A chicken embryo-specific myosin light chain (L23) appears to be identical with one of brain myosin light chains

A novel embryo-specific myosin light chain of 23 kDa molecular weight (L23) was found previously in embryonic chicken skeletal, cardiac, and smooth muscles (Takano-Ohmuro et al. (1985) J. Cell Biol. 100, 2025-2030). When we examined myosin in embryonic and adult brain by two-dimensional electrophoresis, 23 kDa myosin light chain present in brain (Burridge & Bray (1975) J. Mol. Biol. 99, 1-14) comigrated with L23. Two monoclonal antibodies, EL-64 and MT-185d, were applied to clarify the identity of the brain 23 kDa myosin light chain and the chicken embryonic muscle L23. The two antibodies recognize different antigenic determinants in the L23 molecule; the former antibody is specific for L23, whereas the latter recognizes the sequence common to fast skeletal muscle myosin light chains 1 and 3, and also L23. The immunoblots combined with two-dimensional gel electrophoresis showed that both EL-64 and MT-185d can bind to the brain 23 kDa myosin light chain as well as the chicken embryonic muscle L23. These results indicate that chicken brain and chicken embryonic muscles contain a common myosin light chain of 23 kDa molecular weight.     

Changes in myosin isozymes during development of chicken gizzard muscle

The distribution of myosin isozymes in embryonic and adult chicken gizzard muscle were examined by electrophoresis in a non-denaturing gel system (pyrophosphate acrylamide gel electrophoresis), and both light and heavy chains of embryonic and adult myosin isozymes were compared. In pyrophosphate acrylamide gel electrophoresis, there were three isozyme components in embryonic gizzard myosin, but only one isozyme in adult gizzard myosin. The mobility of the fastest migrating embryonic isozyme was similar to that of the adult isozyme. The three embryonic isozymes differ from each other in the light chain distribution. Two of them contain an embryo-specific myosin light chain, which is characterized by its molecular weight and isoelectric point, whereas the other embryonic myosin isozyme contained the same light chains as the adult myosin. The pattern of peptide fragments of embryonic heavy chain produced by digestion with alpha-chymotrypsin in the presence of SDS was not distinguishable from that of adult myosin heavy chain. Thus there are myosin isozymes specific to embryonic gizzard muscle which exhibit embryo-specific light chain compositions, but are similar to adult gizzard myosin in their heavy chain structure.     

Embryonic chicken skeletal, cardiac, and smooth muscles express a common embryo-specific myosin light chain

It has been demonstrated that embryonic chicken gizzard smooth muscle contains a unique embryonic myosin light chain of 23,000 mol wt, called L23 (Katoh, N., and S. Kubo, 1978, Biochem. Biophys. Acta, 535:401-411; Takano-Ohmuro, H., T. Obinata, T. Mikawa, and T. Masaki, 1983, J. Biochem. (Tokyo), 93:903-908). When we examined myosins in developing chicken ventricular and pectoralis muscles by two-dimensional gel electrophoresis, the myosin light chain (Le) that completely comigrates with L23 was detected in both striated muscles at early developmental stages. Two monoclonal antibodies, MT-53f and MT-185d, were applied to characterize the embryonic light chain Le of striated muscles. Both monoclonal antibodies were raised to fast skeletal muscle myosin light chains; the former antibody is specific to fast muscle myosin light chains 1 and 3, whereas the latter recognizes not only fast muscle myosin light chains but also the embryonic smooth muscle light chain L23. The immunoblots combined with both one- and two-dimensional gel electrophoresis showed that Le reacts with MT-185d but not with MT-53f. These results strongly indicate that Le is identical to L23 and that embryonic chicken skeletal, cardiac, and smooth muscles express a common embryo-specific myosin light chain.     

Dinitrophenylation of chicken gizzard myosin: reactivity of the 17 000-dalton light chain

Chicken gizzard myosin rapidly incorporated 3 mol of 1-fluoro-2,4-dinitrobenzene per 4.7 x 10(5) g of protein with little change in the ATPase (ATP phosphohydrolase, EC 3.6.1.3) activity. During an interval when 2 additional mol of the reagent were bound the K+-ATPase activity in the presence of EDTA was inhibited and the Ca2+-ATPase activity was altered to a lesser extent. Cysteine residues were modified in the dinitrophenylated gizzard myosin. The dinitrophenyl group was located mainly in the active proteolytic fragment, subfragment 1. Dinitrophenylation of the heavy and light chains was observed but major changes in the ATPase activity occurred when the 17 000-dalton light chain and some heavy chains were modified as judged by dissociation experiments in sodium dodecyl sulfate. Thiolysis of the dinitrophenylated gizzard myosin with 2-mercaptoethanol restored the ATPase activity and approx. 2 mol of the dinitrophenyl group were removed. The restoration of the enzymic activity, however, occurred when 1 mol of the label was thiolytically cleaved from cysteine residues of the 17 000-dalton light chain. Substrate Mg-ATP(2-) or MgADP did not protect the ATPase activity of modified gizzard myosin. In the presence of nucleotide there was an increase in the incorporation of the reagent, and a change in its distribution into the light and heavy chains. Calcium had no effect on the dinitrophenylation of this myosin. these results indicate that the reagent, 1-fluoro-2,4-dinitrobenzene, could detect chemical differences in smooth muscle myosin when compared to the reactivity of other myosins. Thiol groups of the 17 000-light chain (and some heavy chains) are probably located peripheral to the active site region of gizzard myosin and they are involved in maintaining the enzymic activity of this protein.     

Distribution and properties of myosin isozymes in developing avian and mammalian skeletal muscle fibers

Isozymes of myosin have been localized with respect to individual fibers in differentiating skeletal muscles of the rat and chicken using immunocytochemistry. The myosin light chain pattern has been analyzed in the same muscles by two-dimensional PAGE. In the muscles of both species, the response to antibodies against fast and slow adult myosin is consistent with the speed of contraction of the muscle. During early development, when speed of contraction is slow in future fast and slow muscles, all the fibers react strongly with anti-slow as well as with anti-fast myosin. As adult contractile properties are acquired, the fibers react with antibodies specific for either fast or slow myosin, but few fibers react with both antibodies. The myosin light chain pattern slow shows a change with development: the initial light chains (LC) are principally of the fast type, LC1(f), and LC2(f), independent of whether the embryonic muscle is destined to become a fast or a slow muscle in the adult. The LC3(f), light chain does not appear in significant amounts until after birth, in agreement with earlier reports. The predominance of fast light chains during early stages of development is especially evident in the rat soleus and chicken ALD, both slow muscles, in which LC1(f), is gradually replaced by the slow light chain, LC1(s), as development proceeds. Other features of the light chain pattern include an "embryonic" light chain in fetal and neonatal muscles of the rat, as originally demonstrated by R.G. Whalen, G.S. Butler- Browne, and F. Gros. (1978. J. Mol. Biol. 126:415-431.); and the presence of approximately 10 percent slow light chains in embryonic pectoralis, a fast white muscle in the adult chicken. The response of differentiating muscle fibers to anti-slow myosin antibody cannot, however, be ascribed solely to the presence of slow light chains, since antibody specific for the slow heavy chain continues to react with all the fibers. We conclude that during early development, the myosin consists of a population of molecules in which the heavy chain can be associated with a fast, slow, or embryonic light chain. Biochemical analysis has shown that this embryonic heavy chain (or chains) is distinct from adult fast or slow myosin (R.G. Whalen, K. Schwartz, P. Bouveret, S.M. Sell, and F. Gros. 1979. Proc. Natl. Acad. Sci. U.S.A. 76:5197-5201. J.I. Rushbrook, and A. Stracher. 1979. Proc Natl. Acad. Sci. U.S.A. 76:4331-4334. P.A. Benfield, S. Lowey, and D.D. LeBlanc. 1981. Biophys. J. 33(2, Pt. 2):243a[Abstr.]). Embryonic myosin, therefore, constitutes a unique class of molecules, whose synthesis ceases before the muscle differentiates into an adult pattern of fiber types.     

Changes in myosin isozymes during development of chicken breast muscle

The patterns of myosin isozymes in embryonic and adult chicken pectoralis muscle were examined by electrophoresis in a non-denaturing gel system (pyrophosphate acrylamide gel electrophoresis), and both light chains and heavy chains of embryonic and adult myosin isozymes were compared. In pyrophosphate acrylamide gel electrophoresis, the predominant isozyme component in embryonic pectoralis myosin could be clearly distinguished from adult myosin isozymes. SDS-polyacrylamide gel electrophoresis indicated that the light chain composition of embryonic myosin was also different from that of adult myosin. The pattern of peptide fragments produced by myosin digestion with a-chymotrypsin differed significantly between embryonic and adult skeletal myosin. These results suggest that myosin in the embryonic pectoralis muscle is different in both light and heavy chain composition from myosin in the same adult tissue.     

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.).     

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.     

Structural differences in the subfragment 1 and rod portions of myosin isozymes from adult and developing rat skeletal muscles

During development of fast contracting skeletal muscle in the rat hindleg, embryonic and neonatal forms of the myosin heavy chain are present prior to the accumulation of the adult fast type ( Whalen , R. G., Sell, S. M., Butler-Browne, G.S., Schwartz, K., Bouveret, P., and Pinset -H arstr ?m, I. (1981) Nature (Lond.) 292, 805-809). Polypeptide mapping of the heavy chain subunit using partial proteolysis in the presence of sodium dodecyl sulfate has shown differences in the cleavage patterns for these various heavy chains. Using this technique, we have now examined subfragments, which represent functional domains, from several different myosin isozymes. The heavy chains of the S-1 subfragments containing either light chain 1 or light chain 3 are indistinguishable for the neonatal or fast myosin isozymes. We also isolated the S-1 fragments and the alpha-helical COOH-terminal half of the molecule (rod) from rat embryonic, neonatal, and adult fast and slow myosin, as well as myosin from cardiac ventricles. All of these S-1 and rod fragments were different, indicating that the previously reported differences among these different myosin heavy chain isozymes are located in both the S-1 and rod subfragments for all myosins examined. However, the polypeptide maps of neonatal and adult fast S-1 show clear similarities, as do the maps of slow and cardiac S-1. These similarities in the two pairs of polypeptide maps were confirmed by the results of immunoblotting experiments using antibodies to adult fast and to slow myosin.     

Regenerating adult chicken skeletal muscle and satellite cell cultures express embryonic patterns of myosin and tropomyosin isoforms

Regenerating areas of adult chicken fast muscle (pectoralis major) and slow muscle (anterior latissimus dorsi) were examined in order to determine synthesis patterns of myosin light chains, heavy chains and tropomyosin. In addition, these patterns were also examined in muscle cultures derived from satellite cells of adult fast and slow muscle. One week after cold-injury the regenerating fast muscle showed a pattern of synthesis that was predominately embryonic. These muscles synthesized the embryonic myosin heavy chain, beta-tropomyosin and reduced amounts of myosin fast light chain-3 which are characteristic of embryonic fast muscle but synthesized very little myosin slow light chains. The regenerating slow muscle, however, showed a nearly complete array of embryonic peptides including embryonic myosin heavy chain, fast and slow myosin light chains and both alpha-fast and slow tropomyosins. Peptide map analysis of the embryonic myosin heavy chains synthesized by regenerating fast and slow muscles showed them to be identical. Thus, in both muscles there is a return to embryonic patterns during regeneration but this return appears to be incomplete in the pectoralis major. By 4 weeks postinjury both regenerating fast and slow muscles had stopped synthesizing embryonic isoforms of myosin and tropomyosin and had returned to a normal adult pattern of synthesis. Adult fast and slow muscles yielded a satellite cell population that formed muscle fibers in culture. Fibers derived from either population synthesized the embryonic myosin heavy chain in addition to alpha-fast and beta-tropomyosin. Thus, muscle fibers derived in culture from satellite cells of fast and slow muscles synthesized a predominately embryonic pattern of myosin heavy chains and tropomyosin. In addition, however, the satellite cell-derived myotubes from fast muscle synthesized only fast myosin light chains while the myotubes derived from slow muscle satellite cells synthesized both fast and slow myosin light chains. Thus, while both kinds of satellite cells produced embryonic type myotubes in culture the overall patterns were not identical. Satellite cells of fast and slow muscle appear therefore to have diverged from each other in their commitment during maturation in vivo.     

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.     

Altered synthesis of myosin light chains is associated with contractility in cultures of differentiating chick embryo breast muscle

Cultured chick embryo skeletal muscle cells normally synthesize only the embryonic isoform of mysoin. We have found that aneural muscle cultures that become or are provoked into an extremely contractile state will begin to synthesize a pattern of myosin light chains typical of maturing muscle. Immunoblots with neonatal and adult specific monoclonal antibodies did not reveal a corresponding isozyme transition in myosin heavy chain. These results demonstrate a correlation between contractility and the regulation of myosin light chain maturation, and also suggest that the transitions of heavy and light chain synthesis during development do not appear to be under close coordinate regulation.     

Myosin heavy chain in avian muscular dystrophy corresponds to the neonatal isozyme

We have previously demonstrated, based on comparison of homologous amino acid sequences and of two-dimensional CNBr peptide gel patterns, that the myosin heavy chain in pectoralis muscles of Storrs, Connecticut dystrophic chickens is different from that of their normal controls (Huszar, G., Vigue, L., De-Lucia, J. Elzinga, M., and Haines, J. (1985) J. Biol. Chem. 260, 7429-7434). Others have shown, however, that genomic banks and mRNA complements of the control and dystrophic birds are not different. In the present studies, we have examined the hypothesis that the "dystrophic" myosin heavy chain is not a novel gene product, but is a developmental isozyme which is expressed in pectoralis muscles of adult chickens due to the dystrophic process. Two-dimensional maps of myosin heavy chain CNBr peptides were prepared from breast muscles of 17-day in ovo (embryonic), 25-day posthatch (neonatal), and adult birds of the Storrs dystrophic and of two control strains. Also, myosin and actomyosin ATPase enzymatic activities of the various preparations were determined in the pH range of 5.5 to 9.0. Analysis of the peptide maps demonstrates that the embyronic, neonatal, and control adult myosin heavy chain isozymes are distinctly different gene products with only minute variations between the respective developmental isozymes in dystrophic and control muscles. However, the pectoralis myosin heavy chain of adult dystrophic birds, which is a homogeneous isozyme population by amino acid sequences and gel patterns, corresponds to that of the neonatal-type myosin heavy chain. The ATPase properties of the embryonic, neonatal, or adult pectoralis myosins and actomyosins were not different, whether the level of specific activity or the pattern of pH activation is considered. Since the mobility of neonatal chicks (primarily neonatal-type isozymes) is not restricted, the differences in myosin heavy chain structures are part of the syndrome, but not the cause of avian muscular dystrophy.     

Metabolism of benzo[a]pyrene. Effect of substrate concentration and 3-methylcholanthrene pretreatment on hepatic metabolism by microsomes from rats and mice.

Digestion of insoluble myosin with soluble papain produces heavy meromyosin subfragment 1 (HMM-S-1) having ATPase activity and the ability to combine with actin. These fragments of myosin do not undergo appreciable changes in ATPase activity, chromatographic behavior, or actin combining ability during digestion up to 2 h but, as shown by sodium dodecyl sulfate gel electrophoresis, several splits occur in both the heavy and light polypeptide chains. The largest fragment of heavy chain present in fast, slow, cardiac and embryonic HMM-S-1 has a mass of 89,000 daltons. This fragment undergoes further degradation resulting in fragments having masses of the order of 70,000, 50,000, and 27,000 daltons. The latter fragment and other material resulting from the proteolysis of myosin appear as bands in that region of the gels where the light chains are found in electrophoretograms of the parent myosin. The precise size of the fragments and the rates of their formation depend on the type of myosin; slow and cardiac HMM-S-1 and their fragments show greater stability. Embryonic myosin has properties intermediate between those of fast skeletal and cardiac myosin. Experiments involving the combination of HMM-S-1 with actin and experiments with glutaraldehyde cross linking and chromatography on Sephadex G-200 indicate that the fragments separated by sodium dodecyl sulfate gel electrophoresis are held together by noncovalent forces in HMM-S-1.     

Myosin heavy chain expression during development and following denervation of fast fibers in the red strip of the chicken pectoralis

The myosin heavy chain composition of muscle fibers that comprise the red strip of the pectoralis major was determined at different stages of development and following adult denervation. Using a library of characterized monoclonal antibodies we found that slow fibers of the red strip do not react with antibodies to any of the fast myosin heavy chains of the superficial pectoralis. Immunocytochemical analysis of the fast fibers of the adult red strip revealed that they contain the embryonic fast myosin heavy chain rather than the adult pectoral isoform found throughout the adult white pectoralis. This was confirmed using immunoblot analysis of myosin heavy chain peptide maps. We show that during development of the red strip both neonatal and adult myosin heavy chains appear transiently, but then disappear during maturation. Furthermore, while the fibers of the superficial pectoralis reexpress the neonatal isoform as a result of denervation, the fibers of the red strip reexpress the adult isoform. Our data demonstrate a new developmental program of fast myosin heavy chain expression in the chicken and suggest that the heterogeneity of myosin heavy chain expression in adult fast fibers results from repression of specific isoforms by innervation.     

Structural and functional changes of myosin during development: comparison with adult fast, slow and cardiac myosin.

ATPase (Ca²⁺ and K⁺ activated) activity of myosin prepared from muscles of 3–4 week rabbit embryos (EM) is slighly lower than that of adult fast muscle myosin (FM), but in contrast to the less active adult slow muscle myosin (SM) is stable on exposure to pH 9.2. Studies of the time course, by means of Na dodecyl-SO₄ polyacrylamide gel electrophoresis, of changes in the pattern of polypeptides released by tryptic digestion show that in this regard EM is closest to SM. The light chain complement of EM appears identical with that of FM rather than of SM or cardiac myosin (CM) by the criteria of coelectrophoresis and removal by 5,5′-dithio-2-dinitrobenzoate treatment of LC₂ except that the relative amount of LC₃ is less in EM than in FM. The staining pattern of light meromyosin (EMM) paracrystals prepared from EM is distinct from either the FM, SM or CM LMM staining pattern. These studies suggest that different genes are involved in the coding for embryonic and adult heavy chains.     

Volume occupation, environment, and accessibility in proteins. Environment and molecular area of RNase-S

The myosin light chains of cultured muscle cells and embryonic muscle tissue have been examined by two-dimensional gel electrophoresis. Myosin purified from primary cultures of rat muscle cells or the myogenic cell line L6 contain not only the light chains corresponding to those of fast twitch muscle but also another protein, differing slightly in molecular weight and isoelectric point from the adult LC1 protein. By a number of criteria this additional protein is shown to be a myosin light chain: (1) it is found in highly purified myosin preparations; (2) in L6 myosin it replaces the other LC1-type light chains in stoichiometric amounts; (3) it is part of the subfragment-1 complex of myosin produced by chymotrypsin. as expected for an LC1-type light chain. Total extracts of fused cultured muscle cells, when analyzed by two-dimensional electrophoresis, contain substantial amounts of this additional LC1-type protein, strongly suggesting that it is not a proteolytic fragment produced during myosin isolation. Unfused cultures do not synthesize detectable amounts of the adult light chains or the additional LC1-type light chain. This additional LC1 protein can be detected in embryonic or newborn muscle tissue but it is not present in adult myosin or myofibrils. These results indicate that a novel form of myosin light chain, referred to as an embryonic LC1 or LC1_emb, is characteristic of the early stages of muscle development.     

Conformationally altered aortic myosin light chains

Aorta smooth myosin contains two types of light chain, LC20 and LC17, which fold together with the N-terminal region of each heavy chain to form the globular head region of myosin. We demonstrate an altered conformation of LC20 after its separation from heavy chain by high concentrations of urea, on the basis of the following evidende: 1) A polyclonal antibody against LC20 was not able to recognize this conformationally altered form; 2) Myosin reconstituted from heavy chains and urea-dissociated light chains exhibited extremely low ATPase activity. Circular dichroism unfolding profiles showed that light chains dissociated from heavy chains by SDS appeared to be more stable than those generated by urea dissociation.     

Reconstitution of ventricular myosin with atrial light chains 1 improves its functional properties

Atrial light chain 1 (ALC-1) is expressed in embryonic and hypertrophied human ventricles but not in normal adult human ventricles. We investigated the effects of recombinant human atrial light chains (hALC-1) on the structure and enzymatic activity of synthetic filaments of ventricular myosin. The endogenous ventricular myosin light chain 1 (VLC-1) was partially replaced by recombinant hALC-1 yielding hALC-1 levels of 12%, 24% and 42%. This reconstitution of ventricular myosin with hALC-1 did not change the length of synthetic myosin filaments but led to more rounded myosin heads in comparison with those of control filaments. Actin-activated ATPase activity of myosin, a parameter of functional activity of molecular motor, amounted to 79.5 nmol Pi/mg per min in control myosin filaments. Reconstitution with hALC-1 caused a profound increase of the actin-activated myosin ATPase activity in a dose dependent manner, for example, synthetic myosin filaments formed with 12%, 24% and 42% hALC-1 reconstituted myosin revealed the actin-activated ATPase activity increased by 18%, 26% and 36%, respectively, as compared to control. These results strongly suggest that in vivo expression of ALC-1 enhances ventricular myosin function, thereby contributing to cardiac compensation.     

Regulation by molluscan myosins

Molluscan myosins are regulated molecules that control muscle contraction by the selective binding of calcium. The essential and the regulatory light chains are regulatory subunits. Scallop myosin is the favorite material for studying the interactions of the light chains with the myosin heavy chain since the regulatory light chains can be reversibly removed from it and its essential light chains can be exchanged. Mutational and structural studies show that the essential light chain binds calcium provided that the Ca-binding loop is stabilized by specific interactions with the regulatory light chain and the heavy chain. The regulatory light chains are inhibitory subunits. Regulation requires the presence of both myosin heads and an intact headrod junction. Heavy meromyosin is regulated and shows cooperative features of activation while subfragment-1 is non-cooperative. The myosin heavy chains of the functionally different phasic striated and the smooth catch muscle myosins are products of a single gene, the isoforms arise from alternative splicing. The differences between residues of the isoforms are clustered at surface loop-1 of the heavy chain and account for the different ATPase activity of the two muscle types. Catch muscles contain two regulatory light chain isoforms, one phosphorylatable by gizzard myosin light chain kinase. Phosphorylation of the light chain does not alter ATPase activity. We could not find evidence that light chain phosphorylation is responsible for the catch state.