Selective purification of the 20,000-Da light chains of smooth muscle myosin

The 20,000-Da light chains of gizzard smooth muscle myosin have been purified to homogeneity. Actomyosin, prepared by MgATP extraction of myofibrils, was denatured in 8 M urea, 1 M guanidine HCl, and 0.05% sodium dodecyl sulfate. Myosin heavy chains were precipitated with ethanol and the light chain enriched fraction was dialyzed and subjected to chromatography on DEAE-Sephacel. Fractions containing the 20,000-Da light chains were further purified by hydrophobic chromatography on phenyl-Sepharose. The 20,000-Da light chains eluted at low ionic strength from the phenyl-Sepharose column were judged to be greater than 95% pure by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and contained only 0.04 mol of phosphate/mol of light chain. The yield of light chains was calculated to be 219 +/- 17 mg/kg of starting gizzard smooth muscle. This method may be useful for preparation of homogeneous 20,000-Da smooth muscle myosin light chains in the quantities necessary for study of contractile systems.     

调节轻链在平滑肌肌球蛋白分子上的定位

 应用凝胶电泳覆盖技术和放射自显影法研究了32~P-标记的平滑肌肌球蛋白调节轻链在肌球蛋白分子上的定位。实验结果表明调节轻链(LC_(20))可重新结合于平滑肌肌球蛋白重链(200kD),重酶解肌球蛋白(130kD)及其62kD和26kD肽段上。这提示调节轻链的结合点位于平滑肌肌球蛋白亚段-1羧基端的26kD肽段上。     

Characterization of chicken skeletal muscle myosin light chain kinase. Evidence for muscle-specific isozymes

Myosin light chain kinase purified from chicken white skeletal muscle (Mr = 150,000) was significantly larger than both rabbit skeletal (Mr = 87,000) and chicken gizzard smooth (Mr = 130,000) muscle myosin light chain kinases, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Km and Vmax values with rabbit or chicken skeletal, bovine cardiac, and chicken gizzard smooth muscle myosin P-light chains were very similar for the chicken and rabbit skeletal muscle myosin light chain kinases. In contrast, comparable Km and Vmax data for the chicken gizzard smooth muscle myosin light chain kinase showed that this enzyme was catalytically very different from the two skeletal muscle kinases. Affinity-purified antibodies to rabbit skeletal muscle myosin light chain kinase cross-reacted with chicken skeletal muscle myosin light chain kinase, but the titer of cross-reacting antibodies was approximately 20-fold less than the anti-rabbit skeletal muscle myosin light chain kinase titer. There was no detectable antibody cross-reactivity against chicken gizzard myosin light chain kinase. Proteolytic digestion followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis or high performance liquid chromatography showed that these enzymes are structurally very different with few, if any, overlapping peptides. These data suggest that, although chicken skeletal muscle myosin light chain kinase is catalytically very similar to rabbit skeletal muscle myosin light chain kinase, the two enzymes have different primary sequences. The two skeletal muscle myosin light chain kinases appear to be more similar to each other than either is to chicken gizzard smooth muscle myosin light chain kinase.     

Localisation of light chain and actin binding sites on myosin

A gel overlay technique has been used to identify a region of the myosin S-1 heavy chain that binds myosin light chains (regulatory and essential) and actin. The 125I-labelled myosin light chains and actin bound to intact vertebrate skeletal or smooth muscle myosin, S-1 prepared from these myosins and the C-terminal tryptic fragments from them (i.e. the 20-kDa or 24-kDa fragments of skeletal muscle myosin chymotryptic or Mg2+/papain S-1 respectively). MgATP abolished actin binding to myosin and to S-1 but had no effect on binding to the C-terminal tryptic fragments of S-1. The light chains and actin appeared to bind to specific and distinct regions on the S-1 heavy chain, as there was no marked competition in gel overlay experiments in the presence of 50-100 molar excess of unlabelled competing protein. The skeletal muscle C-terminal 24-kDa fragment was isolated from a tryptic digest of Mg2+/papain S-1 by CM-cellulose chromatography, in the presence of 8 M urea. This fragment was characterised by retention of the specific label (1,5-I-AEDANS) on the SH1 thiol residue, by its amino acid composition, and by N-terminal and C-terminal sequence analyses. Electron microscopical examination of this S-1 C-terminal fragment revealed that: it had a strong tendency to form aggregates with itself, appearing as small 'segment-like' structures that formed larger aggregates, and it bound actin, apparently bundling and severing actin filaments. Further digestion of this 24-kDa fragment with Staphylococcus aureus V-8 protease produced a 10-12-kDa peptide, which retained the ability to bind light chains and actin in gel overlay experiments. This 10-12-kDa peptide was derived from the region between the SH1 thiol residue and the C-terminus of S-1. It was further shown that the C-terminal portion, but not the N-terminal portion, of the DTNB regulatory light chain bound this heavy chain region. Although at present nothing can be said about the three-dimensional arrangement of the binding sites for the two kinds of light chain (regulatory and essential) and actin in S-1, it appears that these sites are all located within a length of the S-1 heavy chain of about 100 amino acid residues.     

Phosphorylation of smooth muscle myosin light chain kinase by the catalytic subunit of adenosine 3': 5'-monophosphate-dependent protein kinase.

Turkey gizzard smooth muscle light chain kinase was purified by affinity chromatography on calcium dependent regulator weight of 125,000 +/- 5,000 in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. When myosin light chain kinase is incubated with the catalytic subunit of cyclic AMP-dependent protein kinase, 1 mol of phosphate is incorporated per mol of myosin kinase. Brief tryptic digestion of the 32P-labeled myosin kinase liberates a single radioactive peptide with a molecular weight of approximately 22,000. Phosphorylation of myosin kinase results in a 2-fold decrease in the rate at which the enzyme phosphorylates the 20,000-dalton light chain of smooth muscle myosin. These results suggest that cyclic AMP has a direct effect on actin-myosin interaction in smooth muscle.     

Turkey gizzard smooth muscle myosin phosphatase-III is a novel protein phosphatase.

Chromatography of turkey gizzard extract on Sephacryl S-300 has been shown to fractionate the various smooth muscle phosphatases. We have previously reported the purification and characterization of three of these enzymes, termed smooth muscle phosphatase (SMP)-I, -II, and -IV. Recently, we have purified SMP-III to near homogeneity. Although all of the smooth muscle phosphatases dephosphorylate the isolated myosin light chains, only SMP-III and -IV are active toward intact myosin and, therefore, are most likely to play a direct role in the muscle contraction-relaxation process. SMP-III has a higher molecular weight (390,000), as determined by gel filtration, than the other smooth muscle phosphatases and migrates as single band with a molecular weight of 40,000 in a sodium dodecyl sulfate-polyacrylamide gel. SMP-III is immunologically distinct from SMP-I and -II. It dephosphorylates heavy meromyosin and the isolated myosin light chains at a rapid rate but has low activity toward phosphorylase alpha. The activity of SMP-III is not affected by Ca2+ but is activated by Mn2+.Mg2+ stimulates the activity toward heavy meromyosin but inhibits the myosin light chain phosphatase activity. Attempts to classify SMP-III according to the scheme proposed by Ingebritsen and Cohen (Ingebritsen T. S., and Cohen, P. (1983) Science 221, 331-338) revealed that it is resistant to the heat stable inhibitor-2, suggesting that it is a Type 2 protein phosphatase. However, SMP-III is inhibited by concentrations of okadaic acid which are characteristic of Type 1 protein phosphatases and it binds to heparin-Sepharose like other Type 1 phosphatases. But most interestingly, SMP-III does not dephosphorylate the alpha- or beta-subunits of phosphorylase kinase, a property not reported for any Ser/Thr protein phosphatase.     

The light chains of scallop myosin as regulatory subunits

In molluscan muscles contraction is regulated by the interaction of calcium with myosin. The calcium dependence of the aotin-activated ATPase activity of scallop myosin requires the presence of a specific light chain. This light chain is released from myosin by EDTA treatment (EDTA-light chains) and its removal desensitizes the myosin, i.e. abolishes the calcium requirement for the actin-activated ATPase activity, and reduces the amount of calcium the myosin binds; the isolated light chain, however, does not bind calcium and has no ATPase activity. Calcium regulation and calcium binding is restored when the EDTA-light chain is recombined with desensitized myosin preparations. Dissociation of the EDTA-light chain from myosin depends on the concentration of divalent cations; half dissociation is reached at about 10^?5 M-magnesium or 10^?7 M-calcium concentrations. The EDTA-light chain and the residual myosin are fairly stable and the components may be kept separated for a day or so before recombination.Additional light chains containing half cystine residues (SH-light chains) are detached from desensitized myosin by sodium dodecyl sulfate. The EDTA-light chains and the SH-light chains have a similar chain weight of about 18,000 daltons; however, they differ in several amino acid residues and the EDTA-light chains contain no half cystine. The SH-light chains and EDTA-light chains have different tryptic fingerprints. Both light chains can be prepared from washed myofibrils.Densitometry of dodecyl sulfate gel electrophoresis bands and Sephadex chromatography in sodium dodecyl sulfate indicate that there are three moles of light chains in a mole of purified myosin, but only two in myosin treated with EDTA. The ratio of the SH-light chains to EDTA-light chains was found to be two to one in experiments where the total light-chain complements of myosin or myofibril preparations were carboxymethylated. A similar ratio was obtained from the densitometry of urea-acrylamide gel electrophoresis bands. We conclude that a myosin molecule contains two moles of SH-light chain and one mole of EDTA-light chain, and that the removal of a single EDTA-light chain completely desensitizes scallop myosin.Heavy meromyosin and S-1 subfragment can be prepared from scallop myosin. Both of these preparations bind calcium and contain light chains in significant amounts. The heavy meromyosin of scallop is extensively degraded; the S-1 preparation, however, is remarkably intact. Significantly, heavy meromyosin has a calcium-dependent actin-activated ATPase while the S-1 does not require calcium and shows high ATPase activity in its absence. These results suggest that regulation involves a co-operativity between the two globular ends of the myosin.Desensitized scallop myosin and scallop S-1 preparations can be made calcium sensitive when mixed with rabbit actin containing the rabbit regulatory proteins. This result makes it unlikely that specific light chains of myosin are involved in the regulation of the vertebrate system.The fundamental similarity in the contractile regulation of molluscs and vertebrates is that interaction between actin and myosin in both systems requires a critical level of calcium. We propose that the difference in regulation of these systems is that the interaction between myosin and actin is prevented by blocking sites on actin in the case of vertebrate muscles, whereas in the case of molluscan muscles it is the sites on myosin which are blocked in the absence of calcium.     

Purification and characterization of a myosin heavy chain kinase from Dictyostelium discoideum

A Dictyostelium discoideum myosin heavy chain kinase has been purified 14,000-fold to near homogeneity. The enzyme has a Mr = 130,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and greater than 700,000 as determined by gel filtration on Bio-Gel A-1.5m. The enzyme has a specific activity of 1 mumol/min X mg when assayed at a Dictyostelium myosin concentration of 0.3 mg/ml. A maximum of 2 mol of phosphate/mol of myosin is incorporated by the kinase, and the phosphorylated amino acid is threonine. Phosphate is incorporated only into the myosin heavy chains, not into the light chains. The actin-activated Mg2+-ATPase of Dictyostelium myosin is inhibited 70-80% following maximal phosphorylation with the kinase. The myosin heavy chain kinase requires 1-2 mM Mg2+ for activity and is most active at pH 7.0-7.5. The activity of the enzyme is not significantly altered by the presence of Ca2+, Ca2+ and calmodulin, EGTA, cAMP, or cGMP. When incubated with Mg2+ and ATP, phosphate is incorporated into the myosin heavy chain kinase, perhaps by autophosphorylation.     

Turnover of myosin heavy and light chains in cultured embryonic chick cardiac and skeletal muscle

The relative rates of synthesis and breakdown of myosin heavy and light chains were studied in primary cell cultures of embryonic chick cardiac and skeletal muscle. Measurements were made after 4 days in culture, at which time both skeletal and cardiac cultures were differentiated and contracted spontaneously. Following a 4-hr pulse of radioactive leucine, myosin and its heavy and light chains were extracted to 90% or greater purity and the specific activities of the proteins were determined. In cardiac muscle, myosin heavy chains were synthesized approximately 1.6 times the rate of myosin light chains, and in skeletal muscle, heavy chains were synthesized at approximately 1.4 times the rate of light chains. Relative rates of degradation of muscle proteins were determined using a dual-isotope technique. In general, the soluble and myofibrillar proteins of both types of muscle had decay rates proportional to their molecular weights (larger proteins generally had higher decay rates) based on analyses utilizing sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A notable exception to this general rule was myosin heavy chains, which had decay rates only slightly higher than the myosin light chains. Direct measurements on purified proteins indicated that the heavy chains of myosin were turning over at a slightly greater rate (approximately 20%) than the myosin light chains in both cardiac and skeletal muscle. The reasons for the apparent discrepancy between these measurements of myosin heavy and light chain synthesis and degradation are discussed.     

Studies on the subunits of myosin from muscle layer of Ascaris lumbricoides suum.

1. A purified preparation of Ascaris myosin was obtained from the muscle layer of Ascaris lumbricoides suum, using gel filtration and ion-exchange chromatography. 2. Ascaris myosin whether purified or unpurified, had almost the same ability for ATP-splitting and superprecipitation. 3. Ascaris myosin and rabbit skeletal myosin were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A significant difference in the number of light chains between both myosins was found. Ascaris myosin was found to have one heavy chain and two distinct light chain components (LC1-A and LC2-A), having molecular weights of 18000 and 16000, respectively. These light chains correspond in molecular weight to the light chain 2 (LC2-S) and light chain 3 (LC3-S) in rabbit skeletal myosin. 4. LC1-A could be liberated from the Ascaris myosin molecule reacted with 5,5'-dithio-bis(2-nirobenzoic acid( Nbs2) with recovery of ATPase activity by addition of dithiothreitol. These properties are equivalent to those of the LC2-S in rabbit skeletal myosin, although Ascaris myosin when treated with Nbs2-urea lost its ATPase activity.     

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.     

Smooth muscle myosin light chain kinase: rapid purification by anion exchange high-performance liquid chromatography

A rapid procedure for the purification of myosin light chain kinase present in chicken gizzard smooth muscle using anion exchange high-performance liquid chromatography is described. The procedure allows preparation of microgram amounts of the protein directly from the extract of gizzard myofibrils and then is suitable for the study of myosin light chain kinase in small muscles. The protein was judged to be greater than 95% pure by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. The enzyme retains its activity since it catalyzes the calcium-calmodulin-dependent phosphorylation of the 20,000-Da myosin light chain.     

Protein kinase C modulates in vitro phosphorylation of the smooth muscle heavy meromyosin by myosin light chain kinase

Protein kinase C phosphorylates different sites on the 20,000-Da light chain of smooth muscle heavy meromyosin (HMM) than did myosin light chain kinase (Nishikawa, M., Hidaka, H., and Adelstein, R. S. (1983) J. Biol. Chem. 258, 14069-14072). Although protein kinase C incorporates 1 mol of phosphate into 1 mol of 20,000-Da light chain when either HMM or the whole myosin molecule is used as a substrate, it catalyzes the incorporation of up to 3 mol of phosphate/mol of 20,000-Da light chain when the isolated light chains are used as a substrate. Threonine is the major phosphoamino acid resulting from phosphorylation of HMM by protein kinase C. Prephosphorylation of HMM by protein kinase C decreases the rate of phosphorylation of HMM by myosin light chain kinase due to a 9-fold increase of the Km for prephosphorylated HMM compared to that of unphosphorylated HMM. Prephosphorylation of HMM by myosin light chain kinase also results in a decrease of the rate of phosphorylation by protein kinase C due to a 2-fold increase of the Km for HMM. Both prephosphorylations have little or no effect on the maximum rate of phosphorylation. The sequential phosphorylation of HMM by myosin light chain kinase and protein kinase C results in a decrease in actin-activated MgATPase activity due to a 7-fold increase of the Km for actin over that observed with phosphorylated HMM by myosin light chain kinase but has little effect on the maximum rate of the actin-activated MgATPase activity. The decrease of the actin-activated MgATPase activity correlates well with the extent of the additional phosphorylation of HMM by protein kinase C following initial phosphorylation by myosin light chain kinase.     

Regulatory and essential light-chain-binding sites in myosin heavy chain subfragment-1 mapped by site-directed mutagenesis

Site-directed mutagenesis of the cloned subfragment-1 (S-1) region of the unc-54 gene, encoding the myosin heavy chain B (MHC B) from Caenorhabditis elegans, has been used to locate binding sites for the regulatory and essential light chains. MHC B S-1 synthesized in Escherichia coli co-migrated with rabbit skeletal muscle myosin S-1 (Mr 90,000), was recognized by anti-nematode myosin antiserum on immunoblots, and specifically bound to 125I-labelled regulatory and essential light chains in a gel overlay assay. Deletion of 102 residues from the C terminus (mutant 655) reduced regulatory and essential light-chain binding to about 30% and 20% of wild-type levels, respectively. Similar reductions in relative binding of the two light chains were seen with mutant 534, in which 38 residues were deleted from the C terminus. Potential binding sites within 75 residues of the C terminus of S-1 were mapped by construction of five other mutant S-1 clones (398, 399, 400, 409 and 411) containing internal deletions of ten to 12 amino acid residues. These showed up to 30% reductions in their ability to bind essential light chains, but did not differ significantly from wild-type in their ability to bind regulatory light chains. Another mutant, 415, containing a deletion of a conserved acidic hexapeptide, E-D-I-R-D-E, showed enhancement of binding of regulatory and essential light chains to 150% and 165% of wild-type levels. Hence, the major binding sites for both light chains are within 38 amino acid residues of the C terminus.     

The heavy-chain stoichiometry of smooth muscle myosin is a characteristic of smooth muscle tissues

The stoichiometry of the two heavy chains of myosin in smooth muscle was determined by electrophoresing extracts of native myosin and of dissociated myosin on sodium dodecyl sulfate (SDS) 4%-polyacrylamide gels. The slower migrating heavy chain was 3.6 times more abundant in toad stomach, 2.3 in rabbit myometrium, 2.0 in rat femoral artery, 1.3 in guinea pig ileum, 0.93 in pig trachea and 0.69 in human bronchus, than the more rapidly migrating chain. Both heavy chains were identified as smooth muscle myosin by immunoblotting using antibodies to smooth muscle and non-muscle myosin. The unequal proportion of heavy chains suggested the possibility of native isoforms of myosin comprised of heavy-chain homodimers. To test this, native myosin extracts wer electrophoresed on non-dissociating (pyrophosphate) gels. When each band was individually analysed on SDS-polyacrylamide gel the slowest was found to be filamin and the other bands were myosin in which the relative proportion of the heavy chains was unchanged from that found in the original tissue extracts. Since this is incompatible with either a heterodimeric or a homodimeric arrangement it suggests that pyrophosphate gel electrophoresis is incapable of separating putative isoforms of native myosin.     

Hydrophobic interaction chromatography of myosin fragments: Potential use in purification

Myosin fragments were fractionated on columns of the hydrophobic gel phenyl-Sepharose CL-4B. In the presence of high NaCl concentrations the fragments bound tightly to the columns; they could be eluted by decreasing the ionic strength, by increasing the pH, or by applying various concentrations of ethylene glycol. In myosin subfragment-1 (S-1), the light chains underwent partial dissociation from the heavy chain and bound separately to the column matrix. The order of strength of binding of the various species to the column was heavy chain > A1 light chain > A2 light chain > native S-1 > denatured heavy chain or S-1. Thus the hydrophobic gel appears to be able to differentiate between enzymatically active and inactive S-1. Under appropriate elution conditions it was possible to obtain S-1 preparations depleted from nicked heavy chains and with specific ATPase activities 34–130% higher than those of untreated S-1. When S-1(A2) was fractionated on phenyl-Sepharose a fivefold enrichment of the heavy chain with respect to the light chains was obtained, while the ATPase activity was equal or larger than that of the original S-1, implying that the light chains are not essential for ATPase activity. Thus, it seems that chromatography of S-1 on phenyl-Sepharose is a potentially useful method for obtaining a purified myosin heavy-chain fragment with a high ATPase specific activity.     

Phosphorylation by cyclic adenosine 3':5'-monophosphate-dependent protein kinase regulates myosin light chain kinase

Smooth muscle myosin light chain kinase, purified to homogeneity, has a molecular weight of 130,000 +/- 5,000 in sodium dodecyl sulfate polyacrylamide gel electrophoresis. The purified enzyme has a specific activity under maximal conditions of 30 mumol Pi transferred to myosin light chain/mg kinase/min at 24 C and is totally dependent on calmodulin and calcium for activity. Incubation of myosin kinase with the catalytic subunit of cyclic adenosine 3':5'-monophosphate-dependent protein kinase results in the covalent incorporation of up to one mol of phosphate per mol of myosin kinase in the absence of bound calmodulin. Limited tryptic digestion of the radioactively labeled kinase indicates that all of the label has been incorporated into a single tryptic peptide (mol wt approximately 22,000), suggesting that a single site is being phosphorylated. Phosphorylation of myosin kinase lowers the rate at which the kinase phosphorylates myosin light chain. The lower rate of light chain phosphorylation is due to a weaker binding of calmodulin to the phosphorylated kinase than to the unphosphorylated kinase. Cyclic adenosine 3':5'-monophosphate-dependent phosphorylation of the kinase actin-myosin interaction represents a possible link between hormonal binding to smooth muscle receptors and muscle relaxation. A scheme for this sequence of events is presented.     

Comparison of the properties of the protein phosphatases from avian and mammalian smooth muscles: purification and characterization of rabbit uterine smooth muscle phosphatases

Three protein phosphatases were purified to near homogeneity from rabbit uterine muscle. These enzymes are termed rabbit uterine smooth muscle phosphatase (RU SMP)-I, -II, and -IV. RU SMP-I is composed of three subunits (Mr 60,000, 55,000, and 38,000) which comigrated with the subunits of turkey gizzard smooth muscle phosphatase (TG SMP)-I. Ethanol treatment of RU SMP-I dissociated the subunits and led to the purification of its catalytic subunit (Mr 38,000), RU SMP-Ic. Structural homology between the turkey gizzard and rabbit uterine SMP-I is indicated by the cross-reactivity of RU SMP-I with the polyclonal antibodies against TG SMP-I and -Ic. Like TG SMP-II, RU SMP-II is inactive in the absence of divalent cations and can be activated by Mg2+ and Mn2+. However, their electrophoretic profiles on sodium dodecyl sulfate-polyacrylamide gel are different. RU SMP-II shows two bands (Mr 42,000 and 44,000) while TG SMP-II is monomeric (Mr 43,000). Western blot analysis revealed that the 42,000 and 44,000-Da proteins cross-react with anti-TG SMP-II antibodies, suggesting that these proteins share common structural properties. The anti-TG SMP-I and Ic antibodies do not cross-react with RU SMP-II and -IV. Likewise, the anti-TG SMP-II antibodies do not cross-react with RU SMP-I and -IV, implying that these enzymes are distinct. RU SMP-IV is composed of a catalytic subunit (Mr 40,000) and a subunit with a molecular weight of 60,000 or 58,000. All three rabbit uterine smooth muscle phosphatases dephosphorylate the isolated myosin light chains but only RU SMP-IV dephosphorylates heavy meromyosin. However, when the catalytic subunit of RU SMP-I is dissociated from the regulatory subunits, it is active toward heavy meromyosin and exhibits higher activity toward myosin light chains and phosphorylase a than its holoenzyme. The substrate specificity of these enzymes and the effects of ATP, NaF, pyrophosphate, okadaic acid, Mg2+, Mn2+, and Ca2+ on their activities are very similar to those of the turkey gizzard smooth muscle phosphatases.     

Regulation by molluscan myosins

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

Myosin heavy-chain isoforms in human smooth muscle

The myosin heavy-chain composition of human smooth muscle has been investigated by sodium dodecyl sulfate/polyacrylamide gel electrophoresis, enzyme immunoassay, and enzyme-immunoblotting procedures. A polyclonal and a monoclonal antibody specific for smooth muscle myosin heavy chains were used in this study. The two antibodies were unreactive with sarcomeric myosin heavy chains and with platelet myosin heavy chain on enzyme immunoassay and immunoblots, and stained smooth muscle cells but not non-muscle cells in cryosections and cultures processed for indirect immunofluorescence. Two myosin heavy-chain isoforms, designated MHC-1 and MHC-2 (205 kDa and 200 kDa, respectively) were reactive with both antibodies on immunoblots of pyrophosphate extracts from different smooth muscles (arteries, veins, intestinal wall, myometrium) electrophoresed in 4% polyacrylamide gels. In the pulmonary artery, a third myosin heavy-chain isoform (MHC-3, 190 kDa) electrophoretically and antigenically distinguishable from human platelet myosin heavy chain, was specifically recognized by the monoclonal antibody. Analysis of muscle samples, directly solubilized in a sodium dodecyl sulfate solution, and degradation experiments performed on pyrophosphate extracts ruled out the possibility that MHC-3 is a proteolytic artefact. Polypeptides of identical electrophoretic mobility were also present in the other smooth muscle preparations, but were unreactive with this antibody. The presence of three myosin heavy-chain isoforms in the pulmonary artery may be related to the unique physiological properties displayed by the smooth muscle of this artery.