Role of myosin light chain kinase in muscle contraction

In resting striated muscles of the rabbit muscle in vivo, the phosphorylatable light chain is partially phosphorylated. Tetanic stimulation increased the level of phosphorylation more rapidly in fast twitch than in slow twitch muscle. In both types of muscle the rate of dephosphorylation was relatively slow. In rabbit fast twitch muscles, phosphorylation levels persisted significantly above the resting value for some time after posttetanic potentiation had disappeared. The role of myosin light chain kinase in modulating contractile response in striated muscle is uncertain. In vertebrate smooth muscle the role of myosin phosphorylation appears to be different from that in striated muscle despite the general similarity of the actomyosin system in both tissues. Although phosphorylation in vitro increases the Mg2+ -ATPase of actomyosin, a number of features imply that a somewhat complex relationship exists between the level of phosphorylation and the actin activation of the Mg2+ -ATPase in vertebrate smooth muscle. Contrary to many earlier reports, preparations of smooth muscle actomyosin can be obtained with Mg2+ -ATPase activities comparable to those of actomyosin from skeletal muscle. Preliminary evidence is presented that suggests that phosphorylation changes the Ca2+ sensitivity of the Mg2+ -ATPase of smooth muscle actomyosin.     

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.     

Mammalian skeletal muscle myosin light chain kinases. A comparison by antiserum cross-reactivity

Purified myosin light chain kinases from skeletal muscle are reported to be significantly smaller (Mr = 75,000-90,000) than the kinases purified from smooth muscle (Mr = 130,000-155,000). It has been suggested that the smaller kinases from striated muscle are proteolytic fragments of a larger enzyme which is homologous, if not identical, to myosin light chain kinase from smooth muscle. Therefore, we have used an antiserum to rabbit skeletal muscle myosin light chain kinase and Western blot analysis to compare the subunit molecular weight of the kinase in skeletal muscle extracts of several mammalian species. In rabbit skeletal muscle, the antiserum only recognized a polypeptide of Mr = 87,000, with no indication that this polypeptide was a proteolyzed fragment of a larger protein. The apparent molecular weights observed in different animal species were 75,000 (mouse), 83,000 (guinea pig), 82,000 (rat), 87,000 (rabbit), 100,000 (dog), and 108,000 (steer). The molecular weight of myosin light chain kinase was constant within an animal species, regardless of skeletal muscle fiber type. The antiserum inhibited the catalytic activity of skeletal muscle myosin light chain kinase. Similar antibody dilution curves for inhibition of myosin light chain kinase activity in extracts were observed for all animal species (rabbit, rat, mouse, guinea pig, dog, cat, steer, and chicken) and different fibers (slow twitch oxidative, fast twitch oxidative glycolytic, and fast twitch glycolytic) tested. The antiserum did not inhibit the activity of rabbit smooth muscle myosin light chain kinase. These results suggest that there may be at least two classes of muscle myosin light chain kinase represented in skeletal and smooth muscles, respectively.     

Structural proteins in the myofilaments and regulation of contraction in vertebrate smooth muscle.

The contractile systems of vertebrate smooth and striated muscles are compared. Smooth muscles contain relatively large amounts of actin and tropomyosin organized into thin filaments, and smaller amounts of myosin in the form of thick filaments. The protein contents are consistent with observed thin:thick filament ratios of about 15-18:1 in smooth compared to 2:1 in striated muscle. The basic characteristics of both types of contractile proteins are similar; but there are a variety of quantitative differences in protein structures, enzymatic activities and filament stabilities. Biochemical and X-ray diffraction data generally support recent ultrastructural evidence concerning the organization of the myofilaments in smooth muscle, although a basic contractile unit comparable to the sarcomere in striated muscle has not been discerned. Myofilament interactions and contraction in smooth muscle are controlled by changes in the Ca2+ concentration. Recent evidence suggests the Ca2+-binding regulatory site is associated with the myosin in vertebrate smooth muscle (as in a variety of invertebrate muscles), rather than with troponin which is the regulatory protein associated with the thin filament in vertebrate striated muscle.     

Smooth muscle myosin light chain kinase efficiently phosphorylates serine 15 of cardiac myosin regulatory light chain

Specific phosphorylation of the human ventricular cardiac myosin regulatory light chain (MYL2) modifies the protein at S15. This modification affects MYL2 secondary structure and modulates the Ca(2+) sensitivity of contraction in cardiac tissue. Smooth muscle myosin light chain kinase (smMLCK) is a ubiquitous kinase prevalent in uterus and present in other contracting tissues including cardiac muscle. The recombinant 130 kDa (short) smMLCK phosphorylated S15 in MYL2 in vitro. Specific modification of S15 was verified using the direct detection of the phospho group on S15 with mass spectrometry. SmMLCK also specifically phosphorylated myosin regulatory light chain S15 in porcine ventricular myosin and chicken gizzard smooth muscle myosin (S20 in smooth muscle) but failed to phosphorylate the myosin regulatory light chain in rabbit skeletal myosin. Phosphorylation kinetics, measured using a novel fluorescence method eliminating the use of radioactive isotopes, indicates similar Michaelis-Menten V(max) and K(M) for regulatory light chain S15 phosphorylation rates in MYL2, porcine ventricular myosin, and chicken gizzard myosin. These data demonstrate that smMLCK is a specific and efficient kinase for the in vitro phosphorylation of MYL2, cardiac, and smooth muscle myosin. Whether smMLCK plays a role in cardiac muscle regulation or response to a disease causing stimulus is unclear but it should be considered a potentially significant kinase in cardiac tissue on the basis of its specificity, kinetics, and tissue expression.     

Changes in tropomyosin subunits and myosin light chains during development of chicken and rabbit striated muscles.

We have selected tropomyosin subunits and myosin light chains as representative markers of the myofibrillar proteins of the thin and thick filaments and have studied changes in the type of proteins present during development in chicken and rabbit striated muscles. The β subunit of tropomyosin is the major species found in all embryonic skeletal muscles studied. During development the proportion of the α subunit of tropomyosin gradually increases so that in adult skeletal muscles the α subunit is either the only or the major species present. In contrast, cardiac muscles of both chicken and rabbit contain only the α subunit which remains invariant with development. Two subspecies of the α subunit of tropomyosin which differ in charge only were found in adult and embryonic chicken skeletal muscles. Only one of these subspecies seems to be common to chicken cardiac tropomyosin. With respect to myosin light chains, embryonic skeletal fast muscle myosin of both species resembles the adult fast muscle myosin except that the LC₃ light chain characteristic of the adult skeletal fast muscle is present in smaller amounts. The significance of these isozymic changes in the two myofibrillar proteins is discussed in terms of a model of differential gene expression during development of chicken and rabbit skeletal muscles.     

Characterization of homologous divalent metal ion binding sites of vertebrate and molluscan myosins using electron paramagnetic resonance spectroscopy.

The binding of Ca²⁺, Mg²⁺ and Mn²⁺ to myosins from rabbit skeletal muscle, scallop striated adductor muscle and clam adductor muscle has been investigated. All three myosins bind two moles of divalent metal ion non-specifically and with high affinity (Mn²⁺ > Ca²⁺ > Mg²⁺). In addition, the molluscan myosins bind about a further two moles of Ca²⁺ specifically. Although rabbit myosin binds some Ca²⁺ in the presence of an excess of free Mg²⁺, this binding occurs at the nonspecific sites and should not be taken as evidence for a myosin-linked regulatory system of the type found in molluscan muscles. If such a system exists in vertebrate skeletal muscle, the homologous Ca²⁺-specific sites must be lost during the early stages of the myosin preparation.The characteristic electron paramagnetic resonance spectrum of the bound Mn²⁺ was utilized to confirm the homology of the non-specific sites in vertebrate and molluscan myosins. The sites are located on the “regulatory” class of light chain. Mn²⁺ bound to scallop myosin has a broad electron paramagnetic resonance spectrum, in contrast to the well-resolved spectra that it gives when bound to many other myosin species. This situation was exploited to identify homologous nonspecific, divalent metal-ion sites on the regulatory light chains from a variety of muscle types, including frog skeletal, rabbit cardiac, chicken gizzard and molluscan adductor muscles. When these light chains are combined with desensitized scallop myofibrils the electron paramagnetic resonance spectra of Mn²⁺ bound to the resultant hybrids are dominated by the signal from the non-specific site of the foreign regulatory light chain.     

Absence of phosphates from the myosin heavy chains of striated muscles

This work aimed to determine whether the heavy chains of myosin from different striated muscle were phosphorylated. Myosin and its heavy chains were prepared from cardiac and skeletal muscles of rats injected in vivo with radioactive phosphates.The results for radioactive phosphate localization indicate the absence of phosphate from pure heavy chains and from any of their purified fragments, whatever the striated muscle used. In addition, phosphates are present in the myosin phosphorylated light chain and in a contaminating protein closely associated to the myosin heavy chain.     

Regulatory light chains in myosins.

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

Contents of myofibrillar proteins in cardiac, skeletal, and smooth muscles

The in situ contents of myosin, actin, alpha-actinin, tropomyosin, troponin, desmin were estimated in dog cardiac, rabbit skeletal, and chicken smooth muscles. Whole muscle tissues were dissolved with 8 M guanidine hydrochloride and subjected to two-dimensional gel electrophoresis, which is a nonequilibrium pH gradient electrophoresis (Murakami, U. & Uchida, K. (1984) J. Biochem. 95, 1577-1584) with some modification. The amount of protein in a spot on a slab gel was determined by quantification of the extracted dye. Dye binding capacity of individual myofibrillar proteins was determined by using the purified protein. Myosin contents were 82 +/- 7 pmol/mg wet weight in cardiac muscle, 105 +/- 10 pmol/mg wet weight in skeletal muscle, and 45 +/- 4 pmol/mg wet weight in smooth muscle. Actin contents were 339 +/- 15 pmol/mg wet weight in cardiac muscle, 625 +/- 27 pmol/mg wet weight in skeletal muscle, and 742 +/- 13 pmol/mg wet weight in smooth muscle. The subunit stoichiometry of myosin in the three types of muscles was two heavy chains and four light chains, and there was one light chain 2 for every heavy chain. The molar ratio of actin to tropomyosin was 7/1 in the three types of muscles. Striking differences were seen in the molar ratio of myosin to actin: 1.0/4.1 in cardiac muscle, 1.0/6.0 in skeletal muscle, and 1.0/16.5 in smooth muscle.     

Differential regulation of the atrial isoforms of the myosin light chains during striated muscle development.

We have isolated a cDNA that encodes the human regulatory myosin light chain isoform predominant in adult atrial muscle. The cDNA contains an open reading frame of 175 amino acids and encodes a hydrophilic protein of a largely helical structure with two potential phosphorylation sites. The protein is different from any other regulatory myosin light chain so far described and is the product of a previously uncharacterized single copy gene. An isoform-specific probe was used to analyze the expression of this isoform in adult muscle and in cardiac and skeletal muscle development in vivo and in vitro. Parallel analysis of the corresponding human alkali myosin light chain (predominant in adult atrium) showed that both isoforms are expressed in early heart development, in both atrium and ventricle. Although the atrial alkali light chain is expressed throughout embryonic striated muscle development, the regulatory myosin light chain was not detected in skeletal myogenesis in vivo or in vitro. Thus the atrial isoforms are not universally or exclusively "paired" and can be independently regulated. We propose that the manner in which these particular isoforms fulfill the functional requirements of the muscle at different developmental times may have direct impact on their regulation.     

Electrophoretic and immunological study of myosin light chains from freshwater teleost fishes

White muscle myosin light chains from nine freshwater teleosts show a qualitative and quantitative variability on PAGE without phylogenetic correlation. They look different from their higher vertebrate counterparts mainly with regard to electric charge and relative amounts of alkali light chains corresponding to various contents of isoenzymic forms of white muscle myosin. Antibodies against carp white myosin LC1 recognize almost entirely white muscle LC1 from the other fishes and to a lesser degree LC1 from other muscles and vertebrates. The primary structure of this light chain is thus relatively constant. LC2 from carp cardiac muscle and mammalian slow and cardiac muscle do not react at all.     

Lamprey contractile protein genes mark different populations of skeletal muscles during development

Agnathan lampreys retain ancestral characteristics of vertebrates in the morphology of skeletal muscles derived from two mesodermal regions: trunk myotomes and unsegmented head mesoderm. During lamprey development, some populations of myoblasts migrate via pathways that differ from those of gnathostomes. To investigate the evolution of skeletal muscle differentiation in vertebrates, we characterize multiple contractile protein genes expressed in the muscle cells of the Japanese lamprey, Lethenteron japonicum. Lamprey actin gene LjMA2, and myosin heavy chain (MyHC) genes LjMyHC1 and LjMyHC2 are all expressed in the developing skeletal muscle cells of early embryos. However, LjMyHC1 and LjMyHC2 are expressed only in cells originating from myotomes, while LjMA2 is expressed in both myotomal and head musculature. Thus, in lampreys, myotomes and head mesoderm differ in the use of genes encoding contractile protein isoforms. Phylogenetic tree analyses including lamprey MyHCs suggest that the variety of muscle MyHC isoforms in different skeletal muscles may correspond to the morphological complexity of skeletal muscles of different vertebrate species. Another lamprey actin gene LjMA1 is likely to be the first smooth muscle actin gene isolated from non-tetrapods. We conclude that, in vertebrate evolution, the different regulatory systems for striated and smooth muscle-specific genes may have been established before the agnathan/gnathostome divergence.     

Homologous calcium-binding proteins in the activation of skeletal, cardiac, and smooth muscle myosin light chain kinases

In order to identify the physiological regulator of calcium dependent myosin light chain kinases of cardiac, skeletal, and smooth muscles, the effects of the three homologous calciproteins, calmodulin, troponin C, and parvalbumin, on the kinases isolated from bovine myocardium, rabbit skeletal muscle, and turkey gizzard were examined. Only calmodulin was effective in stimulating the cardiac, skeletal, or smooth muscle kinase; troponin C and parvalbumin exhibited no activation of any of the three kinases, even when examined at concentrations as high as 10-(5) M. It is concluded that calmodulin is the specific regulator of myosin light chain kinase in cardiac, skeletal, and smooth muscle.     

Immunochemical comparison of myosin light chains from chicken fast white, slow red, and cardiac muscle.

Antibodies were formed against the myosin light chains isolated from chicken fast skeletal, slow skeletal, and cardiac muscle and the antigenicities of the light chains were compared by double immunodiffusion and immunoelectrophoresis. It was shown that fast light chains are immunologically different from light chains of slow and cardiac myosin, while the slow and cardiac muscle light chains have similar immunological characteristics; that is, the light chains of apparent molecular weight about 27,000 daltons in SDS-acrylamide gel electrophoresis of slow and cardiac muscle are immunologically indistinguishable, and the other light chains of apparent molecular weight about 19,000 daltons of both muscles include a common antigenic site.     

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.     

Thin filament length regulation in striated muscle sarcomeres: pointed-end dynamics go beyond a nebulin ruler

The actin (thin) filaments in striated muscle are highly regulated and precisely specified in length to optimally overlap with the myosin (thick) filaments for efficient myofibril contraction. Here, we review and critically discuss recent evidence for how thin filament lengths are controlled in vertebrate skeletal, vertebrate cardiac, and invertebrate (arthropod) sarcomeres. Regulation of actin polymerization dynamics at the slow-growing (pointed) ends by the capping protein tropomodulin provides a unified explanation for how thin filament lengths are physiologically optimized in all three muscle types. Nebulin, a large protein thought to specify thin filament lengths in vertebrate skeletal muscle through a ruler mechanism, may not control pointed-end actin dynamics directly, but instead may stabilize a large core region of the thin filament. We suggest that this stabilizing function for nebulin modifies the lengths primarily specified by pointed-end actin dynamics to generate uniform filament lengths in vertebrate skeletal muscle. We suggest that nebulette, a small homolog of nebulin, may stabilize a correspondingly shorter core region and allow individual thin filament lengths to vary according to working sarcomere lengths in vertebrate cardiac muscle. We present a unified model for thin filament length regulation where these two mechanisms cooperate to tailor thin filament lengths for specific contractile environments in diverse muscles.     

Myosin-linked calcium regulation in vertebrate smooth muscle.

By the use of a new procedure, actomyosin may be extracted in high yield and purity from fowl gizzard which exhibits a calcium-dependent actin-activated ATPase activity comparable to that of the parent myofibril-like preparation. Studies of this vertebrate smooth muscle actomyosin show that the regulation of the actin-myosin interaction is effected, as in molluscan muscles, by the myosin molecule itself and not by an actin-linked regulatory system, as found in vertebrate skeletal muscle.Thus, calcium-sensitive smooth muscle actomyosin is composed of only myosin, actin and tropomyosin, any troponin-like components being absent. Myosin is the only component that binds significant amounts of calcium and shows a calcium-dependent actin-activated ATPase activity in the presence of F-actin from either gizzard or rabbit skeletal muscle.The cross-reaction of gizzard thin filaments with skeletal muscle myosin produces an actomyosin whose actin-activated ATPase is calcium-insensitive, showing that smooth muscle thin filaments do not serve a regulatory function.The effect of Mg²⁺ and pH, and evidence for the involvement of one of the myosin light chains in calcium regulation are described and discussed.