Selective phosphorylation of myosin light chain in intact skeletal muscle

The phosphorylation of myosin light chain was quantitated in fast and slow chicken skeletal muscles and in frog sartorius and semitendinosus muscles. The phosphate content of light chain was determined either as moles [³²P]phosphate per mole of light chain in ³²P-labeled muscles or as percentage phosphorylated light chain of the total P-light chain, measured by densitometry after separating the phospho and dephospho forms of P-light chain with two-dimensional gel electrophoresis. Both methods revealed that the percentage of total P-light chain which was phosphorylated did not exceed 50% either in maximally tetanized or caffeine-contracted skeletal muscle. This suggests that one of the two P-light chains is selectively phosphorylated in skeletal muscle.     

Factor V is a substrate for the transamidase factor XIIIa

Coagulation Factor V (Mr = 330,000), upon cleavage by thrombin, produces Factor Va, which is composed of two subunits with Mr values of 94,000 and 74,000, along with two activation fragments possessing no known function. Studies were undertaken to assess the ability of the transamidase Factor XIIIa to covalently incorporate the lysine analogs [3H]putrescine and dansylcadaverine into the thrombin-cleaved (activated) and unactivated forms of human and bovine Factor V. The incorporation of either probe into thrombin-activated Factor V proceeded at an initial rate approximately twice that for unactivated Factor V. The extent of the incorporation of [3H]putrescine or dansylcadaverine into activated or unactivated human Factor V was identical; 4 mol of either probe per mol of Factor V. In the case of bovine Factor V, however, while 4 mol of probe were bound per mol of the unactivated pro-cofactor, 5 mol of either lysine analog were covalently linked to 1 mol of thrombin-cleaved Factor V. Polyacrylamide gel fluorography, immunoaffinity chromatography, and immunoprecipitation identified the largest activation fragment of human Factor V (Mr = 150,000) and bovine Factor V (Mr = 120,000) to contain the sites of incorporation of the covalently bound probes. High molecular weight, apparently covalent polymers of Factor V were produced by the action of Factor XIIIa on activated and unactivated human or bovine Factor V. The absence of either probe in the reaction mixtures did not appear to allow an enhancement of protein polymerization.     

Exchange of 20-kDa myosin light chain-bound phosphate during sustained contraction of arterial smooth muscle

K(+)-contracted porcine carotid arterial muscles containing phosphorylated 20-kDa myosin light chains (LC) were exposed to carrier-free [32P]orthophosphate in K(+)-stimulating solution during sustained contraction. The covalently bound LC phosphate was completely replaced by [32P]phosphate, indicating that myosin light chain phosphatase and kinase have ready access to the bound phosphate during the sustained contraction. On average, 0.38 mol [32P]phosphate was incorporated per mole LC during the sustained K+ contraction. This value was about half of the maximal value for [32P]phosphate incorporation into LC, 0.74 mol/mol, in muscles contracted with K+ for 1 min. Assuming that sustained contraction involves the maximal number of cross-bridges attached to actin, the data suggest that half of the attached cross-bridges contain phosphorylated LC.     

Structural changes in myosin during contraction and the state of ATP in the intact frog muscle

The reactivity of myosin to [¹⁴C]-labeled N-ethylmaleimide ([¹⁴C] NEM) or to tritium was determined in functionally different frog muscles. The incorporation of [¹⁴C] NEM into myosin decreased during isotonic or isometric contractions, as compared to resting muscle. The cysteine residues which were protected during contraction were not involved in the ATPase activity or the actin-binding ability of myosin. Peptide mapping revealed that several residues were protected simultaneously. The incorporation of tritium into the peptide N-H groups of myosin was also decreased during muscle activity. These data support the idea that activation and subsequent contraction of muscle are correlated with structural changes in the myosin molecule. The reactivity of myosin to [¹⁴C] NEM was increased when the muscle was stretched to 140% rest length and treated with iodoacetate to deplete ATP. Based on in vitro experiments and on literature data, it is suggested that in the resting muscle myosin contains bound MgATP which decreases the rate of incorporation of [¹⁴C] NEM into myosin and that upon the irreversible loss of ATP the rate increases. ³¹P nuclear magnetic resonance signals from a number of phosphates were detected in the intact frog muscle. The data indicated that the minimum concentration of ATP in the muscle is 3 mM, a value which agrees with that of chemical determination. The characteristic chemical shifts, coupling constants, and line widths of ATP in the muscle were considerably altered from that of either free ATP in aqueous solutions or ATP in perchloric acid extracts of muscle.     

Phosphorylation of brush border myosin by brush border calmodulin-dependent myosin heavy and light chain kinases

Calmodulin-dependent myosin light chain kinase isolated from chicken intestinal brush border phosphorylates brush border myosin at an apparently single serine identical to that phosphorylated by smooth muscle myosin light chain kinase. Phosphorylation to 1.8 mol phosphate/mol myosin activated the myosin actin-activated ATPase about 10-fold, to about 50 nmol/min per mg. Myosin phosphorylated on its light chains could then be further phosphorylated to a total of 3.2 mol phosphate per mol by brush border calmodulin-dependent heavy chain kinase. Heavy chain phosphorylation did not alter the actin-activated ATPase of either myosin prephosphorylated on its light chains or of unphosphorylated myosin.     

Reaction of phenylglyoxal with chicken gizzard myosin

Modification of chicken gizzard myosin with phenyl[2-14C]-glyoxal inhibited the K+-ATPase (ATP phosphohydrolase, EC 3.6.1.32) activity as a function of time. During the 2.5 and 15 min interval 3.2 mol of the reagent were incorporated per 4.7 X 10(5) g protein and the K+-ATPase activity was 50% inhibited. Phenylglyoxal reacted with arginine residues of gizzard myosin in a mol ratio of two to one, phenylglyoxal to arginine as determined spectrophotometrically. The modification was limited to the subfragment 1 heavy chain and rod-like regions and none of the light chains were lost. The inhibition of the ATPase activity occurred when the subfragment 1 region was modified predominantly. The same results were obtained when the myosin was phosphorylated and then incubated with phenylglyoxal. Substrate MgATP2- or MgADP enhanced the inactivation of gizzard myosin; there was an increase in the incorporation of the reagent and a change in the distribution into the heavy chains. Approx. 0.5 mol of the nucleotide was bound to 4.7 X 10(5) g of phenylglyoxal myosin. Conformational changes, induced by these modifications, were responsible for the inhibition of enzymic activity. Arginine residues of gizzard myosin are necessary for the maintenance of the ATPase activity of this contractile protein.     

Stretch activates myosin light chain kinase in arterial smooth muscle

Stretching of porcine carotid arterial muscle increased the phosphorylation of the 20 kDa myosin light chain from 0.23 to 0.68 mol [32P]phosphate/mol light chain, whereas stretching of phorbol dibutyrate treated muscle increased the phosphorylation from 0.30 to 0.91 mol/mol. Two-dimensional gel electrophoresis followed by two-dimensional tryptic phosphopeptide mapping was used to identify the enzyme involved in the stretch-induced phosphorylation. Quantitation of the [32P]phosphate content of the peptides revealed considerable light chain phosphorylation by protein kinase C only in the phorbol dibutyrate treated arterial muscle, whereas most of the light chain phosphorylation was attributable to myosin light chain kinase. Upon stretch of either the untreated or treated muscle, the total increment in [32P]phosphate incorporation into the light chain could be accounted for by peptides characteristic for myosin light chain kinase catalyzed phosphorylation, demonstrating that the stretch-induced phosphorylation is caused by this enzyme exclusively.     

The behavior of fetal canine cardiac cells in culture: synthesis and phosphorylation of myosin.

This study describes the first in vitro culturing of canine cardiac cells. Canine cardiac myosin which was synthesized in a 14-day tissue culture, based on l-[³H]leucine incorporation, was precipitated with goat γG antimyosin (cardiac-specific) and analyzed on dodecylsulfate gels; the specific activity of the highly purified myosin chains was determined. Incorporation of ³²PO₄ was similarly analyzed. The comparative degree of synthesis and phosphorylation of myosin chains, occurring in culture, was the same as that obtained in vivo. Both l-[³H]leucine and ³²PO₄ incorporation were inhibited by addition of cycloheximide to the culture medium. Removal of ³²PO₄ from myosin heavy chains with base treatment indicated the presence of phosphoserine and/or phosphothreonine in canine cardiac myosin heavy chains. Myosins from fetal and adult canine cardiac tissue were immunologically identical with each other and with the cultured fetal tissue; all had similar myosin ATPase activity and the degree of heavy chain phosphorylation was similar. The tissue and techniques used here gave a high yield of cardiac myocytes based principally on synthesis of cardiac-specific myosin.     

A comparative study of reactive--SH groups of cardiac and skeletal muscle myosins.

Cardiac and skeletal muscle myosins have been treated by N-ethylmaleimide in presence or absence of Mg-ADP. The variations of Ca2+ and K+-ATPase activities and the incorporation of N-[14C]ethylmaleimide into the whole myosin molecule and into its separated subunits (heavy and light chains) have been measured with N-ethylmaleimide treatment for different lengths of time. The results reported here show the following: 1. The Ca2+-ATPase activity of cardiac myosin is activated by N-ethylmaleimide treatment to a lesser extent than that of skeletal myosin. 2. The K+-ATPase activity of both myosins is inhibited in the same quantitative way. 3. The cardiac light chain L1 contains one highly reactive thiol group which is absent from the skeletal light chains. 4. The labelling of three SH-groups localized in the heavy subunits of both myosins induced the same degree of inactivation. 5. The difference observed between the degree of inhibition of the Ca2+-ATPase activity for the two types of myosin with longer treatments appears to be due to differences in the reactivity of the fourth--SH group labelled on the heavy chains.     

Regulatory light chain-a myosin kinase (aMK) catalyzes phosphorylation of smooth muscle myosin heavy chains of scallop, Patinopecten yessoensis

Regulatory light chain-a myosin kinase (aMK), which phosphorylates one of the myosin regulatory light chains, RLC-a, contained in the catch muscle of scallop, was also found to phosphorylate heavy chains of scallop myosin. After incubation of myosin isolated from the opaque portion of scallop smooth muscle (opaque myosin) with aMK in the presence of [gamma-32P]ATP, about 2 mol of 32P was incorporated per mol of the myosin. The radioactivity was mostly found in the heavy chain at 0.26 M KCl. The pH-activity curve and MgCl2 requirement for the heavy chain phosphorylation were similar to those for RLC-a phosphorylation. In contrast, the dependency of activity on KCl concentration was different from that for RLC-a. The heavy chain phosphorylation activity decreased with increase in KCl concentration up to 0.06 M, and then increased at concentrations over 0.06 M to a maximum at around 0.26 M KCl. This complicated profile probably reflects the solubility of myosin, and the phosphorylation site may be located in the rod portion insoluble at low KCl concentrations. Phosphorylation of heavy chain did not change the solubility of the opaque myosin molecule at all. The acto-opaque myosin ATPase activity in the presence of Ca2+ was found to be decreased to less than one-fourth by the heavy chain phosphorylation.     

Living macrophages phosphorylate the 20,000 dalton light chains and heavy chains of myosin

Brief incubation of rabbit alveolar macrophages in medium containing ³²Pi results in the incorporation of radioactivity into the 20 KD light chains and into the 220 KD heavy chains of myosin. Phosphorylation of the heavy chain is mediated by a kinase that is probably not myosin light chain kinase. Limited proteolysis of the phosphorylated myosin shows that radioactivity is associated with the rod portion of the heavy chain.     

Stretch-induced growth of skeletal myotubes correlates with activation of the sodium pump

Skeletal myotubes responded to passive stretch by increased amino acid uptake (as measured with [³H]α-aminoisobutyric acid), increased incorporation of amino acids into total cellular protein and myosin heavy chains, and increased accumulation of total cellular protein and myosin heavy chains. These alterations were preceded by an increase in the uptake of ouabain-sensitive rubidium-86 (⁸⁶Rb⁺), a potassium tracer used to measure membrane sodium pump activity (Na⁺K⁺ATPase). This stretch-induced stimulation of ⁸⁶Rb⁺ uptake resulted from a 60-70% increase in the V_max of the Na pump with little change in the K_m. [³H] ouabain binding studies showed no stretch-induced change in the number of membrane Na pumps, indicating that stretch activates the Na pumps that are already present on the cell surface. Since the stretch-induced increases in amino acid transport and amino acid incorporation into proteins were inhibited by ouabain, Na pump activation may be involved in stretch-induced cell growth of skeletal muscle cells by hypertrophy.     

Thyroid hormone stimulates synthesis of a cardiac myosin isozyme. Comparison of the two-two-dimensional electrophoretic patterns of the cyanogen bromide peptides of cardiac myosin heavy chains from euthyroid and thyrotoxic rabbits.

The CNBr peptides of [14C]carboxymethylated cardiac myosin heavy chains from euthyroid and thyrotoxic rabbits have been compared using a two-dimensional electrophoretic system. The results indicated that there were extensive differences in the peptide "maps" of these heavy chains, which included differences in the distribution of radiolabeled thiol peptides. Also, the patterns of heavy chain peptides from the cardiac myosins have been compared with those produced by the heavy chain myosin isozymes from skeletal muscles. Peptide maps of heavy chains from red skeletal muscle myosin closely resembled the pattern of peptides found with cardiac myosin heavy chains from euthyroid rabbits. However, peptide maps of heavy chains from white skeletal muscle myosin were dissimilar to those of the cardiac myosin isozymes. We conclude that thyroxine administration stimulates the synthesis of a cardiac myosin isozyme with a heavy chain primary structure which is different from either of the skeletal muscle myosin isozymes.     

Phenotypical temperature adaptation of protein synthesis in wheat seedlings: time curves for readaptation

Optimum temperature and temperature coefficient of protein synthesis in young wheat plants exhibit phenotypical temperature adaptation. In plants grown for 2 days at either chilling (4 C), medium (20 C), or high (36 C) temperature the respective values are: 27 C and 14.2 kilocalories per mole, 31 C and 18.2 kilocalories per mole, 35 C and 23.6 kilocalories per mole, based on in vivo [¹⁴C]leucine incorporation into total protein. The validity of the [¹⁴C]leucine incubation method has been confirmed by double-labeling experiments. Readaptation time curves are complex: the optimum temperature parameter readjusts within approximately 4 hours to an altered temperature regime, whereas the temperature coefficient needs between 4 and 96 hours for complete readaptation—depending on the temperature conditions prior to the temperature shift. Heat-preadapted plants need a recovery period at medium temperature to regain their cold adaptability with respect to optimum temperature. Cycloheximide (30 micrograms per milliliter) reduces [¹⁴C]leucine incorporation into protein by 85%, thus indicating that predominantly the cytoplasmic 80S system of protein synthesis is involved in temperature adaptation.     

Actin and myosin: control of filament assembly

Actin filaments, assembled from highly purified actin from either skeletal muscle or Dictyostelium amoebae, are very stable under physiological ionic conditions. A small and limited amount of exchange of actin filament subunits for unpolymerized actin or subunits in other filaments has been measured by three techniques: fluorescence energy transfer, incorporation of 35S-labelled actin monomers into unlabelled actin filaments, and exchange of [14C]ATP with filament-bound ADP. A 40 kDa protein purified from amoebae destabilizes these otherwise stable filaments in a Ca2+-dependent manner. Myosin purified from Dictyostelium amoebae is phosphorylated both in the tail region of the heavy chain and in one of the light chains. Phosphorylation appears to regulate myosin thick-filament formation.     

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

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

Activation of transglutaminase during embryonic development

Incorporation of [3H]putrescine into proteins was shown to increase markedly in sea urchin eggs upon fertilization. Emetine, an inhibitor of protein synthesis, had no effect on the rate of protein labeling. However, the reaction could be prevented by the addition of 2-[3-(diallylamino)-propionyl]benzothiophene, a noncompetitive inhibitor of transglutaminase, and also by dansylcadaverine, which is a substrate for transglutaminase. The inert N alpha-dimethyl analogue of dansylcadaverine had no influence. Considering the complexity of the incorporation of the [3H]putrescine tracer in this system, it was deemed essential to prove by rigorous analytical methods that the reaction was, indeed, consistent with a transglutaminase mechanism. gamma-Glutamyl[3H]putrescine could be recovered in 80-90% yield from the proteolytic digest of proteins from the 20-min fertilized cell. Another sign of the in vivo activity of transglutaminase was the isolation of substantial amounts of epsilon-(gamma-glutamyl)lysine from proteins of sea urchin embryo, yielding a frequency value for this cross-link as high as 1 mol/400 000 g of protein in the 32-cell-stage material.     

Phosphorylation of smooth muscle myosin heavy and light chains. Effects of phorbol dibutyrate and agonists

A number of different protein kinases phosphorylate purified heavy chains or the 20-kDa light chain of smooth muscle myosin. The physiological significance of these phosphorylation reactions has been examined in intact smooth muscle. Myosin heavy chain was slightly phosphorylated (0.08 mol of phosphate/mol) under control conditions in bovine tracheal tissue. Treatment with carbachol, isoproterenol, or phorbol 12,13-dibutyrate resulted in no significant change. In contrast, heavy chain was phosphorylated to 0.30 mol of phosphate/mol of heavy chain in tracheal smooth muscle cells in culture. This value increased significantly with ionomycin treatment. In control tissues, 9% of the light chain was monophosphorylated with 32P in the serine site phosphorylated by myosin light chain kinase. Carbachol (0.1 microM) alone resulted in contraction and 42% monophosphorylated light chain with 32P only in the serine site phosphorylated by myosin light chain kinase. Similarly, stimulation with histamine, 5-hydroxytryptamine, or KCl resulted in 32P incorporation into only the myosin light chain kinase serine site. Phorbol 12,13-dibutyrate (1 microM) alone resulted in 22% monophosphorylated light chain. However, only 25% of the 32P was in the myosin light chain kinase serine site, whereas 75% was in a serine site phosphorylated by protein kinase C. Phorbol 12,13-dibutyrate plus carbachol resulted in 27% monophosphorylated light chain; 75% of the 32P was in the myosin light chain kinase serine site, with the remainder in the protein kinase C serine site. These results indicate that phorbol esters act to increase phosphorylation of myosin light chain by protein kinase C. However, receptor-mediated stimulation or depolarization leading to tracheal smooth muscle contraction results in phosphorylation of myosin light chain by myosin light chain kinase alone.     

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

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

Further characterization and thiophosphorylation of smooth muscle myosin

(i) Myosin from chicken gizzards was purified by a modification of an earlier procedure (M. N. Malik, 1978,Biochemistry17, 27–32). When this myosin, as well as that prepared by the method of A. Sobieszek and R. D. Bremel (1975,Eur. J. Biochem.55, 49–60), was analyzed by gradient slab gel using the discontinuous buffer system of Neville (1971,J. Biol. Chem.246, 6328–6334), a closely spaced doublet in the heavy chain and four light chains were observed as opposed to one heavy chain and two light chains with the method of Weber and Osborn (1969, J. Biol. Chem.244, 4406–4412). These findings raise the possibility of the existence of myosin isoenzymes in smooth muscle. (ii) The purified gizzard myosin was found to be free of kinase and phosphatase. Phosphorylation or thiophosphorylation of myosin was observed only by exogenously adding kinase. A maximum of 1.2 mol of ³²P/mol of myosin and 2.3 mol of ³⁵S/mol of myosin were obtained. The actin-activated ATPase activity depended upon the extent of thiophosphorylation of myosin; a four- to fivefold increase in the activity was observed when myosin was fully thiophosphorylated. Thiophosphorylated myosin was found to be more stable than phosphorylated myosin.