Effect of caldesmon on the ATPase activity and the binding of smooth and skeletal myosin subfragments to actin

We have previously shown that inhibition of the ATPase activity of skeletal muscle myosin subfragment 1 (S1) by caldesmon is correlated with the inhibition of S1 binding in the presence of ATP or pyrophosphate (Chalovich, J., Cornelius, P., and Benson, C. (1987) J. Biol Chem. 262, 5711-5716). In contrast, Lash et al. (Lash, J., Sellers, J., and Hathaway, D. (1986) J. Biol. Chem. 261, 16155-16160) have shown that the inhibition of ATPase activity of smooth muscle heavy meromyosin (HMM) by caldesmon is correlated with an increase in the binding of HMM to actin in the presence of ATP. We now show, in agreement, that caldesmon does increase the binding of smooth muscle HMM to actin-tropomyosin while decreasing the ATPase activity. The effect of caldesmon on the binding of smooth HMM is reversed by Ca2+-calmodulin. Caldesmon strengthens the binding of smooth S1.ATP and skeletal HMM.ATP to actin-tropomyosin but to a lesser extent than smooth HMM.ATP. Furthermore, this increase in binding of smooth S1.ATP and skeletal HMM.ATP does not parallel the inhibition of ATPase activity. In contrast, in the absence of ATP, all smooth and skeletal myosin subfragments compete with caldesmon for binding to actin. Thus, the effect that caldesmon has on the binding of myosin subfragments to actin-tropomyosin depends on the source of myosin, the type of subfragment, and the nucleotide present. The inhibition of actin-activated ATP hydrolysis by caldesmon, however, is not greatly different for different smooth and skeletal myosin subfragments. Evidence is presented that caldesmon inhibits actin-activated ATP hydrolysis by attenuating the productive interaction between myosin and actin that normally accelerates ATP hydrolysis. The increased binding seen by some myosin subfragments, in the presence of ATP, may be due to binding of these subfragments to a nonproductive site on actin-caldesmon. The subfragments which show an increase in binding in the presence of ATP and caldesmon appear to bind directly to caldesmon as demonstrated by affinity chromatography.     

Comparison of ATPase activities and heavy chains of rabbit atrial and thyrotoxic ventricular myosin subfragment-1

Summary Subfragment-1 of rabbit atrial and thyrotoxic ventricular myosin (V₁ isomyosin) has been prepared and purified by DEAF-cellulose column chromatography. Pyrophosphate-polyacrylamide gel electrophoretic patterns and column chromatographic profile of the atrial subfragment differ from those of thyrotoxic ventricular myosin subfragment-1. On the other hand, Ca²⁺, Mg²⁺ and actin-activated ATPase activities of these subfragments are identical. Comparison of the peptide mapping by limited proteolysis in the presence of sodium dodecyl sulfate of the heavy and the light subunits of these subfragments reveals that the patterns for the heavy chain peptides of these subfragments are substantially similar but their light chain peptide patterns differ. The results suggest that the enzymatic and structural similarities that have been recognized between these isoenzymes using intact myosin hold true for the myosin subfragment-1.The differences between these subfragments are due to the differences in the light chains associated with them.Abbreviations EDTA Ethylene Diamine Tetra-acetic Acid - SDS Sodium Dodecyl Sulfate - S₁ myosin subfragment-1 - HC Heavy Chain - LC Light Chain     

Identical behavior of the two active sites of myosin with respect to trinitrophenylation.

Myosin and its active subfragments were trinitrophenylated under conditions in which mainly the active site(s) was modified. Proteins modified at the active site(s) could be separated by affinity chromatography on agarose-ATP columns. By two independent methods, ATPase activity measurements and analysis of elution patterns on agarose-ATP columns, it was shown that the introduction of two trinitrophenyl groups per myosin or one per heavy meromyosin subfragment 1 molecule is responsible for the remarkable change in the ATPase activities. Heavy meromyosin subfragment 1 prepared from trinitrophenylated myosin retained the original degree of trinitrophenylation per "active head." The kinetic constant of trinitrophenylation of the epsilon-amino group of lysine at the active site was found to be 2000 S-1-M-1, whereas a much smaller constant of 2.2 S-1-M-1 was obtained for the trinitrophenylation of the unessential lysyl residues of myosin. By using affinity chromatography, we could follow the formation of mono- and ditrinitrophenyl myosin. The amounts of these myosin derivatives at various extents of the reaction corresponded approximately to the calculated amounts, assuming a random and independent trinitrophenylation of the two myosin "heads." It is concluded that in each of the two heads of myosin there is one ATPase active site and these two sites behave in an identical manner with respect to trinitrophenylation.     

Substructure of the myosin molecule. 3. Preparation of single-headed derivatives of myosin

Native myosin has two globular regions attached to an a-helical rod. Papain is able to cleave the globular “heads” from the rod, leading to the formation of a variety of single-headed molecules. Among these subfragments are isolated globules (HMM S-1) and single globules attached to helical rods of lengths varying from 500 to 1400 Å. These subfragments can be separated from the other products of the proteolytic digestion by salt elution from a DEAE-cellulose column. Some of the properties of single-headed heavy meromyosin and myosin have been determined by hydrodynamic methods, and shadow-cast preparations of these subfragments have been directly visualized by electron microscopy. In addition to providing further evidence for the presence of two similar halves in myosin, these new subfragments can be used in studies related to the question of why myosin has two active “heads”.     

A new cardiac myosin characterized from the canine atria.

Canine atrial myosin light chains were electrophoretically distinct from myosins of canine ventricles on 5–20% polyacrylamide gradient slab gels (SDS), giving molecular weights of 26,000 and 21,000 as compared to 28,000 and 18,500 for ventricular myosin light chains. While atrial myosin heavy chains were immunologically identical with ventricular myosin heavy chains, in contrast, there was 8.0% relative cross-reactivity of atrial myosin light chains with left ventricular myosin light chains by radioimunoassay. According to charge separation on two-dimensional polyacrylamide urea gels, atrial myosin light chains were different from those of ventricular myosins. Variances in ATPase activities between atrial and ventricular myosins were strongly demonstrated. There was a lower K⁺ activated ATPase activity in atrial myosin, however the Ca²⁺ activated ATPase activity, at ATP saturation levels, was higher in atrial myosin as compared to ventricular myosins.     

Interactions of contractile proteins with free and immobilized cibacron Blue F3GA.

Differential binding of contractile proteins from skeletal muscle to Cibacron Blue F3GA-Sepharose affinity columns provides the basis for a new purification technique. Myosin subfragments bind at low ionic strength and are eluted by high salt (e.g., 1.5 m NaCl). Myosin light chain 2 also binds at low ionic strength, whereas light chain 1 is only partially retarded and light chain 3 does not bind. Myosin's marginal solubility in the low-salt buffers required for binding renders it unsuitable for Blue Sepharose chromatography. Neither G-actin nor F-actin bind. Crude preparations of myosin subfragment-1 or light chains undergo significant purification upon Blue Sepharose chromatography. Nee free chromophore inhibits the ATPase activities of myosin and actomyosin at micromolar dye concentrations, whereas the binding of subfragment-1 to actin (in myofibrils) and the tension of glycerinated fibers are inhibited at millimolar dye concentrations. The dye binds at multiple sites on myosin, and inhibits its actomyosin ATPase both competitively and uncompetitively.     

Location of an essential carboxyl group along the heavy chain of cardiac and skeletal myosin subfragments 1

Cardiac and skeletal myosin subfragments 1 cleaved into three fragments were modified by 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide metho-p-toluene-sulfonate in the presence of the nucleophile nitrotyrosine ethyl ester. The effects observed (first-order kinetics of ATPase inactivation, incorporation of 1 mol of nitrotyrosine/mol of subfragment 1) were similar to those previously observed for the nondigested subfragments 1 [Lacombe, G., Van Thiem, N., & Swynghedauw, B. (1981) Biochemistry 20, 3648-3653; K?rner, M., Van Thiem, N., Lacombe, G., & Swynghedauw, B. (1982) Biochem. Biophys. Res. Commun. 105, 1198-1207]. For both native and digested subfragments 1, which were inactivated to the extent of about 70%, the location of the label nitrotyrosine was performed by immunological blotting with 125I-labeled anti-nitrotyrosine immunoglobulins. It was found that the modified residue was essentially located on the heavy chain for the native subfragments 1 and on the 50K peptide for the digested subfragments 1.     

Three-dimensional reconstruction of thin filaments decorated with a Ca2+-regulated myosin

Three-dimensional reconstructions of “barbed” and “blunted” arrowheads (Craig et al., 1980) show that these two forms arise from arrangement of scallop myosin subfragments (S1) that appear about 40 Å longer in the presence of the regulatory light chain than in its absence. A similar difference in apparent length is indicated by images of single myosin subfragments in partially decorated filaments. The extra mass is located at the end of the subfragment furthest from actin, and probably comprises part of the regulatory light chain as well as a segment of the myosin heavy chain. The fact that barbed arrowheads are also formed by myosin subfragments from vertebrate striated and smooth muscles implies that the homologous light chains in these myosins have locations similar to that of the scallop light chain.The scallop light chain probably does not extend into the actin-binding site on the myosin head, and is therefore unlikely to interfere physically with binding. Rather, regulation of actin-myosin interaction by light chains may involve Ca²⁺-dependent changes in the structure of a region near the head-tail junction of myosin.The reconstructions suggest locations for actin and tropomyosin relative to myosin that are similar to those proposed by Taylor & Amos (1981) and are consistent with a revised steric blocking model for regulation by tropomyosin. The identification of actin from these reconstructions is supported by images of partially decorated filaments that display the polarity of the actin helix relative to that of bound myosin subfragments.     

Steady state kinetics at high enzyme concentration. The myosin MgATPase

The rate of ATP hydrolysis by myosin at high concentrations with an ATP-regenerating system increases linearly with increasing added ATP up to a sharp break at the equivalence point of 1 ATP/myosin active site. Theoretical modeling indicates that the data require a KM on the order of the 30 nM value predicted by the rapid kinetic work (Lymn, R. W., and Taylor, E. W. (1970) Biochemistry 7, 2975-2983). Changes in the experimental conditions are found to change the slope of the initial increase in ATPase rate, but not to change the equivalence point. Proteolytic subfragments of myosin do not exhibit a linear initial increase in rate indicating that they are not homogeneous. Purified myosin is also found to show a small additional increase in ATPase rate at much higher ATP levels with a corresponding increase in flux through a pathway with a low extent of oxygen exchange. This high Km component with low oxygen exchange is distinct from the contaminating ATPase reported previously (Sleep, J. A., Hackney, D. D., and Boyer, P. D. (1980) J. Biol. Chem. 255, 4094-4099) which is shown here to be the CaATPase of the sarcoplasmic reticulum.     

Characterization of a caldesmon fragment that competes with myosin-ATP binding to actin.

The protein caldesmon inhibits actin-activated ATP hydrolysis of myosin and inhibits the binding of myosin.ATP to actin. A fragment isolated from a chymotryptic digest of caldesmon contains features of the intact molecule that make it useful as a selective inhibitor of the binding of myosin.ATP complexes to actin without having the complexity of binding to myosin. The COOH-terminal 20 kDa region of caldesmon binds to actin with one-sixth the affinity of caldesmon with a stoichiometry of binding of one fragment per two actin monomers. This contrasts with the 1:6-9 stoichiometry of intact caldesmon. The binding of the 20 kDa fragments to actin is totally reversed by Ca(2+)-calmodulin and, like intact caldesmon, the 20 kDa fragments are competitive with the binding of myosin subfragments to actin. This competition with myosin binding is largely responsible for the inhibition of ATP hydrolysis, although both the fragments and intact caldesmon also reverse the potentiation of ATPase activity caused by tropomyosin. These polypeptides are useful both in defining the function of caldesmon and in studying the role of weakly bound cross-bridges in muscle.     

Rabbit cardiac myosin. II. Proteolytic fragmentation with insolubilized papain.

The substructure of the cardiac myosin molecule was examined by the limited proteolytic digestion of the parent molecule with (dialdehyde starch)-methylenedianiline-mercuripapain, S-MDA-mercuripapain, at low temperatures and neutral pH, using moderate enzyme to myosin rations. Pertinent properties of the insoluble enzyme complex were also examined. Kinetic, ultracentrifugal, and chromatographic observations of the fragmentation process revealed that a single type of lytic reaction occurs during the early stages, predominately releasing heavy meromyosin subfragment 1 (HMM-S1) and myosin rods. With further time digestion, the rods are additionally cleaved yielding light meromyosin and HMM-S2, and HMM-S1 is found to be partially degraded. The major proteolytic subfragments were isolated, purified, and characterized with respect to their enzymatic, optical, amino acid, and physicochemical properties. Only HMM-S1 exhibited Ca-2+-activated ATPase activity, and at a level three- to fourfold higher than that of native myosin. Moreover, its hydrohynamic properties suggest that it is globular in structure. On the other hand, light meromyosin-A (LMM-A) (which consists mainly of rods), and HMM-S2 appear to be highly asymmetric, rigid, alpha-helical molecules devoid of the amino acid proline. Strong similarities were evident in all aspects upon comparison of these results with documented information concerning the skeletal system. On the basis of the physical and chemical properties of the proteolytic subfragments relative to that of native myosin, it was further concluded that the cardiac myosin molecule is a double-stranded, alpha-helical rod ending in tow subfragment 1 globules, of which only one may be enzymatically active at a time.     

Purification and characterization of myosin from bovine retina.

Myosin has been isolated from bovine retinae and characterised by its ATPase (ATP phosphohydrolase, EC 3.6.1.3) activity, its mobility in sodium dodecyl sulphate polyacrylamide gels and by electron microscopy. The purified myosin shows high ATPase activity in the presence of EDTA or Ca2+ and a low activity in the presence of Mg2+. The Mg2+-dependent ATPase activity is stimulated by rabbit skeletal muscle actin. The presumptive retinal myosin possesses a major component which has a mobility in sodium dodecyl sulphate polyacrylamide gel electrophoresis similar to that of the heavy chain of bovine skeletal muscle myosin. Electron microscopy showed retinal myosin to form bipolar filaments in 0.1 M KCl. It is concluded that the retina possesses a protein with enzymic and structural properties similar to those of muscle myosin.     

Myosin degradation fragments in skeletal muscle

Myosin heavy chain degradation fragments produced in vivo have been identified in chicken pectoralis muscle. The fragments were identified by electrophoresis of unfractionated extracts of chicken pectoralis muscle on sodium dodecyl sulfate/polyacrylamide gels followed by immunoblotting on nitrocellulose sheets. Monoclonal antibodies directed against the S2 and light meromyosin subfragments as well as type II myosin-specific polyclonal antibodies directed against the entire myosin heavy chain were used to characterize the fragments, which range in molecular weight from approximately 80,000 to 180,000. All fragments contain the extreme carboxy-terminal portion of the molecule and are distinct from the classical proteolytic fragments such as heavy and light meromyosin, S1, S2 or rod. These fragments appear to be produced in vivo by proteolytic cleavage of peptides from the amino-terminal (S1) end of the heavy chain while the myosin molecule is still embedded in the thick filament. Fragment concentrations are estimated to be approximately 5 to 10% of that of the intact myosin heavy chain. These fragments are not the result of artifactual damage to myosin, e.g. proteolysis or hydrodynamic shear. The techniques described in this paper provide a probe into the early stages of myosin and thick filament degradation in vivo.     

Tension development in skinned glycerinated rabbit psoas fiber segments irrigated with soluble myosin fragments.

Single glycerinated rabbit psoas muscle fibers were skinned by splitting them lengthwise. The fiber segments thus obtained were more easily accessible to solutes in the surrounding medium than the intact fibers. Using such segments, active tension could be fully abolished by adding N-ethylmaleimide under conditions which lead to inhibition of actin activation of the ATPase activity of myosin. Such muscles could, however, develop tension after irrigation with myosin or with the water-soluble active myosin fragments heavy meromyosin (HMM) or its subfragment 1 (HMM-S1). The induced tensions increased with increasing protein concentration in the irrigating solution. At any given protein concentration, the tension generated by myosin was larger than that produced by HMM which was, in turn, greater than that induced by HMM-S1 e.g. at 15 mg/ml protein the tensions produced by these three myosin moieties were 44.0, 14.0 and 2.8 g/cm2, respectively. The tension was found to be intimately associated with ATP splitting; thus, HMM and HMM-S1 which have been treated with reagents abolishing actin-activated ATPase failed to induce tension development. A contractile force may thus be generated through the interaction with actin of the water-soluble, enzymatically active, myosin subfragments involving the splitting of ATP.     

Purification and characterization of myosin from bovine retina

Myosin has been isolated from bovine retinae and characterised by its ATPase (ATP phosphohydrolase, EC 3.6.1.3) activity, its mobility in sodium dodecyl sulphate polyacrylamide gels and by electron microscopy. The purified myosin shows high ATPase activity in the presence of EDTA or Ca²⁺ and a low activity in the presence of Mg²⁺. The Mg²⁺-dependent ATPase activity is stimulated by rabbit skeletal muscle actin. The presumptive retinal myosin possesses a major component which has a mobility in sodium dodecyl sulphate polyacrylamide gel electrophoresis similar to that of the heavy chain of bovine skeletal mucle myosin. Electron microscopy showed retinal myosin to form bipolar filaments in 0.1 M KCl. It is concluded that the retina possesses a protein with enzymic and structural properties similar to those of muscle myosin.     

Myosin molecule packing within the vertebrate skeletal muscle thick filaments. A complete bipolar model

Computer modelling related to the real dimensions of both the whole filament and the myosin molecule subfragments has revealed two alternative modes for myosin molecule packing which lead to the head disposition similar to that observed by EM on the surface of the cross-bridge zone of the relaxed vertebrate skeletal muscle thick filaments. One of the modes has been known for three decades and is usually incorporated into the so-called three-stranded model. The new mode differs from the former one in two aspects: (1) myosin heads are grouped into asymmetrical cross-bridge crowns instead of symmetrical ones; (2) not the whole myosin tail, but only a 43-nm C-terminus of each of them is straightened and near-parallel to the filament axis, the rest of the tail is twisted. Concurrent exploration of these alternative modes has revealed their influence on the filament features. The parameter values for the filament models as well as for the building units depicting the myosin molecule subfragments are verified by experimental data found in the literature. On the basis of the new mode for myosin molecule packing a complete bipolar structure of the thick filament is created.     

Myosin expression in the developing ascidian embryo

Myosin accumulation was examined in developing ascidian embryos by measuring its ATPase activity and by resolving myosin heavy chains on polyacrylamide gels. Both procedures used a myosin-enriched fraction that was prepared by exploiting the unusual solubility properties of this protein. Myosin ATPase was first observed at neurulation and increased 25- to 50-fold by the time of larval hatching, a sequence similar to that found previously for muscle acetylcholinesterase. This similarity to acetylcholinesterase,and the finding of at least two-thirds of the ATPase activity in the larval tail,imply that most of the myosin studied was muscle myosin. The pattern of expression based on ATPase assays was confirmed in part by gel analysis, but since this technique was less sensitive the appearance of myosin heavy chain was not demonstrated unambiguously until later in development. As found earlier with acetylcholinesterase, actinomycin D treatment only interfered with accumulation of myosin ATPase during early stages of increasing enzymatic activity. Despite certain similarities noted in their ontogeny, differences in the initial increase in the activity of these enzymes and the time of their first response to actinomycin D suggest that the events concerned with the expression of acetylcholinesterase occur 1 hour before those of myosin ATPase.The appearance of these two proteins, representing different enzymes of the muscle cell, is probably controlled independently.     

Cross-linking of contractile proteins from skeletal muscle by treatment with microbial transglutaminase.

The action on muscle proteins of microbial transglutaminase (MTGase), which catalyzes the formation of a "zero-length" covalent cross-link between glutamine and lysine residues in peptides, was studied in order to define a basis for future application of MTGase cross-linking to the study of muscle protein interaction. We examined the cross-linking of skeletal muscle myosin, myosin subfragments, actin, and myofibrils by treatment with MTGase and the possible side-effects of the cross-linking on the enzymic activity of myosin, and found that the rod portions of myosin in myosin filaments were quickly cross-linked to each other by the action of MTGase, but myosin subfragment 1 was not cross-linked to actin. The MgATPase activities at 0.5 M KCl of myosin, heavy meromyosin, subfragment 1, and subfragment 1-actin were not significantly affected by the MTGase reaction. A very small fraction of the head portion of heavy meromyosin was cross-linked to actin in their rigor complexes by MTGase, and the ATPase activity at 0.5 M KCl of the cross-linked heavy meromyosin-actin complexes was slightly enhanced.     

Electrophoretic analysis of multiple forms of myosin in fast-twitch and slow-twitch muscles of the chick.

1. A method is described for the electrophoretic analysis of intact myosin in polyacrylamide gel in a buffer system containing 0.02 M-pyrophosphate and 10% (v/v) glycerol, pH 8.8. 2. In this system chicken skeletal-muscle myosins reveal five distinct electrophoretic components, three components from the fast-twitch posterior latissimus dorsi muscle and two slower-migrating components from the slow-twitch anterior latissimus dorsi muscle. 3. The Ca2+-activated ATPase (adenosine triphosphatase) activity of myosin components was measured by densitometric scanning of the gel for the Ca3(PO4)2 precipitate formed during the ATPase reaction and subsequently for stained protein. Each component from the same muscle appears to have identical ATPase activity, but components from the fast-twitch muscle had an activity 2.2 times higher than those from the slow-twitch muscle. 4. On re-electrophoresis in the same buffer system, individual fractions of fast-twitch myosin did not reproduce the three-band pattern of the original myosin, but migrated at rates consistent with their original mobility. 5. Analysis of the mobility of the three fast-twitch myosin components in gels of different concentrations suggests that they are not stable oligomers of each other. 6. It is suggested that these components of fast-twitch myosin and slow-twitch myosin are isoenzymes of myosin.     

The kinetics of bivalent metal ion dissociation from myosin subfragments.

Bivalent metal ions have multiple roles in subunit association and ATPase regulation in scallop adductor-muscle myosin. To help elucidate these functions, the rates of Ca2+ and Mg2+ dissociation from the non-specific high-affinity sites on the regulatory light chains were measured and compared with those of rabbit skeletal-muscle myosin subfragments. Ca2+ dissociation had a rate constant of about 0.7 s-1 in both species, as measured by the time course of the pH change on EDTA addition. Mg2+ dissociation had a rate constant of 0.05 s-1, as monitored by its displacement with the paramagnetic Mn2+ ion. It is concluded that the exchange between Ca2+ and Mg2+ at the non-specific site, on excitation of both skeletal and adductor muscles, is too slow to contribute to the activation itself. The release of bivalent metal ions from the non-specific site is, however, the first step in release of the scallop regulatory light chain (Bennett & Bagshaw (1986) Biochem. J. 233, 179-186). In scallop myosin additional specific sites are present, which can bind Ca2+ rapidly, to effect activation of the ATPase. In the course of this work, Ca2+ dissociation from EGTA was studied as a model system. This gave rates of 1 s-1 and 0.3 s-1 at pH 7.0 and pH 8.0 respectively.