Postdenervation changes of intracellular potassium and sodium measured by ion selective microelectrodes in rat soleus and extensor digitorum longus muscle fibres

Recent advances of nanopore technique in single cell analysis

Single cells and their dynamic behavior are closely related to biological research. Monitoring their dynamic behavior is of great significance for disease prevention. How to achieve rapid and non-destructive monitoring of single cells is a major issue that needs to be solved urgently. As an emerging technology, nanopores have been proven to enable non-destructive and label-free detection of single cells. The structural properties of nanopores enable a high degree of sensitivity and accuracy during analysis. In this article, we summarize and classify the different types of solid-state nanopores that can be used for single-cell detection and illustrate their specific applications depending on the size of the analyte. In addition, their research progress in material transport and microenvironment monitoring is also highlighted. Finally, a brief summary of existing research challenges and future trends in nanopore single-cell analysis is tentatively provided.

Functional nucleic acid engineered double-barreled nanopores for measuring sodium to potassium ratio at single-cell level

The use of double-barreled nanopipette (θ-nanopipette) to electrically sample, manipulate, or detect biomaterials has recently seen strong growth in single-cell studies, driven by the potential of the nanodevices and applications that they may enable. Considering the pivotal roles of Na/K ratio (R_Na/K) at cellular level, herein we describe an engineered θ-nanopipette for measuring single-cell R_Na/K. The two independently addressable nanopores, located within one nanotip, allow respective customization of functional nucleic acids but simultaneous deciphering of Na and K levels inside a single cell of a non-Faradic manner. Two ionic current rectification signals, corresponding to the Na- and K-specific smart DNA responses, could be easily used to derive the R_Na/K. The applicability of this nanotool is validated by practical probing intracellular R_Na/K during the drug-induced primary stage of apoptotic volume decrease. Especially, the R_Na/K has been shown by our nanotool to be different in cell lines with different metastatic potential. This work is expected to contribute to futuristic study of single-cell R_Na/K in various physiological and pathological processes.

Muscle Ionic Shifts During Exercise: Implications for Fatigue and Exercise Performance

Exercise causes major shifts in multiple ions (e.g., K⁺ , Na⁺ , H⁺ , lactate^- , Ca²⁺ , and Cl^- ) during muscle activity that contributes to development of muscle fatigue. Sarcolemmal processes can be impaired by the trans-sarcolemmal rundown of ion gradients for K⁺ , Na⁺ , and Ca²⁺ during fatiguing exercise, while changes in gradients for Cl^- and Cl^- conductance may exert either protective or detrimental effects on fatigue. Myocellular H⁺ accumulation may also contribute to fatigue development by lowering glycolytic rate and has been shown to act synergistically with inorganic phosphate (Pi) to compromise cross-bridge function. In addition, sarcoplasmic reticulum Ca²⁺ release function is severely affected by fatiguing exercise. Skeletal muscle has a multitude of ion transport systems that counter exercise-related ionic shifts of which the Na⁺ /K⁺ -ATPase is of major importance. Metabolic perturbations occurring during exercise can exacerbate trans-sarcolemmal ionic shifts, in particular for K⁺ and Cl^- , respectively via metabolic regulation of the ATP-sensitive K⁺ channel (K_ATP ) and the chloride channel isoform 1 (ClC-1). Ion transport systems are highly adaptable to exercise training resulting in an enhanced ability to counter ionic disturbances to delay fatigue and improve exercise performance. In this article, we discuss (i) the ionic shifts occurring during exercise, (ii) the role of ion transport systems in skeletal muscle for ionic regulation, (iii) how ionic disturbances affect sarcolemmal processes and muscle fatigue, (iv) how metabolic perturbations exacerbate ionic shifts during exercise, and (v) how pharmacological manipulation and exercise training regulate ion transport systems to influence exercise performance in humans. © 2021 American Physiological Society. Compr Physiol 11:1895-1959, 2021.

X-ray Microanalysis of Elements in the Masticatory Muscle after Paresis of the Right Masseter

Muscle activity and function appear to be related to ionic concentrations in the muscle. We investigated whether muscle paresis induced by injection of Botulinum toxin A (Botox) in 16-week-old pigs over a 56-day period is associated with ionic changes in the affected muscles. Tissue samples were taken from the masseter, temporalis, medial pterygoid, and geniohyoid muscles by a standardized method and used for energy-dispersive x-ray microanalysis in an environmental scanning electron microscope. The largest increase in Na+ was measured in the right and left sides of the masseter muscle in treated animals. Additionally, a significant elevation of Na+ was measured in the anterior part of the temporalis muscle and in the pterygoid muscle (P < 0.05). In temporalis and pterygoid muscles, an increase in sulfur in both sides of treated pigs’ heads was observed. Botox® has an indirect impact on ion concentrations, resulting in changes in muscle functional capacity and adaptive compensation of paretic muscle function by other muscles.

Different sensitivities of rat skeletal muscles and brain to novel anti-cholinesterase agents, alkylammonium derivatives of 6-methyluracil (ADEMS)

BACKGROUND AND PURPOSE

The rat respiratory muscle diaphragm has markedly lower sensitivity than the locomotor muscle extensor digitorum longus (EDL) to the new acetylcholinesterase (AChE) inhibitors, alkylammonium derivatives of 6-methyluracil (ADEMS). This study evaluated several possible reasons for differing sensitivity between the diaphragm and limb muscles and between the muscles and the brain.

EXPERIMENTAL APPROACH

Increased amplitude and prolonged decay time of miniature endplate currents were used to assess anti-cholinesterase activity in muscles. In hippocampal slices, induction of synchronous network activity was used to follow cholinesterase inhibition. The inhibitor sensitivities of purified AChE from the EDL and brain were also estimated.

KEY RESULTS

The intermuscular difference in sensitivity to ADEMS is partly explained caused by a higher level of mRNA and activity of 1,3-bis[5(diethyl-o-nitrobenzylammonium)pentyl]-6-methyluracildibromide (C-547)-resistant BuChE in the diaphragm. Moreover, diaphragm AChE was more than 20 times less sensitive to C-547 than that from the EDL. Sensitivity of the EDL to C-547 dramatically decreased after treadmill exercises that increased the amount of PRiMA AChE(G4), but not ColQ AChE(A12) molecular forms. The A12 form present in muscles appeared more sensitive to C-547. The main form of AChE in brain, PRiMA AChE(G4), was apparently less sensitive because brain cholinesterase activity was almost three orders of magnitude more resistant to C-547 than that of the EDL.

CONCLUSIONS AND IMPLICATIONS

Our findings suggest that ADEMS compounds could be used for the selective inhibition of AChEs and as potential therapeutic tools.

Mechanisms of carbacholine and GABA action on resting membrane potential and Na+/K+-ATPase of Lumbricus terrestris body wall muscles

This work was aimed to identify the action of several ion channel and pump inhibitors as well as nicotinic, GABAergic, purinergic and serotoninergic drugs on the resting membrane potential (RMP) and assess the role of cholinergic and GABAergic sensitivity in earthworm muscle electrogenesis. The nicotinic agonists acetylcholine (ACh), carbacholine (CCh) and nicotine depolarize the RMP at concentrations of 5 μM and higher. The nicotinic antagonists (+)tubocurarine, α-bungarotoxin, muscarinic antagonists atropine and hexamethonium do not remove or prevent the CCh-induced depolarization. Verapamil, tetrodotoxin, removal of Cl(-) and Ca(2+) from the solution also cannot prevent the depolarization by CCh. In a Na(+)-free medium, however, CCh lost this depolarization ability and this indicates that the drug opens the sodium permeable pathway. Serotonin, glutamate, glycine, adenosine triphosphate (ATP) and cis-4-aminocrotonic acid (GABA(C) receptor antagonist) had no effect on the RMP. On the other hand, isoguvacin, γ-aminobutyric acid (GABA) and baclofen (GABA(B) receptor agonist) hyperpolarized the RMP. Ouabain, bicucullin (GABA(A) antagonist) and phaclofen (GABA(B) antagonist), as well as the removal of Cl(-), suppressed the effect of GABA and baclofen. CCh did not enhance the depolarization generated by ouabain but, on the other hand, hindered the hyperpolarizing activity of baclofen both in the absence and presence of atropine and (+)tubocurarine. The long-term application of CCh depolarizes the RMP primarily by inhibiting the Na(+)/K(+)-ATPase. The muscle membrane also contains A and B type GABA binding sites, the activation of which increases the RMP at the expense of increasing the action of ouabain- and Cl(-) -sensitive electrogenic pumps.

Mechanisms of the inhibition of endplate acetylcholine receptors by antiseptic chlorhexidine (experiments and models)

Mechanisms of the inhibition of evoked multiquantal endplate currents (EPC) by chlorhexidine (CHX) were studied in electrophysiological experiments and by mathematical modeling to discriminate between possible channel, receptor, and non-receptor effects of this common antiseptic drug. Experiments were carried out on the isolated neuromuscular preparation of the cut m. sartorius of the frog Rana ridibunda. The nerve-stimulation-evoked endplate currents were measured by standard double microelectrode technique. For the mathematical simulation, a method based on the solution of a system of ordinary differential equations was used. CHX in milimolar concentrations suppressed the amplitude and shortened the evoked EPC. Recovery of the EPC amplitude was very slow, and EPC shortening persisted during 30-40 min washout of the drug. There is no indication that CHX competes for acetylcholine or carbachol binding site(s). A comparison of the experimental data with mathematical simulation made it possible to construct a reliable kinetic scheme, which describes the action of CHX. CHX induces a combined slow blockade of the open ionic channel and long-lasting allosteric inhibition of the nicotinic acetylcholine receptor. The very slow washout of the drug in terms of EPC amplitude and virtually no recovery of the shortened EPC time course might substantiate certain caution to avoid unintentional high-dose application during its antibacterial application.

Early postdenervation depolarization is controlled by acetylcholine and glutamate via nitric oxide regulation of the chloride transporter

Resting non-quantal acetylcholine (ACh) and probably glutamate (Glu) release from nerve endings activates M1- and NMDA receptor-mediated Ca2+ entry into the sarcoplasm with following activation of NOS and production of NO. This is a trophic message from motoneurons, which keeps the Cl- transport inactive in the innervated sarcolemma. After denervation, the secretion of ACh and Glu at the neuromuscular junction is eliminated within 3-4 h and the production of NO in the sarcoplasm is lowered. As a result, the Cl- influx is probably activated by dephosphorylation of the Cl- transporter with subsequent elevation of intracellular Cl- concentration. The equilibrium Cl- potential becomes more positive and the muscle membrane becomes depolarized.

The glutamate and carbachol effects on the early post-denervation depolarization in rat diaphragm are directed towards furosemide-sensitive chloride transport

The membrane potentials of denervated muscle fibres of the rat diaphragm kept in a tissue culture medium are depolarized by about 8-10 mV (10-12%) within 3 h after denervation. This early post-denervation depolarization (EPD) is substantially reduced (2-3 mV) when muscle strips are bathed with 1 mM L-glutamate (GLU) which is found in motor nerve endings, or with 5 x 10(-8) M carbachol (CCh), which mimics the effect of nonquantally released acetylcholine (ACh). The hyperpolarizing effects of GLU and CCh on EPD are not influenced by ouabain, an active sodium transport inhibitor, but are absent when Cl- transport is augmented by increased osmolarity (500 mosmol/l) produced by addition of sucrose or NaCl. The EPD and the effect of hyperosmolarity are effectively prevented by the Cl- transport inhibitor furosemide (1 x 10(-4) M) or by a chloride-free bathing medium. It is suggested that the post-denervation cessation of nonquantal ACh release, and probably also GLU release, from nerve endings leads to the activation of the furosemide-sensitive Cl- transport in the sarcolemma, which is responsible for the early post-denervation depolarization.

Acetylcholine and carbachol prevent muscle depolarization in denervated rat diaphragm

Muscle fibres of the rat diaphragm kept in a tissue culture medium became depolarized by 8-10 mV within 3 h after denervation. In the presence of carbachol (CB; 5 x 10(-8) M), and acetylcholine (ACh; 5 x 10(-8) M, the post-denervation depolarization was reduced. Both drugs were used in concentrations which mimicked the effect of non-quantal release of ACh. (+)Tubocurarine (TC) and ouabain did not prevent the protective action of CB, indicating that this effect is not mediated through ACh nicotinic receptors or the electrogenic Na+, K+ pump. Addition of Mg2+, verapamil, diltiazem, nifedipine and Cd2+ in concentrations which block Ca2+ entry virtually inhibited the effect of both cholinomimetics. L-Nitroarginine methylester (NAME), an inhibitor of NO synthase, and haemoglobin, an extracellular scavenger of the NO radical, completely eliminated the protective effect of CB on post-denervation depolarization. The retrograde action of NO produced by cholinomimetics on nerve terminals is postulated.

Electrochemical potentials of potassium in skeletal muscle under different metabolic states

Intracellular potassium and membrane potential were measured simultaneously by means of double-barrelled liquid ion-exchange microelectrodes in single fibers of rat thigh muscle in vivo in rats maintained in seven different metabolic states. The K+ equilibrium potential (EK) was more negative than the simultaneously measured membrane potential (Em) in the normal state by 18.4 mV. K+ loading, acute and chronic, resulted in depolarization of Em due to increased serum K+ (hyperkalemia) with no increase in intracellular K+. K+ depletion resulted in hyperpolarization of Em as plasma K+ decreased proportionately more than intracellular K+. Low Na+ diet had no effect. Intracellular K+ was decreased in acute acidosis but not in the chronic state. Thus K+ depletion and acute acidosis are associated with intracellular K+ decrease. The fact that hyperpolarization exists in the former and not the latter is a reflection that hypokalemia accompanies the former condition. The hyperpolarizing states of K+ depletion and chronic acidosis are accompanied by decreased excitability and muscle weakness.

Immobilization atrophy and membrane properties in rat skeletal muscle fibres

Wet mass, resting membrane potential, frequency of miniature end-plate potentials and the concentration of [3H]ouabain-binding sites were studied after 7 days' immobilization of the rat soleus and extensor digitorum longus (EDL) muscles in the shortened or stretched position and after 3 and 7 days of remobilization. We observed that the loss of muscle mass by 37% in the rat soleus immobilized for 7 days in the shortened position is accompanied by a membrane depolarization of about 5 mV, a decrease in frequency of miniature end-plate potentials by 60% and a decrease of [3H]ouabain binding by 25%. Only minor changes were found in stretched soleus and in shortened and stretched EDL. After 3 days of remobilization of stretched soleus the muscle mass, [3H]ouabain binding and miniature end-plate potential frequency recovered to control values but the resting membrane potential continued to decrease. All changes induced by immobilization disappeared on day 7 of remobilization.

Intracellular chloride and the mechanism for its accumulation in rat lumbrical muscle

1. Double-barrelled Cl(-)-sensitive microelectrodes have been used to measure the intracellular Cl- activity (aCli) and membrane potential (Em) in rat lumbrical muscles. The mean Cl- equilibrium potential (ECl), calculated from the measured aCli in sixty fibres, was 2.9 +/- 2.5 mV (S.D. of an observation) less negative than Em. The value of aCli was higher than would be expected for a passive distribution, by a mean 1.4 +/- 1.2 mM. The mean Em was -59.5 +/- 8.2 mV. 2. Removal of external Cl- (Cl-(o)) resulted in a rapid fall in aCli and a transient depolarization. aCli stabilized at an apparent level of 1.7 +/- 1.0 mM (n = 24) while Em became substantially more negative than in normal Krebs solution (mean, -80.1 +/- 12.4 mV). Readdition of Cl-(o) caused a rapid rise in aCli and transient hyperpolarization. ECl quickly became less negative than Em and both then fell in parallel towards the levels previously recorded in normal Krebs solution. 3. If lack of selectivity of the Cl(-)-sensitive ion exchanger and the intracellular presence of interfering anions, assumed to be responsible for the apparent aCli recorded in Cl(-)-depleted fibres, were also responsible for the apparently non-passive Cl- distribution recorded under normal conditions, the difference between the calculated ECl and Em would increase at more negative potentials. This was not observed over a range of Em values between -46 and -84 mV. 4. Inhibition of the Cl- permeability by application of 9-anthracene carboxylic acid (9-AC) resulted in an immediate rise in aCli and hyperpolarization. An aCli up to 40 mM higher, or eleven times higher, than that predicted by a passive distribution was recorded. Application of 9-AC after depletion of intracellular Cl- in Cl(-)-free solution had no effect on either the apparent aCli or Em. 5. It is concluded that Cl- ions are actively accumulated by the skeletal muscle fibre and that the Cl- distribution therefore normally exerts a depolarizing influence. 6. In the presence of 9-AC and nominal absence of CO2 and HCO3-, readdition of Cl-(o) to Cl(-)-depleted fibres resulted in a substantial rise in aCli and a small, maintained depolarization. This clear demonstration of active accumulation was used to investigate the mechanism responsible for inward transport of Cl- ions. 7. Neither application of CO2 and HCO3- nor application of DIDS (4,4'-diisothiocyanostilbene-2,2'-disulphonic acid) had any effect on the accumulation of Cl- ions. This suggests that Cl(-)-HCO3- exchange is not involved.(ABSTRACT TRUNCATED AT 400 WORDS)

Adaptation of sarcolemmal action potential mechanisms to chronic depolarization in denervated skeletal muscle

Action potential properties were studied in rat extensor digitorum longus fibers, at different times after locally setting the membrane to a holding potential of -90 mV. Whereas in normal muscles holding potential duration had little effect on the action potential, the holding potential duration markedly influenced membrane excitability in the fibers previously depolarized by increasing the K+ concentration of the bathing medium. In this case, when the holding potential was prolonged from 20 to 180 s, action potential overshoot, maximum rate of rise, and maximum rate of fall increased 1.8-, 3.1-, and 1.8-fold, respectively. In the denervated muscle, overshoot and maximum rate of fall were dependent on the duration of holding potential application until denervation day 6, whereas maximum rate of rise was affected throughout the duration of this study (15 days of denervation). However, 180-s application of -90 mV holding potential elicited about a 2-fold increase of maximum rate of rise in the earlier denervation stages, and only a 1.5-fold increase at later times. These observations suggest that ultra-slow processes of Na+ conductance inactivation were less effective after 6 days of denervation. Correspondingly, extensor digitorum longus fibers acquired the ability to generate action potentials at a depolarized holding potential. The partial removal of ultra-slow Na+ inactivation after muscle denervation could substantially contribute to a general process of membrane adaptation, resulting in the capacity of voltage-dependent ion channels to operate in a condition of chronic depolarization.

Role of sodium and potassium permeabilities in the depolarization of denervated rat muscle fibres

1. Na+ and K+ flux measurements and membrane potential (Vm) determinations were performed on normal and denervated rat extensor digitorum longus (e.d.l.) muscles. 2. The mean Vm in normal muscle fibres was -74.6 mV. During the first week after denervation Vm fell about 20 mV following an S-shaped time course. 3. In that period the Na+ permeability (PNa) increased and the K+ permeability (PK) decreased, so that by the sixth day post-denervation, the PNa/PK ratio was increased by a factor of 2.7. 4. The decrease in PK preceded the increase in PNa. 5. No major contribution to the fall of Vm by a reduced activity of an electrogenic Na+ pump could be detected. 6. A good agreement was found between the experimental values of the depolarization and those calculated using the constant-field equation assuming Cl- is at equilibrium and no significant change of the intracellular K+ concentration ([K+]i) during the first week after denervation. 7. It is concluded that the depolarization promoted by denervation in e.d.l. rat muscle fibres can be fully explained in terms of changes in PNa and PK.

A study on early post-denervation changes of non-quantal and quantal acetylcholine release in the rat diaphragm

The d-tubocurarine (dTC) induced hyperpolarization of antiesterase-treated muscles at the endplate zone, miniature endplate potentials (mepps), resting membrane potentials (RMPs) and the input resistances of single muscle fibres (Rin) were measured in rat diaphragm at various times after denervation. The dTC-induced hyperpolarization decreased in two phases: 2 h after denervation it decreased transiently to 25%, after 4 h it had partially recovered to 60% and from 6 h it progressively decreased up to 12 h after which time it changed to depolarization. The initial fall and recovery were also present in muscles from sham-operated animals. The frequency of mepps decreased by 25% and the amplitude diminished by 10% within the first 2-4 h. After 10 h the frequency had decreased by 35% and the amplitude by 65%. After 12 h no mepps were present. The RMP was not significantly changed during the first 16 h after denervation. From 16 to 24 h the membrane became depolarized at a rate of about 1 mV/h. The input resistance of a single muscle fibre was constant for 12 h after denervation and from 12 to 24 h it increased by 25%. It is concluded that the early decrease in the dTC-induced hyperpolarization is probably due to the desensitization of acetylcholine (ACh) receptors caused by stress-activated non-quantal ACh release. The later decrease of dTC-hyperpolarization reflects a fall in the non-quantal ACh release. The depolarization of the resting membrane after denervation is related to the decrease in passive membrane permeability which is a secondary consequence of transmission failure.(ABSTRACT TRUNCATED AT 250 WORDS)

Characteristics of a glutamine carrier in skeletal muscle have important consequences for nitrogen loss in injury, infection, and chronic disease

A carrier for glutamine, identified in rat muscle, has properties in terms of kinetics, ion dependence and hormone sensitivity, and effects of endotoxin and branched-chain aminoacids that point to an important function in the control of whole-body aminoacid metabolism. The existence of a link between the size of the glutamine pool in muscle and the rate of muscle protein synthesis raises possibilities for therapeutic interventions to limit protein loss in injury, sepsis, and chronic disease.

Effect of denervation during development upon membrane potential and intracellular potassium and sodium activities of skeletal muscle of the rat

Potassium and sodium ion-selective microelectrodes were used in vitro to investigate the effect of denervation of fast-twitch skeletal muscle (extensor digitorum longus) at 5 days of age upon subsequent development of the resting membrane potential. Normally, during the first 3 weeks of life the balance of intracellular potassium and sodium changed to elevate potassium and to lower sodium. These changes were reflected in the development of a more hyperpolarized resting membrane. Periods of denervation delayed, or prevented, the changes in ion activities and membrane hyperpolarization from occurring. The results are compared with those found after denervation of adult skeletal muscle.

Changes in membrane potential and potassium and sodium activities during postnatal development of mouse skeletal muscle

Dual-channel potassium-selective and single-channel sodium-selective microelectrodes were used to investigate the cause of changes in resting membrane potential of muscle fibers of the mouse during early development. The resting membrane of extensor digitorum longus fibers hyperpolarized during the postnatal period from -41.8 mV at 4 days of age to -76.4 mV at 27 days. During this period intracellular potassium activity increased by 42.1% from 82.5 mM at 8 days to 117.2 mM at 29 days. Intracellular sodium activity was high at 8 days, 23.7 mM, but decreased rapidly to adult values by 27 days when it was 9.98 mM, a 57.9% reduction in sodium activity. The time course of the change in resting membrane potential was different from that of the potassium equilibrium potential calculated from the data. If only potassium and sodium ions were to make significant contributions to the potential, then it was calculated that the permeability ratio PNa:PK would have to change from a value of 0.0659 at 8 days to 0.0227 at 27 days. The results indicated that other factors might be involved in generating the membrane potential inasmuch as, although both intracellular potassium and sodium activities did not change significantly after 27 to 30 days, the membrane potential had not attained adult values at that time. The possibility that increases in muscle activity during the postnatal period might initiate the changes in membrane polarization and intracellular ion activities is discussed together with possible complications in interpretation due to great variations in fiber diameters.

Changes in the ionic currents sensitivity to inhibitors in twitch rat skeletal muscles following denervation

Under voltage clamp conditions, using the double mannitol gap technique, ionic currents developed by fast (e.d.l.) and slow (soleus) twitch muscle fibers of the rat were analysed at different times following denervation and the results compared with those obtained in normal cells. In slow fibers, denervation caused the appearance of a new population of TTX-resistant Na+ channels (dissociation constant K2 = 2,800 nM) compared with the normal TTX-sensitive Na+ channels (K1 = 9 nM). This new population of Na channels appeared in 5 days and contributed about 32% of the total Na conductance. Denervated fast fibres developed a slow component in the delayed outward current which was found to be typical of slow innervated muscles. This component appeared 5 to 20 days after nerve section. These changes are associated with modifications of potassium channels' sensitivity for specific inhibitors (TEA and 4-AP). After denervation, the delayed outward current in the two types of muscles becomes resistant to 4-AP whereas TEA, which blocks the total delayed outward current in innervated fibers (dissociation constant of 21.4 mM) becomes more effective in blocking the fast component (dissociation constant of 0.61 mM) and less effective in blocking the slow component in denervated cells. The analysis of the characteristics of the TEA sensitive and TEA insensitive components of the outward current leads to the proposal that these components were related to the fast and to the slow components previously described in fast and slow twitch mammalian skeletal muscles.

Cellular ions in intact and denervated muscles of the rat

Tissue composition, membrane potentials and cellular activity of potassium, sodium and chloride have been measured in innervated and denervated rat skeletal muscles incubated in vitro. After denervation for 3 days, tissue water, sodium and chloride were increased but cellular potassium content and measured activity were little affected, despite a decrease of 16 mV in resting membrane potential which would have necessitated a decrease in cellular potassium activity of almost 50% were potassium distributed at electrochemical equilibrium. These findings, therefore, preclude a decreased electrochemical potential gradient for potassium as the cause of the membrane depolarization characteristic of denervated muscle fibers. Analysis of the data excludes an important contribution of rheogenic sodium transport to the resting potential of innervated muscles. These results strongly support the hypothesis that the decreased membrane potential in denervated fibers reflects a relative increase in the membrane permeability to sodium.

Effects of denervation on sodium, potassium and [3H]ouabain binding in muscles of normal and potassium-depleted rats

K depletion leads to a selective loss of K from skeletal muscles, which is associated with a decrease in the number of [3H]ouabain binding sites. The significance of the nerve supply for these changes has been assessed in denervation experiments with K-depleted rats. In K-depleted rats (age 4-12 weeks) denervation led to a partial recovery of the K contents in soleus (46-77%), gastrocnemius (23%) and extensor digitorum longus (e.d.l.) muscles (19%) within 24 h. These effects were not prevented by beta-adrenoceptor blockade or mimicked by alpha-adrenoceptor blockade. In K-depleted rats the number of [3H]ouabain binding sites was not increased following denervation. In K-depleted rats 24 h of plaster immobilization of the entire hind limb caused 51% recovery of the total K content in soleus, whereas gastrocnemius and e.d.l. showed 49 and 16% recovery, respectively. Tenotomy for 3 h caused a rise in total K content of 33% in soleus muscles from K-depleted rats. Anaesthesia for 3 h increased the total K content by 23%. The recovery of K induced by denervation, immobilization in plaster, tenotomy or anaesthesia was associated with an equivalent decrease in Na content. Denervation performed before K depletion reduced the loss of K from soleus, but not from gastrocnemius and e.d.l. In both soleus and e.d.l. the number of [3H]ouabain binding sites, however, decreased to the same level as in the contralateral innervated muscles. Denervation reduced, but did not prevent, the increase in the number of [3H]ouabain binding sites seen after re-administration of K to K-depleted rats. It is concluded that the changes in Na-K contents seen after denervation in K-depleted rats are the outcome of cessation of muscle activity. The results give no support to the idea that the effects of K depletion on the K content and the number of [3H]ouabain binding sites in skeletal muscle are mediated by the peripheral nerves.