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Department of Physiology, College of Medicine, University of Tennessee Health Science Center, Memphis, Tennessee 38163
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Na+-K+-Cl
cotransporter (NKCC) activity in quiescent skeletal muscle is modest.
However, ex vivo stimulation of muscle for as little as 18 contractions
(1 min, 0.3 Hz) dramatically increased the activity of the
cotransporter, measured as the bumetanide-sensitive 86Rb
influx, in both soleus and plantaris muscles. This activation of
cotransporter activity remained relatively constant for up to 10-Hz
stimulation for 1 min, falling off at higher frequencies (30-Hz
stimulation for 1 min). Similarly, stimulation of skeletal muscle with
adrenergic receptor agonists phenylephrine, isoproterenol, or
epinephrine produced a dramatic stimulation of NKCC activity. It did
not appear that stimulation of NKCC activity was a reflection of
increased Na+-K+-ATPase activity because
insulin treatment did not stimulate NKCC activity, despite insulin's
well-known stimulation of Na+-K+-ATPase
activity. Stimulation of NKCC activity could be blocked by pretreatment
with inhibitors of mitogen-activated protein kinase (MAPK) kinase 1/2
(MEK1/2) activity, indicating that activation of the
extracellular signal-regulated kinase 1/2 (ERK1/2) MAPKs may be
required. These data indicate a regulated NKCC activity in skeletal
muscle that may provide a significant pathway for potassium transport
into skeletal muscle fibers.
potassium; electrical stimulation; adrenergic receptor; epinephrine; slow-twitch muscle; fast-twitch muscle; bumetanide; sodium-potassium-adenosinetriphosphatase; ouabain
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INTRODUCTION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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SKELETAL MUSCLE FIBERS must regulate potassium transport to provide a compensatory response to the ion fluxes that occur during contractile activity. Under resting conditions, steady state is maintained by the active transport of potassium into the muscle fiber to compensate losses due to leakage. However, during contractile activity, potassium efflux can exceed potassium influx (30, 42); this exacerbated potassium loss is thought to contribute to muscle fatigue (4, 14, 26). The potassium lost by the muscle accumulates in the extracellular space and the general circulation (26, 30), but the rapid upregulation of inward transport activity eventually restores intracellular potassium after cessation of contractile activity (12, 37). The increased inward transport activity must eventually be downregulated to maintain steady state and prevent hypokalemia. In addition to its involvement in potassium homeostasis during contractile activity, inward potassium flux in skeletal muscle is also an important buffering mechanism for ingested potassium. After a meal, ingested potassium could increase plasma potassium to dangerous levels if it were not buffered (25, 43). Therefore, the mechanisms responsible for inward potassium flux in skeletal muscle are of great interest.
The best-known potassium influx pathway in skeletal muscle is the
Na+-K+-ATPase.
Na+-K+-ATPase activity can be stimulated by an
increase in intracellular sodium (3, 40) and, in some
nonmuscle cells, by phosphorylation of its 
-subunit (2,
3). Contractile activity, increased levels of circulating
catecholamines, and increased levels of insulin are known stimulators
of Na+-K+-ATPase activity in skeletal muscle
(37). Inwardly rectifying potassium channels may also
participate in potassium recovery, but probably only under conditions
where locally high extracellular or low intracellular concentrations of
potassium shift the equilibrium potential for potassium to values more
positive than the resting membrane potential (19, 41).
Another potential mechanism for potassium influx is through the
activity of sodium-potassium-chloride cotransporters (NKCC). The
regulation of skeletal muscle NKCC activity is the topic of this study.
NKCC activity provides an electroneutral, inwardly directed flux at
virtually all physiological ion concentrations and membrane potentials
encountered by muscle cells. In skeletal muscle at rest, the activity
is low and would not contribute appreciably to net potassium flux
(46). In fact, it has been argued that typical NKCC
activity is not present in rat skeletal muscle (9, 10).
However, we have previously reported the expression of NKCC-like
proteins in skeletal muscle and found at rest the activity is quite low
(46). Therefore, we were interested in whether NKCC
activity could be stimulated, especially by stimuli that are known to
increase Na+-K+-ATPase activity in skeletal
muscle [e.g., contractile activity, catecholamines, and insulin
(7, 15, 37)]. In addition, we were interested in whether
the extracellular-signal regulated kinase 1/2 (ERK1/2) cascade mediates
stimulation of NKCC activity, as has been reported for heart muscle
after 1-adrenergic stimulation (1, 22).
This is a relevant question considering that contractile activity,
insulin, and isoproterenol can stimulate the ERK1/2 pathway in muscle
(39, 47).
We report here that epinephrine and contractile activity, but not
insulin, stimulate skeletal muscle NKCC activity. The
epinephrine-stimulated NKCC activity can be mediated via
1- or 
-adrenergic stimulation. Furthermore, we
demonstrate that the intracellular signaling pathway for stimulation of
NKCC activity involves activation of the ERK1/2 arm of the
mitogen-activated protein kinase (MAPK) pathways.
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METHODS |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Animal care and muscle preparation.
Female Sprague-Dawley rats (50-100 g) were used for all
experiments. Animals were housed in light- and temperature-controlled quarters where they received food and water ad libitum. Animals were
randomly assigned to experimental groups, and all animals were handled
identically. Animals were anesthetized with pentobarbital sodium (45 mg/kg ip) for tissue removal. Soleus (25-45 mg each) and plantaris
muscles (50-90 mg each) were removed by carefully dissecting the
proximal tendons at the muscle origin and severing the distal tendon.
The muscles were placed in oxygenated Krebs-Ringer buffer at 25°C in
preparation for further treatment (see NKCC activity in skeletal
muscle). The integrity of the muscle preparation was verified by
the ability of the muscle to elicit a visible unloaded contractile
response to a single electrical impulse and, in randomly chosen
muscles, the membrane potential of some muscle fibers. Microelectrode
measurement of membrane potential indicated intact preparations with
initial potentials in a range of 
70 to 75 mV. In selected muscles,
membrane potentials changed by 0.8 ± 1.6 (SE) and 1.2 ± 1.7 during 30 min and 2 h of incubation, respectively, in
oxygenated Krebs-Ringer solution at 25°C (n = 8 muscles). The Animal Care and Use Committee of the University of
Tennessee Health Science Center approved all procedures.
86Rb influx rate constant calculation.
A first-order Michaelis-Menten rate constant for 86Rb
influx into muscle can be calculated if the following assumptions are made: 1) [86Rb] in the bathing is much less
than the Michaelis-Menten constant (Km) for the
transport processes, 2) the transport of 86Rb is
far from steady state, and 3) steady-state conditions exist for transport intermediates and diffusion processes. In these experiments, the first condition was met by the low concentration of
86Rb in the solutions used to bathe the muscles (1 µCi/ml
86Rb at 2-10 nmol Rb/µCi). To determine the
transport kinetics and obtain an assay time for the second requirement,
we measured the time course of 86Rb uptake by muscles
suspended in oxygenated (95% O2-5% CO2)
Krebs-Ringer solution (in mM: 120 NaCl, 25.1 NaHCO3, 4.7 KCl, 1.2 KH2PO4, 1.2 MgSO4, 1.3 CaCl2, and 10 D-glucose, pH 7.4) at 30°C
(Fig. 1). After incubation, the muscles
were rinsed three times, 5 min each in 50 ml Krebs-Ringer solution at
4°C, blotted dry, weighed in tared scintillation vials, and counted
as described in NKCC activity in skeletal muscle. The data
indicate that a steady state for 86Rb transport is obtained
after 15 min of incubation. To assess the third requirement for
calculation of a transport rate constant (steady-state intermediates
and diffusion), potassium transport processes in the muscles were
blocked by preincubating for 15 min at 30°C in oxygenated
Krebs-Ringer solution containing 1 mM ouabain, 10 µM bumetanide, 5 mM
tetraethylammonium, and 1 mM BaCl2. The muscle was then
transferred to an identical tissue bath containing 86Rb and
allowed to incubate at 30°C for various times, blotted dry, and
immediately counted without rinsing (Fig. 1). Similarly, the rinsing
procedure was verified by allowing a 10-min incubation of the treated
muscle in the 86Rb-containing bath followed by rinsing in
Krebs-Ringer solution at 4°C for various times before counting (Fig.
1). From these data it is clear that most of the diffusion of
86Rb is taking place during the first 2 min of incubation.
Thus an incubation time of 10 min in the 86Rb-containing
solution was chosen for all experiments to minimize the impact of
diffusion on the rate constants and avoid being near a steady-state
condition for total 86Rb uptake.
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![<FR><NU>d[<SUP>86</SUP>Rb]</NU><DE>d<IT>t</IT></DE></FR><IT>=k<SUB>transport</SUB>×</IT>[<SUP>86</SUP>Rb]<IT>×</IT>[transporters]](/content/vol281/issue2/fulltext/R561/img001.gif)
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1 · min1]. So
![<FR><NU>d[<SUP>86</SUP>Rb]</NU><DE>d<IT>t</IT></DE></FR><IT>=</IT>−<IT>k×</IT>[<SUP>86</SUP>Rb]](/content/vol281/issue2/fulltext/R561/img002.gif)
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![k[(g/ml)<SUP><IT>−</IT>1</SUP><IT> · </IT>min<SUP>−1</SUP>]](/content/vol281/issue2/fulltext/R561/img003.gif)
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NKCC activity in skeletal muscle.
The soleus and plantaris muscles were removed from anesthetized rats
and immediately placed in oxygenated Krebs-Ringer solution. A stock
solution of 103 M bumetanide was prepared by dissolving
bumetanide in 50% DMSO in Krebs-Ringer solution. The working
bumetanide Krebs-Ringer solution was prepared by further diluting the
stock bumetanide with Krebs-Ringer solution to a final
concentration of 105 M bumetanide. Krebs-Ringer vehicle
was similarly prepared except that bumetanide was omitted. The final
concentration of DMSO in the vehicle and bumetanide buffers was 0.5%.
5 M), or in vehicle (DMSO) for the
contralateral muscle]. After preincubation, muscles were either
electrically stimulated for 1 min with 1-ms pulses, 30 V, at
frequencies of either 0, 0.3, 1, 3, 10, or 30 Hz, then incubated for 10 min in incubation media (oxygenated Krebs-Ringer solution
containing 1 µCi/ml 86Rb and either bumetanide or
vehicle) at 30°C; or the muscles were taken directly to incubation
medium, which contained either 100 µU/ml of insulin or epinephrine in
the range of 0.1 to 100 nM. In some experiments muscles were treated to
both electrical and epinephrine treatment. Muscles were immediately
washed with ice-cold 0.9% saline solution. After washing, the muscles
were blotted, weighed, and homogenized in 2 ml of 0.3 M trichloroacetic
acid. 86Rb uptake by the muscle was measured by
scintillation counting. 86Rb transport was expressed as a
rate constant. The bumetanide-sensitive portion of the rate constant
was calculated by subtracting the bumetanide treatment value for the
muscle of one hindlimb from the vehicle treatment value of the
contralateral muscle. Thus the bumetanide and vehicle treatments were
statistically paired.
1- And -adrenergic stimulation and blockade.
1- and -Adrenergic receptors were specifically
stimulated by adding 30 µM phenylephrine (1-adrenergic
receptor agonist) or 30 µM isoproterenol (-adrenergic receptor
agonist) to the bumetanide and vehicle incubation media. The
-adrenergic receptor antagonist propranolol was added to the
preincubation and incubation media of phenylephrine-treated muscle to
block any effects that phenylephrine might have on the -adrenergic
receptors. Likewise, the 1-adrenergic antagonist
prazosin was added to the preincubation and incubation media for
isoproterenol-treated muscle. Separate experiments were performed to
test the specificity of the phenylephrine stimulation. The
1-adrenergic antagonist prazosin (50 µM) alone, or in
combination with the -adrenergic antagonist propranolol (1 µM),
was added to the preincubation and incubation media of phenylephrine-stimulated muscle. Parallel experiments were done for
isoproterenol: propranolol, as well as a combination of propranolol and
prazosin, were tested with the isoproterenol-treated muscle. Any
effects that prazosin or propranolol had on NKCC activity in the
presence of agonists were tested by adding only prazosin or propranolol
to the preincubation and incubation media of the unstimulated muscle.
The bumetanide-sensitive 86Rb rate constant was determined
as before. In some experiments, muscles were treated with a combination
of 30 µM phenylephrine and 30 µM isoproterenol in the incubation medium.
Potassium content measurement. Potassium content was measured by flame photometry. After 1 min of electrical stimulation (see NKCC activity in skeletal muscle), muscles were removed from the incubation bath and placed in ice-cold Krebs-Ringer solution. The muscles were removed from the stimulating electrodes, blotted dry, and clamp-frozen. Tissue was dried under vacuum until weight did not change. The muscle was digested in 10 vol 1:1:1 water-HNO3-H2SO4 for 24-48 h and diluted with water for flame photometry.
MEK1/2 inhibition. Involvement of MAPK intracellular signaling component MAPK kinase 1/2 (MEK1/2) in the activation of NKCC was tested by preincubating muscles for 15 min in the presence of bumetanide or DMSO vehicle, inhibitors of MEK1/2 (10 µM PD-98059 or 0.5 µM U-0126), an inactive analog to U-0126 (0.5 µM U-0124), or vehicle control (DMSO). Muscles were then either electrically stimulated for 1 min at 10 Hz and then incubated for 10 min in incubation media (Krebs-Ringer solutions with 1 µCi/ml 86Rb, either the inhibitors or their vehicle control, and bumetanide or DMSO vehicle), or they were stimulated using 30 µM isoproterenol or 30 µM phenylephrine in the incubation media.
Western blotting of phospho-ERK. Whole muscle was preincubated as described before. Incubation time for stimulation lasted for 5 min and included no 86Rb in the medium. After incubation, the muscles were placed on ice in ice-cold lysis buffer (10 mM Tris · HCl, pH 7.4, 5 mM EDTA, 50 mM NaCl, 30 mM sodium pyrophosphate, 50 mM sodium fluoride, 100 µM Na3VO4, 1% Triton X-100, 1 mM phenylmethylsulfonyl fluoride, 2 µg/ml aprotinin, 2 µg/ml leupeptin, 2 µg/ml antipain, and 1 µg/ml pepstatin A), homogenized with a Teflon pestle, and centrifuged at 4°C for 5 min at 5,000 g. Protein concentration of the supernatant was measured by the bicinchoninic acid assay (Pierce, Rockford, IL). Twenty-five micrograms of protein were mixed with SDS denaturing buffer, warmed to 95°C for 5 min, and electrophoresed on a 10% SDS-PAGE gel. The gels were electroblotted with the semidry blotter from Buchler Instruments (Fairfield, NJ). The membrane was incubated overnight at 4°C in the Western blocking buffer (1.5 mM NaH2PO4, 8 mM Na2HPO4, 0.15 M NaCl, 0.3% Triton X-100, pH 7.4) supplemented with 3% BSA. Immunologic reactions were performed at room temperature for 1.5 h in blocking buffer containing 1% BSA and the specific antibody. Either the phospho-ERK antibody or the ERK-2 antibody (Santa Cruz Biotechnology, Santa Cruz, CA) were used at a 1:1,000 dilution. The membrane was subsequently washed four times for 5 min each with blocking buffer and incubated for 45 min at room temperature with horseradish peroxidase-conjugated goat anti-mouse IgG or goat anti-rabbit IgG secondary antibody (Sigma, St. Louis) in blocking buffer supplemented with 1% BSA. After extensive washing with blocking buffer, the immunocomplexes on the membrane were visualized by chemiluminescent exposure of X-ray film (ECL Plus, Amersham). Bands were quantitated using video densitometry. The extent of ERK phosphorylation was determined by comparing the amount of phosphorylated ERK with the total ERK.
Data analysis and statistics.
Comparisons within and among treatments for the rate constant data were
made by ANOVA; post hoc comparisons, where appropriate, were made using
Dunnett's t-test. Differences between treatments were
considered significant at < 0.05. The power of the
statistical tests was calculated using the G-Power program
(11). Data are reported as means ± SE.
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RESULTS |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Stimulation of bumetanide-sensitive 86Rb transport in
skeletal muscle.
The basal unstimulated 86Rb influx rate constant was
0.0158 ± 0.0013 and 0.0144 ± 0.0013 (g/ml)1 · min1 for the soleus and
plantaris muscles, respectively (mean ± SE, n = 6 muscle pairs each). The basal unstimulated bumetanide-sensitive 86Rb influx rate constant was 0.0013 ± 0.0020 and
0.0013 ± 0.0017 (g/ml)1 · min1 for the soleus and
plantaris muscles, respectively (n = 6 muscle pairs
each). Both the total and the bumetanide-sensitive
86Rb-rate constants in the soleus and plantaris muscles
were significantly increased by electrically stimulated, unloaded
twitch contractions in vitro (P < 0.0001 by ANOVA,
Fig. 2), with the bumetanide-sensitive transport accounting for approximately 20-25% of the total
uptake. There was also a significant effect of vehicle or bumetanide
treatment on the stimulated muscle (P < 0.003 by
ANOVA, Fig. 2). Post hoc analysis indicated a significant increase in
the bumetanide-sensitive rate constant for the soleus muscle at 0.3-, 1-, 3-,and 10-Hz stimulation and for the plantaris muscle at 10-Hz
stimulation (P < 0.05). There was not a significant
effect of stimulation frequency ranging between 0.3 and 30 Hz on the
total or bumetanide-insensitive rate constant for either muscle. We
measured muscle potassium content immediately after 1 min of 10-Hz
stimulation to test whether bumetanide had an effect on muscle
potassium levels during stimulation. Compared with paired
vehicle-treated controls, bumetanide-treated soleus and plantaris
muscle lost potassium during stimulation (23 ± 14 and 30 ± 23 meq/kg dry wt, respectively). This loss was significantly different
from the change in potassium content in the unstimulated,
bumetanide-treated muscles (P < 0.02 and
P < 0.01, respectively, for duplicate comparisons
among paired samples of 6 muscle pairs, each). In the unstimulated
muscles, bumetanide caused an apparent, although not statistically
significant, increase in potassium content of the soleus and plantaris
muscles by 43 ± 25 and 35 ± 16 meq/kg dry wt, respectively.
Stimulation of vehicle-treated muscles caused a decrease in potassium
content of 21 and 12 meq/kg dry wt in the soleus and plantaris muscles,
respectively, from the unstimulated values of 344 ± 30 and
340 ± 13 meq/kg dry wt, respectively. The unstimulated values are
consistent with those reported previously (23).
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-adrenergic antagonist propranolol (1 µM), the total
86Rb uptake rate constants in the soleus and plantaris
muscles increased from 0.0252 ± 0.0017 and 0.0182 ± 0.0016 (g/ml)1 · min1 to 0.0318 ± 0.0038 and 0.0260 ± 0.0033 (g/ml)1 · min1, respectively. The
bumetanide-sensitive 86Rb uptake rate constants in the
soleus and plantaris muscles were significantly increased to
0.0072 ± 0.0020 and 0.0056 ± 0.0024 (g/ml)1 · min1, respectively
(P < 0.05, n = 6) (Fig.
3). The phenylephrine stimulation of the
bumetanide-sensitive 86Rb uptake was blocked by the
addition of the 1-adrenergic antagonist prazosin (50 µM, Fig. 3). Similar to phenylephrine treatment, exposure of the
muscle to isoproterenol (30 µM) in the presence of the
1-adrenergic antagonist prazosin increased the total
86Rb uptake rate constants in the soleus and plantaris
muscles from 0.0284 ± 0.0014 and 0.0209 ± 0.0012 (g/ml)1 · min1 to 0.0377 ± 0.0025 and 0.0266 ± 0.0023 (g/ml)1 · min1, respectively. The
bumetanide-sensitive 86Rb rate constants of the soleus and
plantaris muscles were significantly increased to 0.0108 ± 0.0027 and 0.0032 ± 0.0015 (g/ml)1 · min1, respectively
(P < 0.05, n = 6 muscle pairs per
point, Fig. 3). The isoproterenol effect on bumetanide-sensitive
86Rb uptake was blocked by the -adrenergic antagonist
propranolol (1 µM, Fig. 3). As a control to determine if
phenylephrine was working primarily through an
1-adrenergic receptor pathway, prazosin alone (no
propranolol) was used to block the effects of phenylephrine on
bumetanide-sensitive 86Rb uptake. Similarly, propranolol
alone was used to block the effects of isoproterenol on
bumetanide-sensitive 86Rb uptake. The phenylephrine-induced
increase in bumetanide-sensitive 86Rb uptake was blocked by
prazosin alone, and this blockade was not significantly different from
blocking with the combination of both prazosin and the -adrenergic
antagonist propranolol. The isoproterenol-induced increase in
bumetanide-sensitive 86Rb uptake was also blocked by
propranolol alone and was not significantly different from blocking
with both propranolol and the 1-adrenergic antagonist
prazosin. In the absence of agonist, neither prazosin nor propranolol,
alone or in combination, had an effect on bumetanide-sensitive 86Rb uptake (n = 6 muscle pairs, power of
0.85 and 0.93 for soleus and plantaris muscle, respectively, for
P = 0.05).
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1 · min1 (P = 0.0023, n = 6 muscle pairs) for soleus and plantaris
muscles, respectively. However, the bumetanide-sensitive
86Rb uptake rate constant was significantly lower in the
soleus and plantaris muscles when stimulated with both
1-adrenergic and -adrenergic agonists when compared
with -adrenergic agonist stimulation (P = 0.0002 and
P = 0.01, respectively). These data indicate
interference between the two adrenergic receptor-mediated mechanisms.
Compared with 1-adrenergic stimulation alone, the bumetanide-sensitive 86Rb uptake rate constant with
simultaneous 1- and -adrenergic stimulation was not
significantly different for either of the muscles (n = 6 muscle pairs per point, power of 0.97 and 0.46 for soleus and
plantaris muscle, respectively, for P = 0.05).
Consistent with the 1- and -adrenergic agonist data
presented above, the bumetanide-sensitive 86Rb uptake rate
constant was increased by epinephrine in a dose-dependent manner for
both the soleus and plantaris muscles (Fig.
4). Exposure to 10 nM epinephrine caused
both the soleus and plantaris muscles to reach a maximal rate constant
for bumetanide-sensitive 86Rb uptake stimulation of
0.0032 ± 0.0008 and 0.0018 ± 0.0005 (g/ml)1 · min1, respectively
(P = 0.002 and 0.005 for soleus and plantaris, respectively, n = 6 muscle pairs per point, power of
0.91 and 0.86 for soleus and plantaris muscle, respectively).
Stimulation with 1 nM epinephrine immediately after 1- or 10-Hz
electrical stimulation did not result in a greater bumetanide-sensitive
86Rb rate constant than with either electrical stimulation
or epinephrine alone (n = 6 muscle pairs per point,
power of 0.87 for soleus and plantaris muscle to detect a 1 SD
difference at P 
0.05).
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1 · min1 from an unstimulated
rate constant of 0.0262 ± 0.0040 (g/ml)1 · min1. However, the
bumetanide-sensitive portion of this rate constant was only
0.0010 ± 0.0012 (g/ml)1 · min1, and this was not
significantly different from the value in the untreated control soleus
muscles (n = 22 muscle pairs per point, power of 0.99 to detect a 1 SD difference at P 0.05). Similarly, 100 µU/ml insulin stimulated the plantaris muscle 86Rb uptake
rate constant from a basal value of 0.0195 ± 0.0017 (g/ml)1 · min1 to 0.0257 ± 0.0011 (g/ml)1 · min1. As with the
soleus muscle, the bumetanide-sensitive portion of the rate constant in
plantaris muscle was minuscule [0.0010 ± 0.0007 (g/ml)1 · min1] and not
significantly different from that of unstimulated muscle (n = 22 muscle pairs per point, power of 0.99 to detect
a 1 SD difference at P 0.05).
MEK1/2 inhibition and NKCC activity.
After treatment of muscle with PD-98059, 50% of the
phenylephrine-stimulated, bumetanide-sensitive 86Rb uptake
was abolished in both slow-twitch and fast-twitch skeletal muscle (Fig.
5). When the more potent MEK1/2 inhibitor
U-0126 was used, all of the phenylephrine-stimulated,
bumetanide-sensitive 86Rb uptake was abolished (Fig. 5).
U-0124, the inactive analog of U-0126, did not affect the
phenylephrine-stimulated, bumetanide-sensitive 86Rb uptake
in soleus or plantaris muscles. PD-98059, as well as U-0126, abolished
all of the isoproterenol-stimulated, bumetanide-sensitive 86Rb uptake in the soleus and plantaris muscles (Fig. 5).
The isoproterenol-stimulated, bumetanide-sensitive 86Rb
uptake was unchanged by the addition of U-0124.
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of 0.49). U-0124 did not affect
the electrically stimulated, bumetanide-sensitive 86Rb
uptake (cf. Fig. 2).
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ERK1/2 phosphorylation.
As has been shown by others (32, 35), adrenergic receptor
activation is a relatively weak stimulator of whole tissue or cell
immunoreactive ERK1/2 phosphorylation (Fig.
7). Muscles were stimulated with
isoproterenol for 5 min. SDS-PAGE protein blots were probed with an
anti-doubly phosphorylated ERK antibody, stripped, and reprobed with an
anti-ERK2 antibody to normalize the phosphorylation for ERK expression;
data are expressed as the fractional change in phosphorylation in
treated muscle compared with its contralateral control. Normalized for
total ERK2, isoproterenol-treated soleus and plantaris muscle had
1.23 ± 0.21 and 1.21 ± 0.21 times more phospho-ERK,
respectively, than vehicle-treated contralateral muscle. Pretreatment
with the MEK1/2 inhibitor U-0126 decreased phospho-ERK in
isoproterenol-treated soleus and plantaris muscle 0.87 ± 0.06 and
0.78 ± 0.20 times, respectively, compared with isoproterenol-
plus U-0124-treated contralateral muscle (U-0124 is the inactive isomer
of U-0126). U-0124 had no effect on the level of
isoproterenol-induced phosphorylation of ERK (Fig. 7). Although
stimulation of the ERK pathway is necessary for stimulation of the
bumetanide-sensitive transport (Figs. 5 and 6), at the whole tissue
level it is not sufficient. This was demonstrated by an increased
ERK1/2 phosphorylation after 5 min of insulin stimulation. Insulin
increased phospho-ERK 1.40 ± 0.15 and 1.19 ± 0.17 times in
soleus and plantaris muscles, respectively, compared with
vehicle-treated contralateral control muscle (Fig. 7). Nonetheless, insulin was ineffective for stimulating bumetanide-sensitive transport in the muscle.
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Ion transport by muscle fibers must be regulated to provide a compensatory response to the dynamic movement of ions during contraction (30, 42). Previously, we demonstrated that NKCC mRNA, protein, and activity are present in adult rat skeletal muscle (46). However, whether the NKCC activity could be modulated remained a question. From the data presented here, we conclude that NKCC activity can be modulated by some, but not all, of the stimuli that are also known to stimulate Na+-K+-ATPase activity (15) in a manner that is dependent on MAPK pathways. Three major findings provide the support for this conclusion. First, the skeletal muscle bumetanide-sensitive 86Rb transport activity can be stimulated to levels accounting for as much as 30% of the potassium congener uptake after electrical stimulation of the muscle or exposure of the muscle to epinephrine and its mimetics. Second, unlike the contractile activity or catecholamines, insulin did not stimulate NKCC activity. Finally, MAPK inhibitors blocked stimulation of NKCC activity. We will discuss the significance of these findings in the following paragraphs.
The rate constants for the basal rate of transport reported here allow
comparison with previously reported data. Multiplying the rate constant
by the potassium concentration in the bathing solution gives an
estimate of the maximum rate of potassium transport under basal
conditions. These values for total uptake in the ex vivo muscle
preparation here [rate constants ranging from 0.015 to 0.030 (g/ml)1 · min1] are comparable to
values reported for perfused hindlimb with low-flow perfusion
(28) and cardiac myocytes in culture (44). However, the values reported here are less than those measured under
similar conditions (9, 10, 36), the preparations differing
primarily in the source of the rats and the method of muscle excision
(pentobarbital surgery in this study vs. decapitation). Basal NKCC
activity in skeletal muscle is smaller than the activity observed when
the muscle is stimulated. In fact, bumetanide treatment of resting
skeletal muscle sometimes causes increased 86Rb influx (as
demonstrated by a negative value for the bumetanide-sensitive 86Rb rate constant), although this is not statistically
significant. This trend may be due to an increase in the activity of
other inwardly directed potassium channels and transport mechanisms. Analogously, it has been shown by us and by others that the blockade of
the Na+-K+-ATPase can stimulate NKCC or other
inwardly directed transport activity (8, 38, 46).
Nevertheless, the conclusion from these data is that quiescent muscle
has a very low NKCC-mediated inward flux of isotope compared with total
inward flux.
Electrical stimulation of the muscles was a powerful stimulator of the bumetanide-sensitive 86Rb uptake. As few as 18 electrically induced contractions (0.3 Hz for 1 min) were sufficient stimulus to increase the bumetanide-sensitive 86Rb uptake significantly above basal levels (Fig. 2). The relative magnitude of the increase in total transport rate is comparable to that reported previously by Everts et al. (13). In addition, we found that the stimulation of NKCC activity was not frequency dependent. It has previously been suggested that deoxygenation can stimulate NKCC activity in red blood cells (34); protons, potassium, and epinephrine are also well-documented stimuli for potassium transport in red blood cells during exercise, apparently through stimulation of both Na+-K+- ATPase and NKCC activity (29). Although oxygen in our bathing solution was maintained throughout the preparation, contracting muscle consumes oxygen, creating a possible oxygen gradient within the tissue. However, if the stimulation of NKCC activity due to electrical stimulation occurs by hypoxia, the mechanism is either independent of stimulation frequency or the stimulus threshold is very low.
Adrenergic receptor stimulation was a powerful stimulator of the total
and bumetanide-sensitive 86Rb uptake in skeletal muscle.
Comparable to values reported by others, adrenergic receptor
stimulation increased total uptake by ~40% (7).
Stimulation with either an 1- or -adrenergic receptor
agonist significantly increased NKCC activity in skeletal muscle (Fig.
3). Although -adrenergic receptor-mediated pathways are often
thought to oppose -adrenergic receptor-mediated pathways, in some
cases their activities do complement each other and activate NKCC
activity in some cell types (1, 18, 47). Defining the
specific receptor-mediated pathways responsible for NKCC activation involved pharmacological treatment of the skeletal muscle with the
appropriate agonists and antagonists. The results of these experiments
indicate that NKCC activity was stimulated specifically by both
1- and -adrenergic receptor-mediated pathways. In the case of the -adrenergic receptor-mediated pathway, the
bumetanide-sensitive transport accounted for nearly one-third of the
total 86Rb uptake. Furthermore, the maximum NKCC activity
stimulated by epinephrine (Fig. 4) was not significantly different from
that caused by stimulation with phenylephrine or isoproterenol
(P < 0.05). This may indicate that a maximal level of
stimulation of NKCC activity was obtained with either the phenylephrine
or isoproterenol and that the 1- and -adrenergic
receptor-mediated pathways converge to activate NKCC. Such a
convergence would be consistent with the putative Ca2+ and
cAMP-mediated stimulation of muscle potassium transport by methylxanthines and papaverine (20, 27, 28). Our data may also explain part of the reason why potassium uptake by muscle is
impaired in patients taking -adrenergic receptor blockers (17). Furthermore, considering the relatively low
1-adrenergic receptor density in skeletal muscle
(33), the demonstration of a potential physiological role
for this receptor is a novel result of these experiments.
Both 1- and -adrenergic receptor activation were
stimulatory for NKCC activity in the muscle. Therefore, we tested the
possibility of an interaction between the two adrenergic
receptor-mediated pathways. Treatment of the muscle simultaneously with
agonists for both receptors resulted in a significant negative
interaction for the stimulation of NKCC activity in the predominantly
slow-twitch soleus muscle. It is reasonable to conclude that the
1-adrenergic pathway inhibits the -adrenergic
pathway. This also may explain why soleus muscle NKCC activity declines
when treated with high doses of epinephrine (Fig. 4).
Perhaps the most significant finding presented here is the lack of NKCC stimulation by insulin. As with catecholamines, insulin is a well-known stimulator of potassium uptake by skeletal muscle (15, 21). In both adipocytes and fibroblasts, insulin stimulates Na+-K+ ATPase activity and NKCC (31). Because skeletal muscle is one of the primary targets of insulin, we tested whether insulin stimulated NKCC activity in muscle. Although physiological resting levels of insulin in the rat are 10 µU/ml, 100 µU/ml was used to ensure activation of its receptor. We confirmed that insulin indeed stimulated 86Rb uptake in both soleus and plantaris muscles. However, the increase in uptake was not due to stimulation of NKCC activity because insulin did not significantly stimulate the bumetanide-sensitive 86Rb uptake. We conclude that the insulin-stimulated 86Rb uptake is primarily due to the well-documented stimulation of Na+-K+ ATPase activity (6, 15). Taken with results from catecholamine stimulation and electrical stimulation, these data show that NKCC activity is regulated and stimulated in response to some stimuli, but not by all stimuli known to stimulate potassium uptake by skeletal muscle.
Contractile activity, phenylephrine, and isoproterenol have all been shown to rapidly stimulate MAPK activity (39, 47). Therefore, we were interested in the potential involvement of MAPK in the stimulation of NKCC activity in skeletal muscle. Specifically, we tested the involvement of the ERK arm of the MAPK pathways. ERK1/2, key substrates in this signal cascade, are activated by phosphorylation by MEK1/2. In our experiments, known inhibitors of MEK1/2 abolished the isoproterenol-stimulated NKCC activity (Fig. 5) and the electrically stimulated NKCC activity (Fig. 6). Phenylephrine-stimulated NKCC activity showed the same trend, although the effect was not as striking (Fig. 5). From these data, we conclude that the ERK1/2 pathway is necessary for stimulation of NKCC activity in muscle. However, insulin is also known to stimulate the ERK1/2 pathway (Fig. 7 and Ref. 24), so why does insulin not stimulate NKCC activity in skeletal muscle? One possibility is that ERK1/2 activation alone may not be sufficient to stimulate skeletal muscle NKCC activity. Another possibility is that insulin stimulates a unique subset or compartment of ERK1/2 kinases. It is also possible that insulin activates other intracellular signaling mechanisms (5, 16) that may inhibit ERK1/2 activation of skeletal muscle NKCC activity. Unfortunately, no MAPK-specific activators are currently available that will specifically activate the ERK1/2 pathway without stimulating other mechanisms (e.g., tyrosine kinase receptor agonists). Nevertheless, the demonstration by these data of a difference within skeletal muscle in the consequences of stimulating the ERK1/2 pathway through distinctly different mechanisms is a significant finding. Furthermore, NKCC activity in skeletal muscle may prove to be a valuable model to study the interactions of various intracellular signaling pathways.
In conclusion, we have shown that electrical stimulation,
1-adrenergic stimulation, and -adrenergic stimulation
of muscle increased muscle NKCC activity. The intracellular mechanism
responsible for the increased NKCC activity, regardless of stimulus,
involved the activation of the ERK1/2 arm of the MAPK pathways.
However, complexity in the intracellular signal pathways was evident in that stimulation of the ERK1/2 pathway with insulin did not stimulate NKCC activity. Functionally, the rapid stimulation of NKCC activity in
skeletal muscle may serve as an additional potassium sequestering mechanism by muscle cells. This could provide the body with another rapid, efficient mechanism to buffer potassium and may be of particular importance for insulin-independent control of plasma potassium.
Perspectives
We report a mechanism for control of a putative potassium transport process in skeletal muscle: NKCC activity. Potassium transport by skeletal muscle is important for both muscle function and for buffering plasma potassium; bumetanide-sensitive transport in these experiments could account for 20-30% of the total muscle transport. The measurements here were based, in part, on 86Rb uptake. Two previous reports by Dørup and Clausen (9, 10) have indicated that bumetanide-sensitive 86Rb may not be indicative of a bumetanide-sensitive 42K transport. On the other hand, we have previously reported molecular and functional evidence for the expression of NKCC in skeletal muscle (46). The major differences between these experiments is the source of the animals, the method of tissue removal (decapitation vs. anesthesia), and the use of different radiotracers. Does rat skeletal muscle express an NKCC that discriminates potassium from Rb? Rb generally cosegregates with potassium and has a content in skeletal muscle of ~200 µM (45). The data here indicate that NKCC activity is stimulated by contractile activity and catecholamines through specific signal transduction pathways. Because of the ability of Rb to enter cells through many potassium transport mechanisms, it seems unlikely that a separate, regulated transport mechanism would exist for Rb. However, the previous reports of an apparent discrimination between potassium and Rb by NKCC raise a question of just what the bumetanide-sensitive transport is transporting. Only future experiments will give us insight into its function and regulation.| |
ACKNOWLEDGEMENTS |
|---|
The authors are grateful to L. A. Malinick for assistance with the publication graphics. We are also thankful to S. Sankaran for technical assistance with the flame photometry.
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FOOTNOTES |
|---|
An American Diabetes Association Research Award to D. B. Thomason supported this research.
Address for reprint requests and other correspondence: D. B. Thomason, Dept. of Physiology, College of Medicine, Univ. of Tennessee Health Science Center, Memphis, 894 Union Ave., Memphis, TN 38163 (E-mail: thomason{at}physio1.utmem.edu).
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.
Received 9 November 2000; accepted in final form 19 April 2001.
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REFERENCES |
|---|
|
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
|
|---|
1.
Andersen, GO,
Enger M,
Thoresen GH,
Skomedal T,
and
Osnes JB.
1-Adrenergic activation of myocardial Na-K-2Cl cotransport involving mitogen-activated protein kinase.
Am J Physiol Heart Circ Physiol
275:
H641-H652,
1998
2.
Beguin, P,
Beggah A,
Cotecchia S,
and
Geering K.
Adrenergic, dopaminergic, and muscarinic receptor stimulation leads to PKA phosphorylation of Na-K-ATPase.
Am J Physiol Cell Physiol
270:
C131-C137,
1996
3.
Blanco, G,
and
Mercer RW.
Isozymes of the Na-K-ATPase: heterogeneity in structure, diversity in function.
Am J Physiol Renal Physiol
275:
F633-F650,
1998
4.
Cairns, SP,
Flatman JA,
and
Clausen T.
Relation between extracellular [K+], membrane potential, and contraction in rat soleus muscle: modulation by the Na+-K+ pump.
Pflügers Arch
430:
909-915,
1995[Web of Science][Medline].
5.
Chang, PY,
Le Marchand-Brustel Y,
Cheatham LA,
and
Moller DE.
Insulin stimulation of mitogen-activated protein kinase, p90rsk, and p70 S6 kinase in skeletal muscle of normal and insulin-resistant mice. Implications for the regulation of glycogen synthase.
J Biol Chem
270:
29928-29935,
1995
6.
Clausen, T,
and
Everts ME.
Regulation of the Na,K-pump in skeletal muscle.
Kidney Int
35:
1-13,
1989[Web of Science][Medline].
7.
Clausen, T,
and
Flatman JA.
Effects of insulin and epinephrine on Na+-K+ and glucose transport in soleus muscle.
Am J Physiol Endocrinol Metab
252:
E492-E499,
1987
8.
Dong, J,
Delamere NA,
and
Coca Prados M.
Inhibition of Na+-K+-ATPase activates Na+-K+-2Cl cotransporter activity in cultured ciliary epithelium.
Am J Physiol Cell Physiol
266:
C198-C205,
1994
9.
Dørup, I,
and
Clausen T.
86Rb is not a reliable tracer for potassium in skeletal muscle.
Biochem J
302:
745-751,
1994.
10.
Dørup, I,
and
Clausen T.
Characterization of bumetanide-sensitive Na+ and K+ transport in rat skeletal muscle.
Acta Physiol Scand
158:
119-127,
1996[Web of Science][Medline].
11.
Erdfelder, E,
Faul F,
and
Buchner A.
GPOWER: a general power analysis program.
Behav Res Meth Instr Comp
28:
1-11,
1996.
12.
Everts, ME,
and
Clausen T.
Excitation-induced activation of the Na+-K+ pump in rat skeletal muscle.
Am J Physiol Cell Physiol
266:
C925-C934,
1994
13.
Everts, ME,
Retterstol 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[Web of Science][Medline].
14.
Fitts, RH.
Muscle fatigue: the cellular aspects.
Am J Sports Med
24:
S9-S13,
1996.
15.
Flatman, JA,
and
Clausen T.
Combined effects of adrenaline and insulin on active electrogenic Na+-K+ transport in rat soleus muscle.
Nature
281:
580-581,
1979[Medline].
16.
Goodyear, LJ,
Chang PY,
Sherwood DJ,
Dufresne SD,
and
Moller DE.
Effects of exercise and insulin on mitogen-activated protein kinase signaling pathways in rat skeletal muscle.
Am J Physiol Endocrinol Metab
271:
E403-E408,
1996
17.
Gullestad, L,
Hallen J,
and
Sejersted OM.
K+ balance of the quadriceps muscle during dynamic exercise with and without -adrenoceptor blockade.
J Appl Physiol
78:
513-523,
1995
18.
Haas, M,
and
McBrayer DG.
Na-K-Cl cotransport in nystatin-treated tracheal cells: regulation by isoproterenol, apical UTP, and [Cl]i.
Am J Physiol Cell Physiol
266:
C1440-C1452,
1994
19.
Hallen, J.
K+ balance in humans during exercise.
Acta Physiol Scand
156:
279-286,
1996[Web of Science][Medline].
20.
Hawke, TJ,
Willmets RG,
and
Lindinger MI.
K+ transport in resting rat hindlimb skeletal muscle in response to paraxanthine, a caffeine metabolite.
Can J Physiol Pharmacol
77:
835-843,
1999[Web of Science][Medline].
21.
Koeppen, B,
and
Stanton B.
Renal Physiology. St. Louis, MO: Mosby Year Book, 1992.
22.
Lazou, A,
Sugden PH,
and
Clerk A.
Activation of mitogen-activated protein kinases (p38-MAPKs, SAPKs/JNKs and ERKs) by the G-protein-coupled receptor agonist phenylephrine in the perfused rat heart.
Biochem J
332:
459-465,
1998.
23.
Ledingham, JM.
The influence of the adrenal on the water and electrolyte disturbances following nephrectomy, and its relation to renoprival hypertension.
J Biol Chem
13:
535-553,
1954.
24.
Lee, RM,
Cobb MH,
and
Blackshear PJ.
Evidence that extracellular signal-regulated kinases are the insulin-activated Raf-1 kinase kinases.
J Biol Chem
267:
1088-1092,
1992
25.
Lewis, ED,
Griggs RC,
and
Moxley RT.
Regulation of plasma potassium in hyperkalemic periodic paralysis.
Neurology
29:
1131-1137,
1979
26.
Lindinger, MI.
Potassium regulation during exercise and recovery in humans: implications for skeletal and cardiac muscle.
J Mol Cell Cardiol
27:
1011-1022,
1995[Web of Science][Medline].
27.
Lindinger, MI,
Graham TE,
and
Spriet LL.
Caffeine attenuates the exercise-induced increase in plasma [K+] in humans.
J Appl Physiol
74:
1149-1155,
1993
28.
Lindinger, MI,
and
Hawke TJ.
Increased flow rate and papaverine increase K+ exchange in perfused rat hindlimb skeletal muscle.
Can J Physiol Pharmacol
77:
536-543,
1999[Web of Science][Medline].
29.
Lindinger, MI,
Horn PL,
and
Grudzien SP.
Exercise-induced stimulation of K+ transport in human erythrocytes.
J Appl Physiol
87:
2157-2167,
1999
30.
Lindinger, MI,
McKelvie RS,
and
Heigenhauser GJ.
K+ and Lac distribution in humans during and after high-intensity exercise: role in muscle fatigue attenuation?
J Appl Physiol
78:
765-777,
1995
31.
Longo, N.
Insulin stimulates the Na+,K+-ATPase and the Na+/K+/Cl cotransporter of human fibroblasts.
Biochim Biophys Acta
1281:
38-44,
1996[Medline].
32.
Luttrell, LM,
Ferguson SS,
Daaka Y,
Miller WE,
Maudsley S,
Della Rocca GJ,
Lin F,
Kawakatsu H,
Owada K,
Luttrell DK,
Caron MG,
and
Lefkowitz RJ.
-Arrestin-dependent formation of 2-adrenergic receptor-Src protein kinase complexes.
Science
283:
655-661,
1999
33.
Martin, WH,
Tolley TK,
and
Saffitz JE.
Autoradiographic delineation of skeletal muscle 1-adrenergic receptor distribution.
Am J Physiol Heart Circ Physiol
259:
H1402-H1408,
1990
34.
Muzyamba, MC,
Cossins AR,
and
Gibson JS.
Regulation of Na+-K+-2Cl cotransport in turkey red cells: the role of oxygen tension and protein phosphorylation.
J Physiol (Lond)
517:
421-429,
1999
35.
Napoli, R,
Gibson L,
Hirshman MF,
Boppart MD,
Dufresne SD,
Horton ES,
and
Goodyear LJ.
Epinephrine and insulin stimulate different mitogen-activated protein kinase signaling pathways in rat skeletal muscle.
Diabetes
47:
1549-1554,
1998[Abstract].
36.
Nielsen, OB,
and
Clausen T.
The significance of active Na+,K+ transport in the maintenance of contractility in rat skeletal muscle.
Acta Physiol Scand
157:
199-209,
1996[Web of Science][Medline].
37.
Nielsen, OB,
and
Clausen T.
Regulation of Na+-K+ pump activity in contracting rat muscle.
J Physiol (Lond)
503:
571-581,
1997
38.
Panet, R,
Digregorio DM,
and
Brown RH, Jr.
Irreversible reduction in potassium fluxes accompanies terminal differentiation of human myoblasts to myotubes.
J Cell Physiol
132:
57-64,
1987[Web of Science][Medline].
39.
Sherwood, DJ,
Dufresne SD,
Markuns JF,
Cheatham B,
Moller DE,
Aronson D,
and
Goodyear LJ.
Differential regulation of MAP kinase, p70(S6K), and Akt by contraction and insulin in rat skeletal muscle.
Am J Physiol Endocrinol Metab
276:
E870-E878,
1999
40.
Sjodin, RA.
Transport in Skeletal Muscle. New York: Wiley, 1982.
41.
Sjogaard, G.
Potassium and fatigue: the pros and cons.
Acta Physiol Scand
156:
257-264,
1996[Web of Science][Medline].
42.
Sréter, FA.
Distribution of water, sodium, and potassium in resting and stimulated mammalian muscle.
Can J Biochem Physiol
41:
1035-1045,
1963.
43.
Sweeney, RW.
Treatment of potassium balance disorders.
Vet Clin North Am Food Anim Pract
15:
609-617,
1999[Medline].
44.
Viko, H,
Osnes JB,
and
Skomedal T.
1- And -adrenoceptor-mediated increase in 86Rb+-uptake in isolated cardiomyocytes from adult rat heart: evidence for interaction between the two receptor systems.
Pharmacol Toxicol
79:
287-292,
1996[Web of Science][Medline].
45.
Ward, NI,
and
Abou-Shakra FR.
Rubidium levels in human tissues and fluids.
In: Trace Elements in Man and Animals
TEMA 8, edited by Anke M,
Meissner D,
and Mills CF.. Gersdorf, Germany: Verlag Media Touristik, 1993, p. 82.
46.
Wong, JA,
Fu L,
Schneider EG,
and
Thomason DB.
Molecular and functional evidence for Na-K-2Cl cotransporter expression in rat slow-twitch skeletal muscle.
Am J Physiol Regulatory Integrative Comp Physiol
277:
R156-R161,
1999.
47.
Yamazaki, T,
Komuro I,
Zou Y,
Kudoh S,
Shiojima I,
Hiroi Y,
Mizuno T,
Aikawa R,
Takano H,
and
Yazaki Y.
Norepinephrine induces the raf-1 kinase/mitogen-activated protein kinase cascade through both 1- and -adrenoceptors.
Circulation
95:
1260-1268,
1997
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) to an amount that is easily washed
away within 5 min of washout in ice-cold Krebs-Ringer solution
(
). CPM, counts per minute; inset: expanded
ordinate scale for diffusion (
