Crosslinking by thiol disulfide interchange of 5,5'-dithiobis(2-nitrobenzoic acid)-treated light chain and heavy chain of rabbit skeletal myosin

Interchain disulfide crosslinks between the heavy-chain fragment in heavy meromyosin and myosin light chain 2, generated by 5,5'-dithiobis(2-nitrobenzoic acid (Nbs2), are formed under appropriate ionic conditions at neutral pH as revealed by liberation of the chromogenic 2-nitro-5-thiobenzoic acid. The presence of the original or of a slightly digested light chain 2 reduces the rate of the reaction of heavy meromyosin with Nbs2-modified light chain 2 by 32 - 39%, if Ca2+ is present. Dodecyl sulfate/polyacrylamide gel electrophoresis in absence of reducing agents shows that Nbs2-modified light chain 2 attaches to the heavy chain in the region of the 21-kDa fragment of heavy meromyosin, which contains the essential thiol groups and which has been located at the subfragment 1/subfragment 2 junction of myosin [Balint, M., Wolf, I., Tarcsafalvi, A., Gergely, J. and Sreter, F. A. (1978) Arch. Biochem. Biophys. 190, 793-799]. Modification of thiol-1 groups with iodoacetamide as well as crosslinking the thiol-1 and thiol-2 groups by the bifunctional reagent p-N,N'-phenylenedimaleimide prior to incubation with Nbs2-modified light chain 2 has no substantial effect on the crosslinking reaction. This indicates that other thiol groups are involved in the binding of Nbs2-modified light chain 2 to the heavy chain. An examination of K+, Ca2+, Mg2+ and actin-activated Mg2+ ATPase activities of heavy meromyosin that had been crosslinked with Nbs2-modified light chain 2 shows only a slight change in comparison with intact heavy meromyosin, indicating that crosslinking had not altered significantly the hydrolytic site. Crosslinking of Nbs2-modified light chain 2 to light-chain-2-deficient heavy meromyosin restored the original light-chain-2-dependent Ca2+ sensitivity of the tryptic fragmentation of heavy meromyosin, suggesting that crosslinking takes place at the proper binding site for light 2.     

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.     

Proteolysis of smooth muscle myosin by Staphylococcus aureus protease: preparation of heavy meromyosin and subfragment 1 with intact 20 000-dalton light chains

The proteolysis of gizzard myosin by Staphylococcus aureus protease produces both heavy meromyosin and subfragment 1 in which the 20 000-dalton light chains are intact, and conditions are suggested for the preparation of each. Cleavage of the myosin heavy chain to produce subfragment 1 is dependent on the myosin conformation. Proteolysis of myosin in the 10S conformation yields predominantly heavy meromyosin, and myosin in the 6S conformation yields mostly subfragment 1 and some heavy meromyosin. Two sites are influenced by myosin conformation, and these are located at approximately 68 000 and 94 000 daltons from the N-terminus of the myosin heavy chain. The latter site is thought to be located at the subfragment 1-subfragment 2 junction, and cleavage at this site results in the production of subfragment 1. The time courses of phosphorylation of both heavy meromyosin and subfragment 1 can be fit by a single exponential. The actin-activated Mg2+-ATPase activity of heavy meromyosin is markedly activated by phosphorylation of the 20 000-dalton light chains. From the actin dependence of Mg2+-ATPase activity the following values are obtained: for phosphorylated heavy meromyosin, Vmax approximately 5.6 s-1 and Ka (the apparent dissociation constant for actin) approximately 2 mg/mL; for dephosphorylated heavy meromyosin, Vmax approximately 0.2 s-1 and Ka approximately 7 mg/mL. The actin-activated ATPase activity of subfragment 1 is not influenced by phosphorylation, and Vmax and Ka for both the phosphorylated and dephosphorylated forms are 0.4 s-1 and 5 mg/mL, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Affinity chromatography of myosin, heavy meromyosin, and heavy meromyosin subfragment one on F-actin columns stabilized by phalloidin.

A method of affinity chromatography based on the trapping of actin filaments within agarose gel beads is described. This method can be used for the purification of myosin and its active proteolytic subfragments, as well as for studies on the interaction between actin and these proteins. Actin columns stabilized by phalloidin bind myosin, heavy meromyosin (HMM), and heavy meromyosin subfragment 1 (HMM-S1) specifically and reversibly. The effect of pyrophosphate and KCl on the dissociation of actomyosin, acto-HMM, or acto-HMM-S1 complex is reported. We also describe the single-step purification of myosin from a crude rabbit psoas muscle extract.     

Binding of caldesmon to smooth muscle myosin

Caldesmon, a major calmodulin binding protein, was found to bind smooth muscle myosin. Addition of caldesmon to smooth muscle myosin induced the formation of small aggregates of myosin in the absence of Ca2+-calmodulin, but not in the presence of Ca2+-calmodulin. The binding site of myosin was studied by using caldesmon-Sepharose 4B affinity chromatography. Subfragment 1 was not retained by the column, while heavy meromyosin and subfragment 2 were bound to the caldesmon affinity column in the absence of Ca2+-calmodulin but not in its presence. It was therefore concluded that the binding site of caldesmon on myosin molecule was the subfragment 2 region and that binding of caldesmon to myosin was abolished in the presence of Ca2+ and calmodulin. Cross-linking of actin and myosin mediated by caldesmon was studied. While actomyosin was completely dissociated in the presence of Mg2+-ATP, the addition of caldesmon caused aggregation of the actomyosin. By low speed centrifugation at which actomyosin alone was not precipitated in the presence of Mg2+-ATP, the aggregate induced by caldesmon was precipitated and the composition of the precipitate was found to be actin, caldesmon, and myosin. In the presence of Mg2+-ATP, pure actin did not bind to a myosin-Sepharose 4B affinity column, while all of the actin was retained when the actin/caldesmon mixture was applied to the column. These results indicate that caldesmon can cross-link actin and myosin.     

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     

Light chain dependent effects of actin binding on the S-1/S-2 swivel in myosin

The S-1/S-2 swivel in myosin provides a flexible link between the head and tail portions of the molecule. We have investigated the properties of the swivel by employing limited proteolysis methods. Our results indicate that the binding of actin to heavy meromyosin inhibits both the chymotryptic and papain cleavage of the S-1/S-2 swivel, and that this effect is dependent on the presence of intact LC-2 light chains. Actin did not slow digestions carried out using heavy meromyosin previously treated with proteases to nick the LC-2 chains to 17,000 or 14,000 Mr fragments. Although the integrity of the LC-2 light chain appears to be required to transmit the effects of actin binding from the myosin head to the S-1/S-2 swivel, the binding of Ca2+ to the 17,000 Mr LC-2 fragment can still affect the chemical reactivity of SH1 thiol groups. Both chymotryptic and papain digestions of heavy meromyosin containing intact or fragmented LC-2 light chain show substantial temperature sensitivity between 5 degrees C and 35 degrees C. Calculated apparent activation energies for this process indicate that the S-1/S-2 swivel in myosin can undergo temperature-dependent structural changes independently of the state of the LC-2 light chain. Thus, both actin binding and temperature variations can induce structural transitions in the S-1/S-2 swivel.     

The substructure of heavy meromyosin. The effect of Ca2+ and Mg2+ on the tryptic fragmentation of heavy meromyosin.

Heavy meromyosin, obtained by tryptic digestion of myosin, containing two main polypeptides whose masses were estimated as 81,000 and 74,000 dlatons from Na dodecyl-SO4 polyacrylamide gel electrophoresis, was further digested with trypsin. The Ca2+-activated ATPase activity remainded unchanged and the K+-EDTA activity increased while various smaller fragments were formed. The formation of some of these fragments is affected by Ca2+ or Mg2+ as first shown by Bálint et al. (Bálint, M., Schaefer, A., Biro, N. A., Menczel, L., AND Fejes, E. (1971) J. Physiol. Chem. Phys. 3, 455). On the basis of the time course of the appearance of fragments the following relationship emerges: see article. The 64K leads to 60K step is inhibited by divalent cations, while the breakdown of the 74K fragment is accelerated. The effect of Ca2+ was maximal at 0 similar to 0.1 muM, that of Mg2+ at 10 muM. The original light chains of myosin are not present in the heavy meromyosin serving as the starting material, but peptide material appears on electrophoresis in positions starting material, but peptide material appears on electrophoresis in positions where the light chains would be found. The fragments marked by an asterisk are considered to ba alpha-helical on the basis of their solubility at low ionic strength after precipitation with ethanol (Bálint et al.). The fact that alpha helical fragments are derived from the 60,000-dalton fragment indicateds that it is adjacent to the light meromyosin in the intact myosin while the 74,000- dalton fragment would be part of heavy meromysoin subfragment 1. Chromatography of Sephadex G-200 separates fractions with ATPase activity corresponding to heavy meromyosin and heavy meromyosin subfragment 1. Electrophoresis of these Sephadex fractions suggests that the main peptide constituting heavy meromysoin subfragment 1 is connected by noncobalent forces to a portion of the rod that is not immediately adjacent to it in the primary sequence. The significance of this finding is discussed in terms of the flexibility of the myosin head.     

Effect of myosin DTNB light chain on the actin-myosin interaction in the presence of ATP.

The influence of the DTNB light chain of myosin on its enzymatic activities was examined by studying the superprecipitation of actomyosin and the actin-activated ATPase of heavy meromyosin (HMM) [EC 3.6.1.3]. Although the Ca2+-, Mg2+-, and EDTA-ATPase activities of control and DTNB myosin were practically the same, the superprecipitation of actomyosin prepared from actin and DTNB myosin occurred more slowly than that of control myosin. The apparent binding constant obtained from double-reciprocal plots of actin-activated ATPase of DTNB HMM was lower than that of control HMM. Recombination of DTNB myosin and HMM with DTNB light chains restored the original properties of myosin and HMM. The removal of DTNB light chain from myosin had no effect on the formation of the rigor complex between actin and myosin. These results suggest that the DTNB light chain participates in the interaction of myosin with actin in the presence of ATP.     

The effect of phosphorylation of myosin light chains on the structural state of tropomyosin in thin filaments, decorated with heavy meromyosin

The structural state of tropomyosin (TM) modified by 5-(iodoacetamidoethyl)-aminonaphthalene-1-sulfonate (1.5-IAEDANS) upon F-actin decoration with myosin subfragment 1 (S1) and heavy meromyosin (HMM) in glycerinated myosin- and troponin-free muscle fibers was studied. HMM preparations contained native phosphorylated myosin light chains, while S1 preparations did not. The changes in the polarized fluorescence of 1.5-IAEDANS-TM during the F-actin interaction with S1 were independent of light chains phosphorylation and Ca2+ concentration, but were dependent on these factors during the F-actin interaction with HMM. The binding of myosin heads to F-actin is supposed to initiate conformational changes in TM which are accompanied by changes in the flexibility and molecular arrangement of TM. In the presence of light chains, the structural changes in TM depend on light chains phosphorylation and Ca2+ concentration. The conformational changes in TM seem to be responsible for the mechanisms of coupling of the myosin and tropomyosin modulation system during the actin-myosin interaction in skeletal muscles.     

Fluorescence anisotropy of labeled F-actin: influence of divalent cations on the interaction between F-actin and myosin heads

The interaction between F-actin and soluble proteolytic fragments of myosin, heavy meromyosin and myosin subfragment 1 without ATP, has been studied by measuring the static anisotropy and the transient anisotropy decay of the fluorescent chromophore N-(iodoacetyl)-N'-(5-sulfo-1-naphthyl) ethylenediamine bound to F-actin. In the presence of Ca2+ ions, the mobility of the chromophore was strongly decreased by adding heavy meromyosin or myosin subfragment 1, and this conformation change of F-actin showed a strong cooperativity; that is, a very small amount of myosin heads induced the maximum anisotropy change. On the other hand, in the presence of Mg2+ ions, the addition of a small amount of myosin subfragment 1 or of heavy meromyosin increased the mobility of labeled F-actin that reached a maximum at a molar ratio of about 1/25 or 1/50, respectively. With further addition of myosin heads, the mobility of the labeled actin decreased. From these studies, one concludes that F-actin undergoes a conformation change by interacting with myosin heads, which depends on the nature of the divalent cations present in the solution.     

Immobilization of actin and myosin.

Using glutaric dialdehyde, the muscle proteins myosin, actin, actomyosin and heavy meromyosin subfragment-1 (S-1) have been immobilized on capron fibers. The ATPase activity of myosin and its capability to interact with actin have been preserved whereas the ATPase activity of its subfragment decreased significnatly. Immobilization on capron fibers changes the pH dependence of the ATPase activity of myosin and of S-1 shifting the maximum towards the acid zone (pH 5.5) and increases the thermal stability of the enzyme. Calcium ions produce a stimulatory effect on ATPase; Mg2+ions yield no effect on myosin and S-1 but enhance the activity in the case of immobilized actomyosin though to a lesser degree than the ions of Ca2+. Immobilized actin retains its ability to form actomyosin complex.     

Effect of skeletal muscle myosin light chain 2 on the Ca2+-sensitive interaction of myosin and heavy meromyosin with regulated actin

A low-speed centrifugation assay has been used to examine the binding of myosin filaments to F-action and to regulated actin in the presence of MgATP. While the cross-linking of F-actin by myosin was Ca2+ insensitive, much less regulated actin was cross-linked by myosin in the absence of Ca2+ than in its presence. Removal of the 19000-dalton, phosphorylatable light chain from myosin resulted in the loss of this Ca2+ sensitivity. Readdition of this light chain partially restored the Ca2+-sensitive cross-linking of regulated actin by myosin. Urea gel electrophoresis has been used to distinguish that fraction of heavy meromyosin which contains intact phosphorylatable light chain from that which contains a 17000-dalton fragment of this light chain. In the absence of Ca2+, heavy meromyosin which contained digested light chain bound to regulated actin in MgATP about 10-fold more tightly than did heavy meromyosin which contained intact light chain. The regulated actin-activated ATPases of heavy meromyosin also showed that cleavage of this light chain causes a substantial increase in the affinity of heavy meromyosin for regulated actin in the absence of Ca2+. Thus, the binding of both myosin and heavy meromyosin to regulated actin is Ca2+ sensitive, and this sensitivity is dependent on the phosphorylatable light chain.     

Degradation of smooth-muscle myosin by trypsin-like serine proteinases.

1. Hydrolysis of the myosins from smooth and from skeletal muscle by a rat trypsin-like serine proteinase and by bovine trypsin at pH 7 is compared. 2. Proteolysis of the heavy chains of both myosins by the rat enzyme proceeds at rates approx. 20 times faster than those obtained with bovine trypsin. Whereas cleavage of skeletal-muscle myosin heavy chain by both enzymes results in the generation of conventional products i.e. heavy meromyosin and light meromyosin, the heavy chain of smooth-muscle myosin is degraded into a fragment of mol. wt. 150000. This is dissimilar from heavy meromyosin and cannot be converted into heavy meromyosin. It is shown that proteolysis of the heavy chain takes place in the head region. 3. The 'regulatory' light chain (20kDa) of smooth-muscle myosin is degraded very rapidly by the rat proteinase. 4. The ability of smooth-muscle myosin to have its ATPase activity activated by actin in the presence of a crude tropomyosin fraction on introduction of Ca2+ is diminished progressively during exposure to the rat proteinase. The rate of loss of the Ca2+-activated actomyosin ATPase activity is very similar to the rate observed for proteolysis of the heavy chain and 3-4 times slower than the rate of removal of the so-called 'regulatory' light chain. 5. The significance of these findings in terms of the functional organization of the smooth muscle myosin molecule is discussed. 6. Since the degraded myosin obtained after exposure to very small amounts of the rat proteinase is no longer able to respond to Ca2+, i.e. the functional activity of the molecule has been removed, the implications of a similar type of proteolysis operating in vivo are considered for myofibrillar protein turnover in general, but particularly with regard to the initiation of myosin degradation, which is known to take place outside the lysosome (i.e. at neutral pH).     

The mechanism of regulatory light chain dissociation from scallop myosin.

The dissociation of the regulatory light chains from scallop myosin subfragments, on addition of EDTA, was investigated by using the fluorophore 8-anilinonaphthalene-1-sulphonate as a probe. The rate of this process (0.014 s-1) was partially limited by the rate of Mg2+ dissociation (0.058 s-1) from the non-specific high-affinity site. The dissociation of the regulatory light chain subfragment 1 was less extensive than from heavy meromyosin. Reassociation of the scallop regulatory light chain was induced on addition of Mg2+, but it appeared to be limited by a first-order step. The nature of this step was revealed by the kinetics of Mercenaria regulatory light chain association. Scallop heavy meromyosin, denuded of its regulatory light chains, exists in a refractory state, whose reversal to the nascent state limits the rate of light chain association (0.006 s-1). The formation of the refractory state is the driving force for the net dissociation of regulatory light chains from scallop heavy meromyosin. This mechanism is discussed with reference to existing structural information on light-chain-denuded myosin.     

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.     

Reversible dissociation of dog cardiac myosin regulatory light chain 2 and its influence on ATP hydrolysis

The regulatory light chains of dog heart myosin were removed by digestion with myopathic hamster neutral protease. The heavy chains were also cleaved to an extent of 15%, but a homogeneous, rod-free LC2-deficient myosin was obtained by ion-exchange chromatography. A similar approach was used to prepare LC2-deficient heavy meromyosin. Neither Ca2+- nor K+-EDTA-activated ATPases were affected by LC2 removal. The Lineweaver-Burk plots for actin-activated ATPase in 25 mM KCl were biphasic giving a Vmax of 1.54 s-1 for control and LC2-recombined myosins and 1.08 s-1 for LC2-deficient myosin at low actin concentrations. At high actin concentrations, the Vmax for control and recombined myosins was 2.33 s-1 and 1.39 s-1 for LC2-deficient myosin. Increasing the KCl concentration in the reaction mixtures resulted in more linear plots without suppressing the 35-45% decrease in Vmax that accompanied LC2 removal. The results from assays with control and LC2-deficient heavy meromyosin performed in the absence of KCl, paralleled those obtained with myosin. The latter was also assayed in the presence of equimolar concentrations of C-protein in 50 mM KCl: C-protein induced a significant increase in the actin-activated ATPase of both control and LC2-recombined myosins, with no effect on LC2-deficient myosin. The Vmax for actin-activation in the presence of C-protein was 2.38 s-1, 0.83 s-1, and 1.71 s-1 for control, LC2-deficient, and recombined myosins, respectively. The enhancement of actin-activation in both the control and LC2-recombined myosins represents a possible role for C-protein in a LC2-mediated potentiation of actomyosin ATPase.     

Vanadate-mediated photocleavage of rabbit skeletal myosin

The heavy chain of myosin from rabbit skeletal muscle can be cleaved at three sites by irradiation with near-ultraviolet light in the presence of 0.1-1.0 mM vanadate. The sigmoidal dependence upon vanadate concentration, with half-maximal rate occurring at about 0.5 mM vanadate and a sigmoidicity of 2.7, is consistent with the chromophore responsible for cleavage being oligomeric vanadate. Cleavage occurs at two sites located within the head region of the molecule, 23 kDa and 75 kDa from the NH2-terminus; these sites are cleaved equally well in heavy meromyosin and subfragment 1. In the presence of 1 mM vanadate, the half-times for cleavage of the 23-kDa and 75-kDa sites are about 15 and 10 min, respectively. The rate of cleavage at both these sites is retarded 2-3-fold by the presence of greater than 10 microM MgATP. The third photocleavage site is located about 5-10 kDa from the COOH terminus of the intact heavy chain, and cleaves equally well in the isolated rod and in light meromyosin. Cleavage at this site occurs with a half-time of 138 min, and its rate is unaffected by the presence of MgATP. The vanadate-mediated cleavage of the heavy chains is accompanied by characteristic changes in the myosin ATPase properties, with the Ca2+, Mg2+ and actin-activated Mg2+ ATPases becoming elevated, whereas the K+/EDTA ATPase becomes inactivated. The sites of photocleavage in the myosin heavy chain might be associated with sites of phosphate binding.     

Segmental flexibility and head-head interaction in scallop myosin. A study using saturation transfer electron paramagnetic resonance spectroscopy

Saturation transfer electron paramagnetic resonance spectroscopy was used to investigate the rotational motion of the head domains of native and desensitized scallop myosin and its proteolytic subfragments. Scallop myosin was spin-labelled with 4-(2-iodoacetamido)-2,2,6,6-tetramethylpiperidinooxyl, which reacted with a heavy chain residue in the subfragment 1 domain. As previously shown for rabbit skeletal muscle myosin (Thomas et al., 1975), the two head domains of native scallop myosin appear to have independent motion (rotational correlation time, pi, = 0.8 X 10(-7) s for subfragment 1; 1.4 X 10(-7) s for myosin). However, removal of a regulatory light chain, to effect desensitization of the actin-activated ATPase, was associated with an increase in pi for myosin to a value of 2.4 X 10(-6) s. The Ca2+ sensitivity and initial correlation time were restored on recombination of the regulatory light chain in the presence of Mg2+. Sedimentation velocity profiles in an analytical ultracentrifuge indicated that the desensitized myosin preparations were largely monomeric and therefore the change in pi appears to reflect an intramolecular event. Addition of EDTA to spin-labelled scallop heavy meromyosin caused an immediate 2.5 to 4-fold increase in pi and a partial desensitization of the ATPase activity. Comparable experiments with subfragment 1 yielded a barely detectable increase in pi (1.5-fold) in the first ten minutes. The restricted rotational motion observed in desensitized myosin and heavy meromyosin could arise by a conformational change in the subfragment 1-subfragment 2 hinge region or by an association of one head with its partner. The latter mechanism, involving the exposed light chain binding site, would also explain the preferential release of one regulatory light chain from scallop myosin, and might account for some other co-operative effects observed in this molecule (Bagshaw, 1980).     

Calcium ions modulate regulation of smooth muscle contraction mediated by phosphorylation of myosin regulatory light chains

The effect of calcium ions on conformational changes of F-actin initiated by decoration of thin filaments with phosphorylated and dephosphorylated heavy meromyosin from smooth muscles was studied by fluorescence polarization spectroscopy. It is shown that heavy meromyosin with phosphorylated regulatory light chains (pHMM) promotes structural changes of F-actin which are typical for the "strong" binding of actin to the myosin heads. Heavy meromyosin with dephosphorylated regulatory light chains (dpHMM) causes conformational changes of F-actin which are typical for the "weak" binding of actin to the myosin heads. The presence of calcium enhances the pHMM effect and attenuates the dpHMM effect. We propose that a Ca2+-dependent mechanism exists in smooth muscles which modulates the regulation of actin--myosin interaction occurring via phosphorylation of myosin regulatory light chains.