Structure-function studies on Acanthamoeba myosins IA, IB, and II

Myosins IA and IB are globular proteins with only a single, short (for myosins) heavy chain (140,000 and 125,000 daltons for IA and IB, respectively) and are unable to form bipolar filaments. The amino acid sequence of IB heavy chain shows 55% similarity to muscle myosins in the N-terminal 670 residues, which contain the active sites, and a unique 500-residue C-terminus highly enriched in proline, glycine, and alanine. The C-terminal region contains a second actin-binding site which allows myosins IA and IB to cross-link actin filaments and support contractile activity. Myosins IA and IB are regulated solely by phosphorylation of one serine on the heavy chain positioned between the catalytic site and the actin-binding site that activates ATPase. Myosin II is a more conventional myosin in composition (two heavy chains and two pairs of light chains), heavy chain sequence (globular head 45% identical to muscle myosins and a coiled-coil helical tail), and structure (bipolar filaments). The tail of myosin II is much shorter than that of other conventional myosins, and it contains a 25 amino acid sequence in which helical structure is predicted to be weak or absent. The position of this sequence corresponds to the position of a bend in the monomer. Myosin II heavy chains also have a 29-residue nonhelical tailpiece which contains three regulatory, phosphorylatable serines. Phosphorylation at the tip of the tail regulates ATPase activity in the globular head apparently through an effect on filament structure.     

Formation and characterization of myosin hybrids containing essential light chains and heavy chains from different muscle myosins

Light chain exchange in 4.7 M NH4Cl was used to hybridize the essential light chain of cardiac myosin with the heavy chain of fast muscle myosin subfragment 1, S-1. The actin-activated ATPase properties of this hybrid were compared to those of the two fast S-1 isoenzymes, S-1(A1), fast muscle subfragment 1 which contains only the alkali-1 light chain, and S-1(A2), fast muscle myosin subfragment 1 which contains only the alkali-2 light chain. This hybrid S-1 behaved like S-1(A1)., At low ionic strength in the presence of actin, this hybrid had a maximal rate of ATP hydrolysis about the same as that of S-1(A1) and about one-half that of S-1(A2), while at higher ionic strengths the actin-activated ATPases of these three S-2 species were all similar. Light chain exchange in NH4Cl was also used to hybridize the essential light chains of fast muscle myosin with the heavy chains of cardiac myosin and to hybridize the essential light chains of cardiac myosin with the heavy chains of fast muscle myosin. In 60 and 100 mM KCl, the actin-activated ATPases of these two hybrid myosins were very different from those of the control myosins with the same essential light chains but were very similar to those of the control myosins with the same heavy chains, differing at most by one-third.     

Regulatory light chains in myosins.

Scallop myosin molecules contain two moles of regulatory light chains and two moles of light chains with unknown function. Removal of one of the regulatory light chains by treatment with EDTA is accompanied by the complete loss of the calcium dependence of the actin-activated ATPase activity and by the loss of one of the two calcium binding sites on the intact molecule. Such desensitized preparations recombine with one mole of regulatory light chain and regain calcium regulation and calcium binding. The second regulatory light chain may be selectively obtained from EDTA-treated scallop muscles by treatment with the Ellman reagent (5,5′-dithiobis(2-nitrobenzoic acid)): treatment with this reagent, however, leads to an irreversible loss of ATPase activity. The light chains obtained by treatment with EDTA and then DTNB are identical in composition and function. A different light chain fraction obtained by subsequent treatment with guanidine-HCl does not bind to desensitized or intact myoflbrils and has no effect on ATPase activity.Regulatory light chains which bind to desensitized scallop myofibrils with high affinity and restore calcium control were found in a number of molluscan and vertebrate myosins, including Mercenaria, Spisula, squid, lobster tail, beef heart, chicken gizzard, frog and rabbit. Although these myosins all have a similar subunit structure and contain about two moles of regulatory light chain, only scallop myosin or myofibrils can be desensitized by treatment with EDTA.There appear to be two classes of regulatory light chains. The regulatory light chains of molluscs and of vertebrate smooth muscles restore full calcium binding and also resensitize purified scallop myosin. The regulatory light chains from vertebrate striated, cardiac, and the fast decapod muscles, on the other hand, have no effect on calcium binding and do not resensitize purified scallop myosin unless the myosin is complexed with actin. The latter class of light chains is found in muscles where in vitro functional tests failed to detect myosin-linked regulation.     

Phosphorylation in skeletal myosin light chain modulates the actin--myosin interaction in the presence of regulatory proteins in vitro

The effect of phosphorylation in skeletal myosin light chain (LC2) on the actomyosin and acto-heavymeromyosin (HMM) ATPase activities was investigated in the presence or absence of regulatory proteins (tropomyosin-troponin complex). Phosphorylation in LC2 did not modulate the actin-myosin and actin-HMM interactions over a wide range of KCl concentrations from 30 to 150 mM without regulatory proteins. In the presence of regulatory proteins, phosphorylation in myosin LC2 enhanced the ATPase activity of actomyosin with calcium ions, but the removal of calcium ions made little difference in the ATPase activity between phosphorylated and dephosphorylated myosins. Ca2+-sensitivity of the regulated actomyosin was slightly changed by phosphorylation in myosin LC2. However, both the ATPase activity and Ca2+-sensitivity of the regulated acto-HMM were unaffected by phosphorylation in HMM LC2.     

Regulation of scallop myosin by mutant regulatory light chains

Scallop adductor myosin is regulated by its subunits; the regulatory light chain (R-LC) and essential light chain (E-LC). Myosin light chains suppress muscle activity in the absence of calcium and are responsible for relaxation. The binding of Ca2+ to the myosin triggers contraction by releasing the inhibition imposed on myosin by the light chains. To map the functional domains of the R-LC, we have carried out mutagenesis followed by bacterial expression. Both wild-type and mutant proteins were hybridized to scallop myosin heavy chain/E-LC to map the regions of the light chain that are responsible for the binding to the myosin heavy chain/E-LC, for restoring the specific calcium-binding site, and controlling the myosin ATPase activity. The R-LC is expressed in Escherichia coli using the pKK223-3 (Pharmacia) expression vector and has been purified to greater than 90% purity. E. coli-expressed wild-type R-LC differs from the native R-LC by having the initiating methionine residue and an unblocked NH2 terminus. The wild-type R-LC restores Ca2+ binding and Ca2+ sensitivity when hybridized to scallop myosin. A point mutation of the sixth Ca2(+)-liganding position of domain I (Asp39----Ala39) results in a R-LC that binds more weakly to the heavy chain/E-LC and restores the specific Ca2(+)-binding site but not regulation of the actin-activated Mg2+ ATPase. A second mutation was produced by substituting the last 11 residues of the COOH terminus with 15 different residues. This mutant restores the specific Ca2(+)-binding site, but does not restore Ca2+ regulation to the actin-activated ATPase activity. Several other point mutations do not alter light chain function. The experiments directly establish that the divalent cation-binding site of domain I is functionally distinct from the specific Ca2(+)-binding site. The results indicate that an intact domain I and the COOH terminus are required to suppress the myosin ATPase activity. The fact that the domain I mutation and the COOH-terminal mutation disrupt regulation but do not affect Ca2(+)-binding indicates that these two aspects of regulation are separable and, therefore, the R-LC has distinct functional regions.     

Roles of myosin phosphatase during Drosophila development

Myosins are a superfamily of actin-dependent molecular motor proteins, among which the bipolar filament forming myosins II have been the most studied. The activity of smooth muscle/non-muscle myosin II is regulated by phosphorylation of the regulatory light chains, that in turn is modulated by the antagonistic activity of myosin light chain kinase and myosin light chain phosphatase. The phosphatase activity is mainly regulated through phosphorylation of its myosin binding subunit MYPT. To identify the function of these phosphorylation events, we have molecularly characterized the Drosophila homologue of MYPT, and analyzed its mutant phenotypes. We find that Drosophila MYPT is required for cell sheet movement during dorsal closure, morphogenesis of the eye, and ring canal growth during oogenesis. Our results indicate that the regulation of the phosphorylation of myosin regulatory light chains, or dynamic activation and inactivation of myosin II, is essential for its various functions during many developmental processes.     

Myosins and pathology: genetics and biology

This article summarizes current knowledge on the genetics and possible molecular mechanisms of Human pathologies resulted from mutations within the genes encoding several myosin isoforms. Mutations within the genes encoding some myosin isoforms have been found to be responsible for blindness (myosins III and VIIA), deafness (myosins I, IIA, IIIA, VI, VIIA and XV) and familial hypertrophic cardiomyopathy (beta cardiac myosin heavy chain and both the regulatory and essential light chains). Myosin III localizes predominantly to photoreceptor cells and is proved to be engaged in the vision process in Drosophila. In the inner ear, myosin I is postulated to play a role as an adaptive motor in the tip links of stereocilia of hair cells, myosin IIA seems to be responsible for stabilizing the contacts between adjacent inner ear hair cells, myosin VI plays a role as an intracellular motor transporting membrane structures within the hair cells while myosin VIIA most probably participates in forming links between neighbouring stereocilia and myosin XV probably stabilizes the stereocilia structure. About 30% of patients with familial hypertrophic cardiomyopathy have mutations within the genes encoding the beta cardiac myosin heavy chain and both light chains that are grouped within the regions of myosin head crucial for its functions. The alterations lead to the destabilization of sarcomeres and to a decrease of the myosin ATPase activity and its ability to move actin filaments.     

Regulatory properties of single-headed fragments of scallop myosin.

Calcium control was studied in single-headed myosin and subfragment-1 (S1) preparations obtained by papain digestion of scallop myosin. Single-headed myosin, containing light chains in stoichiometric amounts, was calcium regulated; in contrast, the actin-activated Mg-ATPase of all S1 species lacked calcium sensitivity. Both regulatory and essential light chains were retained by S1 and single-headed myosin preparations provided divalent cations were present during papain digestion, although a peptide amounting to 10% of the mass was removed from regulatory light chains. The modified regulatory light chain retained its ability to confer calcium binding and restore calcium sensitivity to the ATPase of desensitized myofibrils. Regulatory light chains protected the essential light chains from fragmentation by papain. S1 bound regulatory light chains with a uniformly high affinity and appeared to consist of a single species. The results demonstrate that head to head interactions are not obligatory for calcium control, although they may occur in the intact myosin molecule, and suggest a role for the subfragment-2 region in calcium regulation of myosin.     

Isolation and characterization of myosin from amoebae of Physarum polycephalum

Myosin was isolated from amoebae of Physarum polycephalum and compared with myosin from plasmodia, another motile stage in the Physarum life cycle. Amoebal myosin contained heavy chains (Mr approximately 220,000), phosphorylatable light chains (Mr 18,000), and Ca2+-binding light chains (Mr 14,000) and possessed a two-headed long-tailed shape in electron micrographs after rotary shadow casting. In the presence of high salt concentrations, myosin ATPase activity increased in the following order: Mg-ATPase activity less than K-EDTA-ATPase activity less than Ca-ATPase activity. In the presence of low salt concentrations, Mg-ATPase activity was activated approximately 9-fold by skeletal muscle actin. This actin-activated ATPase activity was inhibited by micromolar levels of Ca2+. Amoebal myosin was indistinguishable from plasmodial myosin in ATPase activities and molecular shape. However, the heavy chain and phosphorylatable light chains of amoebal myosin could be distinguished from those of plasmodial myosin in sodium dodecyl sulfate-polyacrylamide gel electrophoresis, peptide mapping, and immunological studies, suggesting that these are different gene products. Ca2+-binding light chains of amoebal and plasmodial myosins were found to be identical using similar criteria, supporting our hypothesis that the Ca2+-binding light chain plays a key role in the inhibition of actin-activated ATPase activity in Physarum myosins by micromolar levels of Ca2+.     

Functional regions in the essential light chain of smooth muscle myosin as revealed by the mutagenesis approach.

The endogenous essential light chain (LC17) of myosin from intestine smooth muscle was replaced with mutated essential light chains prepared using recombinant techniques. Complete exchange was observed with histidine-tagged derivatives of LC17a, LC17b and E122A-LC17a (LC17a and LC17b are the usual constituants of smooth muscle myosin), with small changes in the ATPase activity of reconstituted myosins. Much less exchange was observed with the light-chain derivative lacking the last 12 amino acid residues, demonstrating the importance of this segment, which may act as one arm of a pair of pincers to bind the myosin heavy chain.     

Native nonmuscle myosin II stability and light chain binding in Drosophila melanogaster

Native nonmuscle myosin IIs play essential roles in cellular and developmental processes throughout phylogeny. Individual motor molecules consist of a heterohexameric complex of three polypeptides which, when properly assembled, are capable of force generation. Here, we more completely characterize the properties, relationships and associations that each subunit has with one another in Drosophila melanogaster. All three native nonmuscle myosin II polypeptide subunits are expressed in close to constant stoichiometry to each other throughout development. We find that the stability of two subunits, the heavy chain and the regulatory light chain, depend on one another whereas the stability of the third subunit, the essential light chain, does not depend on either the heavy chain or regulatory light chain. We demonstrate that heavy chain aggregates, which form when regulatory light chain is lacking, associate with the essential light chain in vivo-thus showing that regulatory light chain association is required for heavy chain solubility. By immunodepletion we find that the majority of both light chains are associated with the nonmuscle myosin II heavy chain but pools of free light chain and/or light chain bound to other proteins are present. We identify four myosins (myosin II, myosin V, myosin VI and myosin VIIA) and a microtubule-associated protein (asp/Abnormal spindle) as binding partners for the essential light chain (but not the regulatory light chain) through mass spectrometry and co-precipitation. Using an in silico approach we identify six previously uncharacterized genes that contain IQ-motifs and may be essential light chain binding partners.     

Proteolytic susceptibility of both isolated and bound light chains from various myosins to myopathic hamster protease

Myopathic hamster protease was incubated with turkey gizzard, scallop adductor, and Loligo mantle retractor myosins in order to establish if the regulatory light chain could be selectively digested. In contrast to cardiac or skeletal muscle myosin in which almost all of the regulatory light chain is degraded, these light chains from smooth and invertebrate muscle myosins were remarkably resistant to proteolysis. In the case of scallop myosin, increasing the protease to myosin ratio resulted in comparable digestions of both the regulatory and essential light chains regardless of the presence of Mg2+. The isolated light chains on the other hand were readily digested into smaller fragments. In addition, it was observed that the myosin heavy chains were extremely sensitive and that it was possible to cleave them quantitatively to produce a new band moving with a mobility on SDS gels corresponding to an Mr of approximately 150,000. This was again at variance with cardiac or skeletal myosin where the breakdown of the heavy chains was shown to be minimal. In spite of the significant extent of heavy chain cleavage, gizzard myosin appears to maintain its tertiary structure as demonstrated by sedimentation velocity and equilibrium ultracentrifugation analysis. Moreover, upon examination by electron microscopy, both intact and cleaved gizzard myosin revealed the characteristic folded structure which had a sedimentation rate of about 10 S when dialyzed into a low salt, Mg X ATP-containing buffer. The effects and implications of such modifications on catalytic activities of gizzard, scallop, and Loligo myosins are discussed in detail.     

White muscle differentiation in the eel (Anguilla anguilla L.): changes in the myosin isoforms pattern and ATPase profile during post-metamorphic development

Myosin isoforms and their light and heavy chains subunits were studied in the white lateral muscle of the eel during the post metamorphic development, in relation with the myosin ATPase profile. At elver stage VI A1 the myosin isoforms pattern was characterized by at least two isoforms, FM3 and FM2. The fast isomyosin type 1 (FM1) appeared during subsequent development. It increased progressively in correlation with the increase in the level of the light chain LC3f. FM1 became predominant at stage VI A4. At the elver stage VI A1, sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis showed at least two heavy chains, namely type II-1 and II-2. The type II-1 heavy chain disappeared in the yellow eel white muscle, and V8-protease peptide map showed the appearance of a minor heavy chain type II-3 as early as stage VI B. Comparison of myosin heavy chains and myosin isoforms patterns showed the comigration of different myosin isoforms during white muscle development. The myosin ATPase profile was characterized by a uniform pattern as far as stage VI A4. A mosaic aspect in white muscle was observed as early as stage VI B, showing the appearance of small acid labile fibers. This observation suggests that the type II-3 heavy chain is specific to the small fibers.     

Regulation of protein synthesis and accumulation during oogenesis in Xenopus laevis

The tissue and developmental distribution of the various myosin subunits has been examined in bovine cardiac muscle. Electrophoretic analysis shows that a myosin light chain found in fetal but not in adult ventricular myosin is very similar and possibly identical to the light chain found in fetal or adult atrial and adult Purkinje fiber myosins. This light chain comigrates on two-dimensional gels with the bovine skeletal muscle embryonic light chain. Thus, this protein appears to be expressed only at early developmental stages in some tissues (cardiac ventricles, skeletal muscle) but at all stages in others (cardiac atria). The heavy chains of these myosins have been examined by one- and two-dimensional polypeptide mapping. The ventricular and Purkinje fiber heavy chains are indistinguishable. They are, however, different from the heavy chain found in cultured skeletal muscle myotubes, in contrast to the situation concerning the embryonic/atrial light chain.     

Refined model of the 10S conformation of smooth muscle myosin by cryo-electron microscopy 3D image reconstruction

The actin-activated ATPase activity of smooth muscle myosin and heavy meromyosin (smHMM) is regulated by phosphorylation of the regulatory light chain (RLC). Complete regulation requires two intact myosin heads because single-headed myosin subfragments are always active. 2D crystalline arrays of the 10S form of intact myosin, which has a dephosphorylated RLC, were produced on a positively charged lipid monolayer and imaged in 3D at 2.0 nm resolution by cryo-electron microscopy of frozen, hydrated specimens. An atomic model of smooth muscle myosin was constructed from the X-ray structures of the smooth muscle myosin motor domain and essential light chain and a homology model of the RLC was produced based on the skeletal muscle S1 structure. The initial model of the 10S myosin, based on the previous reconstruction of smHMM, was subjected to real space refinement to obtain a quantitative fit to the density. The smHMM was likewise refined and both refined models reveal the same asymmetric interaction between the upper 50 kDa domain of the "blocked" head and parts of the catalytic, converter domains and the essential light chain of the "free" head observed previously. This observation suggests that this interaction is not simply due to crystallographic packing but is enforced by elements of the myosin heads. The 10S reconstruction shows additional alpha-helical coiled-coil not seen in the earlier smHMM reconstruction, but the location of one segment of S2 is the same in both.     

Regulation of calmodulin-binding myosins

Myosins constitute a diverse superfamily of actin-based mechanoenzymes that are involved in many essential cellular motilities. In addition to conventional muscle myosin II, ten other classes of unconventional myosins are known. Many unconventional myosins bind multiple calmodulin light chains and Ca2+, which can dramatically alter their mechanochemical and enzymatic activity. Calmodulin-binding myosins can also be regulated by phospholipid binding, phosphorylation of the heavy chain and actin-binding proteins. The molecular details linking unconventional-myosin regulation and function are just beginning to emerge.     

Random phosphorylation of the two heads of thymus myosin and the independent stimulation of their actin-activated ATPases

Like other vertebrate nonmuscle myosins, thymus myosin contains two phosphorylatable light chains. Phosphorylation of these light chains regulates the actin-activated ATPase of this myosin. The time courses for the phosphorylation of both monomeric and filamentous thymus myosin by gizzard myosin light chain kinase fitted single exponentials to greater than 85% phosphorylation. This indicates that the two heads of thymus myosin are phosphorylated at the same rate and suggests that these phosphorylations are random processes. The actin-activated ATPases of thymus myosins with different levels of light chain phosphorylation were also determined. A linear relationship was obtained between the extent of light chain phosphorylation and stimulation of the actin-activated ATPase. Since thymus myosin appears to be phosphorylated randomly, this linear relationship indicates that phosphorylation of one head of thymus myosin stimulates the actin-activated ATPase of that head independently of the phosphorylation of the second head. The apparent random phosphorylation of thymus myosin light chains contrasts with the reported ordered phosphorylation of the light chains of filamentous smooth (gizzard) muscle myosin. Also, while the actin-activated ATPases of the two heads of thymus myosin are regulated independently, both heads of gizzard myosin must be phosphorylated before the ATPase of either head is activated by actin.     

Myosins of secretory tissues

Myosin has been purified from the principal pancreatic islet of catfish, hog salivary gland, and hog pituitary. Use of the protease inhibitor Trasylol (FBA Pharmaceuticals, New York) was essential in the isolation of pituitary myosin. Secretory tissue myosins were very similar to smooth muscle myosin, having a heavy chain of 200,000 daltons and light chains of 14,000 and 19,000 daltons. Salivary gland myosin cross-reacted with antibodies directed toward both smooth muscle myosin and fibroblast myosin, but not with antiskeletal muscel myosin serum. The specific myosin ATPase activity measured in 0.6 M KCl was present. Tissues associated with secretion of hormone granules contained substantial amounts of this ATPase, rat pancreatic islets having 4.5 times that of rat liver. Activation of low ionic strength myosin ATPase by actin could not be demonstrated despite adequate binding of the myosin to muscle actin and elution by MgATP. The myosins were located primarily in the cytoplasm as determined by cell fractionation and were quite soluble in buffers of low ionic strength.     

The light chains of scallop myosin as regulatory subunits

In molluscan muscles contraction is regulated by the interaction of calcium with myosin. The calcium dependence of the aotin-activated ATPase activity of scallop myosin requires the presence of a specific light chain. This light chain is released from myosin by EDTA treatment (EDTA-light chains) and its removal desensitizes the myosin, i.e. abolishes the calcium requirement for the actin-activated ATPase activity, and reduces the amount of calcium the myosin binds; the isolated light chain, however, does not bind calcium and has no ATPase activity. Calcium regulation and calcium binding is restored when the EDTA-light chain is recombined with desensitized myosin preparations. Dissociation of the EDTA-light chain from myosin depends on the concentration of divalent cations; half dissociation is reached at about 10^?5 M-magnesium or 10^?7 M-calcium concentrations. The EDTA-light chain and the residual myosin are fairly stable and the components may be kept separated for a day or so before recombination.Additional light chains containing half cystine residues (SH-light chains) are detached from desensitized myosin by sodium dodecyl sulfate. The EDTA-light chains and the SH-light chains have a similar chain weight of about 18,000 daltons; however, they differ in several amino acid residues and the EDTA-light chains contain no half cystine. The SH-light chains and EDTA-light chains have different tryptic fingerprints. Both light chains can be prepared from washed myofibrils.Densitometry of dodecyl sulfate gel electrophoresis bands and Sephadex chromatography in sodium dodecyl sulfate indicate that there are three moles of light chains in a mole of purified myosin, but only two in myosin treated with EDTA. The ratio of the SH-light chains to EDTA-light chains was found to be two to one in experiments where the total light-chain complements of myosin or myofibril preparations were carboxymethylated. A similar ratio was obtained from the densitometry of urea-acrylamide gel electrophoresis bands. We conclude that a myosin molecule contains two moles of SH-light chain and one mole of EDTA-light chain, and that the removal of a single EDTA-light chain completely desensitizes scallop myosin.Heavy meromyosin and S-1 subfragment can be prepared from scallop myosin. Both of these preparations bind calcium and contain light chains in significant amounts. The heavy meromyosin of scallop is extensively degraded; the S-1 preparation, however, is remarkably intact. Significantly, heavy meromyosin has a calcium-dependent actin-activated ATPase while the S-1 does not require calcium and shows high ATPase activity in its absence. These results suggest that regulation involves a co-operativity between the two globular ends of the myosin.Desensitized scallop myosin and scallop S-1 preparations can be made calcium sensitive when mixed with rabbit actin containing the rabbit regulatory proteins. This result makes it unlikely that specific light chains of myosin are involved in the regulation of the vertebrate system.The fundamental similarity in the contractile regulation of molluscs and vertebrates is that interaction between actin and myosin in both systems requires a critical level of calcium. We propose that the difference in regulation of these systems is that the interaction between myosin and actin is prevented by blocking sites on actin in the case of vertebrate muscles, whereas in the case of molluscan muscles it is the sites on myosin which are blocked in the absence of calcium.     

A comparative study of reactive--SH groups of cardiac and skeletal muscle myosins.

Cardiac and skeletal muscle myosins have been treated by N-ethylmaleimide in presence or absence of Mg-ADP. The variations of Ca2+ and K+-ATPase activities and the incorporation of N-[14C]ethylmaleimide into the whole myosin molecule and into its separated subunits (heavy and light chains) have been measured with N-ethylmaleimide treatment for different lengths of time. The results reported here show the following: 1. The Ca2+-ATPase activity of cardiac myosin is activated by N-ethylmaleimide treatment to a lesser extent than that of skeletal myosin. 2. The K+-ATPase activity of both myosins is inhibited in the same quantitative way. 3. The cardiac light chain L1 contains one highly reactive thiol group which is absent from the skeletal light chains. 4. The labelling of three SH-groups localized in the heavy subunits of both myosins induced the same degree of inactivation. 5. The difference observed between the degree of inhibition of the Ca2+-ATPase activity for the two types of myosin with longer treatments appears to be due to differences in the reactivity of the fourth--SH group labelled on the heavy chains.