Transitions in human atrial and ventricular myosin light-chain isoenzymes in response to cardiac-pressure-overload-induced hypertrophy.

1. The light-chain subunits of human atrial and ventricular cardiac muscle were examined by two-dimensional polyacrylamide-gel electrophoresis and limited proteolytic digestion. The light-chain patterns in the normal right and left atria were identical. 2. Myosin preparations isolated from right or left atria that had been subjected to cardiac-pressure-overload-induced hypertrophy also contained ventricular light-chain subunits. These were identified by peptide mapping in sodium dodecyl sulphate. 3. Ventricular light chain-2 was the major species in hypertrophied atria, although light chain-1 subsequently appeared in severe pressure-overload-hypertrophied cases. Evidence is presented for the existence of more than one form of ventricular light chain-2. 4. The transition from atrial to ventricular myosin light chains correlated with the degree of pressure-overload hypertrophy in 83 examples of surgically excised atria. 5. The adult atrial light chain-1 was shown to be homologous to the human foetal ventricular light chain-1 [Price, Littler & Cummins (1980) Biochem. J. 191, 571-580] by peptide mapping. 6. A scheme of atrial/ventricular myosin light-chain isoenzyme transitions is discussed in relation to changing contractile properties in cardiac muscle, together with implications for the role of light-chain subunits.     

Atrial and ventricular myosin during development and senescence of the rat

Myosin was isolated from rat atrial and ventricular myocardium and examined during post-natal development and senescence. The post-natal increase of Ca2+-ATPase activity of myosin from rat atria did not run in parallel with changes of ATPase activity of myosin from the ventricles. Ca2+-ATPase of both atrial and ventricular myosin was activated at pH 9.5, when compared with the assay performed at pH 7.5. The myosin light-chain subunits in the ventricles were different from the light-chain subunits in the atria, when characterized by SDS-polyacrylamide gel electrophoresis and the pattern remained practically unchanged during development, with the exception of atrial myosin from new-born and very old rats which contained an additional protein of low molecular weight.     

Myosin light chains of guinea-pig striated muscles. Similarities and differences with rat myosin light chains

1. Myosin light chains of guinea-pig striated muscles have been screened by two-dimensional gel electrophoresis and compared to rat myosin light chains. 2. The fast type light chains 1F and 3F, slow type light chains 1S and 2S, and embryonic type light chain 1E are shown to differ in the two rodents; only the fast type light chains 2F co-electrophorese on the gel. 3. In guinea-pig, as in rat, ventricle muscle light chains appear the same as the 1S and 2S light chains and atrial light chain type 1 the same as the 1E light chain. We show that this embryonic light chain of guinea-pig myosin is difficult to identify and may be confused with the adult 1F light chain.     

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.     

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.     

The topographic characteristics and changes in the ontogeny of light-chain myosin in the human myocardium

Pattern of myosin light chain in human atrium and ventricles was studied using two-dimensional electrophoresis. Minor fraction was found in ventricles and atria of adult man that coincided in molecular weight, isoelectric point and staining specificity with fetal myosin light chain. The 23 kDa and 24 kDa fractions of auricles were not detected in ventricles.     

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

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

An electrophoretic study of native myosin isozymes and of their subunit content.

Myosin polymorphism in muscles has been studied by a variety of electrophoretic techniques, in non-dissociating and in dissociating conditions. The analysis of myosin isozymes in the native state was achieved in pyrophosphate buffer and required only minute amounts of protein; identical results were obtained with purified or crudely extracted myosin. The determination of the subunit content of each isozyme was done in the presence of sodium dodecyl sulphate or urea for light chain, and in a phenol, acetic acid and urea system for heavy chain screening. Electrophoresis in non-dissociating conditions has led to the separation of up to a dozen of myosin isozymes, differing in mobilities by as much as 30%. Muscle specificity of myosin was clearly established. Apart from a few exceptions, all the muscles tested were shown to contain more than one myosin species; fast-twitch muscles for instance all contained the same three isozymes, but in variable ratios. Class specificity of myosin appeared related to the relative proportions of isozymes in a given muscle. A second electrophoresis in dissociating solvents of the myosin bands first resolved in pyrophosphate buffer has then allowed a further characterization of the various isozymes. The differences in mobilities observed in the native state were shown to come either from the light chains, or from the heavy chains, or from both. The first case was illustrated by the three species present in fast muscles, which were shown to correspond to three alkali light-chain isozymes, the heterodimer representing in some instances up to 40% of the total. Next to light-chain muscle type specificity, electrophoresis in the phenol, acetic acid, urea system has led to the detection of differences in the heavy chains of fast, slow and cardiac myosins. The application of these various electrophoretic techniques to the analysis of the modification of myosin isozymes during development or in pathology studies can be considered.     

Comparison of myosin isoenzymes present in skeletal and cardiac muscles of the Arctic charr Salvelinus alpinus (L.). Sequential expression of different myosin heavy chains during development of the fast white skeletal muscle.

The expression of myosin isoforms and their subunit composition in the white skeletal body musculature of Arctic charr (Salvelinus alpinus) of different ages (from 77-day embryos until about 5 years old) was studied at the protein level by means of electrophoretic techniques. Myosin from the white muscle displayed three types of light chain during all the developmental stages examined: two myosin light chains type 1 (LC1F) differing in both apparent molecular mass and pI, one myosin light chain type 2 (LC2F) and one myosin light chain type 3 (LC3F). The fastest-migrating form of LC1F seemed to be predominant during the embryonic and eleutheroembryonic periods. The slowest-migrating form of LC1F was predominant in the 5-year-old fish. Between 1 year and 4 years, both types of LC1F were present in similar amounts. Cardiac as well as red muscle myosin from 3-year-old fish had two types of light chain. The myosin light chains from atria and ventriculi were indistinguishable by two-dimensional electrophoresis, but were different from the myosin light chains from red muscle. Neither the light chains from cardiac nor red muscle were coexpressed with the myosin light chains of white muscle at any of the developmental stages examined. Two myosin heavy chain bands were resolved by SDS/glycerol/polyacrylamide gel electrophoresis of the extract from embryos. One of the bands was present in minor amounts. The other, and most abundant, band comigrated with the only band found in the extracts of white muscle myosin from older fish. One-dimensional Staphylococcus aureus V8 protease peptide mapping of these bands revealed some differences during development of the white muscle tentatively interpreted as follows. The myosin heavy chain band present in minor amounts in the embryos may represent an early embryonic form that is replaced by a late embryonic or foetal form in the eleutheroembryos. The foetal myosin heavy chain appears to be present until the resorption of the yolk sack and beginning of the free-swimming stage. A new form of myosin heavy chain, termed neonatal and probably expressed around hatching, is present until about 1 year of age.(ABSTRACT TRUNCATED AT 400 WORDS)     

Coexistence of cardiac-type and fast skeletal-type myosin light chains in embryonic chicken cardiac muscle

Myosin from embryonic chicken ventricle contained a light chain component which comigrated with fast skeletal myosin light chain 1 (Lf1) on two dimensional electrophoresis in addition to cardiac type light chains (Lc1 and Lc2). Immunoblot analysis showed that this minor light chain band reacted with anti-Lf1 antibody. Antigens binding with anti-Lc1 and anti-Lf1 antibodies were located on myofibrils in embryonic cardiac muscle cells in vivo and in vitro. From these observations, we conclude that a small amount of Lf1 exists in embryonic chicken cardiac muscle.     

Changes in myosin and myosin light chain kinase during myogenesis

Myosins and myosin light chain kinases have been isolated from a cloned line of myoblasts (L5/A10) as this cell line undergoes differentiation toward adult muscle. At least three myosin isozymes were obtained during this developmental process. Initially a nonmuscle type of myosin was found in the myoblasts. The molecular weights of the myoblast light chains were 20 000 and 15 000. Myosin isolated from early myotubes had light chains with molecular weights of 20 000 and 19 500. Myosin isolated from myotubes which contained sarcomeres had light chains with molecular weights of 23 000, 18 500, and 16 000. This last myosin was similar in light chain complement to adult rat thigh muscle. Two forms of the myosin light chain kinase activity were detected: a calcium-independent kinase in the myoblasts and a calcium-dependent kinase in the myotubes with sarcomeres. No myosin light chain kinase activity was detected in the early myotubes.     

Myosin isoenzymes of fish hearts

1. Myosin extracted from ventricular and atrial muscles of some fish species were analysed by native and SDS gel electrophoresis. 2. Within the single heart, distinct types of native myosin were present in ventricular and atrial tissues. 3. Ventricular and atrial isomyosins contained two classes of light chain subunits. 4. The present results support the suggestion that the presence of multiple molecular forms of myosin in the heart is a common property of all vertebrates.     

Purification and properties of myosin light-chain kinase from fast skeletal muscle.

1. A procedure is described for the isolation of myosin light-chain kinase from rabbit fast skeletal muscle as a homogeneous protein. 2. Myosin light-chain kinase is a monomeric enzyme of mol.wt. 77000. Under some conditions of storage it is converted into components of mol.wts. about 50000 and 30000 that possess enzymic activity. 3. The enzyme is clearly different in structure and properties from any other protein kinase so far isolated from muscle. 4. The enzyme is highly specific for the P-light chain (18000-20000-dalton light chain) of myosin and requires Ca2+ for activity. 5. The P-light chain is phosphorylated at a similar rate whether isolated or associated with the rest of the myosin molecule. 6. The effects of pH, bivalent cation and other nucleotides on the enzymic activity are described. 7. The role of the phosphorylation of the P-light chain of myosin in muscle function is discussed.     

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

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

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

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

Quantitation of myosin in muscle

The amount of myosin per gram of cardiac and skeletal muscle was determined in sodium dodecyl sulfate-solubilized tissue homogenates by radioimmunoassay and by isotope dilution. In the rabbit ventricle, there was an average of 27 mg myosin/g wet wt of tissue. In chickens, the myosin content of typical "red" (anterior latissimus dorsi) and "white" (posterior latissimus dorsi) skeletal muscles was higher than that of ventricular muscle, averaging 36 and 48 mg/g of tissue, respectively. The stoichiometry of the heavy and light chains in cardiac myosin was also determined from the quantitative binding of 125I-labeled Coomassie blue to each subunit after separation of the subunits by sodium dodecyl sulfate-gel electrophoresis. With this procedure, we found that the combined light-chain subunits contributed 19% of the myosin mass. After adjustment for the light-chain contribution, the myosin heavy-chain content of the rabbit ventricle averaged 22 mg/g wet wt of tissue.     

Effects of myosin light-chain kinase inhibitor on catecholamine secretion from rat pheochromocytoma PC12h cells

Release of dopamine from rat pheochromocytoma PC12h cells by high K+ (50 mM) was inhibited by a specific inhibitor of myosin light-chain kinase (ML-9) dose-dependently. The myosin light-chain kinase inhibitor also specifically inhibited the phosphorylation of a 20 KDa protein by myosin light-chain kinase. Myosin light chain kinase may play a stimulatory role in the release reaction of catecholamines from the rat pheochromocytoma cells.     

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.     

The effect of adrenaline on the phosphorylation of the P light chain of myosin and troponin I in the perfused rabbit heart.

1. Two-dimensional electrophoresis has been used to study the extent of phosphorylation of the P light chain of myosin and troponin I in the rabbit beating heart. 2. A procedure has been developed that eliminates endogenous protein phosphatase activity during homogenization and sample preparation for electrophoresis. 3. Evidence has been obtained for two unphosphorylated forms of the P light chain in myosin from the ventricle of the rabbit, guinea pig and cow. 4. In vivo and in the rabbit perfused beating heart about 25% of the P light-chain fraction is in the phosphorylated form. 5. Intervention with adrenaline produced a slight increase in the extent of phosphorylation that reached a maximum after the peak in inotropic response. A similar increase was obtained with ischaemia in the absence of adrenaline. 6. The changes in phosphorylation of the major forms of troponin I identified by electrophoresis occurred after the peak of response to adrenaline and were compatible with previous results.     

Myofibrillar proteins in skeletal muscles of parr,smolt and adult atlantic salmon (Salmo salarl.). Comparison with another salmonid,the arctic charr Salvelinus alpinus (l.)

The heavy and light subunits of myosin from white and red muscles of Atlantic salmon parr, smolt and adult individuals were analyzed by SDS-PAGE and two-dimensional electrophoresis. Tropomyosin was identified by comigration with rat tropomyosins in two-dimensional gels in the presence and absence of urea. These myofibrillar proteins were compared to those of Arctic charr.

• 1.1. The myosin heavy chain from Atlantic salmon red muscles was associated with two types of light chain, 1S and 2S, that comigrated with the light chains 1S and 2S of Arctic charr.
• 2.2. As in the Arctic charr, four myosin light chain spots were detected in white muscles: two fast myosin light chains type 1, one of which comigrated with its analogous in the Arctic charr; one fast myosin light chain type 2, differing slightly in isoelectric point from that of Arctic charr; and one fast myosin light chain type 3 with higher electrophoretic mobility than that of Arctic charr.
• 3.3. Three tropomyosin spots were detected. White muscles contained only one type of β-tropomyosin and red muscles two types of α-tropomyosin. These three tropomyosin spots comigrated with those of Arctic charr.
• 4.4. Two myosin heavy chain bands were observed in red muscles of salmon parrs but only one in the rest of the red muscles analyzed.
• 5.5. Only one myosin heavy chain band was detected in white muscles by SDS-glycerol-polyacrylamide gel electrophoresis. Alfa-chymotryptic peptide mapping of these white myosin heavy chain bands revealed differences attributed to the presence of a new type of myosin heavy chain first detected several months after smoltification.