Amino-acid sequence of the 20 000-molecular-weight light chain of chicken gizzard-muscle myosin

Three-dimensional reconstruction of tarantula myosin filaments suggests how phosphorylation may regulate myosin activity

Muscle contraction involves the interaction of the myosin heads of the thick filaments with actin subunits of the thin filaments. Relaxation occurs when this interaction is blocked by molecular switches on these filaments. In many muscles, myosin-linked regulation involves phosphorylation of the myosin regulatory light chains (RLCs). Electron microscopy of vertebrate smooth muscle myosin molecules (regulated by phosphorylation) has provided insight into the relaxed structure, revealing that myosin is switched off by intramolecular interactions between its two heads, the free head and the blocked head. Three-dimensional reconstruction of frozen-hydrated specimens revealed that this asymmetric head interaction is also present in native thick filaments of tarantula striated muscle. Our goal in this study was to elucidate the structural features of the tarantula filament involved in phosphorylation-based regulation. A new reconstruction revealed intra- and intermolecular myosin interactions in addition to those seen previously. To help interpret the interactions, we sequenced the tarantula RLC and fitted an atomic model of the myosin head that included the predicted RLC atomic structure and an S2 (subfragment 2) crystal structure to the reconstruction. The fitting suggests one intramolecular interaction, between the cardiomyopathy loop of the free head and its own S2, and two intermolecular interactions, between the cardiac loop of the free head and the essential light chain of the blocked head and between the Leu305-Gln327 interaction loop of the free head and the N-terminal fragment of the RLC of the blocked head. These interactions, added to those previously described, would help switch off the thick filament. Molecular dynamics simulations suggest how phosphorylation could increase the helical content of the RLC N-terminus, weakening these interactions, thus releasing both heads and activating the thick filament.

Molecular dynamics simulation of site-directed spin labeling: experimental validation in muscle fibers

We have developed a computational molecular dynamics technique to simulate the motions of spin labels bound to the regulatory domain of scallop myosin. These calculations were then directly compared with site-directed spin labeling experimental results obtained by preparing seven single-cysteine mutants of the smooth muscle (chicken gizzard) myosin regulatory light chain and performing electron paramagnetic resonance experiments on these spin-labeled regulatory light chains in functional scallop muscle fibers. We determined molecular dynamics simulation conditions necessary for obtaining a convergent orientational trajectory of the spin label, and from these trajectories we then calculated correlation times, orientational distributions, and order parameters. Simulated order parameters closely match those determined experimentally, validating our molecular dynamics modeling technique, and demonstrating our ability to predict preferred sites for labeling by computer simulation. In several cases, more than one rotational mode was observed within the 14-ns trajectory, suggesting that the spin label samples several local energy minima. This study uses molecular dynamics simulations of an experimental system to explore and enhance the site-directed spin labeling technique.

Phosphorylation site sequence of smooth muscle myosin light chain (M r = 20 000)

The amino terminal sequence of the myosin light chain (Mr = 20 000) isolated from chicken gizzards was found to be (sequence in text). This sequence assignment differs from that reported by Maita et al. [(1981) European J. Biochem. 117, 417] in the order of the tryptic peptides. The revised amino acid sequence exhibits greater homology with the phosphorylation site sequences of the regulatory light chains from cardiac and skeletal muscle. Moreover it is now apparent why synthetic peptides corresponding to the previously reported sequence were very poor substrates for the myosin light chain kinase.

A hinge at the central helix of the regulatory light chain of myosin is critical for phosphorylation-dependent regulation of smooth muscle myosin motor activity

The motor function of smooth muscle myosin is activated by phosphorylation of the regulatory light chain (RLC) at Ser19. However, the molecular mechanism by which the phosphorylation activates the motor function is not yet understood. In the present study, we focused our attention on the role of the central helix of RLC for regulation. The flexible region at the middle of the central helix (Gly95-Pro98) was substituted or deleted to various extents, and the effects of the deletion or substitution on the regulation of the motor activity of myosin were examined. Deletion of Gly95-Asp97, Gly95-Thr96, or Thr96-Asp97 decreased the actin-translocating activity of myosin a little, but the phosphorylation-dependent regulation of the motor activity was not disrupted. In contrast, the deletion of Gly95-Pro98 of RLC completely abolished the actin translocating activity of phosphorylated myosin. However, the unregulated myosin long subfragment 1 containing this RLC mutant showed motor activity the same as that containing the wild type RLC. Since long subfragment 1 motor activity is unregulated by phosphorylation, i.e. constitutively active, these results suggest that the deletion of these residues at the central helix of RLC disrupts the phosphorylation-mediated activation mechanism but not the motor function of myosin itself. On the other hand, the elimination of Pro98 or substitution of Gly95-Pro98 by Ala resulted in the activation of actin translocating activity of dephosphorylated myosin, whereas it did not affect the motor activity of phosphorylated myosin. Together, these results clearly indicate the importance of the hinge at the central helix of RLC on the phosphorylation-mediated regulation of smooth muscle myosin.

Myosin subfragment-1 is fully equipped with factors essential for motor function

The sliding velocity of actin filaments propelled by chicken skeletal myosin subfragment-1 (S1) was measured when the tail end of S1 was specifically bound to the glass surface. To achieve the specific binding, a regulatory light chain was replaced by a recombinant fusion protein of biotin-dependent transcarboxylase (BDTC) and chicken gizzard smooth muscle regulatory light chain (cgmRLC). The BDTC-cgmRLC of S1 was then attached to the glass surface using a biotin-avidin system. The velocity of actin filaments caused by S1 bound to the surface in this manner was 6.8 +/- 0.6 microm/sec at 29 degrees C, which was 3.5-fold greater than that (1.9 +/- 0.3 microm/sec) when bound directly to the surface as in previous studies, but similar to that caused by native chicken skeletal myosin (6.5 +/- 0.6 microm/sec). The actin-activated Mg-ATPase activity was similar to that of S1 before the RLC of S1 was exchanged for BDTC-cgmRLC. The results indicate that S1 can produce a normal fast movement of actin filaments as well as hydrolyse ATP and generate force.

Mutagenesis of the phosphorylation site (serine 19) of smooth muscle myosin regulatory light chain and its effects on the properties of myosin

A full-length cDNA of smooth muscle regulatory light chain was obtained and the recombinant regulatory light chain was expressed in an Escherichia coli expression system. The recombinant regulatory light chain was introduced into myosin or HMM using a subunit exchange strategy [Morita, J., Takashi, R., & Ikebe, M. (1991) Biochemistry 30, 9539-9545]. The recombinant wild-type regulatory light chain exhibited the same biological properties as the natural isolate, i.e., phosphorylation at Ser-19 by myosin light-chain kinase and phosphorylation-activated actomyosin ATPase activity. To clarify whether or not the activation of the ATPase by phosphorylation is simply due to the introduction of negative charge, we produced three mutant light chains. Two of them contain Ser-19 substituted by either Asp or Ala and the third contains Asp substituted for both Thr-18 and Ser-19. Incorporation of the Asp mutant partially activated actomyosin ATPase activity but the activation level was significantly lower than that by phosphorylation. The Asp/Asp mutant further activated actomyosin ATPase activity. On the other hand, the Ala mutant did not affect the ATPase activity. Incorporation of Asp mutant slightly affected the 10S-6S conformational transition and filament formation of myosin. The Asp/Asp mutant more significantly affected the 10S-6S conformational transition and filament formation of myosin. These results suggested that the activation of smooth muscle myosin requires the introduction of negative charge in the defined spacial position. Using Ser-19 deficient mutants, the effects of Thr-18 phosphorylation on myosin function was also studied. Actin-activated ATPase activity of myosin was significantly activated by phosphorylation of Thr-18.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of gizzard myosin light chains in calcium binding

The contraction of molluscan and vertebrate smooth muscles is regulated by myosin. Although the myosin and its associated two subunits, the regulatory light chain and the essential light chain, constitute the Ca2+ regulatory system in both types of muscles, the mechanisms by which Ca2+ signal is transduced are quite different. In molluscan muscles, the direct binding of Ca2+ to the regulatory system triggers muscle contraction. In vertebrate smooth muscles, however, phosphorylation of the regulatory light chain is the major triggering mechanism. We measured Ca2+ binding in gizzard myosin and in hybrids of scallop myosin containing gizzard regulatory light chain or in hybrids of scallop regulatory domain containing gizzard essential light chain. Isolated chicken gizzard myosin did not bind Ca2+ in the range of pCa 8.0 to 5.0 in the presence of 2 mM MgCl2, supporting the lack of the specific Ca(2+)-binding site in gizzard myosin. Phosphorylation of the regulatory light chain did not generate a specific (Ca2+)-binding site. The hybrid scallop myosin containing gizzard regulatory light chain showed a similar Ca2+ binding as native scallop myosin with a one to one stoichiometry of Ca2+ to myosin head saturating at about pCa 6.0 at pH 7.6. In contrast, the hybrid scallop regulatory domain containing gizzard essential light chain did not bind Ca2+ either at pCa 6.0 or at pCa 8.0. Control preparations reconstituted with scallop essential light chains bound 0.69 mol per mol Ca2+ at pCa 6.0 with no binding at pCa 8.0.(ABSTRACT TRUNCATED AT 250 WORDS)

Differential tissue expression of multiple genes for chicken smooth muscle/nonmuscle myosin regulatory light chains

The cDNA clones for two distinct mRNAs encoding one of the two known isoforms of chicken smooth muscle/nonmuscle myosin regulatory light chain were isolated. The nucleotide sequences of these cDNAs were very similar to each other (99% nucleotide identities) in the 516 bp translated regions and in the first 33 bp of the 3' noncoding regions, whereas the rest of the 3' noncoding regions and the 5' noncoding regions had no significant similarity. Genomic Southern blot analysis showed that these two mRNAs were encoded in two individual genes. Whereas these two genes encoded almost identical polypeptides with only one conservative substitution of amino acid residues, expression of the mRNAs was differentially regulated both at the transcriptional and translational levels in various tissues of the chicken.

Interaction between the heavy and the regulatory light chains in smooth muscle myosin subfragment 1

The interaction between the heavy and the regulatory light chains within chicken gizzard myosin heads was investigated by using a zero-length chemical cross-linker, 1-ethyl-3-[3-(dimethylamino)-propyl]carbodiimide (EDC). The chicken gizzard subfragment 1 (S-1) used was treated with papain so that the heavy chain was partly cleaved into the NH2-terminal 72K and the COOH-terminal 24K fragments and the regulatory light chain into the 16K fragment. S-1 was reacted with EDC either alone or in the presence of ATP or F-actin. In all cases, the 16K fragment of the regulatory light chain formed a covalent cross-link with the 24K heavy chain fragment but not with the 72K fragment. The 38K cross-linked peptide, which was the product of cross-linking between the 16K light chain and the 24K heavy chain fragments, was isolated and further cleaved with cyanogen bromide and arginylendopeptidase. Smaller cross-linked peptides were purified by reverse-phase HPLC and then characterized by amino acid analysis and sequencing. The results indicated that cross-linking occurred between Lys-845 in the heavy chain and Asp-168, Asp-170, or Asp-171 in the regulatory light chain. The position of the cross-linked lysine was only three amino acid residues away from the invariant proline residue mapped as the S-1-rod hinge by McLachlan and Karn [McLachlan, A. D., & Karn, J. (1982) Nature (London) 299, 226-231]. We propose that the COOH-terminal region of the regulatory light chain is located in the neck region of myosin and that this region and the phosphorylation site of the regulatory light chain together may play a role in the phosphorylation-induced conformational change of gizzard myosin.

Formation and properties of smooth muscle myosin 20-kDa light chain-skeletal muscle myosin hybrids and photocrosslinking from the maleimidylbenzophenone-labeled light chain to the heavy chain

Experimental conditions which permit the exchange of smooth muscle 20-kDa light chain into skeletal muscle myosin are described. The hybridization does not result in the regulation of actin-activated ATPase activity of the hybrid myosin by smooth light chain phosphorylation. Further, the KCl dependence of the Mg-ATPase activity of the hybrid was similar to that of skeletal muscle myosin. The dephosphorylation of the smooth light chain in the hybrid did not induce a conformational change in the hybrid from the 6 S to the 10 S state, thereby indicating that the conformational transition is dependent also on the nature of the heavy chain subunit. Exchange of the smooth light chain premodified at its Cys-108 by photolabile 4-(N-maleimido)benzophenone and photolysis resulted in crosslinking to the heavy chain subunit. Immunopeptide mapping using a monoclonal antibody against residues 1-23 at the N-terminus of the skeletal muscle myosin heavy chain identified the location of the photocrosslinking site to be beyond 92 kDa away from the N-terminus.

Mammalian nonsarcomeric myosin regulatory light chains are encoded by two differentially regulated and linked genes

The myosin 20,000-D regulatory light chain (RLC) has a central role in smooth muscle contraction. Previous work has suggested either the presence of two RLC isoforms, one specific for nonmuscle and one specific for smooth muscle, or the absence of a true smooth muscle-specific isoform, in which instance smooth muscle cells would use nonmuscle isoforms. To address this issue directly, we have isolated rat RLC cDNAs and corresponding genomic sequences of two smooth muscle RLC based on homology to the amino acid sequence of the chicken gizzard RLC. These cDNAs are highly homologous in their amino acid coding regions and contain unique 3'-untranslated regions. RNA analyses of rat tissue using these unique 3'-untranslated regions revealed that their expression is differentially regulated. However, one cDNA (RLC-B), predominantly a nonmuscle isoform, based on abundant expression in nonmuscle tissues including brain, spleen, and lung, is easily detected in smooth muscle tissues. The other cDNA (RLC-A; see Taubman, M., J. W. Grant, and B. Nadal-Ginard. 1987. J. Cell Biol. 104:1505-1513) was detected in a variety of nonmuscle, smooth muscle, and sarcomeric tissues. RNA analyses comparing expression of both RLC genes with the actin gene family and smooth muscle specific alpha-tropomyosin demonstrated that neither RLC gene was strictly smooth muscle specific. RNA analyses of cell lines demonstrated that both of the RLC genes are expressed in a variety of cell types. The complete genomic structure of RLC-A and close linkage to RLC-B is described.

Evolution of EF-hand calcium-modulated proteins. I. Relationships based on amino acid sequences

The relationships among 153 EF-hand (calcium-modulated) proteins of known amino acid sequence were determined using the method of maximum parsimony. These proteins can be ordered into 12 distinct subfamilies--calmodulin, troponin C, essential light chain of myosin, regulatory light chain, sarcoplasmic calcium binding protein, calpain, aequorin, Stronglyocentrotus purpuratus ectodermal protein, calbindin 28 kd, parvalbumin, alpha-actinin, and S100/intestinal calcium-binding protein. Eight individual proteins--calcineurin B from Bos, troponin C from Astacus, calcium vector protein from Branchiostoma, caltractin from Chlamydomonas, cell-division-cycle 31 gene product from Saccharomyces, 10-kd calcium-binding protein from Tetrahymena, LPS1 eight-domain protein from Lytechinus, and calcium-binding protein from Streptomyces--are tentatively identified as unique; that is, each may be the sole representative of another subfamily. We present dendrograms showing the relationships among the subfamilies and uniques as well as dendrograms showing relationships within each subfamily. The EF-hand proteins have been characterized from a broad range of organismal sources, and they have an enormous range of function. This is reflected in the complexity of the dendrograms. At this time we urge caution in assigning a simple scheme of gene duplications to account for the evolution of the 600 EF-hand domains of known sequence.

Contractile proteins in Drosophila development

In summary, we have used a multidisciplinary approach to the analysis of actomyosin-based motility during Drosophila embryogenesis. We have documented the movements of early embryogenesis with modern, video methods. We have characterized the cytoplasmic myosin polypeptide, made specific polyclonal antisera to the molecule, studied its distribution during early embryogenesis, cloned and partially characterized the gene that encodes it, and have recently completed the nucleotide sequence of a nearly full length cDNA that encodes the entire protein-coding region. We have initiated studies on myosin function in living embryos both by direct microinjection of antibodies and through classical genetics. To better understand how myosin function is regulated, we have begun analysis of its light chains. Finally, to investigate the molecular mechanism by which its function is integrated into a labile cytoskeleton, whose architecture is constantly changing, we have also investigated Drosophila spectrins. Together, these studies are designed to shed light on the dynamics of biologic form at the cellular level, with current focus on such complex processes as cytokinesis and morphogenesis.

Two isoforms of smooth muscle myosin regulatory light chain in chicken gizzard

We isolated a cDNA clone for a new isoform of chicken smooth muscle myosin regulatory light chain (MRLC) from a cDNA library of embryonic chicken gizzard. The deduced amino acid sequence was different in 10 amino acid residues from the previously reported polypeptide sequences of chicken gizzard MRLC. The in vitro transcription/translation product from the cDNA comigrated with a minor isoform of chicken gizzard MRLC (L20-B) in a two-dimensional gel electrophoresis. This isoform was detected only in the embryonic gizzard and was slightly more acidic than the predominant isoform (L20-A). The partial polypeptide sequence of L20-A was confirmed to be identical to the previously reported MRLC sequence. Nevertheless, Northern blot analysis showed that L20-B-related mRNAs were present in both the embryonic and adult gizzard. Non-denaturing pyrophosphate polyacrylamide gel electrophoresis showed that the in vitro transcription/translation product could be associated with native myosin when mixed and coprecipitated in a low-ionic-strength buffer with adult chicken gizzard myosin. Moreover, the coprecipitated translation product was phosphorylated in vitro by chicken gizzard myosin light chain kinase apparently more rapidly than L20-A on the native myosin heavy chain. From these findings, we concluded that at least two isoforms of smooth muscle MRLC exist in chicken gizzard and that their expression may be regulated translationally depending on the developmental stage.

Study of the phosphorylatable light chains of skeletal and gizzard myosins by nuclear magnetic resonance spectroscopy

31P and 1H n.m.r. studies of the phosphorylatable light chains from rabbit fast skeletal and chicken gizzard muscles in the isolated state and in the intact myosin molecule indicate that the N-terminal region of the light chain containing the sites of phosphorylation has independent segmental flexibility. The ionization behaviour of serine phosphate in both rabbit skeletal and chicken gizzard P light chains exhibits cooperativity and is compatible with the phosphate group being influenced by neighbouring positively charged side-chains. No marked difference in phosphate ionization behaviour was apparent between the monophosphorylated P light chains of rabbit skeletal and chicken gizzard myosins. From 1H and 31P n.m.r. studies of the overall conformation, side-chain ionization properties and the spectral effects of titration with an anionic paramagnetic reagent bound at the basic N-terminal region, it is concluded that Thr-18 and Ser-19 are phosphorylated in the bisphosphorylated P light chain of gizzard myosin, the latter residue being the site of monophosphorylation. In the presence of F-actin the mobility of the serine phosphate of the P light chain of intact gizzard myosin was reduced. No interaction between the isolated P light chain and F-actin was however detected. These results are discussed with reference to the observed conformational features of the P light chain.

Molecular cloning and sequencing of the chicken smooth muscle myosin regulatory light chain

A cDNA probe was constructed from a chicken skeletal muscle regulatory light chain cDNA and was used to screen a chicken gizzard cDNA library. A clone containing the entire coding region of the chicken gizzard regulatory light chain was isolated and sequenced. The deduced protein sequence is identical to the most recently reported chemical sequence of the chicken smooth muscle regulatory light chain, and has homologies with other troponin C-like calcium-binding proteins.

Association of melittin with the isolated myosin light chains

Melittin is a 26-residue peptide which undergoes high-affinity calcium-dependent binding by calmodulin [Barnette, M.S., Daly, R., & Weiss, B. (1983) Biochem. Pharmacol. 32, 2929; Comte, M., Maulet, Y., & Cox, J.A. (1983) Biochem. J. 209, 269; Anderson, S.R., & Malencik, D.A. (1986) Calcium Cell Funct. 6, 1]. The results in this paper show that three different types of myosin light chain--the smooth muscle regulatory light chain, the smooth muscle essential light chain, and the skeletal muscle regulatory 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) light chain--also associate with melittin. The resulting complexes have dissociation constants ranging from 1.1 to 2.5 microM in the presence of 0.10 M NaCl and from approximately 50 to approximately 130 nM in solutions of 20 mM 3-(N-morpholino)propanesulfonic acid alone. The regulatory smooth muscle myosin light chain exhibits two equivalent melittin binding sites while each of the others displays only one. The myosin light chains evidently contain elements of structure related to the macromolecular interaction sites present in calmodulin and troponin C but not in parvalbumin. The association of melittin and other peptides with the light chains requires consideration whenever assays of the calmodulin-dependent activity of myosin light chain kinase are used to determine peptide binding by calmodulin. The binding measurements performed on the DTNB light chain and melittin necessitated derivation of the equation relating complex formation to the observed fluorescence anisotropy of a solution containing three fluorescent components. This analysis is generally applicable to equilibria involving the association of two fluorescent molecules emitting in the same wavelength range.

Hydroxyamino acid specificity of smooth muscle myosin light chain kinase

Synthetic peptides corresponding to the phosphorylation site in the myosin regulatory light chain from smooth muscle, Lys-Lys-Arg-Ala-Arg-Ala-Thr-Ser-Asn-Val-Phe-Ala ([Ala14,15]MLC(11-23] and containing a variety of hydroxyamino acid analogs at position 19, were tested as substrates for the smooth muscle myosin light chain kinase. Peptide analogs containing either D-serine or cis-hydroxyproline were not phosphorylated. The corresponding trans-hydroxyproline containing peptide was poorly phosphorylated with a Km of 2.3 microM and a Vmax of 3 X 10(-3) mumol.min-1.mg-1 compared to a Km of 12.5 microM and a Vmax of 1.43 mumol.min-1.mg-1 for the parent peptide. All three hydroxyamino acid analog peptides acted as relatively potent inhibitors of myosin light chain phosphorylation with Ki values in the range 7.5-10 microM, comparable to 7 microM for the parent peptide. Thus the failure of the hydroxyamino acid analog peptides to act as effective substrates was not the result of poor binding to the enzyme. In contrast, the same substitutions made in the peptide substrate for the cAMP-dependent protein kinase resulted in poor inhibitors. It is likely that the hydroxyl group of the substituting amino acids in the myosin light chain peptide analogs is not presented in the correct orientation in the active site for transfer of the phosphate group.

Cloning and characterization of mammalian myosin regulatory light chain (RLC) cDNA: the RLC gene is expressed in smooth, sarcomeric, and nonmuscle tissues

The 20-kD regulatory light chain (RLC) plays a central role in the regulation of smooth muscle contraction. Little is known about the structure or expression of smooth muscle myosin light chain (MLC) genes. A cDNA library was constructed in the expression vector, lambda gt-11, with mRNA derived from cultured rat aortic smooth muscle cells. Using antibody generated against tracheal smooth muscle myosin, three cDNA clones encoding a RLC were isolated, one of which, SmRLC-2, represents a full-length transcript of the RLC mRNA. The derived amino acid sequence shows 94.2% homology with the chicken gizzard RLC, and 70 and 52% homology with the rat skeletal and cardiac muscle MLC-2 proteins, respectively. Thus, the gene encoding the putative smooth muscle RLC appears to have originated by duplication of the same ancestor that gave rise to the sarcomeric MLC-2 genes. Contrary to the stringent tissue-specific expression of sarcomeric MLC-2 genes, RNA blot hybridization and S1 nuclease mapping demonstrates that the putative smooth muscle RLC gene is expressed in smooth, sarcomeric, and nonmuscle tissues at significant levels. Primer extension analysis suggests that the same promoter region is used in these different tissues. Thus the putative smooth muscle RLC gene appears to be a gene that is constitutively expressed in a large variety of cells and has a differentiated function in smooth muscle.

Characterization of the fluorescein isothiocyanate-reactive site of gizzard myosin ATPase

We describe the reaction of fluorescein 5'-isothiocyanate with gizzard myosin, and investigate the effect of this fluorescent modification on ATPase activities. Changes in the ATPase activities upon modification occur rapidly, paralleling the reaction of 'fast reacting lysine residues' during the fast phase of the reaction. The loss in the ATPase activity is linearly correlated with the extent of modification. About 90% of the ATPase activity is lost with the incorporation of 2.6 mol of reagent per mol of myosin. The fluorescent label is mainly incorporated into the heavy chain of the myosin molecule. Using limited tryptic digestion of labeled S1, we have shown that the fluorescent dye remains in the 18 kDa fragment. The amino acid composition and the partial sequence of the peptide from the N-terminal end is presented. The results presented here suggest the participation of the 18 kDa peptide in the nucleotide binding domain of gizzard myosin.

Position of the amino terminus of myosin light chain 1 and light chain 2 determined by electron microscopy with monoclonal antibody

The position of the N terminus of myosin light chain 1 (LC1) and myosin light chain 2 (LC2) of rabbit skeletal muscle was mapped on the myosin head with a monoclonal antibody (SI304), which recognized the amino acid sequence N-trimethylalanyl-prolyl-lysyl-lysyl at the N terminus of LC1 and LC2. The complex of the antibody and myosin was observed by electron microscopy. By selective cleavage of the N terminus of LC1 or LC2 with papain or chymotrypsin, the position of the N terminus of LC1 and LC2 was determined separately. The N terminus of LC2 is located at the head-rod junction. The N terminus of LC1 is 11 nm (+/- 3 nm, standard deviation) from the head-rod junction. This position is near the actin-binding site of the myosin head.

Interhead fluorescence energy transfer between probes attached to translationally equivalent sites on the regulatory light chains of scallop myosin

Interhead fluorescence energy transfer studies between probes located at translationally equivalent sites on the two heads of scallop myosin indicates that the distance between such sites is no less than 50 A. Regulatory light chains, possessing either one (Mercenaria, chicken gizzard) or two (Loligo, rabbit skeletal) sulfhydryl groups, were modified either with 1,5-IAEDANS (N'-iodoacetyl-N'-(1-sulfo-5-n-naphthyl)ethylenediamine), as energy transfer donor, or with IAF (5-(iodoacetamido)fluorescein) or DABMI (4-dimethylaminophenylazophenyl-4'-maleimide), as energy transfer acceptor. The sulfhydryl groups on these light chains are located at different positions within the regulatory light-chain primary sequence; this enables one to probe a variety of locations, with respect to regulatory light-chain topology, on each myosin head. These independently modified regulatory light chains were added back to desensitized scallop myosin under a variety of conditions, including biphasic re-addition, the aim being to maximize the number of interhead energy transfer couples present. The efficiency of energy transfer was determined on the same samples by both steady-state and time-decay techniques. Results obtained by these two techniques were in good agreement with each other and indicated that the efficiency of energy transfer did not exceed 20% in any of the hybrids studied. Transfer efficiencies were invariant, irrespective of the presence or absence of MgATP, calcium or actin, either separately or in combination. Results using heavy meromyosin at low ionic strength were identical. It is shown that these results, in conjunction with the results of recent crosslinking studies performed on comparable myosin hybrids, may place certain restrictions on the configurations of the two heads of myosin.

Characterization of the myosin light-chain-2 gene of Drosophila melanogaster

Recombinant DNA clones encoding the Drosophila melanogaster homolog of the vertebrate myosin light-chain-2 (MLC-2) gene have been isolated. This single-copy gene maps to the chromosomal locus 99E. The nucleotide sequence was determined for a 3.4-kilobase genomic fragment containing the gene and for two MLC-2 cDNA clones generated from late pupal mRNA. Comparison of these sequences shows that the gene contains two introns, the positions of which are conserved in the corresponding rat sequence. Extension of a primer homologous to the mRNA reveals two start sites for transcription 12 nucleotides apart. The sequence TATA is not present ahead of the mRNA cap site. There are two major sites of poly(A) addition separated by 356 nucleotides. The protein sequence derived from translation of the cDNA sequence shows a high degree of homology with that for the DTNB myosin light chain (MLC-2) of chicken. A lower degree of sequence homology was seen in comparisons with other evolutionarily related calcium-binding proteins. RNA blots show high levels of expression of several transcripts during the developmental time stages when muscle is being produced. In vitro translation of hybrid-selected RNA produces two polypeptides which comigrate on two-dimensional gels with proteins from Drosophila actomyosin, although the cDNA sequence reveals only one 26-kilodalton primary translation product.

Isoforms of the phosphorylatable myosin light chain in arterial smooth muscle

Two isoforms of the phosphorylatable myosin light chain of arterial smooth muscle have been identified, at proportions of 15 and 85%. The isoforms have similar tryptic peptide maps and can be mono-, di- and triphosphorylated. In intact or homogenized muscle, monophosphorylation and, to a small degree, diphosphorylation occur, whereas in isolated actomyosin diphosphorylation and triphosphorylation are manifested. Serine and threonine residues are phosphorylated in all three systems, but the ratio of phosphothreonine to phosphoserine is much higher in actomyosin than in muscle.

Chemical modification of lysine and arginine residues in the myosin regulatory light chain inhibits phosphorylation

The contribution of lysine and arginine residues to the substrate specificity of the myosin light-chain kinase has been studied using chemically modified myosin light chains. Succinylation or maleylation of the myosin light chains caused complete inhibition of their phosphorylation. Modification of 50% of the lysine residues resulted in 90% inhibition of phosphorylation and this was accompanied by a 25-fold increase in the apparent Km. In contrast, phosphorylation of the myosin light chains by the cAMP-dependent protein kinase was relatively insensitive to lysine modification, with only a 15% reduction in phosphorylation following succinylation of 50% of the lysine residues. Treatment with either cyclohexane-1,2-dione or camphorquinone-10-sulfonic acid resulted in between 90 and 98% inhibition of myosin light-chain phosphorylation. These reagents caused modification of both lysine and arginine residues, and accordingly only part of the inhibition can be attributed to arginine modification. Modification of all of the cysteine and methionine residues caused only a 40% inhibition of phosphorylation. The results of this study support the concept that lysine and arginine residues act as essential specificity determinants for the myosin light-chain kinase in protein substrates.

Molecular basis for substrate specificity of protein kinases and phosphatases

Regulation of various metabolic processes occurs by the phosphorylation/dephosphorylation of enzymes. Both the protein kinases that catalyze the phosphorylations and the protein phosphatases that catalyze the dephosphorylations display relatively broad specificity, reacting with a number of distinct sites in target enzymes. In this way changes in the activity of a particular kinase or phosphatase can cause coordinated and pleiotropic responses. However, the kinases and phosphatases do not exhibit a one-to-one correspondence in their reactions. Residues at different positions may be phosphorylated by a single kinase, yet dephosphorylated by different individual phosphatases. Conversely, sites which are substrates for different individual kinases may be dephosphorylated by a single phosphatase. In exploring the molecular basis for these differences this article shows that whereas kinases react with specific primary structures that often times appear as beta bends, the phosphatases recognize higher order structure, less strictly ruled by amino acid sequence surrounding the phosphorylated site. The differences, seen in the ability of these enzymes to utilize synthetic peptide substrates, might be rationalized in terms of function. Kinases need protruding segments of structure that can be enwrapped to exclude water, thereby minimizing ATP hydrolysis and enhancing phosphotransferase activity. On the other hand phosphatases are hydrolytic enzymes that may operate especially well on protein interfaces. Hydrolytic action often measured with p-nitrophenylphosphate is not necessarily indicative of a protein phosphatase and consideration of the mechanism reveals why this substrate can be misleading.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of the myosin light-chain-2 gene of Drosophila melanogaster

Recombinant DNA clones encoding the Drosophila melanogaster homolog of the vertebrate myosin light-chain-2 (MLC-2) gene have been isolated. This single-copy gene maps to the chromosomal locus 99E. The nucleotide sequence was determined for a 3.4-kilobase genomic fragment containing the gene and for two MLC-2 cDNA clones generated from late pupal mRNA. Comparison of these sequences shows that the gene contains two introns, the positions of which are conserved in the corresponding rat sequence. Extension of a primer homologous to the mRNA reveals two start sites for transcription 12 nucleotides apart. The sequence TATA is not present ahead of the mRNA cap site. There are two major sites of poly(A) addition separated by 356 nucleotides. The protein sequence derived from translation of the cDNA sequence shows a high degree of homology with that for the DTNB myosin light chain (MLC-2) of chicken. A lower degree of sequence homology was seen in comparisons with other evolutionarily related calcium-binding proteins. RNA blots show high levels of expression of several transcripts during the developmental time stages when muscle is being produced. In vitro translation of hybrid-selected RNA produces two polypeptides which comigrate on two-dimensional gels with proteins from Drosophila actomyosin, although the cDNA sequence reveals only one 26-kilodalton primary translation product.

Proximity of regulatory light chains in scallop myosin

The distance between the regulatory light chains of the two heads of the scallop myosin molecule was estimated with the aid of two photolabile cross-linkers, benzophenone maleimide and p-azidophenacylbromide. These cross-linkers selectively alkylate thiol groups and have a maximum length of about 9 A. One of the two regulatory light chains of scallop myosin was removed by treatment of myofibrils at 10 degrees C with EDTA and replaced with a foreign regulatory light chain carrying a cross-linker. Cross-linking between the scallop and foreign regulatory light chains was effected by photolysis. This was demonstrated by incubating nitrocellulose transfers of sodium dodecyl sulfate/polyacrylamide gels of the photolyzed hybrid myofibrils with specific antibodies against the different light chains, followed by fluorescein isothiocyanate-125I-labeled secondary antibody. Scallop regulatory light chains cross-linked extensively (20 to 50%) with Mercenaria regulatory light chains (cysteine in position approximately 50) in solutions that induce rigor in skinned fibers (no ATP) and in relaxing solutions (ATP but no Ca2+). Neither the regulatory light chains of chicken skeletal myosin (cysteines 129 and 157) nor those of gizzard myosin (cysteine 108) were cross-linked to scallop regulatory light chains in either medium. These results indicate that the N-terminal portions of the myosin regulatory light chains can approach each other within 9 A or less, while the distance between the C-terminal halves exceeds 9 A, and support the view that the N termini of the regulatory light chains point toward the myosin rod. Since the relative distance between the regulatory light chains of the two myosin heads is not altered between rigor and rest, we suggest that motion of the essential light chains is mainly responsible for the observed difference in the relative positions of the regulatory and essential light chains between conditions of rigor and rest.

Amino acid sequence of the phosphorylation site of bovine cardiac myosin light chain

Amino acid sequences of peptides containing the phosphorylation site of bovine cardiac myosin light chain (L2) were determined. The site was localized to a serine residue in the tentative amino terminus of the light chain and is homologous to phosphorylation sites in other myosin light chains. Phosphorylation of bovine cardiac light chain by chicken gizzard myosin light chain kinase was Ca2+-calmodulin dependent. Kinetic data gave a Km of 107; microM and a Vmax of 23.6 mumol min-1 mg-1. In contrast to what has been observed with smooth muscle light chains, neither the phosphorylation site fragment of the cardiac light chain nor a synthetic tetradecapeptide containing the phosphorylation site were effectively phosphorylated by the chicken gizzard kinase. Phosphorylation of cardiac myosin light chains by chicken gizzard myosin light chain kinase, therefore, requires other regions of the light chain in addition to a phosphate acceptor site.

Requirement of the 20-kDa light chain for the papain-resistant conformation of gizzard myosin

The limited chymotryptic digestion of unphosphorylated gizzard myosin in 0.15 M NaCl converted a papain-insensitive myosin in ATP to a papain-sensitive one. This conversion without phosphorylation of its 20-kDa light chain was accompanied with truncation of a 200-kDa heavy chain to a 195-kDa fragment and with the degradation of a 20-kDa light chain. Papain also yielded the 195-kDa fragment from the heavy chain, irrespective of the presence or absence of ATP. However, the ATP-induced protection of unphosphorylated myosin from the papain-digestion disappeared concurrently with degradation of the 20-kDa light chain by papain rather than the truncation of heavy chain. Papers from two laboratories [Onishi, H. & Watanabe, S. (1984) J. Biochem. (Tokyo) 95, 903-905; Kumon, A., Yasuda, S., Murakami, N., and Matsumura, S. (1984) Eur. J. Biochem. 140, 265-271] have reported that the ATP-protection of unphosphorylated myosin against papain is not observed after the 20-kDa light chain has been phosphorylated. The present results might indicate that the ATP-induced protection is also abolished through the chymotryptic degradation of the 20-kDa light chain.

The phosphorylation site for casein kinase II on 20,000-Da light chain of gizzard myosin

The 20-kDa light chain isolated from gizzard myosin has recently been reported to be phosphorylated by casein kinase II at a site distinct from that phosphorylated by Ca2+- and calmodulin-dependent myosin light-chain kinase. In the present study, the site phosphorylated by casein kinase II has been analyzed through procedures including tryptic digestion of the radioactively phosphorylated light chain and CNBr cleavage of the purified tryptic phosphopeptide, followed by amino acid analysis of these phosphopeptides. Comparison of the amino acid compositions of these peptides with the previously reported sequence has indicated that the phosphorylation site is threonine-134 of the light chain. The significance of the phosphorylation of the light chain by casein kinase II, as well as the substrate specificity of the protein kinase, is discussed on the basis of the result.

Comparison of substrate specificity of myosin kinase and cyclic AMP-dependent protein kinase

A series of synthetic peptides corresponding to the amino-terminal region of chicken gizzard myosin light chain (Mr 20 000) have been tested for their capacity to act as substrates for the cAMP-dependent protein kinase. The 18-residue peptide, K6AKTTK11 K12R13PQRATS19NVFS , was stoichiometrically phosphorylated on serine-19 by the cAMP-dependent protein kinase. This is the same residue phosphorylated by the myosin light chain kinase. The cAMP-dependent protein kinase phosphorylated this peptide with an apparent Km of 120 microM and Vmax of 0.29 mumol . min .-1 mg-1. The Km is 17-fold higher and the Vmax 10-fold lower than the corresponding values obtained with this peptide as substrate for the myosin light chain kinase. The kinetics of phosphorylation of shortened peptides corresponding to this 18-residue sequence together with those of another related sequence, RPQRAKAKTTKATSNVFS , indicated that the myosin light chain kinase had a relatively stronger dependence on lysine residues, whereas the cAMP-dependent protein kinase depends more on arginine residues. Although both the cAMP-dependent protein kinase and the myosin light chain kinase phosphorylate the same serine in the myosin light chain peptides, these enzymes are influenced by different nearby basic residues.