Control of muscle contraction

Calcium signals recorded from cut frog twitch fibers containing antipyrylazo III

The Ca indicator antipyrylazo III was introduced into cut frog twitch fibers by diffusion (Maylie, J., M. Irving, N. L. Sizto, and W. K. Chandler. 1987. Journal of General Physiology. 89:41-81). Like arsenazo III, antipyrylazo III was largely bound to or sequestered by intracellular constituents; on average, a fraction 0.68 was so immobilized. After action potential stimulation, there was an early change in absorbance, with a wavelength dependence that nearly matched a cuvette Ca-difference spectrum. As with arsenazo III, this signal became prolonged as experiments progressed. In a freshly prepared cut fiber containing 0.3 mM indicator, the absorbance change had an average half-width of 10 ms at 18 degrees C. The peak amplitude of this Ca signal depended on the indicator concentration in a roughly parabolic manner, which is consistent with a 1:2 stoichiometry for Ca:indicator complexation and, for indicator concentrations less than or equal to 0.4 mM, constant peak free [Ca]. If all the antipyrylazo III inside a fiber can react normally with Ca, peak free [Ca] is 3 microM at 18 degrees C. If only freely diffusible indicator can react, the estimate is 42 microM. The true amplitude probably lies somewhere in between. The time course of Ca binding to intracellular buffers and of Ca release from the sarcoplasmic reticulum is estimated from the 3- and 42-microM myoplasmic [Ca] transients. After action potential stimulation, the release waveform is rapid and brief; its latency after the surface action potential is 2-3 ms and its half-width is 2-4 ms. This requires rapid coupling between the action potential in the transverse tubular system and Ca release from the sarcoplasmic reticulum. The peak fractional occupancy calculated for Ca-regulatory sites on troponin is 0.46 for the 3-microM transient and 0.93 for the 42-microM transient. During a 100-ms tetanus at 100 Hz, the corresponding fractional occupancies are 0.56 and 0.94. The low value of occupancy associated with the low-amplitude [Ca] calibration seems inconsistent with a brief tetanus being able to produce near-maximal activation (Blinks, J. R., R. Rudel, and S. R. Taylor. 1978. Journal of Physiology. 277:291-323; Lopez J. R., L. A. Wanck, and S. R. Taylor. 1981. Science. 214:47-82).

Interferon-beta inhibition of concanavalin A-stimulated calcium uptake and exchange in HeLa cells

Addition of the lectin concanavalin A (ConA) to HeLa-S3 tumor cells in culture stimulates calcium exchange and uptake. Pretreatment of the cells with interferon-beta (IFN-beta) at a concentration of 640 U/ml for 24 h markedly inhibits this ConA-stimulated calcium exchange and uptake, but not the basal level of calcium exchange. These findings suggest that a number of IFN effects on cell function may reflect an impaired ability of IFN-treated cells to respond to molecules such as growth factors and peptide hormones with increased calcium fluxes.

Lack of communication between LC2 light chain and the SH1 region of myosin S-1 studied by 19F-NMR

Myosin subfragment-1 (S-1) which contains the LC2 light chain has been labelled with fluorine to allow an 19F-NMR study of the coupling and energetics of structural changes in the myosin head. Two fluorine-containing reagents, N-4-(trifluoromethyl)phenyl iodoacetamide and N-3,5-di(trifluoromethyl)phenyl iodoacetamide, have been used to label the myosin heavy chain at the unusually reactive sulfhydryl-1 (SH1) position. The chemical shift of both reagents on S-1 is sensitive to a structural transition in the region of SH1 which occurs upon increasing the temperature from 0 degrees C to 35 degrees C. The midpoint of the transition in both papain and chymotryptic S-1 is at approximately 11 degrees C at pH 7 (0.1 M CKl). The temperature dependence of the chemical shift may be fit assuming a two-state equilibrium where delta G degree' (T) = 101-110T +0.386 T2 (where T is the temperature in Kelvin). Both delta H degree' (T) and delta S degree' (T) have a small temperature dependence from 0 to 35 degrees C: at 20 degrees C, delta H degree' (T) = -33 kcal/mol. delta S degree' (T) = -116 e.u. and delta Cp = -226 cal/mol per deg (pH 7.0, 0.1 M KCl). The NMR data indicate that the presence of the LC2 light chain in papain S-1 does not modify the structure of S-1 in the vicinity of SH1, nor does it modify the energetics of the structural transition from that seen in its absence with chymotryptic S-1. The presence of calcium which is bound by the LC2 of papain S-1 also does not alter the energetics of the transition. Thus it would appear that the LC2 light chain (on myosin S-1) does not participate in the two-state transition, nor does it interact strongly with regions of the heavy chain which participate in the transition.

Effects of partial extraction of troponin complex upon the tension-pCa relation in rabbit skeletal muscle. Further evidence that tension development involves cooperative effects within the thin filament

Partial extraction of troponin C (TnC) decreases the Ca2+ sensitivity of tension development in mammalian skinned muscle fibers (Moss, R. L., G. G. Giulian, and M. L. Greaser. 1985. Journal of General Physiology. 86:585), which suggests that Ca2+-activated tension development involves molecular cooperativity within the thin filament. This idea has been investigated further in the present study, in which Ca2+-insensitive activation of skinned fibers from rabbit psoas muscles was achieved by removing a small proportion of total troponin (Tn) complexes. Ca2+-activated isometric tension was measured at pCa values (i.e., -log[Ca2+]) between 6.7 and 4.5: (a) in control fiber segments, (b) in the same fibers after partial removal of Tn, and (c) after recombination of Tn. Tn removal was accomplished using contaminant protease activity found in preparations of LC2 from rabbit soleus muscle, and was quantitated using sodium dodecyl sulfate-polyacrylamide gel electrophoresis and scanning densitometry. Partial Tn removal resulted in the development of a Ca2+-insensitive active tension, which varied in amount depending on the duration of the extraction, and concomitant decreases in maximal Ca2+-activated tensions. In addition, the tension-pCa relation was shifted to higher pCa values by as much as 0.3 pCa unit after Tn extraction. Readdition of Tn to the fiber segments resulted in the reduction of tension in the relaxing solution to control values and in the return of the tension-pCa relation to its original position. Thus, continuous Ca2+-insensitive activation of randomly spaced functional groups increased the Ca2+ sensitivity of tension development in the remaining functional groups along the thin filament. In addition, the variation in Ca2+-insensitive active tension as a function of Tn content after extraction suggests that only one-third to one-half of the functional groups within a thin filament need to be activated for complete disinhibition of that filament to be achieved.

Some properties of the contractile system and sarcoplasmic reticulum of skinned slow fibres from Xenopus muscle

Properties of both the contractile system and the sarcoplasmic reticulum (s.r.) of slow fibres from the iliofibularis muscle of Xenopus laevis were examined by using 'skinned' preparations mainly at 4 degrees C and pH 7.0. The results were compared with those of skinned fast fibres. The contractile system was activated with various concentrations of alkaline earth metal ions and it was found that the sensitivity of the contractile system of slow fibres to Sr2+ and Ba2+ was much higher than that of fast fibres while their Ca2+ sensitivity was similar. Caffeine (20-50 mM) reversibly induced appreciable active steady contraction of the slow fibre with one-third to one-half maximal isometric tension in the practical absence of Ca2+ (in the presence of 40 mM-EGTA) at relatively high temperatures (10-20 degrees C). The speed of unloaded shortening of caffeine-activated skinned slow fibres in the absence of Ca2+ was not slow but even faster than fibres activated to the same isometric tension level with Ca2+. When the s.r. of a skinned slow fibre was loaded with Ca2+ or Sr2+, 25 mM-caffeine caused transient contraction of the fibre due to a release of Ca2+ or Sr2+ from the s.r. The magnitude of such caffeine contracture was used as a quantitative indicator of the amount of Ca2+ or Sr2+ in the s.r. The dependence on [Ca2+] or [Sr2+] of the initial rate of Ca2+ or Sr2+ uptake by the empty s.r. of slow fibres was almost the same as that of fast fibres. In both types of fibres, a much higher concentration of Sr2+ than Ca2+ was required to activate the pump. When [Ca2+] outside the s.r. was sufficiently high (e.g. 10(-5) M), the maximum level to which the slow fibre s.r. could take up Ca2+ decreased, suggesting that the Ca2+-induced Ca2+ release mechanism also exists in slow fibre s.r. The rate of the Ca2+ leakage from slow fibre s.r. into the media without Ca2+ was higher than that from fast fibre s.r. In the absence of ATP, the enhancing effect of caffeine on the Ca2+-induced Ca2+ release mechanism was much weaker in slow fibres than in fast fibres, although adenosine-5'-monophosphate (AMP) enhanced it to a similar extent in both slow and fast fibres.(ABSTRACT TRUNCATED AT 400 WORDS)

The effect of low ATP concentrations on relaxation in the myosin regulated myofibrils from scallop

Troponin-tropomyosin-regulated myofibrils show a significant increase in ATPase activity and contract in the absence of calcium when the ATP concentration falls significantly below the saturation level. By contrast, the ATPase of the myosin-regulated myofibrils of scallop striated muscle was not activated in the absence of calcium when the ATP concentration was lowered to 10mM. Nevertheless, a very small fraction of crossbridges were active at 10mM ATP resulting in very slow myofibrillar shortening. In contrast to the behaviour of rabbit contractile proteins there was no correlation between myofibrillar shortening and ATP induced turbidity changes of actomyosin taken from scallop.

The time course of ATP cleavage by contracting amphibian and mammalian skeletal muscles

The pattern of energy liberation by tetanically stimulated muscle is reasonably well defined. The energy liberation and ATPase rate are affected by a variety of mechanical factors which, aside from the case of shortening mammalian muscles, are well documented. The amount of ATP consumed by processes associated with the calcium release and sequestration is not trivial, amounting to 30-40% of the energy liberation in an isometric contraction. The energy liberated by isometric and shortening muscles is ultimately accounted for by known chemical reactions. However, there are two instances in which the time course of energy liberation does not correspond to the time course of high energy phosphate utilization. In an isometric tetanus, 30-40 mJ of energy per gram of muscle is produced by reactions probably associated with intracellular circulation of calcium, but not immediately involving ATP hydrolysis. Second, in rapidly shortening muscles, an unknown reaction can produce 6-7 mJ of energy per gram of muscle which is not immediately associated with high energy phosphate splitting. However, immediately after the cessation of shortening, this reaction is reversed by an ATP hydrolysis. Finally, a technique is now available which permits one to perform transient kinetic studies on skinned muscle fibers which are shortening and/or developing force. This development should enable the design of experiments in which the effect of mechanical conditions upon specific steps of the ATPase mechanism can be examined.

The pathobiology of Dupuytren's contracture: effects of prostaglandins on myofibroblasts

The in vitro response of myofibroblasts to prostaglandins F2alpha (a vasoconstrictor) and E2 (a vasodilator) were evaluated in specimens obtained from the Dupuytren's nodules of 12 patients. Fibroblasts from four control samples of palmar fascia were similarly tested. This study demonstrated the ability of prostaglandin F2alpha to induce significant contraction of myofibroblasts. Prostaglandin E2 was noted to cause significant relaxation of myofibroblasts. The contractile/relaxation responses of control fibroblasts to these prostaglandins were minimal.

Neuromuscular transmission and its blockade. Pharmacology, monitoring and physiology updated

The role of two recently introduced muscle relaxants--atracurium and vecuronium--in contemporary anaesthetic practice is assessed. Recent advances in the physiology of neuromuscular transmission, particularly the roles of calcium and calmodulin, are reviewed, and new ideas concerning the reversal and monitoring of neuromuscular blockade are discussed.

Inositol 1,4,5-trisphosphate: a possible chemical link in excitation-contraction coupling in muscle

The role of inositol 1,4,5-trisphosphate (InsP3) in excitation-contraction coupling in skeletal muscle was investigated by several methods. The following results were obtained. InsP3 is released by electrical stimulation of muscles. Exogenous InsP3 releases calcium from skinned muscle fibers at relatively high doses under normal conditions but does so at very low concentrations when blockers of the InsP3 5-phosphatase are present. Blockers of InsP3 release are effective blockers of calcium transients elicited by electrical stimulation of muscle fibers. It is proposed that InsP3 acts as a chemical second messenger between transverse (T)-tubular membrane depolarization and calcium release from the sarcoplasmic reticulum in skeletal muscle.

Time-resolved x-ray diffraction studies of the sarcoplasmic reticulum membrane during active transport

X-ray and neutron diffraction studies of oriented multilayers of a highly purified fraction of isolated sarcoplasmic reticulum (SR) have previously provided the separate profile structures of the lipid bilayer and the Ca2+-ATPase molecule within the membrane profile to approximately 10-A resolution. These studies used biosynthetically deuterated SR phospholipids incorporated isomorphously into the isolated SR membranes via phospholipid transfer proteins. Time-resolved x-ray diffraction studies of these oriented SR membrane multilayers have detected significant changes in the membrane profile structure associated with phosphorylation of the Ca2+-ATPase within a single turnover of the Ca2+-transport cycle. These studies used the flash photolysis of caged ATP to effectively synchronize the ensemble of Ca2+-ATPase molecules in the multilayer, synchrotron x-radiation to provide 100-500-ms data collection times, and double-beam spectrophotometry to monitor the Ca2+-transport process directly in the oriented SR membrane multilayer.

Conformation of spin-labeled tropomyosin in reconstituted muscle thin filaments in response to calcium ion and heavy meromyosin

Tropomyosin (TM) exists in thermal equilibrium between a highly structured N state, a partially unfolded X state, and a completely unfolded D state, i.e., N in equilibrium X in equilibrium D. The strongly immobilized electron spin resonance (ESR) spectral component of spin-labeled TM corresponds to TM in the N state and the weakly immobilized component to TM in the X state below the main unfolding transition and to TM in the D state above this transition [Graceffa, P., & Lehrer, S. S. (1984) Biochemistry 23, 2606-2612]. The addition of actin, troponin (TN), and heavy meromyosin (HMM) to spin-labeled TM reduces the ratio of weakly to strongly immobilized labels, indicating a shift in the N in equilibrium X in equilibrium D equilibrium toward the N state. At 37 degrees C, for spin-labeled TM alone K (=X/N) greater than 1.0 with some TM in the D state, K = 0.8 for spin-labeled TM bound to actin, and K less than 0.05 for spin-labeled TM bound to actin + TN +/- Ca2+, actin + HMM + TN +/- Ca2+, and actin + HMM. Thus, actin + TN dramatically shifts the TM structure to the N conformation with little further effect upon addition of Ca2+ or HMM. The temperature at which spin-labeled TM begins to dissociate from a protein complex was determined from the temperature dependence of the ESR spectra.(ABSTRACT TRUNCATED AT 250 WORDS)

Malignant hyperthermia: molecular defects in membrane permeability

Malignant hyperthermia (MH), a genetically inherited disorder of skeletal muscle, is due to molecular defect in membrane permeability. The alteration in membrane permeability is suggested to be due to enhanced phospholipase A2 activity which is responsible for the increased level in sarcoplasmic Ca2+. The excess Ca2+ is responsible for muscle hyper-rigidity and enhanced rate of glycolysis, resulting in a rapid rate of lactic acid production and a low pH in MH muscle.

Muscle contraction and free energy transduction in biological systems

Muscle contraction occurs when the actin and myosin filaments in muscle are driven past each other by a cyclic interaction of adenosine triphosphate (ATP) and actin with cross-bridges that extend from myosin. Current biochemical studies suggest that, during each adenosine triphosphatase cycle, the myosin cross-bridge alternates between two main conformations, which differ markedly in their strength of binding to actin and in their overall structure. Binding of ATP to the cross-bridge induces the weak-binding conformation, whereas inorganic phosphate release returns the cross-bridge to the strong-binding conformation. This cross-bridge cycle is similar to the kinetic cycle that drives active transport and illustrates the general principles of free energy transduction by adenosine triphosphatase systems.

Multiple tropomyosin polypeptides in chicken embryo fibroblasts: differential repression of transcription by Rous sarcoma virus transformation

We have found that cytoskeletal extracts of cultured chicken embryo fibroblasts contain at least seven distinct polypeptides (two major and five minor) which cross-react with antiserum to chicken smooth muscle tropomyosin. These polypeptides range in apparent molecular weight from 31,000 to 47,000, and each is encoded by mRNAs which specifically hybridize to cloned muscle tropomyosin cDNAs. These nonmuscle tropomyosin species and their respective mRNAs are electrophoretically distinct from those of chicken skeletal muscle and appear by genomic DNA blotting to comprise a part of a multigene tropomyosin family. In Rous sarcoma virus-transformed chicken embryo fibroblasts, synthesis of the tropomyosins is differentially repressed such that the synthesis of the major species (cp35 and cp33, cytoskeletal proteins of molecular weight 35,000 and 33,000, respectively) and three minor species is drastically reduced, whereas the synthesis of two of the minor species (cp32 and cp31) remains essentially unchanged. Analysis of cellular mRNA and runoff nuclear transcription experiments indicate that the repression of tropomyosin synthesis by Rous sarcoma virus transformation occurs at the level of transcription. This repression of tropomyosin synthesis is partially mimicked in normal chicken embryo fibroblasts during incubation in high-NaCl medium, a condition in which chicken embryo fibroblasts acquire many characteristics of transformed cells.

Kinetic studies of Ca2+ release from sarcoplasmic reticulum of normal and malignant hyperthermia susceptible pig muscles

The time-course of Ca2+ release from sarcoplasmic reticulum isolated from muscles of normal pigs and those of pigs susceptible to malignant hyperthermia were investigated using stopped-flow spectrophotometry and arsenazo III as a Ca2+ indicator. Several methods were used to trigger Ca2+ release: (a) addition of halothane (e.g., 0.2 mM); (b) an increase of extravesicular Ca2+ concentration ([Ca2+0]); (c) a combination of (a) and (b), and (d) replacement of ions (potassium gluconate with choline chloride) to produce membrane depolarization. The initial rates of Ca2+ release induced by either halothane or Ca2+ alone, or both, are at least 70% higher in malignant hyperthermic sarcoplasmic reticulum than in normal. The amount of Ca2+ released by halothane at low [Ca2+0] in malignant hyperthermic sarcoplasmic reticulum is about twice as large as in normal sarcoplasmic reticulum. Membrane depolarization led to biphasic Ca2+ release in both malignant hyperthermic and normal sarcoplasmic reticulum, the rate constant of the rapid phase of Ca2+ release induced by membrane depolarization being significantly higher in malignant hyperthermic sarcoplasmic reticulum (k = 83 s-1) than in normal (k = 37 s-1). Thus, all types of Ca2+ release investigated (a, b, c and d) have higher rates in malignant hyperthermic sarcoplasmic reticulum than normal sarcoplasmic reticulum. These results suggest that the putative Ca2+ release channels located in the sarcoplasmic reticulum are altered in malignant hyperthermic sarcoplasmic reticulum.

Multiple tropomyosin polypeptides in chicken embryo fibroblasts: differential repression of transcription by Rous sarcoma virus transformation

We have found that cytoskeletal extracts of cultured chicken embryo fibroblasts contain at least seven distinct polypeptides (two major and five minor) which cross-react with antiserum to chicken smooth muscle tropomyosin. These polypeptides range in apparent molecular weight from 31,000 to 47,000, and each is encoded by mRNAs which specifically hybridize to cloned muscle tropomyosin cDNAs. These nonmuscle tropomyosin species and their respective mRNAs are electrophoretically distinct from those of chicken skeletal muscle and appear by genomic DNA blotting to comprise a part of a multigene tropomyosin family. In Rous sarcoma virus-transformed chicken embryo fibroblasts, synthesis of the tropomyosins is differentially repressed such that the synthesis of the major species (cp35 and cp33, cytoskeletal proteins of molecular weight 35,000 and 33,000, respectively) and three minor species is drastically reduced, whereas the synthesis of two of the minor species (cp32 and cp31) remains essentially unchanged. Analysis of cellular mRNA and runoff nuclear transcription experiments indicate that the repression of tropomyosin synthesis by Rous sarcoma virus transformation occurs at the level of transcription. This repression of tropomyosin synthesis is partially mimicked in normal chicken embryo fibroblasts during incubation in high-NaCl medium, a condition in which chicken embryo fibroblasts acquire many characteristics of transformed cells.

The expression of multiple forms of troponin T in chicken-fast-skeletal muscle may result from differential splicing of a single gene

Troponin T isolated from chicken fast skeletal muscle has been shown to be present in three different molecular forms, one in breast and two in leg muscle. The three forms differ in both size and charge. Troponin T from breast muscle has a molecular mass of 33.5 kDa and a pI of about 7. Of the two leg muscle forms the larger has a molecular mass of 30.5 kDa and a pI of about 8.5 and the smaller a molecular mass of 29.8 kDa and a pI of about 10. Considerably more heterogeneity has been found in the leg than in the breast muscle proteins although this is not reflected in their N-terminal sequences. The reason for this is not clear. Troponin T from breast or leg muscle can be phosphorylated with troponin T kinase at the single serine residue at the N-terminus. No difference in the rate or extent of phosphorylation could be found between proteins from breast or leg muscle. The three proteins have been shown to differ only in the amino acid sequence of their N-terminal tryptic peptides. These peptides are of different length, that from breast troponin T being 58 residues and those from leg troponin T being 36 and 42 residues, these differences account for the difference in molecular mass of the parent proteins. Despite this difference the sequence of the first 12 and last 14 residues is identical in all three N-terminal peptides. The remainder of the sequence of the smallest peptide is also repeated in the other two but they each contain an extra piece of unique sequence. On the basis of these sequences it is proposed that chicken troponin T is coded for by a single gene containing, at the 5' end, a number of small exons and that three different mRNA molecules may be produced by alternative pathways of RNA splicing. The possible significance of these N-terminal sequence variations is discussed.

Development of force-velocity relation and rise of isometric tetanic tension measure the time course of different processes

The time course of the contractile process was investigated in the presence of AR-L 115BS, a twitch potentiator which is thought to increase the rate of the Ca2+ binding by troponin and to improve the Ca2+ mobilization from the sarcoplasmic reticulum. AR-L 115BS increased markedly the rate of development of the force-velocity (T-V) relation and of the isometric tetanic tension. The effect on the rate of development of the T-V relation was however substantially more intense than that on the speed of rise of tetanic tension, thus reducing considerably the isometric tension level at which the T-V relation attained its final characteristics. The velocity of shortening under zero load and the degree of curvature of the T-V relation were not affected by AR-L 115BS. These findings support the view that the development of the T-V relation and the rise of the isometric tetanic tension measure the time course of two different processes.

Dynamic equilibrium between the two conformational states of spin-labeled tropomyosin

Tropomyosin was labeled with a maleimide nitroxide spin-label attached to cysteine-190 via a succinimido ring which was subsequently opened by incubation at alkaline pH. Electron spin resonance (ESR) spectra showed a temperature-dependent equilibrium, below the main unfolding transition of tropomyosin, between labels which were restricted in their motion (strongly immobilized), predominating at low temperatures, and those which were highly mobile (weakly immobilized), predominating at higher temperatures. These label states were associated with two protein states from a comparison of the ESR spectral changes with the thermal unfolding profile of tropomyosin. The strongly immobilized labels were associated with the completely folded molded and the weakly immobilized labels with a partially unfolded (in the cysteine-190 region) state which is an intermediate in the thermal unfolding of tropomyosin. A spectral subtraction technique was used to measure the concentration ratio of strongly and weakly immobilized labels from which an equilibrium constant, K, was determined at different temperatures. A linear van't Hoff plot was obtained, indicating that the spin-labeled protein is in thermal equilibrium between these two conformational states with delta H = 17 kcal/mol, delta S = 56 cal/(deg X mol), and K = 1.0 at 34 degrees C. An upper limit of 10(7) s-1 for the conformational fluctuation was estimated from the shapes and separation of the two ESR spectral components. In contrast to the label with the opened succinimido ring, the spin-label with an intact succinimido ring remained strongly immobilized on the protein, indicating that in the partially unfolded state the molecule retains structure in the cysteine-190 region.

Model of calcium movements during activation in the sarcomere of frog skeletal muscle

A model of calcium movement during activation of frog skeletal muscle is described. The model was based on the half sarcomere of a myofibril and included compartments representing the terminal cisternae, the longitudinal sarcoplasmic reticulum, the extramyofibrillar space, and the myofibrillar space. The calcium-binding proteins troponin, parvalbumin, and calsequestrin were present in appropriate locations and with realistic binding kinetics. During activation a time-dependent permeability in the terminal cisternal wall led to calcium release into the myoplasm and its diffusion through the myoplasm longitudinally and radially was computed. After adjustment of three parameters, the model produced a myoplasmic free-calcium concentration that was very similar to those recorded experimentally with calcium indicators. The model has been used to demonstrate the importance of parvalbumin in the relaxation of skeletal muscle, to describe the time course and magnitude of calcium gradients associated with diffusion across the sarcomere, and to estimate the errors associated with the use of aequorin as an intracellular calcium indicator in muscle.

Contraction of rabbit skinned skeletal muscle fibers at low levels of magnesium adenosine triphosphate

The contractile properties of skinned single fibers from rabbit psoas muscle were investigated under conditions of low MgATP and no Ca2+ (i.e., less than 10(-8) M). At 1 microM MgATP, fibers shortened at a maximum velocity of 660 +/- 420 A/half sarcomere/s (n = 9), compared with 34,000 A/half sarcomere/s measured during maximum Ca2+-activation at 1 mM MgATP (Moss, R. L., 1982. J. Muscle Res. Cell. Motil ., 3:295-311). The observed dependence of Vmax on pMgATP between 7.0 and 5.3 was similar to that of actomyosin ATPase measured previously by Weber, A., R. Herz , and I. Reiss (1969, Biochemistry, 8:2266-2270). Isometric tension was found to vary with pMgATP in a manner much like that reported by Reuben , J. P., P. W. Brandt, M. Berman , and H. Grundfest (J. Gen. Physiol. 1971. 57:385-407). A simple cross-bridge model was developed to simulate contractile behaviour at both high and low levels of MgATP. It was found that the pMgATP dependence of Vmax and ATPase could be successfully modeled if the rate of detachment of the cross-bridge was made proportional to the concentration of MgATP. In the model, the similar dependence of Vmax and ATPase on pMgATP was derived from the fact that in this range of pMgATP every pass of a cross-bridge by an actin site resulted in an attachment-detachment cycle, and every such cycle caused hydrolysis of one molecule of ATP.

Stiffness of glycerinated rabbit psoas fibers in the rigor state. Filament-overlap relation

The stiffness of glycerinated rabbit psoas fibers in the rigor state was measured at various sarcomere lengths in order to determine the distribution of the sarcomere compliance between the cross-bridge and other structures. The stiffness was determined by measuring the tension increment at one end of a fiber segment while stretching the other end of the fiber. The contribution of the end compliance to the rigor segments was checked both by laser diffractometry of the sarcomere length change and by measuring the length dependence of the Young's modulus; the contribution was found to be small. The stiffness in the rigor state was constant at sarcomere lengths of 2.4 microns or less; at greater sarcomere lengths the stiffness, when corrected for the contribution of resting stiffness, scaled with the amount of overlap between the thick and thin filaments. These results suggest that the source of the sarcomere compliance of the rigor fiber at the full overlapping of filaments is mostly the cross-bridge compliance.

Phosphorylation of skeletal-muscle troponin I and troponin T by phospholipid-sensitive Ca2+-dependent protein kinase and its inhibition by troponin C and tropomyosin

Skeletal-muscle troponin I and troponin T were found to be rapidly phosphorylated by cardiac phospholipid-sensitive Ca2+-dependent protein kinase, with Km values of 6.66 and 0.13 microM respectively. Stoichiometric phosphorylation of skeletal troponin I (endogenous phosphate content 0.7 mol/mol) indicated that the Ca2+-dependent enzyme and cyclic AMP-dependent protein kinase incorporated 0.9 and 0.8 mol/mol respectively. The same experiments with skeletal troponin T (endogenous phosphate content 1.9 mol/mol) revealed a maximal phosphorylation of 2 mol/mol by the Ca2+-dependent enzyme, whereas the cyclic AMP-dependent enzyme was unable to phosphorylate troponin T. The Ca2+-dependent enzyme phosphorylated both serine and threonine residues in skeletal and cardiac troponin I or troponin T; the cyclic AMP-dependent enzyme, in comparison, phosphorylated only serine in skeletal and cardiac troponin I. Although an equimolar amount of skeletal or cardiac troponin C markedly inhibited (80-90%) phosphorylation of skeletal and cardiac troponin I by the Ca2+-dependent enzyme, these troponin C preparations inhibited only phosphorylation of skeletal troponin I, but not that of cardiac troponin I, by the cyclic AMP-dependent enzyme. Calmodulin and Ca2+-binding protein S-100a could mimic the inhibitory effect of troponin C. A tissue specificity appeared to exist for the skeletal troponin T-skeletal troponin C interaction. Inhibition of troponin T phosphorylation by an equimolar amount of troponin C was lower than that of troponin I phosphorylation; these findings might explain in part why troponin T was the major substrate for the Ca2+-dependent enzyme in the troponin complex. The present studies indicate that skeletal and cardiac troponin I and troponin T were effective substrates for phospholipid-sensitive Ca2+-dependent protein kinase, suggesting a potential involvement of this Ca2+-effector enzyme in the regulation of myofibrillar activity.

Thin filament proteins and thin filament-linked regulation of vertebrate muscle contraction

Recent developments in the field of myofibrillar proteins will be reviewed. Consideration will be given to the proteins that participate in the contractile process itself as well as to those involved in Ca-dependent regulation of striated (skeletal and cardiac) and smooth muscle. The relation of protein structure to function will be emphasized and the relation of various physiologically and histochemically defined fiber types to the proteins found in them will be discussed.

Ultrastructural localization of calsequestrin in rat skeletal muscle by immunoferritin labeling of ultrathin frozen sections

The ultrastructural localization of calsequestrin in rat skeletal muscle (gracilis) was determined by indirect immunoferritin labeling of ultrathin frozen sections. Calsequestrin was found in the lumen of transversely and longitudinally oriented terminal cisternae but was absent from most of the longitudinal sarcotubules and the fenestrated sarcoplasmic reticulum. Calsequestrin was occasionally observed in vesicular structures found in the central region of the I band. Since calsequestrin is believed to provide the major site of Ca2+ sequestration in the sarcoplasmic reticulum, the present results support the view that Ca2+, transported to the lumen of the sarcoplasmic reticulum, is preferentially sequestered in the terminal cisternae, but they also suggest that additional Ca2+ sequestration may occur near the center of the I band.

Sarcoplasmic reticulum calcium release in frog skeletal muscle fibres estimated from Arsenazo III calcium transients

Single twitch fibres, dissected from frog muscle, were injected with the metallochromic dye Arsenazo III. Changes in dye-related absorbance measured at 650 or 660 nm were used to estimate the time course of myoplasmic free [Ca2+] following either action potential stimulation or voltage-clamp depolarization (temperature, 15-17 degrees C). The amplitude of the Ca2+ transient decreased when fibres were stretched to sarcomere spacings approaching 4 microns. The effect appeared to be less marked in H2O Ringer than in D2O Ringer, where a reduction of about 40% was observed in going from 3.0 microns to 3.7-3.9 microns. In fibres heavily injected with dye (1.5-2.2 mM-dye) at least 0.1 mM-Ca2+ was complexed with Arsenazo III following a single action potential, implying that at least 0.1 mM-Ca2+ was released from the sarcoplasmic reticulum (s.r.) into the myoplasm. Computer simulations were carried out to estimate the flux of Ca2+ between the s.r. and myoplasm (in fibres containing no more that 0.8 mM-dye). The amounts and time courses of Ca2+ bound to the Ca2+-regulatory sites on troponin and to the Ca2+, Mg2+ sites on parvalbumin were estimated from the free [Ca2+] wave form and the law of mass action. In the computations the total myoplasmic [Ca2+] was taken as the total amount of Ca2+ existing either as free ion or as ion complexed with dye, troponin or parvalbumin. The time derivative of total myoplasmic [Ca2+] was used as an estimate of net Ca2+ flux (release minus uptake) from the s.r. into myoplasm. Rate constants for formation of cation: receptor complex were taken from published values. For the Ca2+-regulatory sites on troponin, three sets of rate constants, corresponding to two values of dissociation constant (0.2 and 2 microM) were used. Each set of three simulations was carried out both with and without parvalbumin. The simulations show that following action potential stimulation, 0.2-0.3 mM-Ca2+ enters the myoplasm from the s.r. The wave form of s.r. Ca2+ release is early and brief compared with the wave form of free [Ca2+]. Neither the selection of troponin rate constants nor the inclusion of parvalbumin has much effect on the shape of the release wave form; the main effect of varying these parameters is to change the magnitude. After the initial, rapid phase of Ca2+ release from the s.r. there is a longer, maintained period of Ca2+ uptake.(ABSTRACT TRUNCATED AT 400 WORDS)

Kinetic model for the interaction of myosin subfragment 1 with regulated actin

A one-dimensional kinetic Ising model is developed to describe the binding of myosin subfragment 1 (SF-1) to regulated actin. The model allows for cooperative interactions between individual actin sites with bound SF-1 ligands rather than assuming that groups of actin monomer sites change their state in a cooperative fashion. With the triplet closure approximation, the model yields a set of 16 independent differential (master) equations which may be solved numerically to yield the extent of binding as a function of time. The predictions of the model are compared with experiments on the transient binding of SF-1 to regulated actin in the presence of Ca2+ and in the absence of Ca2+ with varying amounts of SF-1 prebound to the actin filament and on the equilibrium binding of SF-1 X ADP to regulated actin in the absence of Ca2+. In all cases, the calculations fit the data to within the experimental errors. In the case of SF-1 X ADP, the results suggest that a repulsive interaction exists between adjacently bound SF-1 at the ends of two neighboring seven-site actin units.