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.     

Actin and Myosin in pea tendrils

We demonstrate here the presence of actin and myosin in pea (Pisum sativum L.) tendrils. The molecular weight of tendril actin is 43,000, the same as rabbit skeletal muscle actin. The native molecular weight of tendril myosin is about 440,000. Tendril myosin is composed of two heavy chains of molecular weight approximately 165,000 and four (two pairs) light chains of 17,000 and 15,000. At high ionic strength, the ATPase activity of pea tendril myosin is activated by K⁺-EDTA and Ca²⁺ and is inhibited by Mg²⁺. At low ionic strength, the Mg²⁺-ATPase activity of pea tendril myosin is activated by rabbit skeletal muscle F-actin. Superprecipitation occurred after incubation at room temperature when ATP was added to the crude actomyosin extract. It is suggested that the interaction of actin and myosin may play a role in the coiling movement of pea tendril.     

The contractile proteins of smooth muscle. Properties and components of a Ca2+-sensitive actomyosin from chicken gizzard.

The preparation and characterization of a Ca²⁺-sensitive actomyosin from chicken gizzard is described. The pH curve of the Mg²⁺ ATPase activity of the actomyosin was dominated by the activity of the myosin component, and this gave rise to the acid and alkaline optima. Skeletal muscle myosin showed a similar curve. Both the activation of myosin ATPase by actin, and the Ca²⁺ sensitivity were confined to the neutral pH region. The subunit composition of the Ca²⁺-sensitive actomyosin was interesting in that no components corresponding to skeletal muscle troponin were obvious. It is suggested that the activity of gizzard actomyosin is regulated by a protein on the thin filaments with a subunit weight of ~130,000.     

Characterization of the active site of platelet myosin in comparison to smooth and skeletal muscle myosin.

Heavy meromyosin subfragment-1 from human platelets and chicken gizzard exhibited an identical chromatographic pattern on agarose-ATP columns both in the absence and in the presence of Ca²⁺ and Mg²⁺. In the presence of Ca²⁺, the behavior differed from that of rabbit white skeletal muscle subfragment-1. The reaction of lysyl residues of platelet myosin with 2,4,6-trinitrobenzene sulfonate did not affect the K⁺- or Mg²⁺-stimulated ATPase activity. A similar behavior was exhibited by chicken gizzard myosin whereas trinitrophenylation of the more active lysyl residues in skeletal muscle myosin caused a marked increase in Mg²⁺-stimulated and a decrease in K⁺-stimulated ATPase activity. These features may point to a similar location of the essential lysyl residue in platelet and smooth muscle myosin, which is different from that of skeletal muscle. Alkylation of thiol groups by N-ethyl maleimide in the absence of added nucleotides resulted in a loss of K⁺-ATPase and in an increase in the Ca²⁺-ATPase in all three myosins, the increase for the skeletal myosin being much greater than for the platelet and chicken gizzard preparations. Alkylation of myosin in the presence of MgADP led to a decrease in K⁺-ATPase of all preparations whereas the Ca²⁺-ATPase as a function of time exhibited a maximum for the platelet and skeletal muscle proteins. These features may point to a certain similarity with respect to the active site of platelet and smooth muscle myosins and a difference between these and skeletal muscle myosin.     

The effect of phosphorylation of gizzard myosin on actin activation

Gizzard myosin is phosphorylated by a kinase found in chicken gizzards. The 20,000 dalton light chains are the only subunits to show an appreciable extent of ³²P incorporation. Phosphorylation requires trace amounts of Ca²⁺. The Mg²⁺-ATPase activity of gizzard myosin in the phosphorylated form is activated to an appreciable extent by skeletal actin, whereas the activation of the non-phosphorylated myosin is verylow. These results suggest that the Ca²⁺-sensitive regulatory mechanism of gizzard actomyosin is mediated via a kinase. In the presence of Ca²⁺ the onset of contraction and the resultant increase of the Mg²⁺-ATPase activity we suggest is due, at least partly, to the phosphorylation of the 20,000 dalton light chains. Whether or not Ca²⁺ binding by myosin is also essential remains to be established.     

Contractile Proteins of a Benthic Fish. II. Composition and ATPase Properties of Actomyosin

SYNOPSIS. Actomyosin was extracted from skeletal muscle of Coryphaenoides,a benthic fish living at 2,200 meters depth, at a temperatureof 2°C, or less, and at pressure of 3,000 psi. On SDS-ureaelectrophoresis on acrylamide gel, the actomyosin extracts yieldcomponents of apparent molecular weight 210,000 (myosin heavychains), 47,000 (actin), 35,000 (tropomyosin and/or troponinsubunits), and 13,000 (myosin light chains). The Mg²⁺-ATPaseof Coryphaenoides actomyosin shows a complex Arrhenius plot,with marked denaturation at temperatures above 30°C, anddiminished temperature sensitivity at temperatures below 15°C.Mg²⁺-ATPase is inhibited by pressure, with activation volumesof + 160 cc/mole at 25°C, and + 230 cc/mole at 2°C.Ca²⁺-ATPase of actomyosin exhibits the same pH, temperature,and pressure dependence as Ca²⁺-ATPase of myosin. The overalldata would be consistent with a positive activation volume thatis independent of temperature (to first approximation) and isrelated to the interaction of actin and myosin, and a negativeactivation volume that is temperature dependent and is relateddirectly to activation of myosin ATPase. The net effect appearsto be an adaptive mechanism whereby Mg²⁺-ATPase of Coryphaenoidesactomyosin is relatively insensitive to pressure and temperatureunder conditions encountered by the living fish.     

Evidence for a role for cardiac myosin in regulating the contractile response.

Dinitrophenylated bovine cardiac myosin incorporates 1.3 mol of 1-fluoro-2,4-dinitro-benzene per 5 × 10⁵ g of protein. Concomitantly there was an activation of the Ca²⁺-ATPase activity and an inhibition of the K⁺(EDTA)-ATPase activity. The dinitrophenyl group is located in the smallest active proteolytic fragment, subfragment 1. Virtually all of the labeling occurs in the region containing the heavy chains of cardiac myosin as judged by dissociation experiments in sodium dodecyl sulfate. Dinitrophenylated myosin failed to form calcium-sensitive actomyosin when tested in an ATPase assay system containing actin, tropomyosin, troponin and ethylene glycol-bis(β-aminoethyl ether)N,N′-tetraacetic acid. Thiolysis of the dinitrophenyl group from myosin with 2-mercaptoethanol restored its ability to form a calcium-sensitive actomyosin. The Ca²⁺ and K⁺(EDTA)-ATPase activities were also restored to control values. These results indicate that cardiac myosin participates in the regulation of the interaction between the contractile proteins.     

Phosphorylation of myosin light chain by protease activated kinase I

Protease activated kinase I from rabbit reticulocytes has been shown to phosphorylate the P-light chain of myosin light chains isolated from rabbit skeletal muscle. The enzyme is not activated by Ca²⁺ and calmodulin or phospholipids. Protease activated kinase I is not inhibited by trifluoperazine at concentrations up to 200 μM or by the antibody to the Ca²⁺, calmodulin-dependent myosin light chain kinase from rabbit skeletal muscle. Two-dimensional peptide mapping of chymotryptic digests of myosin P-light chain show the site phosphorylated by the protease activated kinase is different from that phosphorylated by the Ca²⁺, calmodulin-dependent myosin light chain kinase.     

Erythrocyte troponin inhibitor-like protein: Isolation and characterization

A protein was isolated from a human erythrocyte lysate with an apparent molecular weight of 23,000–24,000 daltons. This protein was purified by batch DEAE cellulose followed by column DEAE cellulose chromatography and a gradient of NaCl. On sodium dodecyl sulfate acrylamide electrophoresis, the erythrocyte protein comigrated with muscle troponin inhibitor. An isoelectric precipitation (pH 9.25) was used for the separation of muscle troponin inhibitor from a complex with another troponin component. Both the erythrocyte protein and the muscle troponin inhibitor partially inhibited muscle myosin Ca²⁺ and K⁺-EDTA ATPase activity. Furthermore, they inhibited actin-activated Mg²⁺-ATPase of muscle myosin. The inhibitory effects were absent in the presence of muscle troponin calcium-binding component. Muscle troponin inhibitor and the erythrocyte troponin inhibitor-like protein bound to muscle myosin when myosin was precipitated twice at low ionic strength. The presence of a troponin inhibitor-like protein in erythrocytes suggests that it may be a component in the regulation of contractile activity.     

Dissociation and reassociation of rabbit skeletal muscle myosin

Whereas dissociation of rabbit skeletal muscle myosin light chains occurs at an increased temperature (25°) and in the obsence of divalent cations, reassociation of the myosin oligomer requires a low temperature (4°C) and the presence of divalent cations, thus resulting in the original light to heavy chain stoichiometry. With a 5–10 per cent release of alkali light chains, LC₁ and LC₃, and a 50 per cent dissociation of the Ca²⁺ binding light chain, LC₂, there is no significant decrease in myosin ATPase activity irrespective of the cation activator, however, there is an approximate 15–20 per cent decrease in actomyosin ATPase activity. With reassociation of the myosin oligomer, actomyosin ATPase activity is partially restored as well as the original number of Ca²⁺ binding sites.     

An investigation into the role of SH1 and SH2 groups of myosin in calcium binding and tension generation

Myosin heavy chains influence the Ca²⁺ binding properties of the light chains. When the SH₁ + SH₂ moieties of myosin, located on heavy meromyosin S-1, are blocked, myosin loses its Ca²⁺ binding capabilities. Furthermore, (SH₁ + SH₂)-blocked myosin no longer expresses tension when analyzed as modified actomyosin threads. When the SH₁ moiety of myosin is blocked, myosin continues to express normal Ca²⁺ binding properties as well as normal tension.     

Effect of bivalent cations on the adenosine triphosphatase of actomyosin and its modification by tropomyosin and troponin

1. After removal of tropomyosin and troponin from the `natural'' actomyosin complex, the adenosine triphosphatase activity of the resulting `desensitized'' actomyosin is stimulated to the same extent by various bivalent cations with an ionic radius in the range 0·65–0·99å when tested at optimum concentration of the metal ion in the presence of 2·5mm-ATP at low ionic strength and pH7·6. Under identical conditions the adenosine triphosphatase activity of myosin alone is stimulated to an appreciable extent only by Ca²⁺ (ionic radius 0·99å). 2. Tropomyosin narrows the range of size of the stimulatory cations by inhibiting specifically the adenosine triphosphatase activity of `desensitized'' actomyosin when stimulated by Ca<sup>2+</sup> or the slightly smaller Cd<sup>2+</sup> (ionic radius 0·97å). Tropomyosin has no effect on the adenosine triphosphatase activity of `desensitized'' actomyosin when stimulated by the smaller cations, nor on the Ca²⁺-activated adenosine triphosphatase activity of myosin alone. 3. The adenosine triphosphatase activity of the `natural'' actomyosin system (containing tropomyosin and troponin) stimulated by the smallest cation, Mg²⁺ (ionic radius 0·65å), is low when the system is deprived of Ca²⁺ but high in the presence of small amounts of Ca²⁺. This sensitivity to Ca²⁺ seems to be a unique feature of the Mg²⁺-stimulated system. 4. The changes in specificity of the myosin adenosine triphosphatase activity in its requirement for bivalent cations caused by interaction with actin, tropomyosin and troponin primarily concern the size of the metal ions. The effects on enzymic properties of myofibrils due to tropomyosin and troponin can be demonstrated at low and at physiological ionic strength.     

Two calcium regulation systems in squid (Ommastrephes sloani pacificus) muscle. Preparation of calcium-sensitive myosin and troponin-tropomyosin.

The Ca-regulatory system in squid mantle muscle was studied. The findings were as follows. (a) Squid mantle myosin B (squid myosin B) was Ca-sensitive, and its Ca-sensitivity was unaffected by addition of a large amount of rabbit skeletal myosin (skeletal myosin) or rabbit skeletal F-actin (skeletal F-actin). (b) Squid myosin was prepared from the mantle muscle. It showed a heavy chain component and two light chain components in the SDS-gel electrophoretic pattern: the molecular weights of the latter two were 17,000 and 15,000. Actomyosin reconstituted from squid myosin and skeletal (or squid) actin showed Ca-sensitivity in superprecipitation and Mg-ATPase assays. EDTA- treatment had no effect on the Ca-sensitivity of squid myosin. (c) Squid mantle actin (squid actin) was prepared by the method of Spudich and Watt. Hybrid actomyosin reconstituted by using the pure squid actin preparation with skeletal myosin showed no Ca-sensitivity in Mg-ATPase assay, whereas that reconstituted using crude squid actin showed marked Ca-sensitivity. The crude squid actin contained four protein components which were capable of associating with F-actin in 0.1 M KCl, 1 mM MgCl2 and 20 mM Tris-maleate (pH7.5). (d) Native tropomyosin was prepared from squid mantle muscle, and it conferred Ca-sensitivity on skeletal actomyosin as well as on a hybrid actomyosin reconstituted from squid actin and skeletal myosin. (e) Squid native tropomyosin was separated into troponin and tropomyosin fractions by placing it in 0.4 M LiCl at pH 4.7. The troponin fraction was further purified by DEAE-cellulose chromatography. Squid troponin thus obtained was different in mobility from rabbit skeletal or carp dorsal troponin; three bands of squid troponin corresponded to molecular weights of 52,000, 28,000, and 24,000 daltons. It could confer Ca-sensitivity in the presence of tropomyosin on skeletal actomyosin as well as on a hybrid reconstituted from squid actin and skeletal myosin. (f) Squid myosin B, and two hybrid actomyosins were compared as regards Ca and Sr requirements for their Mg-ATPase activities. The myosin-linked regulatory system rather than the thin-filament-linked regulatory system was predominant in squid myosin B. Squid myosin B required higher Ca2+ and Sr2+ concentrations for Mg-ATPase activity; half-maximal activation of Mg-ATPase was obtained at 0.8 micron Ca2+ and 28 micron Sr2+ with skeletal myosin B, and at 2.5 micron Ca2+ and 140 micron Sr2+ with squid myosin B.     

Characterization of the Single Tyrosine Containing Troponin C from Lungfish White Muscle. Comparison with Several Fast Skeletal Muscle Troponin C's from Fish Species

Troponin C molecules from fast skeletal muscle of the following fish species (trout, whiting, lungfish, tilapia, and cod) have been purified to homogeneity. Upon binding of Ca²⁺ or Mg²⁺, lungfish troponin C is the only troponin C from fish white muscle to show the typical increase of tyrosine fluorescence emission quantum yield reported for rabbit fast skeletal muscle troponin C. The increase of tyrosine fluorescence signal occurring upon Ca²⁺ and Mg²⁺ titration of lungfish troponin C has been used to determine the corresponding affinity constants. With K_(Ca) = 7.0 10⁷ M⁻¹ and K_(Mg) = 3.6 10³ M⁻¹, the sites probed by the tyrosine residue of lungfish troponin C are typical of the COOH-terminal domain of fast skeletal troponin C's. The amino acid sequencing of the tyrosine containing tryptic peptides has allowed us to position the single tyrosine residue at position 7 in the Ca²⁺ binding loop of the third site, in identical position to Tyr109 of troponin C from rabbit fast skeletal muscle. Metal ion binding studies followed by intrinsic fluorescence or Tb³⁺ luminescence indicate that the conformation of the structural domain of lungfish troponin C with one metal ion bound is close to the physiological conformation of this domain.     

Influence of myosin heavy chains on the Ca2+-binding properties of light chain, LC2

The association of myosin light chains with heavy chains, i.e. the intact oligomeric structure, profoundly affects the Ca²⁺-binding properties of the light chains. The Ca²⁺-binding affinity of the light chains is more than two magnitudes higher in the presence of heavy chains than in its absence. Modification of the reactive SH₂ thiol of myosin results in an alteration in the conformation of heavy chains of the molecule that influences the Ca²⁺-binding properties of light chains and generation of tension. When the SH₂ moiety is blocked with N-ethylmaleimide the influence of the heavy chains on the Ca²⁺-binding properties of light chain LC₂ is lost; under these conditions the Ca²⁺-binding affinity value of SH₂-N-ethylmaleimide-blocked myosin (3.3×10⁴m⁻¹) decreases to near that expressed with the dissociated light chain LC₂ (0.7×10⁴m⁻¹). Conversely, the presence of actin, nucleotides or modification of either the reactive lysyl residue or SH₂ thiol does not affect Ca²⁺ binding. The native secondary and tertiary structure of myosin seem to be required for Ca²⁺ binding; binding does not occur in the presence of 6m-urea with either native myosin or the dissociated light chains. With SH₂-N-ethylmaleimide-blocked myosin normal Ca²⁺- and (Mg²⁺+actin)-stimulated ATPase activities are expressed; however, there is a loss in K⁺-stimulated ATPase activity and the synthetic actomyosin threads of such myosin express no isometric tension. There are also variances in the binding of Ca²⁺ with alterations in pH values. In the absence of Ca²⁺/EGTA buffer the biphasic Ca²⁺-binding affinity of myosin is twice as high at pH7.4 (site one: 1.2×10⁶m⁻¹ and site two: 0.4×10⁶m⁻¹) as compared with values obtained at pH6.5 (site one: 0.64×10⁶m⁻¹ and site two: 0.2×10⁶m⁻¹). The Ca²⁺-binding affinity of light chain LC₂ and S₁, where the (S-1)–(S-2) junction was absent, were not influenced by changes in pH values. Both expressed a low Ca²⁺-binding affinity, approx. 0.7×10⁴m⁻¹, whereas heavy meromyosin, where both (S-1) and (S-2) myosin subfragments were present, expressed a Ca²⁺-binding affinity value similar to that of native myosin, but was not biphasic. However, it is important to point out than in preparation of S₁ myosin subfragment light chain LC₂ was lost and thus was added back to the purified S₁ fraction. Light chain LC₂ was not, however, added to the heavy meromyosin fraction because it was not lost during preparation of the heavy meromyosin subfragment. In conclusion, it appears that the (S-1)–(S-2) junction is needed for the positioning of light chain LC₂ and thus influences its essential conformation for Ca²⁺ binding.     

Role of myosin light chain kinase in muscle contraction

In resting striated muscles of the rabbit muscle in vivo, the phosphorylatable light chain is partially phosphorylated. Tetanic stimulation increased the level of phosphorylation more rapidly in fast twitch than in slow twitch muscle. In both types of muscle the rate of dephosphorylation was relatively slow. In rabbit fast twitch muscles, phosphorylation levels persisted significantly above the resting value for some time after posttetanic potentiation had disappeared. The role of myosin light chain kinase in modulating contractile response in striated muscle is uncertain. In vertebrate smooth muscle the role of myosin phosphorylation appears to be different from that in striated muscle despite the general similarity of the actomyosin system in both tissues. Although phosphorylation in vitro increases the Mg2+ -ATPase of actomyosin, a number of features imply that a somewhat complex relationship exists between the level of phosphorylation and the actin activation of the Mg2+ -ATPase in vertebrate smooth muscle. Contrary to many earlier reports, preparations of smooth muscle actomyosin can be obtained with Mg2+ -ATPase activities comparable to those of actomyosin from skeletal muscle. Preliminary evidence is presented that suggests that phosphorylation changes the Ca2+ sensitivity of the Mg2+ -ATPase of smooth muscle actomyosin.     

Myosin-linked calcium regulation in vertebrate smooth muscle.

By the use of a new procedure, actomyosin may be extracted in high yield and purity from fowl gizzard which exhibits a calcium-dependent actin-activated ATPase activity comparable to that of the parent myofibril-like preparation. Studies of this vertebrate smooth muscle actomyosin show that the regulation of the actin-myosin interaction is effected, as in molluscan muscles, by the myosin molecule itself and not by an actin-linked regulatory system, as found in vertebrate skeletal muscle.Thus, calcium-sensitive smooth muscle actomyosin is composed of only myosin, actin and tropomyosin, any troponin-like components being absent. Myosin is the only component that binds significant amounts of calcium and shows a calcium-dependent actin-activated ATPase activity in the presence of F-actin from either gizzard or rabbit skeletal muscle.The cross-reaction of gizzard thin filaments with skeletal muscle myosin produces an actomyosin whose actin-activated ATPase is calcium-insensitive, showing that smooth muscle thin filaments do not serve a regulatory function.The effect of Mg²⁺ and pH, and evidence for the involvement of one of the myosin light chains in calcium regulation are described and discussed.     

Regulatory light chains modulate in vitro actin motility driven by skeletal heavy meromyosin

Phosphorylation and Ca²⁺-Mg²⁺ exchange on the regulatory light chains (RLCs) of skeletal myosin modulate muscle contraction. However, the relation between the mechanisms for the effects of phosphorylation and metal ion exchange are not clear. We propose that modulation of skeletal muscle contraction by phosphorylation of the myosin regulatory light chains (RLCs) is mediated by altered electrostatic interactions between myosin heads/necks and the negatively charged thick filament backbone. Our study, using the in vitro motility assay, showed actin motility on hydrophilic negatively charged surfaces only over the HMM with phosphorylated RLCs both in the presence and absence of Ca²⁺. In contrast, good actin motility was observed on silanized surfaces (low charge density), independent of RLC phosphorylation status but with markedly lower velocity in the presence of Ca²⁺. The data suggest that Ca²⁺-binding to, and phosphorylation of, the RLCs affect the actomyosin interaction by independent molecular mechanisms. The phosphorylation effects depend on hydrophobicity and charge density of the underlying surface. Such findings might be exploited for control of actomyosin based transportation of cargoes in lab-on-a chip applications, e.g. local and temporary stopping of actin sliding on hydrophilic areas along a nanosized track.     

Calcium-Dependent Interaction Sites of Tropomyosin on Reconstituted Muscle Thin Filaments with Bound Myosin Heads as Studied by Site-Directed Spin-Labeling

To identify the interaction sites of Tm, we measured the rotational motion of a spin-label covalently bound to the side chain of a cysteine that was genetically incorporated into rabbit skeletal muscle tropomyosin (Tm) at positions 13, 36, 146, 160, 174, 190, 209, 230, 271, or 279. Most of the Tm residues were immobilized on actin filaments with myosin-S1 bound to them. The residues in the mid-portion of Tm, namely, 146, 174, 190, 209, and 230, were mobilized when the troponin (Tn) complex bound to the actin-Tm-S1 filaments. The addition of Ca²⁺ ions partially reversed the Tn-induced mobilization. In contrast, residues at the joint region of Tm, 13, 36, 271, and 279 were unchanged or oppositely changed. All of these changes were detected using a maleimide spin label and less obviously using a methanesulfonate label. These results indicated that Tm was fixed on thin filaments with myosin bound to them, although a small change in the flexibility of the side chains of Tm residues, presumably interfaced with Tn, actin and myosin, was induced by the binding of Tn and Ca²⁺. These findings suggest that even in the myosin-bound (open) state, Ca²⁺ may regulate actomyosin contractile properties via Tm.     

Calcium-Dependent Interaction Sites of Tropomyosin on Reconstituted Muscle Thin Filaments with Bound Myosin Heads as Studied by Site-Directed Spin-Labeling

To identify the interaction sites of Tm, we measured the rotational motion of a spin-label covalently bound to the side chain of a cysteine that was genetically incorporated into rabbit skeletal muscle tropomyosin (Tm) at positions 13, 36, 146, 160, 174, 190, 209, 230, 271, or 279. Most of the Tm residues were immobilized on actin filaments with myosin-S1 bound to them. The residues in the mid-portion of Tm, namely, 146, 174, 190, 209, and 230, were mobilized when the troponin (Tn) complex bound to the actin-Tm-S1 filaments. The addition of Ca²⁺ ions partially reversed the Tn-induced mobilization. In contrast, residues at the joint region of Tm, 13, 36, 271, and 279 were unchanged or oppositely changed. All of these changes were detected using a maleimide spin label and less obviously using a methanesulfonate label. These results indicated that Tm was fixed on thin filaments with myosin bound to them, although a small change in the flexibility of the side chains of Tm residues, presumably interfaced with Tn, actin and myosin, was induced by the binding of Tn and Ca²⁺. These findings suggest that even in the myosin-bound (open) state, Ca²⁺ may regulate actomyosin contractile properties via Tm.