (NBA) (0.3-1 mM) and studied in excised patches using patch-clamp techniques. After NBA treatment, channels opened only occasionally, and, in contrast to untreated channels, the open probability was no longer sensitive to intracellular surface calcium ions (1 nM to 100 microM). Channel activity did, however, exhibit a voltage dependence similar in direction and magnitude to that shown before NBA treatment (increasing e-fold with 19 mV depolarization). Distributions of open channel lifetimes revealed that NBA treatment virtually abolished openings of long duration, which suggests that this class of openings requires calcium sensitivity. These effects were not reversed by subsequent washing. Quantitatively similar open probability, voltage dependence, and open-interval distributions were observed in untreated channels in calcium-free medium. These results suggest that NBA removed a calcium-dependent component of channel opening, and that normal channels are able to open in the absence of significant intracellular calcium concentrations.     

Opening of mitochondrial ATP-sensitive potassium channels evokes oxygen radical generation in rabbit heart slices

The purpose of this study was to determine whether ATP-sensitive potassium channel (K(ATP) channel) activation generates oxygen free radicals in the rabbit heart. We assayed malondialdehyde (MDA) in rabbit heart slices in vitro as an indicator of oxygen free radical generation. The K(ATP) channel openers, pinacidil and cromakalim, significantly increased MDA production in a concentration-dependent manner. MDA formation also increased linearly with incubation time in the presence of K(ATP) channel openers. The K(ATP) channel blockers, glibenclamide and 5-hydroxydecanoate (5-HD), decreased K(ATP) channel opener-induced MDA formation in a concentration-dependent manner. When Fe(2+) was administered to heart slices that had been pretreated with K(ATP) channel openers, a marked elevation in MDA was observed, compared to heart slices that were treated with Fe(2+) alone. A positive linear correlation between Fe(2+) and MDA level was observed. The MDA levels of heart slices subjected to anoxia for 15 min remained unchanged until reperfusion. When the heart slices were reoxygenated for 30 min, a marked increase in MDA formation was observed. However, in the presence of glibenclamide and 5-HD, reperfusion following anoxia did not result in increased MDA. These results suggest that the opening of mitochondrial K(ATP) channels in rabbit heart slices evokes oxygen free radical generation via a Fenton-type reaction.     

Hypoxia affects mitochondrial protein expression in rat skeletal muscle

Hypoxia affects mammalian mitochondrial function, as well as mitochondria-based energy metabolism. The detail mechanism has not been fully understood. In this study, we detected protein expression levels in mitochondrial fractions of Wistar rats exposed to hypobaric hypoxia by use of proteomic methods. Adult male Wistar rats were randomized into an hypoxic (4,500?m, 30 days) group and a normoxic control group (sea level). Gastrocnemius muscles mitochondria were extracted and purified. Mitochondrial oxygen consumption was measured with a Clark oxygen electrode; mitochondrial transmembrane potential was detected with Rhodamine 123 as a fluoresce probe. Using 2-DE and MALDI-TOF MS analysis, we identified eight mitochondrial protein spots that were differentially expressed in the hypoxic group compared with the normoxic control. These proteins included Chain A of F1-ATPase, voltage dependent anion channel 1 (VDAC), hydroxyacyl Coenzyme A dehydrogenase α-subunit, mitochondrial F1 complex γ-subunit, androgen-regulated protein and tripartite motif protein 50. Two of the spots, VDAC and ATP synthase α-subunit, were confirmed by Western blotting analysis. Oxygen consumption during State 3 respiration, as well as the respiratory control ratio (RCR) was significantly higher in the control than that in the hypoxic group; mitochondrial transmembrane potential was significantly higher in hypoxic group than that in the control. With successful use of multiple proteomic analysis techniques, we demonstrates that 30 days hypoxia exposure has effects on the expression of mitochondrial proteins involved in ATP production and lipid metabolism, decrease the stability of mitochondrial membrane, and affect the mitochondrial electron transport chain.     

Slow components of potassium tail currents in rat skeletal muscle

The kinetics of potassium tail currents have been studied in the omohyoid muscle of the rat using the three-microelectrode voltage-clamp technique. The currents were elicited by a two-pulse protocol in which a conditioning pulse to open channels was followed by a test step to varying levels. The tail currents reversed at a single well-defined potential (VK). At hyperpolarized test potentials (-100 mV and below), tail currents were inward and exhibited two clearly distinguishable phases of decay, a fast tail with a time constant of 2-3 ms and a slow tail with a time constant of approximately 150 ms. At depolarized potentials (-60 mV and above), tail currents were outward and did not show two such easily separable phases of decay, although a slow kinetic component was present. The slow kinetic phase of outward tail currents appeared to be functionally distinct from the slow inward tail since the channels responsible for the latter did not allow significant outward current. Substitution of Rb for extracellular K abolished current through the anomalous (inward-going) rectifier and at the same time eliminated the slow inward tail, which suggests that the slow inward tail current flows through anomalous rectifier channels. The amplitude of the slow inward tail was increased and VK was shifted in the depolarizing direction by longer conditioning pulses. The shift in VK implies that during outward currents potassium accumulates in a restricted extracellular space, and it is suggested that this excess K causes the slow inward tail by increasing the inward current through the anomalous rectifier. By this hypothesis, the tail current slowly decays as K diffuses from the restricted space. Consistent with such a hypothesis, the decay of the slow inward tail was not strongly affected by changing temperature. It is concluded that a single delayed K channel is present in the omohyoid. Substitution of Rb for K has little effect on the magnitude or time course of outward current tails, but reduces the magnitude and slows the decay of the fast component of inward tails. Both effects are consistent with a mechanism proposed for squid giant axon (Swenson and Armstrong, 1981): that (a) the delayed potassium channel cannot close while Rb is inside it, and (b) that Rb remains in the channel longer than K.     

Role of mitochondrial ATP-sensitive potassium channels on fatigue in mouse muscle fibers

The role of mitochondrial K_ATP (mitoK_ATP) channels on muscle fatigue was assessed in adult mouse skeletal muscle bundles. Muscle fatigue was produced by eliciting short repetitive tetani. Isometric tension and the rate of production of reactive oxygen species (ROS) were measured at room temperature (20-22 °C) using a force transducer and the fluorescent indicator CM-H₂DCFDA. We found that opening mitoK_ATP channels with diazoxide (100 μM) significantly reduced muscle fatigue. Fatigue tension was 34% higher in diazoxide-treated fibers relative to controls. This effect was blocked by the mitoK_ATP channel blocker 5-hydroxydecanoate (5-HD), by the protein kinase C (PKC) inhibitor chelerythrine, and by the nitric oxide (NO) synthase inhibitor N^G-nitro-l-arginine methyl ester hydrochloride (l-NAME) but was not accompanied by a change in the rate of ROS production during fatigue. A physiological role of mitoK_ATP channels on muscle fatigue is proposed.     

Regular training modulates the accumulation of reactive carbonyl derivatives in mitochondrial and cytosolic fractions of rat skeletal muscle

The oxygen flux into the mitochondria of skeletal muscle increases with exercise. However, the extent of oxidative damage to mitochondrial proteins of skeletal muscle has only been estimated. We studied the alteration of reactive carbonyl derivatives (RCD) in mitochondrial and cytosolic fractions of skeletal muscle following 9 weeks of swimming training in rats. The RCD content of mitochondria was significantly elevated compared with the cytosolic fraction of both control and exercised animals. Accumulation of RCD in muscle mitochondria of the exercised group was also significantly elevated (P < 0.05). On the other hand, alteration of the accumulation of RCD was not apparent in the cytosolic fraction of skeletal muscle. The activity of proteasome complex, however, was increased in the cytosolic fraction of exercised muscle (P < 0.05). The data suggest that mitochondria of skeletal muscle accumulate significantly larger amounts of RCD than the cytosolic fraction and the tendency of the accumulation varies in cell fractions. Exercise training increases the accumulation of protein damage in mitochondria of skeletal muscle but cytosolic proteins are protected by increased activity of proteasome complex and possibly by other antioxidant enzymes.     

ATP-sensitive potassium channels participate in glucose uptake in skeletal muscle and adipose tissue

ATP-sensitive potassium (K(ATP)) channels are known to be critical in the control of both insulin and glucagon secretion, the major hormones in the maintenance of glucose homeostasis. The involvement of K(ATP) channels in glucose uptake in the target tissues of insulin, however, is not known. We show here that Kir6.2(-/-) mice lacking Kir6.2, the pore-forming subunit of these channels, have no K(ATP) channel activity in their skeletal muscles. A 2-deoxy-[(3)H]glucose uptake experiment in vivo showed that the basal and insulin-stimulated glucose uptake in skeletal muscles and adipose tissues of Kir6.2(-/-) mice is enhanced compared with that in wild-type (WT) mice. In addition, in vitro measurement of glucose uptake indicates that disruption of the channel increases the basal glucose uptake in Kir6.2(-/-) extensor digitorum longus and the insulin-stimulated glucose uptake in Kir6.2(-/-) soleus muscle. In contrast, glucose uptake in adipose tissue, measured in vitro, was similar in Kir6.2(-/-) and WT mice, suggesting that the increase in glucose uptake in Kir6.2(-/-) adipocytes is mediated by altered extracellular hormonal or neuronal signals altered by disruption of the K(ATP) channels.     

Exercise modulates the insulin-induced translocation of glucose transporters in rat skeletal muscle

Insulin and acute exercise (45 min of treadmill run) increased glucose uptake into perfused rat hindlimbs 5-fold and 3.2-fold, respectively. Following exercise, insulin treatment resulted in a further increase in glucose uptake. The subcellular distribution of the muscle glucose transporters GLUT-1 and GLUT-4 was determined in plasma membranes and intracellular membranes. Neither exercise nor exercise----insulin treatment altered the distribution of GLUT-1 transporters in these membrane fractions. In contrast, exercise, insulin and exercise----insulin treatment caused comparable increases in GLUT-4 transporters in the plasma membrane. The results suggest that exercise might limit insulin-induced GLUT-4 recruitment and that following exercise, insulin may alter the intrinsic activity of plasma membrane glucose transporters.     

IS3 peptide-formed ion channels in rat skeletal muscle cell membranes

A 22-mer peptide, identical to the primary sequence of domain I segment 3 (IS3) of rat brain sodium channel I, was synthesized. With the patch clamp cell-attached technique, single channel currents could be recorded from the patches of cultured rat myotube membranes when the patches were held at hyperpolarized potentials and the electrode solution contained NaCl and 1 microM IS3, indicating that IS3 incorporated into the membranes and formed ion channels. The single channel conductances of IS3 channels were distributed heterogeneously, but mainly in the range of 10-25 pS. There was a tendency that the mean open time and open probability of IS3 channels increased and the mean close time decreased with the increasing of hyperpolarized membrane potentials. IS3 channels are highly selective for Na+ and Li+ but not for Cl- and K+, similar to the authentic Na+ channels.     

ATP-sensitive potassium channels in adult mouse skeletal muscle: Characterization of the ATP-binding site

Summary Single K⁺-selective channels were studied in excised inside-out membrane patches from dissociated mouse toe muscle fibers. Channels of 74 pS conductance in symmetrical 160mm KCl solutions were blocked reversibly by 10 m internal ATP and thus identified as ATP-sensitive K⁺ channels. The channels were also blocked reversibly bymm concentrations of internal adenosine, adenine and thymine, but not by cytosine and uracil. The efficacy of the reversible channel blockers was higher when they were present in internal NaCl instead of KCl solutions. An irreversible inhibition of ATP-sensitive K⁺ channels was observed after application of several sulphydryl-modifying substances in the internal solution: 0.5mm chloramine-T, 50mm hydrogen peroxide or 2mm n-ethylmaleimide (NEM). Largeconductance Ca-activated K⁺ channels were not affected by these reagents. The presence of 1mm internal ATP prevents the irreversible inhibition of ATP-sensitive K⁺ channels by NEM. The results suggest that internal Na⁺ ions increase the affinity of the ATP-sensitive K⁺ channel to ATP and to other reversible channel blockers and that a functionally important SH-group is located at or near the ATP-binding site.     

Single channel recordings from calcium-activated potassium channels in cultured rat muscle

Single channel recordings from cultured rat skeletal muscle have revealed a large conductance (230 pS) channel with a high selectivity for K⁺ over Na⁺. In excised patches of membrane, the probability of channel opening is sensitive to micromolar concentrations of calcium ions at the intracellular surface of the patch. Channel openings appear grouped together into bursts whose duration increases with Ca²⁺ and membrane depolarization. Statistical analysis of the individual open times during each burst showed that there are two distinct open states of similar conductance but dissimilar average lifetimes. These channels might contribute to a macroscopic calcium-activated potassium conductance in rat skeletal muscle and other preparations.     

Rundown and reactivation of ATP-sensitive potassium channels (KATP) in mouse skeletal muscle

Dissociated single fibers from the mouse flexor digitorum brevis (FDB) muscle were used in patch clamp experiments to investigate the mechanisms of activation and inactivation of K_ATP in mammalian skeletal muscle. Spontaneous rundown of channel activity, in many excised patches, occurred gradually over a period of 10–20 min. Application of 1.0 mm free-Ca²⁺ to the cytoplasmic side of the patch caused irreversible inactivation of K_ATP within 15 sec. Ca²⁺-induced rundown was not prevented by the presence of 1.0 m okadaic acid or 2.0 mg ml^– of an inhibitor of calcium-activated neutral proteases, a result consistent with the conclusion that phosphatases or calcium-activated neutral proteases were not involved in the rundown process. Application of 1.0 mm Mg.ATP to Ca²⁺inactivated K_ATP caused inhibition of residual activity but little or no reactivation of the channels upon washout of ATP, even in the presence of the catalytic subunit of cyclic AMP-dependent protein kinase (10 U ml^–1). Mg.ATP also failed to reactivate K_ATP, even after only partial spontaneous rundown, despite the presence of channels that could be activated by the potassium channel opener BRL 38227. Nucleotide diphosphates (500 m; CDP, UDP, GDP and IDP) caused immediate and reversible opening of Ca²⁺-inactivated K_ATP. Reactivation of K_ATP by ADP (100 m) increased further upon removal of the nucleotide. In contrast to K_ATP from cardiac and pancreatic cells, there was no evidence for phosphorylation of K_ATP from the surface sarcolemma of dissociated single fibers from mouse skeletal muscle. The small degree of activation occasionally observed following application of 10 m or 1.0 mm Mg.ATP could have been due to the generation of ADP from ATP hydrolysis and not through phosphorylation. Data are consistent with the suggestion that Ca²⁺ inactivation of K_ATP involves a gating mechanism that can be reopened by nucleotide diphosphates.M.H. is supported by the Medical Research Council.     

Nitric oxide modulates oxygen consumption by arteriolar walls in rat skeletal muscle

To study the role of nitric oxide (NO) in regulating oxygen consumption by vessel walls, the oxygen consumption rate of arteriolar walls in rat cremaster muscle was measured in vivo during flow-induced vasodilation and after inhibiting NO synthesis. The oxygen consumption rate of arteriolar walls was calculated based on the intra- and perivascular PO2 values measured by phosphorescence quenching laser microscopy. The perivascular PO2 value of the arterioles during vasodilation was significantly higher than under control conditions, although the intravascular PO2 values under both conditions were approximately the same. Inhibition of NO synthesis, on the other hand, caused a significant increase in arterial blood pressure and a significant decrease in arteriolar diameter. Inhibition of NO synthesis also caused a significant decrease in both the intra- and perivascular PO2 values of the arterioles. Inhibition of NO synthesis increased the oxygen consumption rate of the vessel walls by 42%, whereas enhancement of flow-induced NO release decreased it by 34%. These results suggest that NO plays an important role not only as a regulator of peripheral vascular tone but also as a modulator of tissue oxygenation by reducing oxygen consumption by vessel walls. In addition, enhancement of NO release during exercise may facilitate efficient oxygen supply to the surrounding high metabolic tissue.     

Cryopreservation of mitochondria and mitochondrial function in cardiac and skeletal muscle fibers

Long-term preservation of muscle mitochondria for consequent functional analysis is an important and still unresolved challenge in the clinical study of metabolic diseases and in the basic research of mitochondrial physiology. We here present a method for cryopreservation of mitochondria in various muscle types including human biopsies. Mitochondrial function was analyzed after freeze-thawing permeabilized muscle fibers using glycerol and dimethyl sulfoxide as cryoprotectant. Using optimal freeze-thawing conditions, high rates of adenosine 5(')-diphosphate-stimulated respiration and high respiratory control were observed, showing intactness of mitochondrial respiratory function after cryopreservation. Measurement of adenosine 5(')-triphosphate (ATP) formation showed normal rates of ATP synthesis and ATP/O ratios. Intactness of the outer mitochondrial membrane and functional coupling between mitochondrial creatine kinase and oxidative phosphorylation were verified by respiratory cytochrome c and creatine tests. Simultaneous confocal imaging of mitochondrial flavoproteins and nicotinamide adenine dinucleotide revealed normal intracellular arrangement and metabolic responses of mitochondria after freeze-thawing. The method therefore permits, after freezing and long-term storage of muscle samples, mitochondrial function to be estimated and energy metabolism to be monitored in situ. This will significantly expand the scope for screening and exchange of human biopsy samples between research centers, thus providing a new basis for functional analysis of mitochondrial defects in various diseases.     

Relationship between insulin sensitivity and in vivo mitochondrial function in skeletal muscle

Recent data have shown that individuals with low insulin sensitivity (S(I)) also have reduced whole body maximal oxygen uptake. The objectives of this study were to determine 1) whether muscle mitochondrial function was independently related to S(I) after being adjusted for known determinants of S(I) and 2) whether lower S(I) among African-American (AA) vs. Caucasian-American (CA) women was due to lower muscle mitochondrial function among AA women. Subjects were 37 CA and 22 AA premenopausal women (age: 33.6 +/- 6.3 yr). Mitochondrial function [time constant of ADP (ADP(tc))] was assessed during a 90-s unilateral isometric contraction using (31)P magnetic resonance spectroscopy, S(I) with an intravenous glucose tolerance test, body composition by dual-energy X-ray absorptiometry, and visceral adipose tissue (VAT) with computed tomography. ANOVA was used to compare AA and CA groups, and multiple linear regression modeling was used to identify independent predictors of S(I). Between-race comparisons indicated that muscle oxidative capacity was lower among AAs vs. CAs (ADP(tc): 25.6 +/- 9.8 vs. 21.4 +/- 9.9 s). Multiple linear regression models for the dependent variable S(I) contained 1) VAT and race and 2) VAT, race, and ADP(tc). Significant independent effects for all predictor variables were observed in both the first (r(2) = 0.345) and second (r(2) = 0.410) models. The partial correlation for race was lower in the second model (-0.404 vs. -0.300), suggesting that muscle mitochondrial function contributed to the racial difference in S(I). Lower muscle mitochondrial function among AAs may in part explain lower S(I) among them.