Actin-activated Mg-ATPase activity of Dictyostelium myosin II. Effects of filament formation and heavy chain phosphorylation.

The actin-activated Mg-ATPase activities of unphosphorylated and heavy chain phosphorylated Dictyostelium myosin II and of a Dictyostelium myosin II heavy meromyosin (HMM) fragment were examined at different Mg2+ and KCl concentrations. The Mg-ATPase activity of HMM displayed a maximum rate, Vmax, of about 4.0/s and a Kapp (actin concentration required to achieve 1/2 Vmax) that increased from 8 to 300 microM as the KCl concentration increased from 0 to 120 mM. When assayed with greater than 5 mM Mg2+ and 0 mM KCl the unphosphorylated Dictyostelium myosin II yielded a Kapp of 0.25 microM and a Vmax of 2.8/s. At lower Mg2+ concentrations or with 50 mM KCl the data were not fit well by a single hyperbolic curve and Kapp increased to 25-100 microM. The increase in Kapp did not correlate with the loss of sedimentable filaments. At KCl concentrations above 100 mM Vmax increased to greater than 4/s. Heavy chain phosphorylated myosin (3.5 mol of phosphate/mol myosin) displayed a Vmax of about 5/s and a Kapp of 50 microM under all conditions tested. Thus, heavy chain phosphorylation inhibited the actin-activated Mg-ATPase activity of Dictyostelium myosin II in 5-10 mM Mg2+ and low ionic strength through an increase in Kapp.     

Chicken-gizzard actin. Interaction with skeletal-muscle myosin

Interaction of actin from chicken gizzard and from rabbit skeletal muscle with rabbit skeletal muscle myosin was compared by measuring the rate of superprecipitation, the activation of the Mg-ATPase and inhibition of K-ATPase activity of myosin and heavy meromyosin, and determination of binding of heavy meromyosin in the absence of ATP. Both the rate of superprecipitation of the hybrid actomyosin and the activation of myosin ATPase by gizzard actin are lower than those obtained with skeletal muscle actin. The activation of myosin Mg-ATPase by the two actin species also shows different dependence on substrate concentration: with gizzard actin the substrate inhibition starts at lower ATP concentration. The double-reciprocal plots of the Mg-ATPase activity of heavy meromyosin versus actin concentration yield the same value of the extrapolated ATPase activity at infinite actin concentration (V) for the two actins and nearly double the actin concentration needed to produce half-maximal activation (Kapp) in the case of gizzard actin. A corresponding difference in the abilities of the two actin species to inhibit the K-ATPase activity of heavy meromyosin in the absence of divalent cations was also observed. The results are discussed in terms of the effect of substitutions in the amino acid sequence of gizzard and skeletal muscle actins on their interaction with myosin.     

Quantitative studies on the polarization optical properties of striated muscle. I. Birefringence changes of rabbit psoas muscle in the transition from rigor to relaxed state

The changes in birefringence in the rigor to relax transition of single triton-extracted rabbit psoas muscle fibers have been investigated with quantitative polarized light techniques. The total birefringence of rest lenght fibers in rigor was (1.46 +/- 0.08) x 10(-3) and increased to (1.67 +/- 0.05) x 10(-3) after Mg-ATP relaxation. Pyrophosphate relaxation increased the total birefringence only slightly, whereas subsequent Mg-ATP relaxation elicited the maximum increase in birefringence. Changes in lattice spacing did not account for the total increase in birefrigence during relaxation. Moreover, the increase in total birefringence was attributable to increases in intrinsic birefringence as well as form birefringence. No change in birefringence was exhibited upon exposure to a relaxation solution after myosin extraction. Synthetic myosin filaments were prepared and treated with relaxation and rigor solutions. The negatively stained filaments treated with a rigor solution had gross irregular projections at either end, while the filaments treated with a relaxing solution were more spindle shaped. The results are compatible with the view that the subfragment-2 moieties of myosin angle away from the myosin aggregates (light meromyosin) to permit the attachment of the subfragment-1 moieties to actin.     

Temperature-dependent transitions of the myosin-product intermediate at 10 degrees during Mn(II)-ATP hydrolysis by myosin from rabbit psoas muscle.

The initial burst of Pi liberation during the hydrolysis of Mn(II)-ATP by heavy meromyosin from rabbit psoas muscle was investigated. Below 10 degrees, the initial burst of Pi liberation was inhibited by the pre-addition of ADP without any change in the steady-state activity, but it was not inhibited above 10 degrees. The burst size was about one mole per mole of heavy meromyosin. The initial burst of Pi liberation in Mg-ATP hydrolysis at 8 degrees, however, was not inhibited by the pre-addition of ADP. These results, obtained with psoas muscle heavy meromyosin, were almost the same as those obtained with heavy meromyosin from rabbit leg and back muscles (Hozumi and Tawada (1975) Biochim. Biophys. Acta 376, 1-12) and, therefore, indicate that in Mn-ATP above 10 degrees there is at the burst site a predominant myosin -product complex generated by ATP hydrolysis. Similarly, below 10 degrees there is a myosin-product complex identical with the one generated by adding ADP (and Pi) to myosin.     

Determination of quantitative parameters of the binding of F-protein (phosphofructokinase) with myosin and localization of binding sites on the myosin molecule

To determine the localization of F-protein binding sites on myosin, the interaction of F-protein with myosin and its proteolytic fragments in 0.1 M KCl, 10 mM K-phosphate pH 6.5 was studied, using sedimentation, electron microscopic and optical diffraction methods. Sedimentation experiments showed that F-protein binds to myosin and myosin rod rather than to light meromyosin or S-1. The F-protein binding to myosin and rod is of a similar character. The calculated values of the constants of F-protein binding to myosin and rod are 2.6 X 10(5) M-1 and 2.1 X 10(5) M-1, respectively. The binding sites are probably located on the subfragment-2 portion of the myosin molecule. The number of F-protein binding sites on myosin calculated per chain weight of 80 000 is 5 +/- 1. The sedimentation results were confirmed by electron microscopic data. F-protein does not bind to light meromyosin paracrystals, but decorates myosin and rod filaments with the interval of 14.3 nm regardless of whether F-protein is added before or after filamentogenesis. A comparison of optical diffraction patterns obtained from myosin and rod filaments with those from decorated ones revealed a marked enhancement of meridional reflection at (14.3 nm)-1 in the latter case.     

Difference between subfragment-1 and heavy meromyosin in their interaction with F-actin

To elucidate the difference between subfragment-1 and heavy meromyosin in their interaction with F-actin, we used limited tryptic digestion and cross-linking with 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide. The binding of actin to subfragment-1 lowers the susceptibility of the 50K-20K junction of its heavy chain to tryptic digestion. At a molar ratio of one actin to one subfragment-1, all the sites were gradually cleaved by trypsin whereas the sites were completely protected in the presence of a 2-fold molar excess of actin over subfragment-1. In the case of heavy meromyosin, nearly half of the sites were protected completely by the presence of an equimolar amount of actin to its heads suggesting that the two heads of heavy meromyosin bound actin in a different manner. The rate of the cross-linking reaction between subfragment-1 heavy chain and actin with 1-ethyl-3-[3-(dimethylamino) propyl]carbodiimide also depended on the molar ratio of actin to subfragment-1. The rate was maximum at a molar ratio of about 5 actin to 1 subfragment-1. When heavy meromyosin was cross-linked to actin, the maximum rate was observed at a molar ratio of about 3 actin to 1 heavy meromyosin head, the level being about 60% that for subfragment-1 and actin. It was suggested that the presence of the subfragment-2 portion of heavy meromyosin caused these differences by restricting the motion of the two heads.     

Active-site titration of enzymes at high concentration. Application to myosin ATPase

The number of active sites of soluble and filamentous myosin and of its subfragments, heavy meromyosin and subfragment-1, has been determined. The titration involves steady-state kinetic measurements at a high enzyme concentration and varying substrate concentrations (or vice versa), in the presence of a substrate-regenerating system. Some practical and theoretical conditions for its execution are given, and, in particular, the effect of a possible heterogeneity of the active sites on the titration curves is analysed. Under the experimental conditions of the study, the number of active sites is close to that of myosin heads, and the heads seem to be functionally identical; the catalytic constants kcat and Km characterizing each active site are similar within some limits (1-2 for the ratio of kcat values; 1-5 for that of Km values).     

The phosphorylated L2 light chain of skeletal myosin is a modifier of the actomyosin ATPase

Incubation of rabbit skeletal myosin with an extract of light chain kinase plus ATP phosphorylated the L2 light chain and modified the steady state kinetics of the actomyosin ATPase. With regulated actin, the ATPase activity of phosphorylated myosin (P-myosin) was 35 to 181% greater than that of unphosphorylated myosin when assayed with 0.05 to 5 micro M Ca2+. Phosphorylation had no effect on the Ca2+ concentration required for half-maximal activity, but it did increase the ATPase activity at low Ca2+. With pure actin, the percentage of increase in the actomyosin ATPase activity correlated with the percentage of phosphorylation of myosin. Steady state kinetic analyses of the actomyosin system indicated that 50 to 82% phosphorylation of myosin decreased significantly the Kapp of actin for myosin with no significant effect on the Vmax. Phosphorylaton of heavy meromyosin similarly modified the steady state kinetics of the acto-heavy meromyosin system. Both the K+/EDTA- and Mg-ATPase activities of P-myosin and phosphorylated heavy meromyosin were within normal limits indicating that phosphorylaiion had not altered significantly the hydrolytic site. Phosphatase treatment of P-myosin decreased both the level of phosphorylation of L2 and the actomyosin ATPase activity to control levels for unphosphorylated myosin. It is concluded levels for unphosphorylated myosin. It is concluded from these results that the ability of P-myosin to modify the steady state kinetics of the actomyosin ATPase was: 1) specific for phosphorylation; 2) independent of the thin filament regulatory proteins.     

Kinetics of steady state ATPase activity and rigor complex formation of acto-heavy meromyosin

1. Actin and heavy meromyosin, initially mixed in a Mg-ATP solution, began to form the rigor complex slowly after ATP in the solution had been completely hydrolyzed.

2. This was because the heavy meromyosin-product complex formed via ATP hydrolysis was almost completely dissociated from actin even in the absence of ATP and as soon as this heavy meromyosin-product complex was decomposed, the heavy meromyosin combined with actin forming the rigor complex.

3. Linear plots were obtained when the reciprocal of the excess rate of the actin-accelerated rigor complex formation was plotted against the reciprocal of the added actin concentration as similar with those made on the steady acto-heavy meromyosin ATPase.

4. The V of the rigor complex formation process was about 1/5 of that of the steady acto-heavy meromyosin ATPase activity, showing that the actomyosin ATPase activity could not be explained merely by the actin-accelerated decomposition of the heavy meromyosin-product complex.

5. The same analyses were carried out on myosin subfragment 1.

6. Our results could be explained by considering the two non-identical active sites of myosin, and we propose the following scheme for the actomyosin ATPase.

7. Actin accelerates the rate-limiting bond hydrolysis in the ATPase occurring at one active site of myosin, as well as the rate-limiting decomposition of the heavy meromyosin-product complex formed at another site.     

The mechanism of the skeletal muscle myosin ATPase. I. Identity of the myosin active sites.

In the present study, the question of whether the two myosin active sites are identical with respect to ATP binding and hydrolysis was reinvestigated. The stoichiometry of ATP binding to myosin, heavy meromyosin, and subfragment-1 was determined by measuring the fluorescence enhancement caused by the binding of MgATP. The amount of irreversible ATP binding and the magnitude of the initial ATP hydrolysis (initial Pi burst) was determined by measuring [gamma-32P]ATP hydrolysis with and without a cold ATP chase in a three-syringe quenched flow apparatus. The results show that, under a wide variety of experimental conditions: 1) the stoichiometry of ATP binding ranges from 0.8 to 1 mol of ATP/myosin active site for myosin, heavy meromyosin, and subfragment-1, 2) 80 to 100% of this ATP binding is irreversible, 3) 70 to 90% of the irreversibly bound ATP is hydrolyzed in the initial Pi burst, 4) the first order rate constant for the rate-limiting step in ATP hydrolysis by heavy meromyosin is equal to the steady state heavy meromyosin ATPase rate only if the latter is calculated on the basis of two active sites per heavy meromyosin molecule. It is concluded that the two active sites of myosin are identical with respect to ATP binding and hydrolysis.     

The modulatory effect of MgATP on heterotrimeric smooth muscle myosin phosphatase activity.

Regulation of the enzymatic activity of heterotrimeric smooth muscle myosin phosphatase (SMMP) by MgATP was examined using phosphorylated myosin (P-myosin), heavy meromyosin (P-HMM), subfragment-1 (P-S1), and 20 kDa myosin light chain (P-MLC(20)) as substrates. The activity toward P-myosin and P-HMM was dose-dependently reduced by MgATP, whereas that toward P-S1 or P-MLC(20) was unchanged. The reduction was mainly due to a decrease in the affinity of SMMP for the substrate with the unchanged maximum activity. This regulation is entirely new in the respect that the responsible molecule is the substrate, not SMMP. Because P-myosin derived from myosin stored in 50% glycerol at -20 degrees C was insensitive to MgATP, the proper integrity of P-myosin is required. Coexisting myosin did not affect this regulation, but it inhibited the SMMP activity in the absence of MgATP. With P-myosin, the enzyme activity was biphasically steeply dependent on the ionic strength. This requires that determinations are conducted with a fixed ionic strength. The Q(10) value was about 2, which was quite similar to that for myosin light chain kinase. These results suggest that the rate of dephosphorylation of P-myosin is lowered at rest, but that it may reach a value comparable to the rate of phosphorylation of myosin in the sarcoplasm with the increased level of P-myosin during muscle activation. This regulation by MgATP may underlie the "latch mechanism" in some respects.     

An enzyme-probe study of motile domains in the subfragment-2 region of myosin

The temperature-dependence of local melting within the subfragment-2 region of rabbit skeletal muscle myosin has been investigated using an enzyme-probe technique. Rate constants of fragmentation of two long subfragment-2 particles (61,000 Mr and 53,000 Mr per polypeptide chain) and a short subfragment-2 particle (34,000 Mr per polypeptide chain) by three different enzymes (alpha-chymotrypsin, trypsin and papain) have been determined over the temperature range 5 to 40 degrees C. We followed the time-course of digestion at specific sites at high (I = 0.50, pH 7.3) and low (physiological, I = 0.15, pH 7.3) ionic strengths by electrophoresis of the digestion products on sodium dodecyl sulfate-containing gels. All rate constants were corrected for the intrinsic temperature-dependence of the enzymes by comparison with model substrates. Normalized rate constant versus temperature profiles for the three enzyme-probes are similar in showing that local melting in long subfragment-2 (61,000 Mr) occurs in two distinct stages as was observed earlier for the intact myosin rod. Over the temperature range 5 to 25 degrees C a restricted region at Mr = 53,000 to 50,000 from the N terminus of the rod (the light meromyosin/heavy meromyosin junction) shows the highest susceptibility to proteolytic cleavage. At temperatures above 25 degrees C local melting was detected by all three enzymes at several specific sites within the hinge domain (Mr = 53,000 to 34,000). Activation energies for cleavage at the susceptible sites were similar for the three enzyme probes. They suggest that this region of the myosin rod has significantly lower thermal stability than the flanking light meromyosin and short subfragment-2 segments. These results, together with other physico-chemical studies, point to the hinge domain of the myosin cross-bridge as an important functional element in the mechanism of force generation in muscle.     

Analysis of the interaction of rabbit skeletal muscle adenylate deaminase with myosin subfragments. A kinetically regulated system

The interaction of rabbit skeletal muscle adenylate deaminase with myosin fragments (heavy meromyosin and subfragment-2) has been studied by analytical centrifugation, gel chromatography, and stopped flow light scattering. Formation of the complex is highly cooperative with respect to addition of two molecules of adenylate deaminase/molecule of myosin fragment to form a ternary complex. Ternary complex formation is also highly pH-dependent with less complex formed at higher pH values, and the pH dependence is steeper with heavy meromyosin than with subfragment-2. At pH 6.5, the dissociation constant for the heavy meromyosin-deaminase complex is approximately 1.2 X 10(-15) M2. Over the pH range 6.5-7.0, rate constants for the formation and dissociation of both the ternary and binary complexes of adenylate deaminase with heavy meromyosin have been determined. From analysis of the time course of stopped flow light scattering, the association steps are found to be extremely rapid, while the rate constant for dissociation of the first molecule of adenylate deaminase from the ternary complex is quite slow. This rate constant increases as the pH increased, but is sufficiently low that the interacting system does not equilibrate on the time scale of mass transport experiments (sedimentation velocity and gel chromatography), and thus displays apparent "slow" behavior. The kinetic regulatory properties of adenylate deaminase are influenced by heavy meromyosin and subfragment-2, particularly with respect to inhibition by GTP. The association and dissociation of adenylate deaminase and myosin fragments and the resultant changes in kinetic properties of the adenylate deaminase can markedly alter the time course of the enzymatic reaction. The time scale over which this interaction is modulated by changes in pH may have significance in the metabolism of exercising muscle.     

Acrylamide fluorescence quenching studies on the actin-induced change in protein dynamics in the subfragment-1/subfragment-2 link region of cardiac myosin

In order to obtain information about the actin-induced conformational change around the subfragment-1/subfragment-2 link region of myosin, measurements of the fluorescence quenching by acrylamide were made on cardiac myosin and its heavy meromyosin, in which the reactive lysyl residue located in the link region was labeled with an extrinsic fluorophore, the N-methyl-2-anilino-6-naphthalenesulfonyl group. The results with the model compound indicated the involvement of a collisional quenching mechanism for the fluorophore. The quenching rate constant calculated from measured quenching constants using available lifetime data was extremely low for the labeled myosin (0.59 X 10(8) M-1 . S-1), suggesting that the fluorophore bound to myosin is surrounded by segments of proteins. This value was independent of the solvent viscosity, indicating that the quenching reaction is limited by fluctuations in the protein matrix, which produce the inward movement of acrylamide. Chymotryptic digestion of the labeled myosin, which yielded the light chain-2-deficient heavy meromyosin, made the bound fluorophore slightly exposed. Addition of F-actin resulted in about 40% reduction in the quenching rate constants for the labeled myosin and heavy meromyosin. The actin effect was reversed by adding ATP. These results suggest that the binding of actin to myosin makes the protein matrix around the subfragment-1/subfragment-2 link region less mobile.     

Myosin and actomyosin from human skeletal muscle.

Human skeletal natural actomyosin contained actin, tropomyosin, troponin and myosin components as judged by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. Purified human myosin contained at least three light chains having molecular weights (+/-2000) of 25 000, 18 000 and 15 000. Inhibitory and calcium binding components of troponin were identified in an actin-tropomyosin-troponin complex extracted from acetone-dried muscle powder at 37 degrees C. Activation of the Mg-ATPase activity of Ca2+-sensitive human natural or reconstituted actomyosin was half maximal at approximately 3.4 muM Ca2+ concentration (CaEGTA binding constant equals 4.4 - 10(5) at pH 6.8). Subfragment 1, isolated from the human heavy meromyosin by digestion with papain, appeared as a single peak after DEAE-cellulose chromatography. In the pH 6-9 range, the Ca2+-ATPase activity of the subfragment 1 was 1.8- and 4-fold higher that the original heavy meromyosin and myosin, respectively. The ATPase activities of human myosin and its fragments were 6-10 fold lower than those of corresponding proteins from rabbit fast skeletal muscle. Human myosin lost approximately 60% of the Ca2+-ATPase activity at pH 9 without a concomitant change in the number of distribution of its light chains. These findings indicate that human skeletal muscle myosin resembles other slow and fast mammalian muscles. Regulation of human skeletal actomyosin by Ca2+ is similar to that of rabbit fast or slow muscle.     

The covalent modification of myosin's proteolytic fragments by a purine disulfide analog of adenosine triphosphate. Reaction at a binding site other than the active site.

A purine disulfide analog of ATP, 6,6'-dithiobis(inosinyl imidodiphosphate), forms mixed disulfide bonds between the 6 thiol group on the purine ring and certain key cysteines on myosin, heavy meromyosin, and subfragment one. The EDTA ATPase activities of myosin and heavy meromyosin were completely inactivated when 4 mol of thiopurine nucleotide was bound. When similarly inactivated, subfragment one, depending on its method of preparation, incorporated either 1 or 2 mol of thiopurine nucleotide. Modification of a single cysteine on subfragment one resulted in an inhibition of both the Ca2+ and the EDTA ATPase activities, but the latter always to a greater extent. Modification of two cysteines per head of heavy meromyosin had the same effect suggesting that the active sites were not blocked by the thiopurine nucleotides. Direct evidence for this suggestion was provided by equilibrium dialysis experiments. Heavy meromyosin and subfragment one bound 1.9 and 0.8 mol of [8-3H]adenylyl imidodiphosphate per mol of enzyme, respectively, with an average dissociation constant of 5 X 10(-7) M. Heavy meromyosin with four thiopurine nucleotides bound or subfragment one with two thiopurine nucleotides bound retained 65-80% of these tight adenylyl imidodiphosphate binding sites confirming the above suggestion. Thus previous work assuming reaction of thiopurine nucleotide analogs at the active site of myosin must be reevaluated. Ultracentrifugation studies showed that heavy meromyosin which had incorporated four thiopurine nucleotides did not bind to F-actin while subfragment one with one thiopurine nucleotide bound interacted only very weakly with F-actin. Thus reaction of 6,6'-dithiobis(inosinyl imidodiphosphate) at nucleotide binding sites other than the active sites reduces the rate of ATP hydrolysis and inhibits actin binding. It is suggested that these second sites may function as regulatory sites on myosin.     

Dialdehyde derivatives of purine mononucleotides: substrate properties and affinity modification of myosin ATPase

It was demonstrated that the dialdehyde derivative of ATP is a good substrate for Ca-ATPase of heavy meromyosin (Km = (1.2-1.4) X 10(-4) M; V = VATP). At the same time, this compound can induce irreversible inhibition of the enzyme. Since oxo-ATP is rapidly hydrolyzed by myosin to form oxo-ADP, this inhibition is the result of the enzyme interaction with oxo-ADP. It was found that the kinetics of heavy meromyosin inhibition by oxo-ADP are typical of affinity modification; in this case ATP fully protects heavy meromyosin from the activity loss. Similar results on the irreversible inhibition of the ATPase activity under the action of oxo-ADP were obtained in the presence of myosin, heavy meromyosin, subfragment I and natural actomyosin and in the absence of bivalent cations, thus suggesting the modification of the active center of myosin ATPase.     

The effect of genetically expressed cardiac titin fragments on in vitro actin motility.

Titin is a striated muscle-specific giant protein (M(r) approximately 3,000,000) that consists predominantly of two classes of approximately 100 amino acid motifs, class I and class II, that repeat along the molecule. Titin is found inside the sarcomere, in close proximity to both actin and myosin filaments. Several biochemical studies have found that titin interacts with myosin and actin. In the present work we investigated whether this biochemical interaction is functionally significant by studying the effect of titin on actomyosin interaction in an in vitro motility assay where fluorescently labeled actin filaments are sliding on top of a lawn of myosin molecules. We used genetically expressed titin fragments containing either a single class I motif (Ti I), a single class II motif (Ti II), or the two motifs linked together (Ti I-II). Neither Ti I nor Ti II alone affected actin-filament sliding on either myosin, heavy meromyosin, or myosin subfragment-1. In contrast, the linked fragment (Ti I-II) strongly inhibited actin sliding. Ti I-II-induced inhibition was observed with full-length myosin, heavy meromyosin, and myosin subfragment-1. The degree of inhibition was largest with myosin subfragment-1, intermediate with heavy meromyosin, and smallest with myosin. In vitro binding assays and electrophoretic analyses revealed that the inhibition is most likely caused by interaction between the actin filament and the titin I-II fragment. The physiological relevance of the novel finding of motility inhibition by titin fragments is discussed.     

Purification and characterization of a smooth muscle myosin phosphatase from turkey gizzards

A phosphoprotein phosphatase that dephosphorylates smooth muscle myosin has been purified to apparent homogeneity from turkey gizzards. Smooth muscle phosphatase (SMP) IV has a molecular weight of 150,000 as determined by gel filtration on a Sephadex G-200 column and is composed of two subunits (Mr = 58,000 and 40,000). Although it is active toward a number of proteins, its activities toward the contractile proteins, intact myosin, heavy meromyosin, and isolated myosin light chains are higher than its activities toward phosphorylase alpha, histone IIA, and phosphorylase kinase. SMP-IV preferentially dephosphorylates the beta-subunit of phosphorylase kinase. The properties of the enzyme have been studied using heavy meromyosin, a soluble chymotryptic fragment of myosin, and isolated myosin light chains as substrates. SMP-IV has high affinity for both substrates and is optimally active at neutral pH. Divalent cations, Ca2+ and Mg2+, activate the dephosphorylation of heavy meromyosin but inhibit the activity toward myosin light chains. Low concentrations of ATP (1-5 mM) activate SMP-IV but concentrations higher than 5 mM are inhibitory. Inhibition of 50% of the activity of the enzyme by NaF and PPi requires concentrations higher than 10 mM. Rabbit skeletal muscle heat stable inhibitor-2 has no effect on the activity of SMP-IV toward heavy meromyosin, myosin light chains, and phosphorylase alpha.     

Myosin and actomyosin from human skeletal muscle

Human skeletal natural actomyosin contained actin, tropomyosin, troponin and myosin components as judged by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. Purified human myosin contained at least three light chains having molecular weights (±2000) of 25 000, 18 000 and 15 000. Inhibitory and calcium binding components of troponin were identified in an actin-tropomyosin-troponin complex extracted from acetone-dried muscle powder at 37°C. Activation of the Mg-ATPase activity of Ca²⁺-sensitive human natural or reconstituted actomyosin was half maximal at approximately 3.4 μM Ca²⁺ concentration (CaEGTA binding constant = 4.4 · 10⁵ at pH 6.8). Subfragment 1, isolated from the human heavy meromyosin by digestion with papain, appeared as a single peak after DEAE-cellulose chromatography. In the pH 6–9 range, the Ca²⁺-ATPase activity of the subfragment 1 was 1.8-and 4-fold higher that the original heavy meromyosin and myosin, respectively. The ATPase activities of human myosin and its fragments were 6–10 fold lower than those of corresponding proteins from rabbit fast skeletal muscle. Human myosin lost approximately 60% of the Ca²⁺-ATPase activity at pH 9 without a concomitant change in the number of distribution of its light chains. These findings indicate that human skeletal muscle myosin resembles other slow and fast mammalian muscles. Regulation of human skeletal actomyosin by Ca²⁺ is similar to that of rabbit fast or slow muscle