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+.     

Effect of N-ethylmaleimide on Ca-inhibition of Physarum myosin

We have established a quick method for preparing Physarum myosins whose actin-activated ATPase activities are inhibited by microM levels of Ca2+ (from plasmodial stage: Kohama, K. & Kendrick-Jones, J. (1986) J. Biochem. 99, 1433-1446; and from amoebal stage: Kohama, K., Takano-Ohmuro, H., Tanaka, T., Yamaguchi, Y., & Kohama, T. (1986) J. Biol. Chem. 261, 8022-8027). N-Ethylmaleimide alkylates sulfhydryl (SH) groups on the heavy chains in the heads of the plasmodial myosin. The actin-activated ATPase activity of the modified myosin was significantly decreased when assayed in low Ca2+ concentrations. Moreover, the activity remained low even when the Ca2+ concentrations was increased, i.e., the myosin was desensitized. For complete desensitization, about 4 mol SH per mol myosin (500,000 Mr) must be modified. These residues are probably the "reactive thiols" which have been predicted from primary structure studies to be conserved among myosins of higher and lower eukaryotes. Ultraviolet absorption spectra of the modified and intact myosins showed a peak at 277 nm. The height of this peak in intact myosin was reduced when the Ca2+ concentration was increased. This Ca-induced reduction was hardly detectable in the modified myosin although Ca-binding activity to myosin did not appear to be affected by the modification. We interprete these results that Ca2+ may change the conformation of the myosin heavy chain by binding to myosin and speculate that impairment of this process upon modification could cause the desensitization to Ca2+ in the ATPase activity.     

Canine cardiac myosin with special referrence to pressure overload cardiac hypertrophy. I. Subunit composition.

In studies of myosin from left and right ventricles of normal hearts and hypertrophic hearts at 5 weeks and 13 weeks after aortic banding, polyacrylamide gel electrophoresis shows intermediate molecular weight components which derive from heavy chains fragmented in the presence of dodecyl sulfate. The proportion of degraded heavy chains is greater in myosin from hypertrophic hearts than normal hearts, with comparable degradation in left and right ventricle myosin. The observed fragmentation of myosin results from proteolysis due to contaminant proteases or a thermally activated, heat-stable nonenzymatic process, or both. The susceptibility of heavy chains to crude myofibrillar proteases differs in normal and hypertrophic cardiac myosin; however, the kinetics of tryptic digestion are identical for both myosins. With precautions to minimize proteolytic artifacts on dodecyl sulfate-polyacrylamide gel electrophoresis, preparations of myosin from left and right ventricles of normal and hypertrophic hearts exhibit comparable subunit composition, with approximately molar ratios of heavy chains, light chain L1, and light chain L2. Comparable stoichiometry for the light chain fraction is determined by high speed sedimentation equilibrium at pH 11 and direct fractionation of the different cardiac myosins. We do not confirm reports (e.g. Wikman-Coffelt, J., Fenner, C., Smith, A., and Mason, D. T. (1975) J. Biol. Chem. 250, 1257-1262) of different proportions of light chains in left and right ventricle myosin of normal and hypertrophic canine hearts. The light chains display microheterogeneity, with L1 generating two isoelectric variants and L2 generating two major and two minor variants, but identical mobilities and isoelectric values are obtained in the different myosin preparations.     

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.     

Phylogenetic studies of cardiac myosins from amphibia to mammals

Comparison between pig atrial and ventricular myosins was performed on the light chains (using SDS-PAGE) and on the heavy chains (using Ca2+-ATPase measurements and NTCBA peptide mapping). Light chain composition of pig cardiac myosins was compared to three other species ones (frog, chicken and human). Up to birds, atrial and ventricular myosin light chain composition was identical whereas in mammals atrial and ventricular myosin light chain composition was different; likewise the heavy chains. Six cardiac myosin isoenzymes have been thus characterized. No correlation can be established between cardiac myosin light chain pattern and species evolution.     

Myosin light chain kinase and myosin light chain phosphatase from Dictyostelium: effects of reversible phosphorylation on myosin structure and function

We have partially purified myosin light chain kinase (MLCK) and myosin light chain phosphatase (MLCP) from Dictyostelium discoideum. MLCK was purified 4,700-fold with a yield of approximately 1 mg from 350 g of cells. The enzyme is very acidic as suggested by its tight binding to DEAE. Dictyostelium MLCK has an apparent native molecular mass on HPLC G3000SW of approximately 30,000 D. Mg2+ is required for enzyme activity. Ca2+ inhibits activity and this inhibition is not relieved by calmodulin. cAMP or cGMP have no effect on enzyme activity. Dictyostelium MLCK is very specific for the 18,000-D light chain of Dictyostelium myosin and does not phosphorylate the light chain of several other myosins tested. Myosin purified from log-phase amebas of Dictyostelium has approximately 0.3 mol Pi/mol 18,000-D light chain as assayed by glycerol-urea gel electrophoresis. Dictyostelium MLCK can phosphorylate this myosin to a stoichiometry approaching 1 mol Pi/mol 18,000-D light chain. MLCP, which was partially purified, selectively removes phosphate from the 18,000-D light chain but not from the heavy chain of Dictyostelium myosin. Phosphatase-treated Dictyostelium myosin has less than or equal to 0.01 mol Pi/mol 18,000-D light chain. Phosphatase-treated myosin could be rephosphorylated to greater than or equal to 0.96 mol Pi/mol 18,000-D light chain by incubation with MLCK and ATP. We found myosin thick filament assembly to be independent of the extent of 18,000-D light-chain phosphorylation when measured as a function of ionic strength. However, actin-activated Mg2+-ATPase activity of Dictyostelium myosin was found to be directly related to the extent of phosphorylation of the 18,000-D light chain. MLCK-treated myosin moved in an in vitro motility assay (Sheetz, M. P., and J. A. Spudich, 1983, Nature (Lond.), 305:31-35) at approximately 1.4 micron/s whereas phosphatase-treated myosin moved only slowly or not at all. The effects of phosphatase treatment on the movement were fully reversed by subsequent treatment with MLCK.     

Hybrids of Physarum myosin light chains and desensitized scallop myofibrils

The two light chains of Physarum myosin have been purified in a 1:1 ratio with a yield of 0.5-1 mg/100 g of plasmodium and a purity of 40- 70%; the major contaminant is a 42,000-dalton protein. The 17,700 Mr Physarum myosin light chain (PhLC1) binds to scallop myofibrils, providing the regulatory light chains (ScRLC) have been removed. The 16,500 Mr light (PhLC2) does not bind to scallop myofibrils. The calcium control of scallop myosin ATPase is lost by the removal of one of the two ScRLC's and restored equally well by the binding of either PhLC1 or rabbit skeletal myosin light chains. When both ScRLC's are removed, replacement by two plasmodial light chains does not restore calcium control as platelet or scallop light chains do. Purified plasmodial actomyosin does not bind calcium in 10(-6) M free calcium, 1 mM MgCl2. No tropomyosin was isolated from Physarum by standard methods. Because the Physarum myosin light chains can substitute only partially for light chains from myosin linked systems, because calcium does not bind to the actomyosin, and because tropomyosin is apparently absent, the regulation of plasmodial actomyosin by micromolar Ca++ may involve other mechanisms, possibly phosphorylation.     

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.     

Myosin and paramyosin of Caenorhabditis elegans: biochemical and structural properties of wild-type and mutant proteins.

Myosin and paramyosin have been purified from the nematode, Caenorhabditis elegans. The properties of the myosin in general resemble those of other myosins. The native molecule is a dimer of heavy (210,000 dalton) polypeptide chains and contains 18,000 and 16,000 dalton light chains. When rapidly precipitated from solution, it forms small, bipolar aggregates, about 150 nm long, consistent with the expected molecular structure of a rigid rod with a globular head region at one end. Its ATPase activity is stimulated by Ca2+ and EDTA. The myosin binds to F actin in a polar and ATP-sensitive manner, and the Mg2+-ATPase is activated by either F actin or nematode thin filaments. Dialysis of myosin to low ionic strength produces very long filaments. When a myosin-paramyosin mixture is dialyzed under the same condtions, co-filaments form which consist of a myosin cortex, surrounding a paramyosin core. Some properties of myosin from the mutants E675 and E190, which have functionally and structurally altered body wall muscles, are compared with those of wild-type myosin. These myosins of these results are discussed in terms of the myosin heavy chain composition.     

Effect of phosphorylation and dinitrophenylation on chicken gizzard myosin

Treatment of phosphorylated chicken gizzard myosin which had incorporated 1.5 mol of phosphate per 4.7 x 10(5) g of protein with 1-fluoro-2,4-dinitrobenzene resulted in the modification of the heavy and light chains when 5.8 mol of the reagent were bound to myosin. Concurrently, the K+-ATPase activity was inhibited and the modified myosin possessed actin activated-ATPase activity. Thiolysis of nearly 2 mol of the dinitrophenyl group mainly from the heavy chains (and some light chains) of the modified myosin with 2-mercaptoethanol restored the K+-ATPase activity. Digestion of phosphorylated gizzard myosin with chymotrypsin or papain occurred to a lesser extent than a control myosin. Chymotryptic fragments of phosphorylated and dinitrophenylated myosin were formed at a faster rate than those of dinitrophenylated myosin alone suggesting that phosphorylation of the light chain of Mr 20,000 altered the susceptibility of the heavy chains of myosin to proteolysis. Phosphorylation of dinitrophenylated gizzard myosin which had incorporated 5.5 mol of 1-fluoro-2,4-dinitrobenzene per 4.7 x 10(5) g of protein was the same as that of a control myosin; this was also the case for the thiolyzed dinitrophenylated myosin. In the absence of calcium, phosphorylation of control and dinitrophenylated myosins decreased by 73% suggesting that the phosphorylation reaction was calcium dependent. Phosphorylation and dinitrophenylation induced conformational changes in the light chains of gizzard myosin that may be involved in maintaining the structure of the heavy chain region.     

Myosin subunit composition in human developing muscle.

Previous pyrophosphate-gel studies have reported the existence of embryonic neonatal myosin isoenzymes in human developing muscle. The present investigation was undertaken to characterize their subunit composition more precisely. Two immature muscle myosins are contrasted with adult myosin: neonatal myosin and foetal myosin. The neonatal form of myosin is weakly cross-reactive with rabbit slow myosin and contains only fast-type light chains (LC), LC1F and LC2F. The associated heavy chains consist of a single electrophoretic component that reacts exclusively with antibodies against human foetal myosin and has a mobility and peptide pattern distinct from that of adult fast and slow heavy chains. Foetal myosin is distinguished by the presence of low amounts of a heavy chain immunologically cross-reactive with the adult slow form and of two additional light-chain components: a LC2S light chain and a foetal-specific light chain (LCemb.). The foetal-specific light chain, as shown by one-dimensional-peptide-map analysis, is structurally unrelated to both LC1S and LC1F light chains of human adult myosin. We conclude from these results that the ontogenesis of human muscle myosin shares certain common features with that observed in other species, except for the persistence until birth of a foetal form of heavy chain (HCemb.).     

Characterization of the myosin-phosphorylating system in normal murine astrocytes and derivative sv40 wild-type and A-mutant transformant

Myosin and myosin light-chain kinase have been isolated and characterized from small quantities of normal and SV40-transformed, murine astrocytic neuroglial cells in culture and from intact normal mouse brain. Sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis of the astrocyte myosins revealed a heavy chain of 200,000 daltons and two light chains of 20,000 and 15,000 daltons. These myosins are similar to other cytyplasmic myosins. The astrocyte 20,000-dalton light chain can be phosphorylated by an endogenous myosin light-chain kinase which has properties similar to those of the myosin light-chain kinase found in human platelets. No differences were detected in either the astrocyte myosins or myosin light-chain kinases between (a) the normal and transformed cells, (b) the transformed cells grown at the permissive and nonpermissive temperatures, or (c) the SV40 wild-type and A-mutant transformants.     

Diversity in expression of myosin heavy chain isoforms and M-band proteins in rat muscle spindles

The composition of adult rat soleus muscle spindles, with respect to myosin heavy chain isoforms and M-band proteins, was studied by light-microscope immunohistochemistry. Serial sections were labelled with antibodies against slow tonic, slow twitch, fast twitch and neonatal myosin isoforms as well as against myomesin, M-protein and the MM form of creatine kinase. Intrafusal fiber types were distinguished according to the pattern of ATPase activity following acid and alkaline preincubations. Nuclear bag1 fibers were always strongly stained throughout with anti-slow tonic myosin, were positive for anti-slow twitch myosin towards and in the C-region but were unstained with anti-fast twitch and anti-neonatal myosins. The staining of nuclear bag2 fibers was in general highly variable. However, they were most often strongly stained by anti-slow tonic myosin in the A-region and gradually lost this reactivity towards the poles, whereas a positive reaction with anti-slow twitch myosins was found along the whole fiber. Regional staining variability with anti-neonatal and anti-fast myosins was apparent, often with decreasing intensity towards the polar regions. Nuclear chain fibers showed strong transient reactivity with anti-slow tonic myosin in the equatorial region, did not react with anti-slow twitch and were always evenly stained by anti-fast twitch and anti-neonatal myosins. All three intrafusal fiber types were stained with anti-myomesin. Nuclear bag1 fibers lacked staining for M-protein, whereas bag2 fibers displayed intermediate staining, with regional variability, often increasing in reactivity towards the polar regions. Chain fibers were always strongly stained by anti-M-protein. The MM form of creatine kinase was present in all three fiber types, but bag1 fibers were less reactive and clear striations were not observed, in contrast to bag2 and chain fibers. Out of 38 cross sectioned spindles two were found to have an atypical fiber composition (lack of chain fibers) and a rather diverse staining pattern for the different antibodies tested. Taken together, the data show that in adult rat soleus, slow tonic and neonatal myosin heavy chain isoforms are only expressed in the muscle spindle fibers and that each intrafusal fiber type has a unique, although variable, composition of myosin heavy chain isoforms and M-band proteins. We propose that both motor and sensory innervation might be the determining factors regulating the variable expression of myosin heavy chain isoforms and M-band proteins in intrafusal fibers of rat muscle spindles.     

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.     

Protein kinase C phosphorylates both the light chains and the head portion of the heavy chains of brain myosin

Protein kinase C phosphorylated both the 19/21-kDa regulatory light chains and heavy chains of bovine brain myosin. The major phosphorylation sites of the light chains were on their threonyl residues, while those for myosin light chain kinase were on their seryl residues. Whereas several non-muscle regular myosins have been reported to be phosphorylated by different types of protein kinases at the non-helical small segments at the tail ends of the heavy chains, the phosphorylation sites for protein kinase C were localized on the head portion of the heavy chains of brain myosin. The possible role of phosphorylation of brain myosin by protein kinase C in the regulation of motility of neural cells is discussed.     

Purification and characterization of a third isoform of myosin I from Acanthamoeba castellanii

A third isoform of myosin I has been isolated from Acanthamoeba and designated myosin IC. Peptide maps and immunoassays indicate that myosin IC is not a modified form of myosin IA, IB, or II. However, myosin IC has most of the distinctive properties of a myosin I. It is a globular protein of native Mr approximately 162,000, apparently composed of a single 130-kDa heavy chain and a pair of 14-kDa light chains. It is soluble in MgATP at low ionic strength, conditions favoring filament assembly by myosin II. Myosin IC has high Ca2+- and (K+,EDTA)-ATPase activities. Its low Mg2+-ATPase activity is stimulated to a maximum rate of 20 s-1 by the addition of F-actin if its heavy chain has been phosphorylated by myosin I heavy chain kinase. The dependence of the Mg2+-ATPase activity of myosin IC on F-actin concentration is triphasic; and, at fixed concentrations of F-action, this activity increases cooperatively as the concentration of myosin IC is increased. These unusual kinetics were first demonstrated for myosins IA and IB and shown to be due to the presence of two actin-binding sites on each heavy chain which enable those myosins I to cross-link actin filaments. Myosin IC is also capable of cross-linking F-actin, which, together with the kinetics of its actin-activated Mg2+-ATPase activity, suggests that it, like myosins IA and IB, possesses two independent actin-binding domains.     

Myosin from human erythrocytes

We have purified myosin from human erythrocytes using methods similar to that for other cytoplasmic myosins with a yield of about 500 micrograms/100 ml of packed cells. It consists of a 200-kDa heavy chain and light chains of 26- and 19.5 kDa and therefore differs from the isozyme in platelets which has light chains of 20- and 15 kDa. At low ionic strength, the myosin forms short bipolar filaments like those of platelet myosin. Eight of eight monoclonal antibodies to platelet myosin also bind to erythrocyte myosin. Like most myosins, it has a high ATPase activity in the presence of Ca2+ or EDTA, but is inhibited by Mg2+. Myosin light-chain kinase transfers 1 phosphate from ATP to the 20-kDa light chain, and this stimulates the actin-activated ATPase. Thus, myosin may play a role in shape changes in the erythrocytes.     

Diversity in expression of myosin heavy chain isoforms and M-band proteins in rat muscle spindles

Summary The composition of adult rat soleus muscle spindles, with respect to myosin heavy chain isoforms and M-band proteins, was studied by light-microscope immunohistochemistry. Serial sections were labelled with antibodies against slow tonic, slow twitch, fast twitch and neonatal myosin isoforms as well as against myomesin, M-protein and the MM form of creatine kinase. Intrafusal fiber types were distinguished according to the pattern of ATPase activity following acid and alkaline preincubations.Nuclear bag₁ fibers were always strongly stained throughout with anti-slow tonic myosin, were positive for anti-slow twitch myosin towards and in the C-region but were unstained with anti-fast twitch and anti-neonatal myosins. The staining of nuclear bag₂ fibers was in general highly variable. However, they were most often strongly stained by anti-slow tonic myosin in the A-region and gradually lost this reactivity towards the poles, whereas a positive reaction with anti-slow twitch myosins was found along the whole fiber. Regional staining variability with antineonatal and anti-fast myosins was apparent, often with decreasing intensity towards the polar regions. Nuclear chain fibers showed strong transient reactivity with anti-slow tonic myosin in the equatorial region, did not react with anti-slow twitch and were always evenly stained by anti-fast twitch and anti-neonatal myosins. All three intrafusal fiber types were stained with anti-myomesin. Nuclear bag₁ fibers lacked staining for M-protein, whereas bag₂ fibers displayed intermediate staining, with regional variability, often increasing in reactivity towards the polar regions. Chain fibers were always strongly stained by anti-M-protein. The MM form of creatine kinase was present in all three fiber types, but bag₁ fibers were less reactive and clear striations were not observed, in contrast to bag₂ and chain fibers. Out of 38 cross sectioned spindles two were found to have an atypical fiber composition, (lack of chain fibers) and a rather diverse staining pattern for the different antibodies tested.Taken together, the data show that in adult rat solcus, slow tonic and neonatal myosin heavy, chain isoforms are only expressed in the muscle spindle fibers and that each intrafusal fiber type has a unique, although variable, composition of myosin heavy chain isoforms and M-band proteins. We propose that both motor and sensory innervation might be the determining factors regulating the variable expression of myosin heavy chain isoforms and M-band proteins in intrafusal fibers of rat muscle spindles.     

Polymorphism of myosin light chains. An electrophoretic and immunological study of rabbit skeletal-muscle myosins.

Antibodies specific for rabbit fast-twitch-muscle myosin LCIF light chain were purified by affinity chromatography and characterized by both non-competitive and competitive enzyme-linked immunosorbent assay (ELISA) and a gel-electrophoresis-derived assay (GEDELISA). The antibodies did not cross-react with myosin heavy chains, and were weakly cross-reactive with the LC2F [5,5'-dithio-(2-nitrobenzoic acid)-dissociated] light chain and with all classes of dissociated light chains (LC1Sa, LC1Sb and LC2S), as well as with the whole myosin, from hind-limb slow-twitch muscle. The immunoreactivity of myosins with a truly mixed light-chain pattern (e.g. vastus lateralis and gastrocnemius) correlated with percentage content of fast-twitch-muscle-type light chains. A more extensive immunoreactivity was observed with diaphragm and masseter myosins, which were also characterized, respectively, by a relative or absolute deficiency of LC1Sa light chain. Furthermore, it was found that the LC1Sb light chain of masseter myosin is antigenically different from its slow-twitch-muscle myosin analogue, and is immunologically related to the LC1F light chain. Rabbit masseter muscle from its metabolic and physiological properties and the content, activity and immunological properties of sarcoplasmic-reticulum adenosine triphosphatase, is classified as a red, predominantly fast-twitch, muscle. Therefore our results suggest that the two antigenically different iso-forms of LC1Sb light chain are associated with the myosins of fast-twitch red and slow-twitch red fibres respectively.     

Myosin from abdominal flexor muscle in a crayfish, Procambarus clarki Girard.

1. Crayfish (Procambarus clarki) myosin was obtained from abdominal flexor muscle. The Ca2+-ATPase activity of crayfish myosin was much lower than that of rabbit skeletal myosin. However, F-actin-activated Mg2+-ATPase of crayfish and its superprecipitation closely resembled those of rabbit skeletal myosin. This fact suggests that the ability of crayfish myosin to combine with F-actin is essentially the same as that of skeletal myosin, although the chemical structures of both the myosin molecules when involved in their Ca2+-ATPast activity must be different from each other. 2. Crayfish and rabbit skeletal myosins were subjected to SDS-polyacrylamide gel electrophoresis. Crayfish myosin was found to have one heavy chain and two distinct light chain components (CF-gl and CF-g2), which have molecular weights of 18,000 and 16,000, respectively. These light chains correspond in molecular weight to the light chains (SK-g2 and SK-g3) in rabbit skeletal myosin. 3. CF-g1 could be liberated from the crayfish myosin molecule reacting with 5,5'-dithio-bis (2-nitrobenzoic acid), (Nbs2), without recovery of ATPase activity by the addition of DTT. These properties are equivalent to those of SK-g2 in rabbit skeletal myosin, although Nbs2-treated crayfish myosin did not recover its ATPase activity at all.