Contracture Coupling of Slow Striated Muscle in Non-Ionic Solutions and Replacement of Calcium, Sodium, and Potassium

The development of contracture related to changes of ionic environment (ionic contracture coupling) has been studied in the slowly responding fibers of frog skeletal muscle. When deprived of external ions for 30 minutes by use of solutions of sucrose, mannitol, or glucose, the slow skeletal muscle fibers, but not the fast, develop pronounced and easily reversible contractures. Partial replacement of the non-ionic substance with calcium or sodium reduces the development of the contractures but replacement by potassium does not. The concentration of calcium necessary to prevent contracture induced by a non-ionic solution is greater than that needed to maintain relaxation in ionic solutions. To suppress the non-ionic-induced contractures to the same extent as does calcium requires several fold higher concentrations of sodium. Two types of ionic contracture coupling occur in slow type striated muscle fibers: (a) a calcium deprivation type which develops maximally at full physiological concentration of external sodium, shows a flow rate dependency for the calcium-depriving fluid, and is lessened when the sodium concentration is decreased by replacement with sucrose; (b) a sodium deprivation type which occurs maximally without external sodium, is lessened by increasing the sodium concentration, and has no flow rate dependency for ion deprivation. Both types of contracture are largely prevented by the presence of sufficient calcium. There thus seem to be calcium- and sodium-linked processes at work in the ionic contracture coupling of slow striated muscle.     

Nitrendipine blocks high potassium contractures but not twitches in rat skeletal muscle

The effects of the organic calcium channel blocker nitrendipine was tested on electrically evoked twitches and on potassium depolarization-induced contractures of rat lumbricalis muscles. Nitrendipine (10(-7) to 5 X 10(-5) M) blocked only the potassium contractures. It was concluded that blocking calcium uptake through the slow voltage-sensitive calcium channels during potassium depolarization blocks the mechanical response of the muscle. Thus extracellular calcium ions are required for the excitation-contraction (E-C) coupling during depolarization contractures. On the other hand, electrically evoked twitches were not affected by nitrendipine; therefore, extracellular calcium ions entering via the slow voltage-sensitive channels are not required for E-C coupling during the twitch.     

Contractile effects of 4-aminopyridine on isolated frog rectus abdominis muscles

The contractile effects of 4-aminopyridine (4-AP) on isolated frog rectus abdominis muscles were examined, and compared with KCl-induced contractures. 4-AP (1-40 mM) caused slowly developing, concentration-dependent contractures which were not modified by (+)-tubocurarine (2.7-13.3 microM). The contractures were prolonged and very slowly relaxed (greater than 30 min) on washout. KCl-induced contractures developed more rapidly and relaxation was equally rapid, both occurring within 90 s of application and washout, respectively. KCl contractures were slightly but significantly (P less than 0.05) attenuated by (+)-tubocurarine in concentrations that blocked carbachol contractures. In calcium-free Ringer's solution, KCl (10-120 mM) responses were completely abolished, but 4-AP concentration-response curves were shifted to the right three- to four-fold. The results show that 4-AP causes contracture of the frog rectus abdominis. It is suggested that at the lower concentration employed (less than 10 mM), 4-AP increases extracellular calcium entry into the muscle, while larger concentrations produce contractures by a direct intracellular mechanism. 4-AP contractures were independent of postjunctional nicotinic cholinoceptor activation.     

The role of calcium in excitation-contraction coupling of lobster muscle

Potassium contractures were induced in lobster muscle bundles under conditions which produced varying KCl fluxes into the fibers. The presence or absence of chloride fluxes during depolarization by high concentrations of potassium, had no effect on the tensions developed. The curve relating tension to the membrane potential had a typical sigmoid shape with an apparent "threshold" for tension at -60 mv. Soaking the muscles in low (0.1 mM) calcium salines for 30 min completely eliminated the potassium contractures but the caffeine contractures were only slightly reduced under these conditions. The potassium contracture could be completely restored in less than 2 min by return of the calcium ions to the saline. Evidence is presented for independent, superficial, and deep calcium sites; the superficial sites appear to be involved in the coupling mechanisms associated with potassium contractures. These sites are highly selective for Ca⁺⁺, and attempts to substitute either Cd⁺⁺, Co⁺⁺, Mg⁺⁺, Ba⁺⁺, or Sr⁺⁺ for Ca⁺⁺ were unsuccessful. However, K⁺ appeared to compete with Ca⁺⁺ for these sites, and the evoked tension could be reduced by prestimulation of the muscle fibers with high K⁺ salines. The results of studies on the influx of ⁴⁵Ca during potassium contractures were compatible with the view of muscle activation by the entry of extracellular calcium.     

The Time Course of the Loss and Recovery of Contracture Ability in Frog Striated Muscle Following Exposure to Ca-Free Solutions

Using area under the contracture curve to quantitate contractures, the diffusion coefficient of calcium ions within the frog toe muscle during washout in a calcium-free solution and subsequent recovery after reintroduction of calcium to the bathing solution was calculated to be about 2 x 10^-6 cm²/sec. The diffusion coefficient measured during washout was found to be independent of temperature or initial calcium ion concentration. During recovery it was found to decrease if the temperature was lowered. This was likely due to the repolarization occurring after the depolarizing effect of the calcium-free solution. The relation between contracture area and [Ca]_o was found to be useful over a wider range than that between maximum tension and [Ca]_o. The normalized contracture areas were larger at lower calcium concentrations if the contractures were produced with cold potassium solutions or if NO₃ replaced Cl in the bathing solutions. Decreasing the potassium concentration of the contracture solution to 50 mM from 115 mM did not change the relation between [Ca]_o and the normalized area. If the K concentration of the bathing solution was increased, the areas were decreased at lower concentrations of Ca.     

Effects of External Calcium Deprivation on Single Muscle Fibers

Deprivation of external calcium causes sudden potentiation of the twitch response of single muscle fibers. The potentiation was 64 ± 8%. Potentiation is simultaneous with membrane depolarization occurring after Ca⁺⁺ removal. This depolarization amounted to 9 ± 2 mv. Ca⁺⁺ removal also alters the action potential. 3 min after calcium withdrawal, action potential amplitude fell by 36 ± 3 mv; maximum rates of rise and fall of the spike decreased by 55 ± 5 and 63 ± 5% respectively. Changes in shape of the A. P. differ from those seen with other potentiators of the twitch response, such as Zn⁺⁺. After short exposure to calcium-free media, potassium-induced contractures show potentiation of peak tension. The S-shaped curve relating potassium contracture tension to log [K]_o shifts to the left after such treatment. Calcium deprivation also increased the rate of relaxation of the contractures. This effect depends on the duration of calcium deprivation, and is probably related to the effect of calcium lack on the membrane. The change in relaxation occurred immediately after calcium deprivation, and was reversed by sudden readmission of calcium. Relaxation of twitch and tetanus responses also were affected by Ca lack, but not as rapidly as potassium contractures. The results suggest that external calcium is not directly involved in the process responsible for tension development, supporting the view that this process is mediated by translocation of intracellular calcium. The relaxation process, however, appears to be rapidly affected by deprivation of external calcium.     

Non-specific termination of simian virus 40 DNA replication.

Axial X-ray diffraction patterns have been studied from relaxed, contracted and rigor vertebrate striated muscles at different sarcomere lengths to determine which features of the patterns depend on the interaction of actin and myosin. The intensity of the myosin layer lines in a live, relaxed muscle is sometimes less in a stretched muscle than in the muscle at rest-length; the intensity depends not only on the sarcomere length but on the time that has elapsed since dissection of the muscle. The movement of cross-bridges giving rise to these intensity changes are not caused solely by the withdrawal of actin from the A-band.When a muscle contracts or passes into rigor many changes occur that are independent of the sarcomere length: the myosin layer lines decrease in intensity to about 30% of their initial value when the muscle contracts, and disappear completely when the muscle passes into rigor. Both in contracting and rigor muscles at all sarcomere lengths the spacings of the meridional reflections at 143 Å and 72 Å are 1% greater than from a live relaxed muscle at rest-length. It is deduced that the initial movement of cross-bridges from their positions in resting muscle does not depend on the interaction of each cross-bridge with actin, but on a conformational change in the backbone of the myosin filament: occurring as a result of activation. The possibility is discussed that the conformational change occurs because the myosin filament, like the actin filament, has an activation control mechanism. Finally, all the X-ray diffraction patterns are interpreted on a model in which the myosin filament can exist in one of two possible states: a relaxed state which gives a diffraction pattern with strong myosin layer lines and an axial spacing of 143.4 Å, and an activated state which gives no layer lines but a meridional spacing of 144.8 Å.     

Characteristics of functioning of electromechanical coupling in striated muscles of higher and lower vertebrates

A comparative pharmacological analysis of relative contributions of different signal transduction pathways in the activation of contraction (excitation-contraction coupling, ECC) in intact fast striated muscles of frog and lamprey was performed. It was found that the major mechanism responsible for the ECC in muscles of both animals is Ca2+ release from the sarcoplasmic reticulum through the ryanodine-sensitive channels. However, the ECC in lamprey muscle displays some important differences in the units of electromechanical coupling, which precede the calcium release from sarcoplasmic reticulum. The maximum contraction force in frog muscle develops during caffeine-induced contracture, which indicates that all Ca2+ stored in sarcoplasmic reticulum is released through ryanodine-sensitive channels. In contrast, in lamprey muscle, the maximum force develops not in response to high caffeine concentration, but in response to repetitive electrical stimulation. Hence, in addition to stores liberated by ryanodine-sensitive channels, some other sources of calcium ions should exist, which contribute to the contraction activation. A source of this additional Ca2+ ions can be external medium, because acetylcholine contracture is abolished in a calcium-free medium. In frog muscle, the acetylcholine contracture was abolished in a Na(+)-free solution. It was concluded that in frog muscle ECC can be triggered by changes in the transmembrane potential (depolarization-induced calcium release), while in lamprey muscle the entry of calcium ions into myoplasm as the trigger in ECC (calcium-induced calcium release). The lamprey muscle was found to be more resistant to tetrodotoxin and tetracaine, which is indicative of a role in the activation of contraction of tetrodotoxin-resistant Na+ and/or Ca2+ channels. It was concluded, that ECC mechanism in striated muscles of low vertebrates is not limited by the generally accepted scheme of depolarization-induced calcium release but can include some other schemes, which require the Ca2+ influx into the cell.     

Aminoacyl-tRNA synthetases: inter-site interaction as a possible proofreading mechanism

Smooth muscle cell energetics of taenia caeci during relaxation, activity and maximal contraction were investigated using ³¹P-NMR. In relaxed muscle obtained in calcium-free medium, [ATP], [phosphocreatine] and [sugar phosphate] were 4.4 mM, 7.7 mM and 2.8 mM, respectively. There was only a small difference in the energetics of spontaneously active and maximally contracted muscles, but under both conditions substantial changes occurred as compared with relaxed muscles. The internal pH in relaxed muscle was found to be 7.05, which acidified to 6.5 during contraction. The level of sugar phosphates was found to be not a limiting factor in energetics.     

The earliest form of C-protein expressed during striated muscle development is immunologically the same as cardiac-type C-protein

A monoclonal antibody (C-315) specific for cardiac-type C-protein was prepared and, in combination with other antibodies specific for fast and slow skeletal muscle C-proteins, it was used to investigate the expression of C-protein isoforms in developing striated muscle cells in vivo and in vitro. During embryonic development of skeletal muscles, a C-protein recognized by C-315 appeared first but only transiently, it being replaced subsequently by two other isoforms recognized by the antibodies to slow and fast skeletal muscle C-proteins in a fiber-type specific manner as previously demonstrated (Obinata et al. (1984) Develop. Biol. 101, 116-124). In contrast, only cardiac-type C-protein was detected in cardiac muscle throughout the developmental stages. When myogenesis in vitro was monitored using the same antibodies, C-315 binding appeared first in multinucleated myotubes as in vivo which was followed by the sequential expression of two other C-protein variants. The reactivity of C-315 as well as that of anti-slow and anti-fast skeletal C-protein antibodies persisted during muscle development in culture. Thus, this study demonstrates that the earliest form of C-protein expressed in striated muscles may either be a cardiac-type isoform or a unique embryonic protein containing an epitope in common with the adult cardiac-type protein, and that transitions of C-protein isoform expression characteristic of each fiber-type occur during muscle development in vivo but not in vitro.     

Studies of the halothane-cooling contractures of skeletal muscle

The characteristics of transient contractures elicited by rapid cooling of frog or mouse muscles perfused in vitro with solutions equilibrated with 0.5-2.0% halothane are reviewed. The data indicate that these halothane-cooling contractures are dose dependent and reproducible, and their amplitude is larger in muscles containing predominantly slow-twitch type fibers, such as the mouse soleus, than in muscles in which fast-twitch fibers predominate, such as the mouse extensor digitorum longus. The halothane-cooling contractures are potentiated in muscles exposed to succinylcholine. The effects of Ca2+-free solutions, of the local anesthetics procaine, procainamide, and lidocaine, and of the muscle relaxant dantrolene on the halothane-cooling contractures are consistent with the proposal that the halothane-cooling contractures result from synergistic effects of halothane and low temperature on Ca sequestration by the sarcoplasmic reticulum. Preliminary results from skinned rabbit muscle fibers support this proposal. The halothane concentrations required for the halothane-cooling contractures of isolated frog or mouse muscles are comparable with those observed in serum of patients during general anesthesia. Accordingly, fascicles dissected from muscle biopsies of patients under halothane anesthesia for programmed surgery develop large contractures when rapidly cooled. The amplitude of these halothane-cooling contractures declined with the time of perfusion of the muscle fascicles in vitro with halothane-free physiological solutions. It is suggested that the halothane-cooling contractures could be used as a simple experimental model for the investigation of the effects of halothane on Ca homeostasis and contractility in skeletal muscle and for study of drugs of potential use in the management of the contractures associated with the halothane-induced malignant hyperthermia syndrome.(ABSTRACT TRUNCATED AT 250 WORDS)     

Localization of the acetylcholine receptors in denervated muscles of rats.

ACh contractures of denervated lumbricalis muscles of rats were washed in Tris-methanesulfonate solutions and in sucrose solutions. The peak tension was diminished by about 80% following a 30 min exposure to solutions containing 400-600 mM glycerol when Tris solutions were used in the testing period, and by about 50% when sucrose solutions were used. The amplitude of the membrane potential changes provoked by ACh was decreased by about 36% following the glycerol treatment. The treatment had no effect on the ACh-induced 45Ca uptake of muscles. Electron microscopy of the glycerol-treated muscles showed widespread vacuolization apparently originating from swelling and disruption of the T system. It was concluded that ACh receptors which arise in the muscle membrane following nerve section are distributed in the external surface membrane and in the membranes of the T system.     

Caffeine- and Potassium-Induced Contractures of Frog Striated Muscle Fibers in Hypertonic Solutions

The effect of hypertonic solutions on the caffeine- and KCl-induced contractures of isolated fibers of frog skeletal muscle was tested. Hypertonic solutions, twice the normal osmotic strength, prepared by adding NaCl or sucrose, potentiate the caffeine-induced contractures. The fibers may develop tensions of 3.6 kg/cm² of fiber transverse section. The same hypertonic medium reduced the peak tension of KCl-induced contractures. Thus the hypertonic condition does not affect the contractile mechanism itself. These findings give further support to the view that the differential effect of hypertonic solution is on the excitation-contraction coupling mechanism. Extracellular calcium is not essentially required for the first few of a series of caffeine-induced contractures either in hypertonic or in isotonic solutions.     

Calcium dependency and the effect of calcium antagonists on molluscan proboscis smooth muscles from the whelk,Buccinum undatum

In all four proboscis muscles of the whelk Buccinum undatum, the potassium-induced depolarization response was acutely dependent upon extracellular calcium, being eliminated in calcium-free conditions. The responses to acetylcholine were found to be partly dependent upon intracellular calcium. Responses to the peptides phenylalanine-methionine-arginine-phenylalanine-NH₂ and phenylalanine-leucine-arginine-phenylalanine-NH₂ were much more resistant to calcium-free conditions and appeared to engage the excitation-contraction coupling mechanism by mobilizing stored intracellular calcium. Sucrose-gap studies of radular retractor muscles showed that the organic calcium “antagonist” nifedipine enhanced potassium-induced depolarization responses, initiating spike-like action potentials and associated fast twitch activity. The inorganic calcium antagonist gadolinium exerted concentration-dependent inhibitory actions on these muscles. Basal tonus and fast twitch activity in response to potassium-induced depolarization were eliminated as were the spike-like action potentials of the membrane electrical response. The inorganic calcium “antagonist” cadmium greatly enhanced potassium-induced contractures in all four muscles, and on its own it induced tonic force and fast twitches in all the muscles. It seems likely that cadmium may have displaced stored intracellular calcium to induce myofilament activation. While these molluscan smooth muscles appear to possess calcium channels with fast and slow characteristics, their behaviour and pharmacological manipulation is very different from their more well known mammalian transient and long-lasting channel counterparts.     

Ryanodine modification of cardiac muscle responses to potassium-free solutions. Evidence for inhibition of sarcoplasmic reticulum calcium release

To test whether ryanodine blocks the release of calcium from the sarcoplasmic reticulum in cardiac muscle, we examined its effects on the aftercontractions and transient depolarizations or transient inward currents developed by guinea pig papillary muscles and voltage-clamped calf cardiac Purkinje fibers in potassium-free solutions. Ryanodine (0.1-1.0 microM) abolished or prevented aftercontractions and transient depolarizations by the papillary muscles without affecting any of the other sequelae of potassium removal. In the presence of 4.7 mM potassium and at a stimulation rate of 1 Hz, ryanodine had only a small variable effect on papillary muscle force development and action potential characteristics. In calf Purkinje fibers, ryanodine (1 nM-1 microM) completely blocked the aftercontractions and transient inward currents without altering the steady state current-voltage relationship. Ryanodine also abolished the twitch in potassium-free solutions, but it enhanced the tonic force during depolarizing voltage- clamp steps. This latter effect was dependent on the combination of ryanodine and potassium-free solutions. The slow inward current was not blocked by 1 microM ryanodine, but ryanodine did appear to abolish an outward current that remained in the presence of 0.5 mM 4- aminopyridine. Our observations are consistent with the hypothesis that ryanodine, by inhibiting the release of calcium from the sarcoplasmic reticulum, prevents the oscillations in intracellular calcium that activate the transient inward currents and aftercontractions associated with calcium overload states.     

Functional deficits in skeletal muscle grafts

Individual skeletal muscle fibers degenerate and regenerate with minimal functional deficits. When whole skeletal muscles are grafted in rats or cats by standard grafting techniques, revascularization and reinnervation must occur spontaneously. Under these circumstances, contraction times and maximum velocities of shortening eventually return to control values, but a significant deficit is observed in maximum tetanic tension. Grafts made with anastomosis of nerves or with nerves left intact have smaller deficits in tension development than do standard grafts made without nerve repair. The measurement of contractile properties of single motor units in extensor digitorum longus (EDL) muscles and in EDL grafts in rats indicates that the decreased maximum tetanic tension of whole grafts is due to a 10-20% decrease in the maximum tetanic tension of individual motor units, whereas standard grafts also show a 40-45% decrease in the number of motor units. Compared with control values, the fatigability of 100-mg grafts in rats is decreased, whereas larger 3-g grafts in cats show an increased fatigability. The deficits observed in large grafts can be reduced, but not eliminated, by grafting with neurovascular anastomoses.     

Glycerol treatment in mammalian skeletal muscle

Summary Potassium (K-) contractures were recorded from slow-twitch (mouse soleus) and fast-twitch (mouse extensor digitorum longus (EDL) and rat sternomastoid) muscles. The mouse limb muscles responded to a maintained increase in external potassium concentration with a rapid increase in tension (fast contracture) which inactivated and was followed by a slow contracture. Rat sternomatoid muscles responded with fast contractures only. The threshold potassium concentration for contraction was higher in fast-twitch muscles than in soleus muscles, at 22 and at 37°C. After corrections had been made for the more rapid depolarization of soleus fibers, the threshold potential for soleus fiber contraction was 15 mV closer to the resting membrane potential than the threshold for fast-twitch fiber contraction. The K-contracture results were confirmed by two microelectrode voltage-clamp experiments. Activation of fast twitch fibers required depolarizing pulses that were 15 to 20 mV greater than the pulses required to activate soleus fibers. When the time courses of K-contractures were compared it was evident that inactivation with prolonged depolarization was much faster in the fast-twitch muscles than in the soleus muscles. The results suggest that the voltage dependence and kinetics of the process coupling T-tubule depolarization with calcium release from the sarcoplasmic reticulum may depend on fiber type in mammalian skeletal muscle.     

Enhanced permeability to sugar associated with muscle contraction. Studies of the role of Ca++

When contractures were induced in isolated frog sartorius muscles with 4 mM caffeine, there was an increase in permeability of the muscle cells to 3-methylglucose. This observation suggests that the changes in permeability to sugar that are known to occur in electrically stimulated muscles may not be intimately related to the depolarization phase of the tissue response. Contractures that were elicited by exposing the muscles to a high concentration of K+ were also associated with an increased permeability to sugar. As the concentration of 45Ca in the medium was raised, more 45Ca entered the muscles during potassium contractures, and the contractures lasted longer, in agreement with the observations of other investigators. There was also a greater change in permeability to sugar when potassium contractures were elicited in the presence of higher concentrations of Ca++. The possibility that the enhanced permeability to sugar may be related to changes in the intracellular concentration of Ca++ is discussed.     

Regulation of muscular contraction. Distribution of actin control and myosin control in the animal kingdom

The control systems regulating muscle contraction in approximately 100 organisms have been categorized. Both myosin control and actin control operate simultaneously in the majority of invertebrates tested. These include insects, chelicerates, most crustaceans, annelids, priapulids, nematodes, and some sipunculids. Single myosin control is present in the muscles of molluscs, brachiopods, echinoderms, echiuroids, and nemertine worms. Single actin control was found in the fast muscles of decapods, in mysidacea, in a single sipunculid species, and in vertebrate striated muscles. Classification is based on functional tests that include measurements of the calcium dependence of the actomyosin ATPase activity in the presence and the absence of purified rabbit actin and myosin. In addition, isolated thin filaments and myosins were also analyzed. Molluscs lack actin control since troponin is not present in sufficient quantities. Even though the functional tests indicate the complete lack of myosin control in vertebrate striated muscle, it is difficult to exclude unambiguously the in vivo existence of this regulation. Both control systems have been found in animals from phyla which evolved early. We cannot ascribe any simple correlation between ATPase activity, muscle structure, and regulatory mechanisms.     

Barium responsiveness of the rat aorta and femoral artery during pregnancy

The barium responses of isolated aortic strips and femoral arteries from non-pregnant and pregnant rats were investigated. Barium caused concentration-related increases in tension of vessels from both pregnant and non-pregnant rats. The concentration-response curves of femoral arteries from non-pregnant and 3 week pregnant rats were not different; however contractility and slopes of concentration-response lines for thracic aortas from 1, 2 and 3 week pregnant rats were significantly less than those of aortas from non-pregnant rats. In addition, barium caused rhythmic contractions to develop in both femoral arteries and aortas of 3 week pregnant rats more frequently than vessels from non-pregnant rats. Rhythmic contractions did not develop in aortas from 3 week pregnant rats rats in calcium-free Krebs. Since the effects of barium on the electrical and mechanical activity of various muscles have been postulated to be similar to and/or dependent on calcium, these results may indicate that changes in calcium sensitivity of vascular smooth muscle occur during pregnancy. Such changes may contribute to the blood flow redistribution and other cardiovascular adaptations of pregnancy.