The afterdepolarization in Rana temporaria muscle fibres following osmotic shock

Reciprocal dihydropyridine and ryanodine receptor interactions in skeletal muscle activation

Dihydropyridine (DHPR) and ryanodine receptors (RyRs) are central to transduction of transverse (T) tubular membrane depolarisation initiated by surface action potentials into release of sarcoplasmic reticular (SR) Ca2+ in skeletal muscle excitation-contraction coupling. Electronmicroscopic methods demonstrate an orderly positioning of such tubular DHPRs relative to RyRs in the SR at triad junctions where their membranes come into close proximity. Biochemical and genetic studies associated expression of specific, DHPR and RyR, isoforms with the particular excitation-contraction coupling processes and related elementary Ca2+ release events found respectively in skeletal and cardiac muscle. Physiological studies of intramembrane charge movements potentially related to voltage triggering of Ca2+ release demonstrated a particular qγ charging species identifiable with DHPRs through its T-tubular localization, pharmacological properties, and steep voltage-dependence paralleling Ca2+ release. Its nonlinear kinetics implicated highly co-operative conformational events in its transitions in response to voltage change. The effects of DHPR and RyR agonists and antagonists upon this intramembrane charge in turn implicated reciprocal rather than merely unidirectional DHPR-RyR interactions in these complex reactions. Thus, following membrane potential depolarization, an orthograde qγ-DHPR-RyR signaling likely initiates conformational alterations in the RyR with which it makes contact. The latter changes could then retrogradely promote further qγ-DHPR transitions through reciprocal co-operative allosteric interactions between receptors. These would relieve the resting constraints on both further, delayed, nonlinear qγ-DHPR charge transfers and on RyR-mediated Ca2+ release. They would also explain the more rapid charging and recovery qγ transients following larger depolarizations and membrane potential repolarization to the resting level.

Pathways of abnormal stress-induced Ca2+ influx into dystrophic mdx cardiomyocytes

In Duchenne muscular dystrophy, deficiency of the cytoskeletal protein dystrophin leads to well-described defects in skeletal muscle, but also to dilated cardiomyopathy, accounting for about 20% of the mortality. Mechanisms leading to cardiomyocyte cell death and cardiomyopathy are not well understood. One hypothesis suggests that the lack of dystrophin leads to membrane instability during mechanical stress and to activation of Ca2+ entry pathways. Using cardiomyocytes isolated from dystrophic mdx mice we dissected the contribution of various putative Ca2+ influx pathways with pharmacological tools. Cytosolic Ca2+ and Na+ signals as well as uptake of membrane impermeant compounds were monitored with fluorescent indicators using confocal microscopy and photometry. Membrane stress was applied as moderate osmotic challenges while membrane current was quantified using the whole-cell patch-clamp technique. Our findings suggest a major contribution of two primary Ca2+ influx pathways, stretch-activated membrane channels and short-lived microruptures. Furthermore, we found evidence for a secondary Ca2+ influx pathway, the Na+-Ca2+ exchange (NCX), which in cardiac muscle has a large transport capacity. After stress it contributes to Ca2+ entry in exchange for Na+ which had previously entered via primary stress-induced pathways, representing a previously not recognized mechanism contributing to subsequent cellular damage. This complexity needs to be considered when targeting abnormal Ca2+ influx as a treatment option for dystrophy.

Control of cell volume in skeletal muscle

Regulation of cell volume is a fundamental property of all animal cells and is of particular importance in skeletal muscle where exercise is associated with a wide range of cellular changes that would be expected to influence cell volume. These complex electrical, metabolic and osmotic changes, however, make rigorous study of the consequences of individual factors on muscle volume difficult despite their likely importance during exercise. Recent charge-difference modelling of cell volume distinguishes three major aspects to processes underlying cell volume control: (i) determination by intracellular impermeant solute; (ii) maintenance by metabolically dependent processes directly balancing passive solute and water fluxes that would otherwise cause cell swelling under the influence of intracellular membrane-impermeant solutes; and (iii) volume regulation often involving reversible short-term transmembrane solute transport processes correcting cell volumes towards their normal baselines in response to imposed discrete perturbations. This review covers, in turn, the main predictions from such quantitative analysis and the experimental consequences of comparable alterations in extracellular pH, lactate concentration, membrane potential and extracellular tonicity. The effects of such alterations in the extracellular environment in resting amphibian muscles are then used to reproduce the intracellular changes that occur in each case in exercising muscle. The relative contributions of these various factors to the control of cell volume in resting and exercising skeletal muscle are thus described.

Extracellular charge adsorption influences intracellular electrochemical homeostasis in amphibian skeletal muscle

The membrane potential measured by intracellular electrodes, E_m, is the sum of the transmembrane potential difference (E₁) between inner and outer cell membrane surfaces and a smaller potential difference (E₂) between a volume containing fixed charges on or near the outer membrane surface and the bulk extracellular space. This study investigates the influence of E₂ upon transmembrane ion fluxes, and hence cellular electrochemical homeostasis, using an integrative approach that combines computational and experimental methods. First, analytic equations were developed to calculate the influence of charges constrained within a three-dimensional glycocalyceal matrix enveloping the cell membrane outer surface upon local electrical potentials and ion concentrations. Electron microscopy confirmed predictions of these equations that extracellular charge adsorption influences glycocalyceal volume. Second, the novel analytic glycocalyx formulation was incorporated into the charge-difference cellular model of Fraser and Huang to simulate the influence of extracellular fixed charges upon intracellular ionic homeostasis. Experimental measurements of E_m supported the resulting predictions that an increased magnitude of extracellular fixed charge increases net transmembrane ionic leak currents, resulting in either a compensatory increase in Na⁺/K⁺-ATPase activity, or, in cells with reduced Na⁺/K⁺-ATPase activity, a partial dissipation of transmembrane ionic gradients and depolarization of E_m.

Membrane potentials in Rana temporaria muscle fibres in strongly hypertonic solutions

Conventional microelectrode methods were used to measure variations in resting membrane potentials, E(m), of intact amphibian skeletal muscle fibres over a wide range of increased extracellular tonicities produced by inclusion of varying extracellular concentrations of sucrose. Moderate increases in extracellular tonicity to up to 2.6x normal (2.6tau) under Cl(-) free conditions produced negative shifts in E(m) that followed expectations for the K(+) Nernst equation (E(K)) applied to a perfect osmometer containing a conserved intracellular K(+) content despite any accompanying cell volume change. In contrast, E(m) remained stable in fibres studied in otherwise similar Cl(-) containing solutions, consistent with E(m) stabilization despite negative shifts in E(K) through inward cation-Cl(-) co-transport activity. Short exposures to higher tonicities (>3tau) similarly produced negative shifts in E(m) in Cl(-) free but not Cl(-) containing solutions. However, prolonged exposures to solutions of >3tau caused gradual net positive changes in E (m) in both Cl(-) containing and Cl(-) free solutions suggesting that these changes were independent of cation-Cl(-) transport. Indeed, there was no evidence of cation-Cl(-) co-transport activity in strongly hypertonic solutions despite its predicted energetic favourability, suggesting its possible regulation by E (m) in muscle. Additional findings implicated a failure to maintain greatly increased transmembrane [K(+)] gradients in these E(m) changes. Thus: (1) halving or doubling [K(+)](e) produced negative or positive shifts in E(m), respectively in isotonic or moderately hypertonic (<2.7tau), but not strongly hypertonic (>3tau) solutions; (2) subsequent restoration of isotonic extracellular conditions produced further positive changes in E(m) consistent with a dilution of the depleted [K(+)](i) by fibres regaining their original resting volumes; (3) quantitative modelling similarly predicted a gradual net efflux of K(+) as the balance between active and passive [K(+)] fluxes altered due to increased transmembrane [K(+)] gradients in hypertonic and low [K(+)](e) solutions. However, the observed positive changes in E(m) in the most strongly hypertonic solutions eventually exceeded these predictions suggesting additional limitations on Na(+)/K(+)-ATPase activity in strongly hypertonic solutions.

Detubulation abolishes membrane potential stabilization in amphibian skeletal muscle

A recently reported stabilization ('splinting') of the resting membrane potential ( Em) observed in amphibian skeletal muscle fibres despite extracellular hyperosmotic challenge has been attributed to high resting ratios of membrane Cl- to K+ permeability ( P Cl/ P K) combined with elevations of their intracellular Cl- concentrations, [Cl-]i, above electrochemical equilibrium by diuretic-sensitive cation-Cl-, Na-Cl (NCC) and/or Na-K-2Cl (NKCC), co-transporter activity. The present experiments localized this co-transporter activity by investigating the effects of established detubulation procedures on Em splinting. They exposed fibres to introduction and subsequent withdrawal of 400 mM extracellular glycerol, high divalent cation concentrations, and cooling. An abolition of tubular access of extracellularly added lissamine rhodamine fluorescence, visualized by confocal microscopy, and of the action potential afterdepolarization together confirmed successful transverse (T-) tubular detachment. Fibre volumes, V , of such detubulated fibres, determined using recently introduced confocal microscope-scanning methods, retained the simple dependence upon 1/[extracellular osmolarity], without significant evidence of the regulatory volume increases described in other cell types, previously established in intact fibres. However detubulation abolished the Em splinting shown by intact fibres. Em thus varied with extracellular osmolarity in detubulated fibres studied in standard, Cl(-)-containing, Ringer solutions and conformed to simple predictions from such changes in assuming that intracellular ion content was conserved and membrane potential change DeltaEm was principally determined by the K+ Nernst potential. Furthermore, cation--Cl- co-transport block brought about by [Cl-]o or [Na+]o deprivation, or inclusion of bumetanide (10 microM) and chlorothiazide (10 microM) in the extracellular fluid gave similar results. When taken together with previous reports of significant Cl- conductances in the surface membrane, these findings suggest a model that contrastingly suggests a T-tubular location for cation--Cl- co-transporter activity or its regulation.

Slow volume transients in amphibian skeletal muscle fibres studied in hypotonic solutions

The influence of extracellular hypotonicity on the relationship between cell volume (V(c)) and resting membrane potential (E(m)) was investigated in Rana temporaria skeletal muscle. V(c) was measured by confocal microscope imaging of fibres through their transverse (xz) planes, and E(m) was determined using standard microelectrode techniques. Hypotonic solutions first elicited a rapid increase in fibre volume, DeltaV(R+) that fulfilled expectations of simple osmotic behaviour described in earlier reports. However, this was consistently followed by a slow increase in V(c) (DeltaV(S+)) to 10-15% above osmotic predictions. Longer (>1 h) exposures to hypotonic solutions permitted a subsequent slow decrease in V(c) (DeltaV(S-)), the eventual magnitude of which exceeded that of the preceding DeltaV(S+). Restoration of isotonic conditions elicited a prompt recovery in V(c) that matched simple osmotic predictions and thus left a net change in V(c). Such alterations in V(c) attributable to DeltaV(S+) then gradually reversed, while those due to DeltaV(S-) persisted. Both DeltaV(S+) and DeltaV(S-) persisted under conditions of Cl- deprivation. The depolarization of E(m) that accompanied DeltaV(R+) was consistent with dilution of intracellular [K(+)]. E(m) did not significantly alter during the subsequent DeltaV(S) transients. These empirical features of DeltaV(S+) and DeltaV(S-) were analysed using the quantitative charge-difference model of Fraser and Huang, published in 2004. This attributed the DeltaV(S+) to an electroneutral increase in the effective osmotic activity of normally membrane-impermeant intracellular anions. In contrast, the DeltaV(S-) could only be explained by an efflux of such anions and was accordingly comparable to organic anion-dependent regulatory volume decreases reported in other cell types.

Membrane potential stabilization in amphibian skeletal muscle fibres in hypertonic solutions

This study investigated membrane transport mechanisms influencing relative changes in cell volume (V) and resting membrane potential (E(m)) following osmotic challenge in amphibian skeletal muscle fibres. It demonstrated a stabilization of E(m) despite cell shrinkage, which was attributable to elevation of intracellular [Cl(-)] above electrochemical equilibrium through Na(+)-Cl(-) and Na(+)-K(+)-2Cl(-) cotransporter action following exposures to extracellular hypertonicity. Fibre volumes (V) determined by confocal microscope x z - scanning of cutaneous pectoris muscle fibres varied linearly with [1/extracellular osmolarity], showing insignificant volume corrections, in fibres studied in Cl(-)-free, normal and Na(+)-free Ringer solutions and in the presence of bumetanide, chlorothiazide and ouabain. The observed volume changes following increases in extracellular tonicity were compared with microelectrode measurements of steady-state resting potentials (E(m)). Fibres in isotonic Cl(-)-free, normal and Na(+)-free Ringer solutions showed similar E(m) values consistent with previously reported permeability ratios P(Na)/P(K)(0.03-0.05) and P(Cl)/P(K) ( approximately 2.0) and intracellular [Na(+)], [K(+)] and [Cl(-)]. Increased extracellular osmolarities produced hyperpolarizing shifts in E(m) in fibres studied in Cl(-)-free Ringer solution consistent with the Goldman-Hodgkin-Katz (GHK) equation. In contrast, fibres exposed to hypertonic Ringer solutions of normal ionic composition showed no such E(m) shifts, suggesting a Cl(-)-dependent stabilization of membrane potential. This stabilization of E(m) was abolished by withdrawing extracellular Na(+) or by the combined presence of the Na(+)-Cl(-) cotransporter (NCC) inhibitor chlorothiazide (10 microM) and the Na(+)-K(+)-2Cl(-) cotransporter (NKCC) inhibitor bumetanide (10 microM), or the Na(+)-K(+)-ATPase inhibitor ouabain (1 or 10 microM) during alterations in extracellular osmolarity. Application of such agents after such increases in tonicity only produced a hyperpolarization after a time delay, as expected for passive Cl(-) equilibration. These findings suggest a model that implicates the NCC and/or NKCC in fluxes that maintain [Cl(-)](i) above its electrochemical equilibrium. Such splinting of [Cl(-)](i) in combination with the high P(Cl)/P(K) of skeletal muscle stabilizes E(m) despite volume changes produced by extracellular hypertonicity, but at the expense of a cellular capacity for regulatory volume increases (RVIs). In situations where P(Cl)/P(K) is low, the same co-transporters would instead permit RVIs but at the expense of a capacity to stabilize E(m).

Detubulation experiments localise delayed rectifier currents to the surface membrane of amphibian skeletal muscle fibres

Ionic currents in intact and detubulated frog sartorius muscle fibres were compared at room temperature using a loose-patch voltage clamp configuration in four experimental groups. The test fibres (i) were detubulated by a previously established osmotic shock protocol that involved the introduction and withdrawal of extracellular glycerol followed by exposure to Ca2+/Mg2+-Ringer solution and cooling. The control fibres were spared osmotic shock and (ii) simply studied in normal Ringer solution, (iii) exposed to 30 min of steady cooling to 9-10 degrees C before electrophysiological study or (iv) exposed to and studied in glycerol-Ringer solution. The presence or absence of detubulation was confirmed for all the experimental groups through assessing for the abolition or otherwise of the delayed after-depolarisation normally associated with action potential propagation into the transverse (T) tubules. All fibre groups showed similar resting potentials (-80 to -90 mV) thus ensuring consistent baseline voltages from which the voltage clamp steps were imposed. The intact muscle fibres in the three control groups (ii)-(iv) spared osmotic shock showed both inward Na+ and delayed rectifier outward (K+) currents. In contrast, patches from detubulated muscle fibres in the test group (i) showed only delayed outward currents, consistent with contrasting contributions to Na+ and K+ currents from regions of membrane affected or spared by the detubulation procedure. Nevertheless, the voltage dependence, maximum steady state amplitudes and timecourses of the delayed outward currents were conserved through all the experimental groups. These findings suggest that the surface as opposed to the tubular membrane contributes the greater part of the delayed rectifier current in amphibian skeletal muscle.

Separation of detubulation and vacuolation phenomena in amphibian skeletal muscle

Sartorius muscle fibres from cold-adapted Rana temporaria were exposed to variants of an established detubulation procedure (Koutsis et al. (1995) J Muscle Res Cell Motil 16, 519-528) to test the extent to which detubulation and tubular vacuolation phenomena could be separated using different conditions of osmotic shock. A control procedure was optimised to a 28-min exposure to 400 mM glycerol-Ringer. This was followed by a recovery step involving its replacement by a Ca2+/Mg(2+)-Ringer solution and steady cooling over 30 min from room temperature (approximately 18 degress C) to approximately 10 degress C, followed by the restoration of the normal Ringer solution. This procedure successfully abolished the action potential after-depolarisation component, reflecting a loss of tubular conduction ('detubulation') in 74.3 +/- 5.9% of the fibres studied. Omitting the cooling during the recovery step sharply reduced the incidence of detubulation. So did omitting either the high-[Ca2+] and/or [Mg2+] in the recovery solutions in test procedures, but to significantly different extents (P < 5%). Yet trapping of fluorescent Sulfhorhodamine B dye in 'closed' vacuoles persisted albeit with reduced proportions of fibre volume occupied by vacuoles. Furthermore, the variations in recovery conditions produced similar levels of vacuolation despite smaller vacuole sizes in the cooled fibres (P < 0.05). These findings demonstrate that fibre vacuolation and detubulation are phenomena that are potentially separable through varying the conditions of osmotic shock, with detubulation requiring significantly more stringent conditions than vacuolation.

Persistent tubular conduction in vacuolated amphibian skeletal muscle following osmotic shock

The transverse (T-)tubules primarily function in conducting the action potentials that initiate excitation contraction coupling in skeletal muscle but may additionally subserve longer-term roles in volume regulation, membrane fusion and other trafficking processes. Osmotic shock thus both electrically detaches the T-tubules from surface membrane ('detubulation') and produces tubular vacuolation. The present experiments separated these effects. An established, reference osmotic shock protocol that exposed muscles to Ca2+/Mg2+-Ringer and gradual cooling to 10 degrees C after 18 min in glycerol-Ringer accomplished significant detubulation (77.5+/-13.15%, mean +/- SEM; n = 4). In contrast, a test protocol conducted entirely at room temperature using Mg2+-rather than Ca2+/ Mg2+-Ringer yielded reduced (P < 0.05, post hoc Duncan's multiple range test) detubulation indices (1.67+/-1.67%, n = 6) statistically indistinguishable from findings in fibres spared osmotic shock. Yet both osmotic shocks caused a formation of closed vacuoles, demonstrated by Sulphorhodamine B trapping, that occupied statistically similar fractions of total fibre volume (reference procedure: 14.38+/-2.7%, n = 6; test procedure: 13.36+/-2.00%, n = 22) in turn higher than determinations in control fibres (P < 0.05). The findings reconcile reports associating detubulation with vacuolation in osmotically shocked muscle [S. Nik-Zainal et al. (1999) J Muscle Res Cell Motil 20: 45-53; K.N. Khan et al. (2000) J Muscle Res Cell Motil 21: 79-90] with the persistence of tubular electrical activity in extensively vacuolated amphibian fibres following fatigue [J. Lannergren and H. Westerblad (1987) Acta Physiol Scand 129: 311-318; J. Lannergren et al. (1999) J Muscle Res Cell Motil 20: 19-32]. Furthermore test protocols produced higher densities of open vacuoles (13.38+/-2.33%, n = 9) than did reference protocols (6.66+/-1.63%, n = 20) contrary to their possible involvement in the electrophysiological changes. Abolition of tubular electrophysiological activity thus either follows or is independent of tubular vacuolation whilst sharing some of its underlying osmotic mechanisms.

Normal conduction of surface action potentials in detubulated amphibian skeletal muscle fibres

1. The influence of the transverse (T) tubules on surface action potential conduction was investigated by comparing electrophysiological and confocal microscopic assessments of tubular changes in osmotically shocked and control fibres from frog sartorius muscle. 2. The membrane-impermeant fluorescent dye, di-8-ANEPPs spread readily from the bathing extracellular solution into the tubular membranes in control, intact fibres. Prior exposure of muscles to a hypertonic glycerol-Ringer solution, its replacement by an isotonic Ca(2+)-Mg(2+) Ringer solution and cooling sharply reduced such access. In contrast, dye application in the course of this osmotic shock procedure stained the large tubular vacuoles hitherto associated with successful muscle detubulation. 3. Conduction velocities in intact, control fibres (1.91 +/- 0.048 m s(-1), mean +/- S.E.M., n = 32 fibres) agreed with earlier values reported at room temperature (18-21 degrees C) and were unaffected by prior episodes of steady cooling to 8-10 degrees C (1.91 +/- 0.043 m s(-1), n = 30). 4. Cooling to 11.5 degrees C reduced these velocities (1.47 +/- 0.081 m s(-1), n = 25) but action potential waveforms still included early overshoots and the delayed after-depolarizations associated with tubular electrical activity. 5. In contrast, action potentials from cooled, superficial fibres in osmotically shocked muscles lacked after-depolarization phases implying tubular detachment. Their mean conduction velocities (1.62 +/- 0.169 m s(-1), n = 25) were not significantly altered from values obtained in untreated controls or in intact fibres in muscle similarly treated with glycerol, in direct contrast to earlier results. 6. Cooling produced similar reductions in maximum rates of voltage change dV/dt in action potentials from all fibre groups with lower rates of change shown by detubulated fibres. 7. Use of an antibody to a conserved epitope of the alpha-subunit of voltage-gated sodium channels suggested a concentration of sodium channels close to the mouths of the T tubules. 8. These electrophysiological and anatomical findings are consistent with a partial independence of electrical events in the transverse tubules from those responsible for the rapid conduction of surface regenerative activity. 9. The findings are discussed in terms of a partial separation of the electrical activity propagated over the surface membrane, from the initiation of propagated activity within the T tubules, by the triggering of the sodium channels clustered selectively around the mouths of the T tubules.

Reversible vacuolation of T-tubules in skeletal muscle: mechanisms and implications for cell biology

The majority of investigations of the transverse tubules (T-system) of skeletal muscle have been devoted to their role in excitation-contraction coupling, with particular reference to contact with the sarcoplasmic reticulum and the mechanism of Ca2- release. By contrast, this review is concerned with structural and functional aspects of the vacuolation of T-tubules. It covers experimental procedures used in reversible vacuolation induced by the efflux-influx of glycerol and other small nonelectrolytes, sugars, and ions. The characteristics of the phenomenon, associated alterations in muscle function, and the swelling of analogous structures in nonmuscle cells are considered. Possible functions of reversible vacuolation in water balance, transport, membrane repair, muscle pathology, and fatigue are considered, and the potential application of reversible vacuolation in the transfection of skeletal muscle is discussed. In relation to the possible mechanisms involved in reversible vacuolation, particular attention is given to the dynamic and structural aspects of the opening and closing of T-tubules, the origin of vacuolar membranes, and the localized character of tubular swelling.

Loop diuretics inhibit detubulation and vacuolation in amphibian muscle fibres exposed to osmotic shock

The effect of loop diuretics at concentrations known to influence cellular water entry coupled to Na-K-Cl co-transport, upon the vacuolation and detubulation following osmotic shock, was investigated in amphibian skeletal muscles. These were exposed to a glycerol-Ringer solution (18 min), an isotonic Ca2+/Mg2+ Ringer solution and cooling. Adding bumetanide (1.0 and 2.0 microM) to these solutions sharply reduced the incidence of detubulation, assessed by abolition or otherwise of action potential after-depolarisations, from 93.9 +/- 4.7% (n = 6) to 5.0 +/- 1.1% (n = 4: mean +/- SEM: 2.0 microM bumetanide). It dramatically reduced the number and fraction of muscle volume occupied by tubular vacuoles, measured using confocal microscopy, from 60.3 +/- 4.3% (n = 10) to 9.0 +/- 1.1% (n = 35). The incidence of large horseradish peroxidase-lined tubular vacuoles, viewed using electronmicroscopy, similarly was reduced with 2 microM bumetanide in the glycerol-Ringer solution. Bumetanide acted through cellular volume adjustments early in the detubulation protocol. Thus, it exerted its maximum effect when added to the glycerol-Ringer, rather than the Ca2+/Mg2+ Ringer solution. Furthermore, whereas fibre diameters measured using scanning electron microscopy returned to normal during glycerol treatment relative to those of control fibres left in isotonic Ringer, addition of 2.0 microM bumetanide in the glycerol Ringer left markedly smaller fibre diameters. Finally equipotent concentrations of the chemically distinct loop diuretics. furosemide and ethacrynic acid similarly influenced detubulation. These findings implicate Na-K-Cl co-transport in the water entry into muscle fibres that would be expected following introduction of extracellular glycerol. This might then enable the subsequent Na-K-ATPase dependent water extrusion that produces the tubular distension (vacuolation) and detachment (detubulation) following glycerol withdrawal, phenomena also observed in muscular dystrophy.

Cardiac glycosides inhibit detubulation in amphibian skeletal muscle fibres exposed to osmotic shock

It has recently been suggested that the 'vacuolation' of the transverse tubular system that follows the imposition of an osmotic shock is a component process in the eventual 'detubulation' of amphibian skeletal muscle. However, such a hypothesis requires net fluid transfers from the intracellular space into the lumina of the transverse tubules against the prevailing transmembrane osmotic gradients. The present experiments tested the effects of cardiac glycosides on the consequences of established osmotic protocols known reliably to achieve high levels of both detubulation and vacuolation in Rana temporaria sartorius muscle. Tubular isolation (detubulation) was assessed through electrophysiological observations of the abolition or otherwise of the after-depolarisation components of muscle action potentials. Vacuolation was assessed by stereological estimation of the volume fraction of muscle that was occupied by fluorescence-labelled vacuoles observed using confocal microscopy. Introduction of ouabain in the osmotic shock solutions sharply reduced such measures of vacuolation from 48.5 +/- 3.6% (mean +/- SEM; n = 70) to 12.1 +/- 2.7% (n = 190) of the total fibre volume. This was accompanied by sharp reductions in the incidence of detubulation (detubulation index reduced from 96.3 +/- 2.6% to 0.0 +/- 0.0%). The presence of ouabain was critical at the osmotic shock stage in the procedures at which the hypertonic glycerol-containing solutions were replaced by isotonic Ca(2+)-Mg(2+)-Ringer solutions. Finally, the alternative cardiac glycosides, strophanthidine and digoxin, exerted similar effects. These findings support a scheme in which the osmotic shock initiates a metabolically dependent fluid expulsion. This distends the transverse tubules into vacuoles that in turn lead to fibre detubulation.

The tubular vacuolation process in amphibian skeletal muscle

The exposure of amphibian muscle to osmotic shock through the introduction and subsequent withdrawal of extracellular glycerol causes 'vacuolation' in the transverse tubules. Such manoeuvres can also electrically isolate the transverse tubules from the surface ('detubulation'), particular if followed by exposures to high extracellular [Ca2+] and/or gradual cooling. This study explored factors influencing vacuolation in Rana temporaria sartorius muscle. Vacuole formation was detected using phase contrast microscopy and through the trapping or otherwise of lissamine rhodamine dye fluorescence within such vacuoles. The preparations were also examined using electron microscopy, for penetration into the transverse tubules and tubular vacuoles of extracellular horseradish peroxidase introduced following the osmotic procedures. These comparisons distinguished for he first time two types of vacuole, 'open' and 'closed', whose lumina were respectively continuous with or detached from the remaining extracellular space. The vacuoles formed closed to and between the Z-lines, but subsequently elongated along the longitudinal axis of the muscle fibres. This suggested an involvement of tubular membrane material; the latter appeared particularly concentrated around such Z-lines in the electron-micrograph stereopairs of thick longitudinal sections. 'Open' vacuoles formed following osmotic shock produced by extracellular glycerol withdrawal from a glycerol-loaded fibre at a stage when one would expect a net water entry to the intracellular space. This suggests that vacuole formation requires active fluid transport into the tubular lumina in response to fibre swelling. 'Closed' vacuoles only formed when the muscle was subsequently exposed to high extracellular [Ca/+] and/or gradual cooling following the initial osmotic shock. Their densities were similar to those shown by 'open' vacuoles in preparations not so treated, suggesting that both vacuole types resulted from a single process initiated by glycerol withdrawal. However, vacuole 'closure' took place well after formation of 'open' vacuoles, over 25 min after glycerol withdrawal. Its time course closely paralleled the development of detubulation reported recently. It was irreversible, in contrast to the reversibility of 'open' vacuole formation. These findings identify electrophysiological 'detubulation' of striated muscle with 'closure' of initially 'open' vacuoles. The reversible formation of open vacuoles is compatible with some normal membrane responses to some physiological stresses such as fatigue, whereas irreversible formation of closed vacuoles might only be expected in pathological situations as in dystrophic muscle.

Osmotic 'detubulation' in frog muscle arises from a reversible vacuolation process

Isolated Rana temporaria sartorius muscle fibres were subject to introduction and subsequent withdrawal of 400 mM extracellular glycerol, exposures to high divalent ion concentrations and then cooling. Tubular detachment was then assessed through changes in the action potential afterdepolarization. (1) The rapid (5-10 min) rather than slow cooling step (30 min) produced a gradual (30 min) development of detubulation arrested by the subsequent replacement of glycerol and reversed by addition of 350 mM sucrose. Such osmotic agents influenced neither resting potentials of intact or detubulated fibres nor action potentials in intact fibres. (2) Full tubular detachment was achieved by 40 min. Laser epifluorescence microscopy demonstrated an accompanying tubular vacuolation through its trapping of a Rhodamine dye. (3) Subsequent re-additions (at 10-80 min) of glycerol restored the afterdepolarization in 30% of detubulated fibres and correspondingly reduced vacuolation. Sustained (> 60 min) exposures to 350 mM sucrose, applied between 30-60 min, both reversed tubular isolation in 70% of detubulated fibres and abolished tubular vacuolation. Finally, results from transient (10-30 min) sucrose exposures resembled the consequences of sustained applications of glycerol, suggesting that detubulation and its reversal result from an osmotic mechanism. (4) Nevertheless, irreversible changes developed after 70-80 min in 70% of detubulated fibres, a process hastened by slow cooling steps in the initial osmotic stress. The present study thus correlates morphological and electrophysiological consequences of applying osmotic shock to skeletal muscle for the first time. It additionally differentiates reversible and irreversible components of detubulation. Finally, it suggests that detubulation results from the similarly reversible vacuolation observed under comparable osmotic conditions, and that such vacuolation can eventually lead to irreversible detubulation.