Effects of lactic acid and catecholamines on contractility in fast-twitch muscles exposed to hyperkalemia

Anders Krogh Hansen, Torben Clausen, and Ole Bækgaard Nielsen

Department of Physiology, University of Aarhus, Århus, Denmark

Submitted 7 December 2004 ; accepted in final form 25 February 2005


    ABSTRACT
 TOP
 ABSTRACT
 METHODS
 RESULTS
 DISCUSSION
 GRANTS
 REFERENCES
 
Intensive exercise is associated with a pronounced increase in extracellular K+ ([K+]o). Because of the ensuing depolarization and loss of excitability, this contributes to muscle fatigue. Intensive exercise also increases the level of circulating catecholamines and lactic acid, which both have been shown to alleviate the depressing effect of hyperkalemia in slow-twitch muscles. Because of their larger exercise-induced loss of K+, fast-twitch muscles are more prone to fatigue caused by increased [K+]o than slow-twitch muscles. Fast-twitch muscles also produce more lactic acid. We therefore compared the effects of catecholamines and lactic acid on the maintenance of contractility in rat fast-twitch [extensor digitorum longus (EDL)] and slow-twitch (soleus) muscles. Intact muscles were mounted on force transducers and stimulated electrically to evoke short isometric tetani. Elevated [K+]o (11 and 13 mM) was used to reduce force to ~20% of control force at 4 mM K+. In EDL, the {beta}2-agonist salbutamol (10–5 M) restored tetanic force to 83 ± 2% of control force, whereas in soleus salbutamol restored tetanic force to 93 ± 1%. In both muscles, salbutamol induced hyperpolarization (5–8 mV), reduced intracellular Na+ content and increased Na+-K+ pump activity, leading to an increased K+ tolerance. Lactic acid (24 mM) restored force from 22 ± 4% to 58 ± 2% of control force in EDL, an effect that was significantly lower than in soleus muscle. These results amplify and generalize the concept that the exercise-induced acidification and increase in plasma catecholamines counterbalance fatigue arising from rundown of Na+ and K+ gradients.

muscle fatigue; Na+-K+ pump; membrane potential


DURING EXERCISE, contracting muscles lose K+, leading to increased extracellular K+ ([K+]o) (19, 25). In humans, a plasma concentration of 8–9 mM K+ has been reported (32) and in the interstitium of active muscles, [K+]o might reach values of 10–12 mM (23, 29, 33). Elevated [K+]o leads to depolarization, which has been shown to cause slow inactivation of voltage-dependent Na+ channels (42) and to some degree, inactivation of the dihydropyridine receptors (8). Hence, increased [K+]o induces a loss of excitability and contractility and thereby potentially contributes to muscle fatigue (2, 9, 28, 41, 43). Recent in vitro studies show that the loss of K+ during stimulation is considerably larger in fast-twitch muscles than in slow-twitch muscles (14), indicating that elevated [K+]o may contribute more to fatigue in fast-twitch muscles than in slow-twitch muscles.

Intensive exercise also causes an increase in the level of circulating catecholamines (22). Studies (10) on isolated slow-twitch muscles have shown that the depressing effects of high [K+]o on muscle contractility can be counteracted by the action of these compounds on muscular {beta}2-adrenoceptors. {beta}2-Agonists such as salbutamol stimulate the Na+-K+ pumps (13, 40), which has two implications. First, it improves and accelerates the restoration of the transmembrane chemical gradients for Na+ and K+ (35). Second, it increases the electrogenic contribution of the Na+-K+ pumps to the membrane potential (Vm) and thereby further protects the excitability of the muscle fibers (24). Early studies (18, 40) indicate that the stimulating effect of {beta}2-agonists on the activity of the Na+-K+ pumps is smaller in fast-twitch muscles than in slow-twitch muscles. On the basis of this, we hypothesize that at high [K+]o the protective effect of {beta}2-agonists on excitability is less in fast-twitch muscles than in slow-twitch muscles. We therefore examined the effects of {beta}2-agonists on contractility in extensor digitorum longus (EDL) muscles at high [K+]o and compared this with their effects in soleus muscles.

Concomitant with the increases in [K+]o and the level of circulating catecholamines, intensive exercise also causes an increase in the level of lactic acid (20, 21, 45). Recent in vitro studies (30, 31, 36) on slow-twitch muscles have shown that in these muscles, the depressing effect of high [K+]o on excitability and contractility can also be counteracted by lactic acid. The effect on excitability is secondary to the ensuing reduction in muscle pH and might be related to an inhibitory effect of acidosis on the chloride conductance (38, 39). It is well established that fast-twitch muscles have a higher rate of lactic acid production than slow-twitch muscles. During intermittent electrical stimulation at 100 Hz (200 ms/s for 5 min), the in vivo lactic acid production was 22.4 µmol/g wet wt in the rat EDL and 1.3 µmol/g wet wt in soleus muscle (3). Moreover, it has been proposed that there is a "lactate shuttle," where especially fast-twitch muscles produce lactic acid, which is then transported to other areas of the body (e.g., slow-twitch muscles), where it is used as an energy source (4, 5). Measurements of biopsies showed that in human fast-twitch muscles, the content of lactic acid reached 17–29 mmol/kg wet wt during intensive work, whereas in slow-twitch muscles, values of 13–19 mmol/kg wet wt were reached (16). On the basis of this, we hypothesize that fast-twitch muscles are better protected by lactic acid, than slow-twitch muscles, against loss of force induced by high [K+]o. Moreover, we selected the concentration range 20–30 mmol/l buffer (20–30 mM) of lactic acid as appropriate for in vitro experiments with EDL and soleus muscles.

The overall aim of this study was to identify and quantify the protective effects of catecholamines and lactic acidosis on the maintenance of contractility in EDL muscles exposed to physiological elevations in [K+]o and to compare this with soleus muscles. The importance of catecholamines and lactic acid is of particular interest in fast-twitch muscle fibers because they are known to be recruited during intense exercise, a situation where the plasma [K+], lactic acidosis, and catecholamines are known to reach their maximum.


    METHODS
 TOP
 ABSTRACT
 METHODS
 RESULTS
 DISCUSSION
 GRANTS
 REFERENCES
 
Animal handling and muscle preparation. All experiments were carried out using 4-wk-old male or female Wistar rats of own breed and weighing 60–70 g. Animals were fed ad libitum and maintained under 12:12-h light-dark conditions at a thermostatically controlled temperature of 21°C. The rats were euthanized by cervical dislocation, followed by decapitation, and intact soleus or EDL muscles (17–26 mg) were dissected out. The animals were handled and maintained in accordance with the European Convention for the Protection of Vertebrate Animals Used for Experimental and other Scientific Purposes. The animal facilities were checked by the Danish Inspectorate for Experimental Animals and the Animal Welfare Officer of the Medical Faculty of the University of Aarhus.

Muscles were incubated in standard Krebs-Ringer bicarbonate buffer (pH 7.4 at 30°C) containing (in mM) 122 NaCl, 25 NaHCO3, 2.8 KCl, 1.2 KH2PO4, 1.2 MgSO4, 1.3 CaCl2, and 5.0 D-glucose. All buffers were equilibrated with a 95% O2-5% CO2 mixture. In buffers with high [K+], an equivalent amount of Na+ was omitted to maintain isosmolarity. To avoid exposing muscles to damaging fluctuations in pH, the buffer to which L-lactic acid had been added was equilibrated for at least 20 min with a 95% O2-5% CO2 mixture before use. The pH of standard buffer and buffers containing lactic acid or elevated CO2 were, in all experiments, determined with the use of a pH meter (model PHM 92 Lab, Radiometer, Copenhagen, Denmark).

Isometric force. Muscles were mounted on isometric force transducers at optimal length and exposed to field stimulation across the central part of the muscle through platinum electrodes. The stimulation paradigms were 2-s 60-Hz trains of 0.2-ms pulses of 10 V, given every 10 min for soleus muscle and 0.5-s 90-Hz trains of 0.2-ms pulses of 10 V given every 20 min for EDL. The choice of stimulation frequency (60 or 90 Hz) was based on a force-frequency analysis to ensure that full tetanic force was obtained. Force was recorded on a chart recorder and/or digitally on a computer.

Na+-K+ pump activity and muscle Na+ content. The activity of the Na+-K+ pumps was determined from the ouabain-suppressible 86Rb+ uptake in resting muscles as previously described (6). Briefly, the muscles were mounted at resting length. After equilibration for 30 min in standard Krebs-Ringer bicarbonate buffer containing 11 mM K+ (soleus) or 13 mM K+ (EDL), the muscles were preincubated for 15 min in the absence or presence of ouabain (10–3 M). This was followed by incubation for 10 min in buffer containing 86Rb+ (0.1 µCi ml–1) without or with salbutamol (10–5 M). Finally, the muscles were washed for 4 x 15 min at 0°C in Na+-free Tris-sucrose buffer containing (in mM) 263 sucrose, 10 Tris·HCl, 4.7 KCl, 1.3 CaCl2, 1.2 MgSO4, and 1.2 KH2PO4 (pH 7.4) to remove extracellular 86Rb+ and Na+. After washout, the muscles were blotted, weighed for determination of wet weight, soaked in 0.3 M trichloroacetic acid, and taken for counting of 86Rb+ activity by Cerenkov radiation in a beta counter (Packard). The amount of 86Rb+ activity retained after the cold wash and the uptake of K+ was then calculated by converting the relative uptake of 86Rb+ to K+ using the concentration of K+ in the incubation medium. The uptake of K+ could thus be expressed as nanomoles per gram wet weight per minute. Earlier studies (12) with isolated resting muscles showed that the use of 86Rb+ and 42K+ gave closely similar results for the Na+-K+ pump-mediated K+ uptake. Thus 86Rb+ is a suitable and comparable tracer for the transport of K+ via that system. Ouabain was used to block the activity of the Na+-K+ pumps, with subtraction of the ouabain-insensitive 86Rb+ uptake from the total 86Rb+ uptake, giving the ouabain-sensitive 86Rb+ uptake. The concentration of Na+ in the tricholoroacetic acid extract was determined by flame photometry (model FLM3, Radiometer). Part of the intracellular Na+ was, however, lost during the washout in the Na+-free Tris-sucrose buffer. As shown in an earlier study (17), this could be corrected for by using semilogarithmic plots of the time course of Na+. After the early rapid loss of Na+ representing washout of Na+ from the extracellular phase there was a rectilinear reduction in Na+ content, decreasing by a factor of 1.46 per hour. Because four 15-min washouts in the Na+-free buffer removed extracellular Na+, the concomitant loss of intracellular Na+ was corrected for by multiplying the Na+ content of the muscles at the end of washout by a factor of 1.46.

Membrane potential. In experiments where resting Vm was measured, the muscles were placed in an experimental setup as previously described in detail (13). Shortly thereafter, the Vm was recorded in surface fibers using standard techniques with glass microelectrodes filled with 3 M KCl and tip resistances of 10–30 M{Omega}. The potential was recorded via an Axoclamp-2 amplifier and displayed simultaneously on an oscilloscope and a chart recorder.

Chemicals and isotope. All chemicals were of analytical grade. Salbutamol, L-lactic acid, and ouabain were from Sigma-Aldrich and 86RbCl (0.4 Ci/mmol) was from Amersham International (Aylesbury, Buckinghamshire, UK). Rat calcitonin gene-related peptide (rCGRP) was from Bachem (Bubendorf, Switzerland).

Statistics. All data were expressed as means ± SE. The statistical significance of any difference between groups was ascertained with the use of Student’s two-tailed t-test for nonpaired observations.


    RESULTS
 TOP
 ABSTRACT
 METHODS
 RESULTS
 DISCUSSION
 GRANTS
 REFERENCES
 
Effect of salbutamol on Na+-K+ pump activity in EDL and soleus muscles incubated at high [K+]o. Everts et al. (18) showed that when muscles are incubated at normal [K+]o, the stimulating effect of {beta}2-agonists on the Na+-K+ pumps is larger in soleus than in EDL muscle. To examine whether a similar difference occurs in muscles incubated at high [K+]o, the effect of the {beta}2-agonist salbutamol on the ouabain-suppressible 86Rb+ uptake was determined in EDL and soleus muscles incubated at a [K+]o of 13 and 11 mM, respectively. These levels of [K+]o corresponded to the [K+]o needed to depress tetanic force of the respective muscles to 20% of control force. In these experiments, as well as in those with other agents used to stimulate the Na+-K+ pumps, we used supramaximal concentrations. Table 1 shows that the basal activity of the Na+-K+ pumps in EDL was similar to that of soleus, but the increase in the activity of the Na+-K+ pumps on addition of salbutamol was almost 50% less. Thus salbutamol augmented the ouabain-suppressible 86Rb+ uptake by 88% in soleus and by 47% in EDL. The control level of intracellular Na+ was almost 50% lower in EDL compared with soleus, and the increase in Na+-K+ pump activity after the addition of salbutamol led to a decrease in intracellular Na+ content by 37% and 53% in the EDL and soleus, respectively. In the presence of ouabain, salbutamol caused no change in 86Rb+ uptake (Table 1) and intracellular Na+ content (data not shown).


View this table:
[in this window]
[in a new window]
 
Table 1. Effect of salbutamol on 86Rb+ uptake and intracellular Na+ in resting rat soleus muscles and resting rat EDL muscles

 
Effects of salbutamol, catecholamines, and rCGRP on tetanic force in EDL and soleus muscles incubated at high [K+]o. The smaller effect of salbutamol on the Na+-K+ pump activity in EDL (Table 1) would suggest that the protecting effect of salbutamol against the inhibitory effect of high [K+]o on contractility was less in EDL than in soleus. To examine this, the effect of salbutamol on tetanic force in EDL and soleus muscles incubated at high [K+]o was measured. Figure 1 shows that when [K+]o was increased to 13 mM in tetanic EDL force was reduced to 23 ± 3% of the control force obtained at 4 mM K+. Subsequent addition of 10–5 M salbutamol resulted in recovery of tetanic force to 83 ± 2% of the force obtained at 4 mM K+.



View larger version (18K):
[in this window]
[in a new window]
 
Fig. 1. Effect of 10–5 M salbutamol on tetanic force in extensor digitorum longus (EDL) muscles incubated at 13 mM K+. EDL muscles were mounted for isometric contractions in Krebs-Ringer bicarbonate buffer containing 4 mM K+. The muscles were stimulated tetanically every 20 min with the use of 0.2-ms pulses of 10 V at 90 Hz for 0.5 s. After measurements of control force at 4 mM K+, extracellular [K+] ([K+]o) was changed to 13 mM (control). When the force was depressed to ~20% of control force, 10–5 M salbutamol was added. Values are presented as a percentage of control force at 4 mM K+. Each point indicates the mean ± SE of observations on 4 muscles.

 
Figure 2 shows that by increasing [K+]o to 11 mM, where tetanic force in soleus muscles was reduced to 25 ± 3% of the control force obtained at 4 mM K+, addition of 10–5 M salbutamol recovered force to 93 ± 1% of the force obtained at 4 mM K+. This indicates that despite the smaller stimulation of the Na+-K+ pump activity in EDL than in soleus muscle, salbutamol induced almost the same force recovery in EDL as in soleus, when exposed to 13 or 11 mM [K+]o, respectively.



View larger version (19K):
[in this window]
[in a new window]
 
Fig. 2. Effect of 10–5 M salbutamol on tetanic force in soleus muscles incubated at 11 mM K+. Soleus muscles were mounted for isometric contractions in Krebs-Ringer bicarbonate buffer containing 4 mM K+. The muscles were stimulated tetanically every 10 min using 0.2-ms pulses of 10 V at 60 Hz for 2 s. After measurements of control force at 4 mM K+, [K+]o was changed to 11 mM. When the force was depressed to ~20% of control force, 10–5 M salbutamol was added. Values are the percentage of control force at 4 mM K+. Each point indicates the mean ± SE of observations on 4 muscles.

 
To further quantify the salbutamol-induced force recovery in EDL muscle, the experiment shown in Fig. 1 was repeated using a range of [K+] (11–16 mM), with the data shown in Fig. 3. The data were fitted to a Bolzmann sigmoid equation.



View larger version (14K):
[in this window]
[in a new window]
 
Fig. 3. Effects of 10–5 M salbutamol on tetanic force in EDL muscles exposed to increasing [K+]o. Experimental conditions are the same as in Fig. 1, except that the muscles were incubated at varying [K+]o. The figure shows force before the addition of salbutamol and the maximum force after addition of salbutamol, both presented as percentage of control force at 4 mM K+. Each point indicates the mean ± SE of observations on 4 muscles. Data showed an accurate fit to a Bolzmann sigmoid equation (r2 = 0.98–0.99).

 
In control muscles, elevation of [K+]o caused a graded depression of tetanic force. It appears that over the range of concentrations from 11 to 15 mM K+, salbutamol induced a marked and highly significant increase of tetanic force. The [K+]o required to reduce tetanic force to 50% of the force measured at 4 mM K+ (IC50) increased from 12.2 mM in control muscles to 14.2 mM with salbutamol. Taken together, the data in Figs. 1 and 3 show that salbutamol induces considerable force recovery in EDL muscles exposed to high [K+]o, despite a relatively small stimulation of Na+-K+ pump activity (Table 1).

In soleus muscles, the Na+-K+ pumps can also be stimulated by rCGRP, epinephrine, and norepinephrine (9). We therefore examined the effect of these compounds on force development in EDL muscles that had been exposed to 13 mM K+. Table 2 shows that in muscles where tetanic force had been reduced to 25–35% of control force by increasing [K+]o to 13 mM, all three compounds induced a significant two- to threefold increase of tetanic force.


View this table:
[in this window]
[in a new window]
 
Table 2. Effect of rCGRP, epinephrine, and norepinephrine on tetanic force in rat EDL muscles at 13 mM K+

 
Effect of lactic acid and salbutamol on tetanic force in EDL muscles at high [K+]o. Recent studies (36) showed that in rat soleus, where force had been reduced to 25% of the control level by exposure to 11 mM K+, 20 mM lactic acid could almost fully restore tetanic force. The following experiments were undertaken to evaluate the effect of lactic acid on force in EDL muscles exposed to high [K+]o. Figure 4 shows that when [K+]o was increased to 13 mM, tetanic force was reduced to 22 ± 4% of that obtained at 4 mM K+. The addition of 24 mM lactic acid recovered force to 57 ± 2% of that obtained at 4 mM K+, and the subsequent addition of 10–5 M salbutamol rapidly restored force to 88 ± 2%.



View larger version (16K):
[in this window]
[in a new window]
 
Fig. 4. Effects of 24 mM lactic acid and 10–5 M salbutamol on tetanic force in EDL muscles incubated at 13 mM K+. EDL muscles were mounted for isometric contractions in Krebs-Ringer bicarbonate buffer containing 4 mM K+. Experimental conditions are as described in Fig. 1. When the force was depressed to ~20% of control force, 24 mM lactic acid was added, followed by 10–5 M salbutamol as indicated. Values are the percentage of control force at 4 mM K+. Each point indicates the mean ± SE of observations on 4 muscles.

 
To further clarify the extent to which lactic acid increases the tolerance of EDL muscles to elevated [K+]o, the experiment shown in Fig. 4 was repeated with varying [K+]o (11–18 mM). Figure 5 shows the relationship between the tetanic force and [K+]o in EDL before (control) and after exposure to 24 mM lactic acid, 10–5 M salbutamol, alone or combined. The data were fitted to a Bolzmann sigmoid equation. The addition of 24 mM lactic acid increased the [K+]o required to reduce the force to 50% of the control force at 4 mM K+ (IC50) from 12.2 mM in control muscles to 12.8 mM. Thus, whereas salbutamol increased IC50 by 2.0 mM (Fig. 3), lactic acid alone increased IC50 by 0.6 mM, and in combination lactic acid and salbutamol increased IC50 by 2.3 mM K+. Figure 5 also shows that the effect of salbutamol on the tolerance to increased [K+]o was almost fully maintained in acidified muscles, producing a 1.7 mM increase in IC50.



View larger version (20K):
[in this window]
[in a new window]
 
Fig. 5. Effects of 24 mM lactic acid and 10–5 M salbutamol on tetanic force in EDL muscles exposed to increasing [K+]o. Experimental conditions are the same as described in Fig. 4, except that the muscles were incubated at varying [K+]o. The figure shows tetanic force at elevated [K+]o in control muscles, in muscles treated with lactic acid, salbutamol, or both salbutamol and lactic acid. For muscles treated with lactic acid or salbutamol, the force shown is the maximal force obtained after addition of the compound. Values are the percentage of control force at 4 mM K+. Each point indicates the mean ± SE of observations on 4 muscles. Data showed an accurate fit to a Bolzmann sigmoid equation (r2 = 0.98–0.99).

 
Effect of salbutamol and lactic acid on Vm in soleus and EDL muscles at high [K+]o. The recovery of force induced by Na+-K+ pump stimulation in muscles at elevated [K+]o has been associated with a partial repolarization of the muscles (13, 24). To evaluate the possible role of a hyperpolarization in the force recovery induced by salbutamol in the present study, muscle Vm was measured during experiments similar to that shown in Fig. 1. Table 3 shows recordings of Vm for both soleus and EDL and illustrates that at 4 mM K+, EDL had a significantly lower resting Vm than soleus (P < 0.001). After exposure to 11 mM K+ (soleus) or 13 mM K+ (EDL), the membrane was depolarized to the same level (no significant difference). The subsequent addition of salbutamol repolarized the Vm by 5–8 mV (P < 0.001) in both EDL and soleus muscle.


View this table:
[in this window]
[in a new window]
 
Table 3. Effect of lactic acid and salbutamol on Vm in rat soleus muscles at 11 mM K+ and rat EDL muscles at 13 mM K+

 
Series B in Table 3 shows the effect of lactic acid on the Vm in EDL and soleus. Lactic acid alone caused no change in the Vm in either EDL or soleus muscle depressed with 13 and 11 mM K+, respectively. The addition of salbutamol after lactic acid repolarized the membrane potential by 5 mV (P < 0.001), and again there was no statistically significant difference between the EDL and soleus.

Effect of pH on EDL. The increase in [K+]o tolerance induced by 24 mM lactic acid in EDL muscles, as illustrated in Fig. 5, was modest compared with that seen in soleus muscles (15). We therefore tested whether the protective effect of lactic acid in EDL at 13 mM K+ could be augmented by increasing the lactic acid concentration, using an experimental procedure as depicted in Fig. 4.

Figure 6 shows that when the lactic acid concentration was increased >20 mM, recovery of force increased with the concentration of the acid, starting with 50 ± 7% at 20 mM, and increasing to 71 ± 4% at 28 mM. At values higher than 28 mM, the force recovery effect eased off. At lactic acid concentrations >24 mM, the recovery of force was in several instances transient, with a tendency for this phenomenon to become more pronounced at the highest concentrations of lactic acid (data not shown).



View larger version (18K):
[in this window]
[in a new window]
 
Fig. 6. Effects of increasing lactic acid concentration on tetanic force in EDL muscles incubated at 13 mM K+. Experimental conditions are the same as in Fig. 4, but without the addition of salbutamol and with increasing lactic acid concentrations. Each muscle was tested at only 1 concentration of lactic acid. Values are the percentage of control values at 4 mM K+. Each bar indicates the mean of observations on 4–5 muscles with bars showing means and SE. pH values are means of 2–3 measurements.

 
In another study (36) it has been shown that in soleus the effect of lactic acid on force recovery is caused by the ensuing reduction in muscle pH. To test whether acidification plays a similar role for the recovery of force in EDL, where force had been depressed by high [K+]o, we reduced pH by increasing the fraction of CO2 in the gas mixture used for equilibration of the Krebs-Ringer buffer.

Figure 7 shows the effect of increasing CO2 fraction on force recovery in K+-depressed EDL muscles. These data are generally in keeping with previous observations on soleus muscle, showing that also in EDL, the force recovery by lactic acid can be mimicked by CO2 acidification (36). The effect of CO2 was highest at 20% CO2 where force was recovered from 16 ± 5% to 51 ± 5% of the force obtained at 4 mM K+. At values higher than 20% CO2, the force recovery effect eased off, indicating that the maximum value had already been reached. It should be noted that 20% CO2, which reduced pH to 6.75, gave approximately the same force recovery as the addition of 24 mM lactic acid, which also reduced pH to 6.75 (Figs. 6 and 7). At higher levels of acidification, the recovery of force was less when pH was lowered by increased CO2 than by the addition of lactic acid.



View larger version (15K):
[in this window]
[in a new window]
 
Fig. 7. Effects of increasing the CO2 fraction on tetanic force in EDL muscles incubated at 13 mM K+. Experimental conditions are the same as in Fig. 6, but with pH being modulated by increasing the CO2 fraction. Values are the percentage of control values at 4 mM K+. Each bar indicates the mean of observations on 3–4 muscles with bars showing means and SE. pH values are means of 2–3 measurements.

 

    DISCUSSION
 TOP
 ABSTRACT
 METHODS
 RESULTS
 DISCUSSION
 GRANTS
 REFERENCES
 
Previous studies (10, 15, 31, 36, 38) on K+-induced inhibition of contractile force and the protective effects of Na+-K+ pump stimulation and acidosis, have focused on slow-twitch muscles. Because a large fraction of skeletal muscles are composed of fast-twitch fibers, it was of interest to characterize the response of these fibers to high [K+]o, Na+-K+ pump stimulation, and acidosis, in particular because in these fibers, excitation induces a much more pronounced loss of K+ than in slow-twitch fibers (14).

The major new information gained from the present study is that when exposed to the inhibitory effect of high [K+]o, the fast-twitch EDL muscles responds to stimulation of the Na+-K+ pumps with a marked force recovery. This indicates that the protective effect of Na+-K+ pump stimulation against hyperkalemia is as important as previously shown for slow-twitch muscles. The data also show that acidosis induced by lactic acid or elevation of CO2 induces a significant force recovery, although somewhat lower than that found in soleus muscles (36). Taken together, these observations indicate that Na+-K+ pump stimulation and acidosis both contribute to the maintenance of force in skeletal muscles exposed to elevated [K+]o, but that the combined effect of these two factors is larger in soleus than in EDL.

Compared with the time it takes for humans to reach exhaustion during intensive exercise, the time course for the effects of increased buffer K+ and the addition of salbutamol and lactic acid on force in the present study was very slow. The reason for the slow time course is likely to be related to slow diffusion of the added substances into the core of the muscles rather than to a slow development of the biological effect within the muscle fibers. In the case of increased buffer K+, the time until full effect may be further delayed by uptake of K+ into more superficial fibers via the Na+-K+ pumps (11) and by limitation to diffusion of K+ into the elaborate t-tubular system of the muscle fibers. Because the t-tubular network is larger in fast-twitch muscles than in slow-twitch muscles, such limitation to diffusion may also explain that the rate of force decline when exposed to elevated [K+]o is slower in EDL than in soleus muscle (Figs. 1 and 2). This explanation for the slow response of the muscles to manipulations of the buffers is supported by the observation that when the chemical gradient for K+ across the t-tubular system is manipulated in experiments with mechanically skinned single fibers, the effect of changes in the K+ gradient is observed within seconds (37). Likewise the use of the same preparation has demonstrated that the recovery of force and excitability induced by stimulation of the Na+-K+ pumps or acidification of the muscle develops within seconds (37, 39). In the present study, the increase in [K+]o and the addition of salbutamol or lactic acid were separated in time to allow for a quantification of their separate effects on muscle function. This method represents another difference to the case of intensive exercise, when the increase in [K+]o may be closely followed by increased blood levels of catecholamines and muscle acidification. In earlier studies on isolated muscle (10, 36), however, it was shown that if catecholamines or lactic acid were added before or together with the increase in [K+]o, their presence could completely prevent the loss of force otherwise induced by elevated [K+]o. Together these findings indicate that changes in Na+-K+ pump activity or muscle pH are important for the regulation of muscle excitability, even during short bouts of intensive exercise.

Effect of salbutamol on Na+-K+ pump activity and tetanic force. The salbutamol-induced increase in the Na+-K+ pump mediated 86Rb+ uptake at high [K+]o was 50% less in EDL than in soleus muscles. This would indicate that the protective effect of {beta}-adrenergic agonists against the force-depressing effect of high [K+]o is smaller in EDL than in soleus muscle. However, Figs. 1 and 2 show that salbutamol (10–5 M) produced almost as much force recovery in EDL as in soleus muscles, where force was depressed to ~20%. Considering the increase in IC50 from 12.2 to 14.2 mM K+ (Fig. 5), salbutamol increases the tolerance of EDL to elevated [K+]o by 2 mM. Figure 5 further shows that the effect of salbutamol on the K+ tolerance of EDL was almost completely preserved in muscles acidified by addition of lactic acid. In similar experiments on rat soleus excited with 1-ms pulses, stimulation of the Na+-K+ pumps by the addition of 10–5 M epinephrine, increased IC50 of the muscles from 11.5 to 14.4 mM K+, indicating an increase in the tolerance to increased [K+]o by 2.9 mM (F. de Paoli and O. B. Nielsen, unpublished observations). Previous studies (10) have shown that, like the effect of salbutamol, the effect of epinephrine on force in muscles at elevated [K+]o is caused by stimulation of the Na+-K+ pumps via {beta}-adrenergic receptors. As in EDL, the effect of Na+-K+-pump stimulation is well maintained in soleus when acidified by addition of lactic acid, the increase in the tolerance to [K+]o being 2.2 mM (15). Together, these results demonstrate that {beta}2-agonists induce almost the same protection of force in EDL and soleus muscles exposed to hyperkalemia, although salbutamol induced a relatively lower increase in the Na+-K+ pump activity of the former. This difference may, in part, be related to the lower intracellular Na+ in EDL (Table 1), limiting the activity of the Na+-K+ pumps. Thus, given the size of the salbutamol-induced decrease in Na+ content of soleus, there is no way the EDL could possibly have matched that decrease without the cells becoming devoid of Na+. Despite this, the more modest salbutamol-induced increase of the 86Rb+ uptake in EDL appeared sufficient to cause force recovery similar to that seen in soleus. It is interesting that for more modest numbers of Na+ and K+ ions pumped, EDL reaches the same force recovery as soleus.

Mechanisms of salbutamol action. In EDL exposed to 13 mM K+, the improvement of contractility by salbutamol was associated with membrane hyperpolarization and a reduction in intracellular Na+ content (Tables 1 and 3). Salbutamol reduced intracellular Na+ content by 2.4 ± 0.5 µmol/g wet wt, which augments the equilibrium potential for Na+ (ENa+) (assuming constant [Na+]o). Together with the concomitant 5-mV hyperpolarization, this increases the driving force for the electrodiffusion of Na+ (Vm – ENa+). Hyperpolarization has also been shown to reduce the level of slow inactivation of the Na+ channels (42), which increases the conductance for Na+. Because enhanced driving force and increased conductance for Na+ improves excitability (26), these changes are likely to contribute to the improved contractility. Because the activity of the Na+-K+ pumps is electrogenic, and because intracellular [Na+] ([Na+]i) depends on the active rate of extrusion, the salbutamol-induced hyperpolarization and reduction in [Na+]i could both be explained by an increase in the Na+-K+ pump activity. This is in accordance with the salbutamol-induced increase in the ouabain-suppressible 86Rb+ uptake in both EDL and soleus muscles (Table 1). Another potential mechanism for the salbutamol-induced hyperpolarization is an increase in the K+ permeability of the muscle fibers, bringing the Vm closer to the Nernst equilibrium potential for K+, supposing that the membrane potential and the equilibrium potential for K+ are substantially different. This would, however, cause an increase in the ouabain-nonsuppressible 86Rb+ uptake, which we do not find (Table 1).

The depression of force induced by high [K+]o occurred in a narrow range of [K+] (Figs. 3 and 5), which indicates a high K+ sensitivity, and this is in accordance with an earlier study (7). Our data show that in the EDL muscles there is a large force depression between 11 and 13 mM K+. This implies that when force is depressed to 20% by exposure to 13 mM [K+]o, a reduction of [K+]o of 2 mM would be expected to induce a force recovery to ~80% of the force at 4 mM K+ (see Figs. 3 and 5). According to the Nernst equilibrium potential for K+, changing the [K+]o from 13 to 11 mM, should theoretically cause a 4.3-mV repolarization (assuming [K+]i = 140 mM). We can therefore conclude that the stimulating effect of salbutamol on the Na+-K+ pumps, causing a hyperpolarization of 5 mV (Table 3), should be sufficient to explain the salbutamol- induced restoration of force.

Effects of catecholamines and rCGRP on tetanic force. Similar to the effects of salbutamol, addition of epinephrine, norepinephrine, and rCGRP all produced a recovery of force in EDL muscles depressed by elevated [K+]o. Because the effects of both epinephrine and norepinephrine, in common with the effect of the {beta}2-agonist salbutamol (13), have been related to a stimulation of the muscle Na+-K+ pumps via the {beta}2-adrenoceptors, these results indicate that the increase in circulating catecholamines during exercise will improve the tolerance of the skeletal muscles to elevated [K+]o. In common with catecholamines, CGRP also stimulates the Na+-K+ pumps via the adenylate cyclase system (1), but at variance with the catecholamines, CGRP is released locally from motor and sensory nerve endings in the contracting muscles (44, 46), with little effect on the circulating levels of the neuropeptide. These findings indicate that in active muscles, the protection against elevated [K+]o induced by circulating catecholamines may be reinforced by local release of CGRP from nerve endings, which will further stimulate the Na+-K+ pumps.

Effects of CO2 and lactic acid. In this study we showed force restoration in EDL by increasing the fraction of CO2 in the gas mixture used for gassing the Krebs-Ringer buffer. This is in accordance with earlier studies showing that in the soleus, the effect of lactic acid on force recovery could be mimicked by an intracellular acidification induced by CO2 (36). The same study also showed that lactic acid could fully restore force in soleus muscles where force had been depressed to ~20% by a [K+]o of 11 mM. In EDL, lactic acid restored force to only 57 ± 2% of that obtained at 4 mM K+, when force had been depressed to ~20% by 13 mM K+. Moreover, in the soleus, 20 mM lactic acid increased IC50 from 11.5 to 13.4 mM K+ (15), whereas in EDL 24 mM lactic acid increased IC50 only from 12.2 to 12.7 mM, indicating that lactic acid offers less protection against the depressing effect of increased [K+]o in EDL than in soleus muscle. To investigate this, we examined whether the effect of further reducing pH by increasing the concentration of lactic acid could increase the force recovery effect in EDL. Increasing the lactic acid concentration to >24 mM induced a larger restoration of force, with a maximum at 28 mM lactic acid (Fig. 6). Even at 28 mM lactic acid, force recovery in EDL depressed by elevated [K+]o is not as great as that seen with 20 mM lactic acid in soleus muscles depressed to a similar extent. Thus the protecting effect of lactic acid against the depressing effect of increased [K+]o is smaller in EDL than in soleus. Furthermore, increasing lactic acid >28 mM did not provide greater protection of the muscles, suggesting that the physiological concentrations of lactic acid reached in rat and human working muscles (3, 16) are sufficient to exert the maximal protective effect of lactic acid observed in the present study. Recently, Kristensen et al. (31) explored the protective effect of lactic acid on the endurance of slow-twitch muscles and found no protective effect on endurance of preincubation with 20 mM lactic acid. A possible explanation might be that the work-induced generation of lactic acid in the muscles per se leads to a reduction in muscle pH that is sufficient to elicit the maximal protective effect against increased extracellular K+. Further reduction in muscle pH by addition of exogenous lactic acid would then be expected to either have no effect or even to reduce endurance by inhibiting force production.

As described earlier, it has been suggested that the acidification induced by lactic acid contributes to force recovery by lowering the chloride conductance (38, 39). At elevated [K+]o this does not change the Vm (47) but causes a recovery of excitability (38, 39). In the present study we have confirmed that lactic acid has no effect on Vm (Table 3), although it causes considerable recovery of tetanic force in EDL depressed by a [K+]o of 13 mM.

EDL and soleus muscles. The increase in the tolerance to elevated [K+]o (IC50) induced by {beta}2-adrenoceptor stimulation of the Na+-K+ pumps was almost as large in EDL as in soleus. In contrast, the effect of lactic acid on IC50 for extracellular K+ appeared to be somewhat smaller in EDL than in soleus. Moreover, when combined, {beta}2-adrenoceptor stimulation of the Na+-K+ pumps and lactic acid was, in the present study, found to increase IC50 by 2.3 mM K+ in EDL, whereas the combination of Na+-K+ pump stimulation and lactic acid was observed to increase IC50 by 4.1 mM K+ in soleus muscles (15). Thus the combined protective effect of salbutamol and lactic acid against the force-depressing effects of hyperkalemia is somewhat smaller in EDL than in soleus.

In contrast, a comparison of EDL and soleus muscles incubated in the absence of {beta}2-agonists and lactic acid indicate that EDL muscles per se can tolerate a higher [K+]o than soleus without any substantial force depression. Thus, in soleus muscles excited with 0.2- or 1-ms pulses, the [K+]o required to depress force production by 50% were 10.2 and 11.5 mM, respectively (15), whereas in EDL excited with 0.2-ms pulses, a [K+]o of 12.2 mM was required to depress force by 50% (Fig. 5). The tendency for a larger [K+]o tolerance in EDL compared with soleus is in accordance with earlier studies (7). EDL muscles may tolerate a higher [K+]o before starting to lose force because they maintain higher gradients for Na+ and K+ (14). The higher K+ gradient causes a more negative equilibrium potential for K+ and thereby a more negative Vm. In the present study this was confirmed by obtaining the resting Vm of –75 and –82 mV in soleus and EDL, respectively. Because of their higher intracellular [K+], EDL muscles can tolerate a higher [K+]o before depolarizing to a level that would depress excitability (7). Both muscle types are depolarized to the same value (Table 3) when tetanic force is depressed to 20% of that obtained at 4 mM K+, by 11 mM K+, and 13 mM K+ in soleus and EDL, respectively. This could indicate that the slow inactivation of the Na+ channels occurs at the same Vm in the two muscles. However, this is not in accordance with earlier observations showing that the slow inactivation of the Na+ channels occurs at a more negative Vm in fast-twitch fibers than in slow-twitch fibers (42, 48).

The present study suggests an exercise scenario in fast-twitch muscle, like the one observed in slow-twitch muscle, where the decrease in excitability caused by increased [K+]o is counteracted simultaneously by lactic acidosis and elevation of circulating catecholamines. Therefore, lactic acid, as well as Na+-K+ pump stimulation via the {beta}2-adrenoceptors, also provide a synergistic improvement of contractility in those fibers, which are known to be most susceptible to rapid rundown of Na+-K+ gradients and ensuing fatigue. However, our results indicate that compared with slow-twitch muscles, fast-twitch muscles show a somewhat smaller response to the protecting effect of {beta}2-stimulation and lactic acid. This difference may, to some extent, be compensated for by a larger tolerance of fast-twitch muscle per se to elevated [K+]o. In addition, the endogenous production of lactic acid is considerably larger in fast-twitch muscles than in slow-twitch muscle, and within a few minutes, the lactic acid level reached in working fast-twitch muscles (3) is sufficient to induce effects similar to those described in the present study. During intensive exercise, however, the reduction in intracellular pH taking place in slow-twitch fibers may be enhanced by cellular uptake of lactate and protons that are liberated from fast-twitch muscles. In that context, the lactate shuttle (4, 5) may be important not only as an improvement of the energy supplies of muscle fibers during exercise but also for the regulation of their excitability.

During exercise of increasing intensity, more fast-twitch fibers are recruited, leading to more pronounced hyperkalemia and lactate production. Concomitantly, exercise induces an increase in plasma catecholamines, which in turn stimulate the Na+-K+ pumps, leading to increased glycolysis (27). Our results indicate that optimal performance of these fibers may depend on their capacity for active Na+-K+ transport and their endogenous lactic acid production from glycogenolysis.


    GRANTS
 TOP
 ABSTRACT
 METHODS
 RESULTS
 DISCUSSION
 GRANTS
 REFERENCES
 
This study was supported by grants from Aarhus Universitets Forskningsfond, The Danish Medical Research Council Grants 9802488 and 22020188, The Danish Biomembrane Research Center, and The Lundbeck Foundation.


    ACKNOWLEDGMENTS
 
We thank Ann-Charlotte Andersen, Marianne Stürup Johansen, Tove Lindahl Andersen, and Vibeke Uhre for skilled technical assistance. We also thank Dr. John Flatman for assistance with the measurements of Vm.


    FOOTNOTES
 

Address for reprint requests and other correspondence: A. K. Hansen, Dept. of Physiology, Univ. of Aarhus, Ole Worms Allé 160, DK-8000 Århus C, Denmark (e-mail: Obn{at}fi.au.dk)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.


    REFERENCES
 TOP
 ABSTRACT
 METHODS
 RESULTS
 DISCUSSION
 GRANTS
 REFERENCES
 
1. Andersen SL and Clausen T. Calcitonin gene-related peptide stimulates active Na+-K+ transport in rat soleus muscle. Am J Physiol Cell Physiol 264: C419–C429, 1993.[Abstract/Free Full Text]

2. Bigland-Ritchie B, Jones DA, and Woods JJ. Excitation frequency and muscle fatigue: electrical responses during human voluntary and stimulated contractions. Exp Neurol 64: 414–427, 1979.[CrossRef][ISI][Medline]

3. Blomstrand E, Larsson L, and Edström L. Contractile properties, fatigability and glycolytic metabolism in fast- and slow-twitch rat skeletal muscles of various temperatures. Acta Physiol Scand 125: 235–243, 1985.[ISI][Medline]

4. Brooks GA. Intra- and extra-cellular lactate shuttles. Med Sci Sports Exerc 32: 790–799, 2000.[CrossRef][ISI][Medline]

5. Brooks GA. Lactate shuttles in nature. Biochem Soc Trans 30: 258–264, 2002.[CrossRef][ISI][Medline]

6. Buchanan R, Nielsen OB, and Clausen T. Excitation- and {beta}2-agonist-induced activation of the Na+-K+ pump in rat soleus muscles. J Physiol 545: 229–240, 2002.[Abstract/Free Full Text]

7. Cairns SP, Hing WA, Slack JR, Mills RG, and Loiselle DS. Different effects of raised [K+]o on membrane potential and contraction in mouse fast- and slow-twitch muscle. Am J Physiol Cell Physiol 273: C598–C611, 1997.[Abstract/Free Full Text]

8. Chua M and Dulhunty AF. Inactivation of excitation-contraction coupling in rat extensor digitorum longus and soleus muscles. J Gen Physiol 91: 737–757, 1988.[Abstract]

9. Clausen T. Na+-K+ pump regulation and skeletal muscle contractility. Physiol Rev 83: 1269–1324, 2003.[Abstract/Free Full Text]

10. Clausen T, Andersen SL, and Flatman JA. Na+-K+ pump stimulation elicits recovery of contractility in K+-paralysed rat muscle. J Physiol 472: 521–536, 1993.[Abstract]

11. Clausen T and Everts ME. K+-induced inhibition of contractile force in rat skeletal muscle: role of active Na+-K+ transport. Am J Physiol Cell Physiol 261: C799–C807, 1991.[Abstract/Free Full Text]

12. Clausen T, Everts ME, and Kjeldsen K. Quantification of the maximum capacity for active sodium-potassium transport in rat skeletal muscle. J Physiol 388: 163–181, 1987.[Abstract]

13. Clausen T and Flatman JA. The effect of catecholamines on Na+-K+ transport and membrane potential in rat soleus muscle. J Physiol 270: 383–414, 1977.[ISI][Medline]

14. Clausen T, Overgaard K, and Nielsen OB. Evidence that the Na+-K+ leak/pump ratio contributes to the difference in endurance between fast- and slow-twitch muscles. Acta Physiol Scand 180: 209–216, 2004.[CrossRef][ISI][Medline]

15. De Paoli F, Overgaard K, and Nielsen OB. Protective effects of acidosis and Na+,K+-pump activation on force in K+-depressed skeletal muscle. J Physiol 544P: 82P, 2002.

16. Essen B and Haggmark T. Lactate concentration in type I and II muscle fibers during muscular contraction in man. Acta Physiol Scand 95: 344–346, 1975.[ISI][Medline]

17. Everts ME and Clausen T. Activation of the Na+-K+ pump by intracellular Na+ in rat slow- and fast-twitch muscle. Acta Physiol Scand 145: 353–362, 1992.[ISI][Medline]

18. Everts ME, Retterstøl K, and Clausen T. Effects of adrenaline on excitation-induced stimulation of the sodium-potassium pump in rat skeletal muscle. Acta Physiol Scand 134: 189–198, 1988.[ISI][Medline]

19. Fenn WO and Cobb DB. Electrolyte changes in muscle during activity. Am J Physiol 115: 345–356, 1936.[Free Full Text]

20. Fitts RH. Cellular mechanisms of muscle fatigue. Physiol Rev 74: 49–94, 1994.[Abstract/Free Full Text]

21. Fletcher W and Hopkins FRS. Lactic acid in amphibian muscle. J Physiol 35: 247–309, 1906.

22. Galbo H, Holst JJ, Christensen NJ, and Hilsted J. Glucagon and plasma catecholamines during beta-receptor blockade in exercising man. J Appl Physiol 40: 855–863, 1976.[Abstract/Free Full Text]

23. Green S, Langberg H, Skovgaard D, Bülow J, and Kjaer M. Interstitial and arterial-venous K+ in human calf muscle during dynamic exercise: effect of ischaemia and relation to muscle pain. J Physiol 529: 849–861, 2000.[Abstract/Free Full Text]

24. Hicks A and McComas AJ. Increased sodium pump activity following repetitive stimulation of rat soleus muscles. J Physiol 414: 337–349, 1989.[Abstract]

25. Hnik P, Holas M, Krekule I, Kuriz N, Mejsnar J, Smiesko V, Ujec E, and Vyskocil F. Work-induced potassium changes in skeletal muscle and effluent venous blood assessed by liquid ion-exchanger microelectrodes. Pflügers Arch 362: 85–94, 1976.[CrossRef][ISI][Medline]

26. Hodgkin AL and Katz B. The effect of sodium ions on the electrical activity of the giant axon of the squid. J Physiol 108: 37–77, 1949.[ISI]

27. James JH, Wagner KR, King JK, Leffler RE, Upputuri RK, Balasubramaniam A, Friend LA, Shelly DA, Paul RJ, and Fischer JE. Stimulation of both aerobic glycolysis and Na+-K+-ATPase activity in skeletal muscle by epinephrine or amylin. Am J Physiol Endocrinol Metab 277: E176–E186, 1999.[Abstract/Free Full Text]

28. Jones DA, Bigland-Ritchie B, and Edwards RH. Excitation frequency and muscle fatigue: mechanical responses during voluntary and stimulated contractions. Exp Neurol 64: 401–413, 1979.[CrossRef][ISI][Medline]

29. Juel C, Pilegaard H, Nielsen JJ, and Bangsbo J. Interstitial K+ in human skeletal muscle during and after dynamic graded exercise determined by microdialysis. Am J Physiol Regul Integr Comp Physiol 278: R400–R406, 2000.[Abstract/Free Full Text]

30. Karelis AD, Marcil M, Peronnet F, and Gardiner PF. Effect of lactate infusion on M-wave characteristics and force in the rat plantaris muscle during repeated stimulation in situ. J Appl Physiol 96: 2133–2138, 2004.[Abstract/Free Full Text]

31. Kristensen M, Albertsen J, Rentsch M, and Juel C. Lactate and force production in skeletal muscle. J Physiol 562: 507–520, 2005.[Abstract/Free Full Text]

32. Medbø JI and Sejersted OM. Plasma potassium changes with high intensity exercise. J Physiol 421: 105–122, 1990.[Abstract]

33. Nielsen JJ, Kristensen M, Hellsten Y, Bangsbo J, and Juel C. Localization and function of ATP-sensitive potassium channels in human skeletal muscle. Am J Physiol Regul Integr Comp Physiol 284: R558–R563, 2003.[Abstract/Free Full Text]

34. Nielsen JJ, Mohr M, Klarskov C, Kristensen M, Krustrup P, Juel C, and Bangsbo J. Effects of high-intensity intermittent training on potassium kinetics and performance in human skeletal muscle. J Physiol 554: 857–870, 2004.[Abstract/Free Full Text]

35. Nielsen OB and Clausen T. The Na+/K+-pump protects muscle excitability and contractility during exercise. Exerc Sport Sci Rev 28: 159–164, 2000.[Medline]

36. Nielsen OB, de Paoli F, and Overgaard K. Protective effects of lactic acid on force production in rat skeletal muscle. J Physiol 536: 161–166, 2001.[Abstract/Free Full Text]

37. Nielsen OB, Ørtenblad N, Lamb GD, and Stephenson DG. Excitability of the T-tubular system in rat skeletal muscle: roles of K+ and Na+ gradients and Na+-K+ pump activity. J Physiol 557: 133–146, 2004.[Abstract/Free Full Text]

38. Pedersen TH, de Paoli F, and Nielsen OB. Increased excitability of acidified skeletal muscle: role of chloride conductance. J Gen Physiol 125: 237–246, 2005.[Abstract/Free Full Text]

39. Pedersen TH, Nielsen OB, Lamb GD, and Stephenson DG. Intracellular acidosis enhances the excitability of working muscle. Science 305: 1144–1147, 2004.[Abstract/Free Full Text]

40. Pfliegler G, Szabo I, and Kovacs T. The influence of catecholamines on Na+, K+ transport in slow- and fast-twitch muscles of the rat. Pflügers Arch 398: 236–240, 1983.[CrossRef][ISI][Medline]

41. Renaud JM. Modulation of force development by Na+, K+, Na+-K+ pump and KATP channel during muscular activity. Can J Appl Physiol 27: 296–315, 2002.[ISI][Medline]

42. Ruff RL. Sodium channel slow inactivation and the distribution of sodium channels on skeletal muscle fibers enable the performance properties of different skeletal muscle fiber types. Acta Physiol Scand 156: 159–168, 1996.[CrossRef][ISI][Medline]

43. Ruff RL. Effects of temperature on slow and fast inactivation of rat skeletal muscle Na+ channels. Am J Physiol Cell Physiol 277: C937–C947, 1999.[Abstract/Free Full Text]

44. Sakaguchi M, Inaishi Y, Kashihara Y, and Kuno M. Release of calcitonin gene-related peptide from nerve terminals in rat skeletal muscle. J Physiol 434: 257–270, 1991.[Abstract]

45. Street D, Bangsbo J, and Juel C. Interstitial pH in human skeletal muscle during and after dynamic graded exercise. J Physiol 537: 993–998, 2001.[Abstract/Free Full Text]

46. Uchida S, Yamamoto H, Iio S, Matsumoto N, Wang XB, Yonehara N, Imai Y, Inoki R, and Yoshida H. Release of calcitonin gene-related peptide-like immunoreactive substance from neuromuscular junction by nerve excitation and its action on striated muscle. J Neurochem 54: 1000–1003, 1990.[ISI][Medline]

47. Van Emst MG, Klarenbeek S, Schot A, Plomp JJ, Doornenbal A, and Everts ME. Reducing chloride conductance prevents hyperkalaemia-induced loss of twitch force in rat slow-twitch muscle. J Physiol 561: 169–181, 2004.[Abstract/Free Full Text]

48. Zebedin E, Sandtner W, Galler S, Szendroedi J, Just H, Todt H, and Hilber K. Fiber type conversion alters inactivation of voltage-dependent sodium currents in murine C2C12 skeletal muscle cells. Am J Physiol Cell Physiol 287: C270–C280, 2004.[Abstract/Free Full Text]