The heavy chain of smooth muscle myosin is phosphorylated in aorta cells

The 204-kDa smooth muscle myosin heavy chain (MHC) from rat aorta smooth muscle cells was found to be phosphorylated following isolation of myosin from strips of intact aorta as well as from primary cultures of aorta cells. Two-dimensional maps of the tryptic peptides revealed that the phosphate was confined to only three peptides and gave a similar pattern for the MHC isolated from intact aorta strips and cultured cells. This map was quite different from the phosphopeptide map found for the 196-kDa MHC of nonmuscle myosin isolated from the same cell culture. Smooth muscle MHC purified from primary cell cultures was found to contain approximately 0.7 mol of phosphate/mol of MHC while the nonmuscle MHC contained approximately 0.8 mol of phosphate/mol of MHC. These observations raise the possibility of an additional regulatory mechanism in smooth muscle operating via MHC phosphorylation.     

Sarcomeric myosin heavy chain is degraded by the proteasome

Cardiac myofibrillar proteins, like all other intracellular proteins, are in a dynamic state of continual degradation and resynthesis. The balance between these opposing metabolic processes ultimately determines the number of functional contractile units within each cardiac muscle cell. Although alterations in myofibrillar protein degradation have been shown to contribute to cardiac growth and remodeling, the intracellular proteolytic systems responsible for degrading myofibrillar proteins to their constitutive amino acids are currently unknown. Lactacystin, a recently developed, highly specific proteasome inhibitor, was used in this study to examine the role of the proteasome in myosin heavy chain (MHC) degradation in cultured neonatal rat ventricular myocytes. Cells were treated with growth medium alone or with lactacystin (1-50 microM) for up to 48 h. Lactacystin significantly increased the total protein/DNA ratio and markedly prolonged MHC half-life. Other proteasome inhibitors, namely carbobenzoxy-L-leucyl-L-leucyl-L-leucinal (10 microM) and N-acetyl-L-leucyl-L-leucyl-norleucinal (100 microM), were also effective in suppressing MHC degradation. Lactacystin and other proteasome inhibitors also suppressed the markedly accelerated MHC degradation associated with Ca2+ channel blockade but did not prevent the disassembly and loss of myofibrils that accompanied contractile arrest. Thus, sarcomere disassembly precedes the degradation of MHC, which is at least in part mediated by the proteasome.     

The long myosin light chain kinase is differentially phosphorylated during interphase and mitosis

We have shown previously that the activity of the long myosin light chain kinase (MLCK) is cell cycle regulated with a decrease in specific activity during mitosis that can be restored following treatment with alkaline phosphatase. To better understand the role and significance of phosphorylation in regulating MLCK function during mitosis, we examined the phosphorylation state of in vivo derived MLCK. Phosphoamino acid analysis and phosphopeptide mapping demonstrate that the long MLCK is differentially phosphorylated on serine residues during interphase and mitosis with the majority of the phosphorylation sites located within the N-terminal IgG domain. Biochemical assays show that Aurora B binds and phosphorylates the IgG domain of the long MLCK. In addition, phosphopeptide maps of the endogenous full-length MLCK from mitotic cells and in vitro phosphorylated IgG domain demonstrate that Aurora B phosphorylates the same sites as those observed in vivo. Altogether, these studies suggest that the long MLCK may be a cellular target for Aurora B during mitosis.     

The phosphorylated L2 light chain of skeletal myosin is a modifier of the actomyosin ATPase

Incubation of rabbit skeletal myosin with an extract of light chain kinase plus ATP phosphorylated the L2 light chain and modified the steady state kinetics of the actomyosin ATPase. With regulated actin, the ATPase activity of phosphorylated myosin (P-myosin) was 35 to 181% greater than that of unphosphorylated myosin when assayed with 0.05 to 5 micro M Ca2+. Phosphorylation had no effect on the Ca2+ concentration required for half-maximal activity, but it did increase the ATPase activity at low Ca2+. With pure actin, the percentage of increase in the actomyosin ATPase activity correlated with the percentage of phosphorylation of myosin. Steady state kinetic analyses of the actomyosin system indicated that 50 to 82% phosphorylation of myosin decreased significantly the Kapp of actin for myosin with no significant effect on the Vmax. Phosphorylaton of heavy meromyosin similarly modified the steady state kinetics of the acto-heavy meromyosin system. Both the K+/EDTA- and Mg-ATPase activities of P-myosin and phosphorylated heavy meromyosin were within normal limits indicating that phosphorylaiion had not altered significantly the hydrolytic site. Phosphatase treatment of P-myosin decreased both the level of phosphorylation of L2 and the actomyosin ATPase activity to control levels for unphosphorylated myosin. It is concluded levels for unphosphorylated myosin. It is concluded from these results that the ability of P-myosin to modify the steady state kinetics of the actomyosin ATPase was: 1) specific for phosphorylation; 2) independent of the thin filament regulatory proteins.     

Selective removal of the carboxyl-terminal tail end of the Dictyostelium myosin II heavy chain by chymotrypsin

Dictyostelium myosin II is a conventional myosin consisting of two heavy chains of 243,000 Da and two pairs of light chains of 16,000 and 18,000 Da. In this paper, we show that the heavy chain of myosin II can be rapidly and selectively cleaved by chymotrypsin to yield two fragments with molecular weights of 195,000 and 38,000 Da as estimated from sodium dodecyl sulfate-polyacrylamide gels. Chymotryptic cleavage at this site occurs most readily in the absence of salt and is greatly inhibited as the salt concentration is increased from 0 to 60 mM. Amino acid sequence analysis of the small fragment demonstrates that its amino terminus corresponds to lysine 1826 of the myosin II heavy chain. If the fragment extends to the carboxyl terminus of the myosin II heavy chain, it would have a molecular weight of 33,700. Upon digestion of myosin II which has been phosphorylated with a high molecular weight Dictyostelium myosin heavy chain kinase (C?té, G.P., and Bukiejko, U. (1987) J. Biol. Chem. 262, 1065-1072), all of the phosphate is recovered on the 33,700-Da tail-end fragment. Chymotrypsin-cleaved myosin II is shown to be capable of forming filaments at salt concentrations between 20 and 100 mM as judged by its ability to be sedimented by centrifugation. Only the large fragment of myosin II is found in the pellet; the 33,700-dalton fragment remains soluble. Chymotrypsin-cleaved myosin II can bind to actin and displays a high Ca2+-activated ATPase activity but has very low actin-activated ATPase activity.     

Amino acid sequence around the serine phosphorylated by casein kinase II in brain myosin heavy chain

Casein kinase II from bovine brain transfers about one mole of phosphate to a serine residue near the COOH terminus of the heavy chain of myosin isolated from bovine brain. We have purified and characterized a peptide that contains this phosphoserine. The peptide was generated by chymotryptic and thermolytic digestion and was isolated by gel filtration, Fe3+ affinity chromatography, and reverse-phase high pressure liquid chromatography. Its sequence, Leu-Glu-Leu-Ser(PO4)-Asp-Asp-Asp-Asp-Glu-Ser-Lys-Ala-Ser-(Xaa)-Ile-Asn-Glu-Thr- Gln-Pro-Pro-Gln, shows that the Ser(PO4) is in an acidic environment, as is typical for casein kinase II phosphorylation sites. The "hydrophobic repeat" typical of alpha-helical coiled-coils is absent, suggesting that the sequence is part of a non-helical "tail piece" of the heavy chain. A synthetic peptide corresponding to residues 1-9 is shown to be an effective substrate for casein kinase II.     

The 204-kDa smooth muscle myosin heavy chain is phosphorylated in intact cells by casein kinase II on a serine near the carboxyl terminus

The heavy chain of smooth muscle myosin was found to be phosphorylated following immunoprecipitation from cultured bovine aortic smooth muscle cells. Of a variety of serine/threonine kinases assayed, only casein kinase II and calcium/calmodulin-dependent protein kinase II phosphorylated the smooth muscle myosin heavy chain to a significant extent in vitro. Two-dimensional maps of tryptic peptides derived from heavy chains phosphorylated in cultured cells revealed one major and one minor phosphopeptide. Identical tryptic peptide maps were obtained from heavy chains phosphorylated in vitro with casein kinase II but not with calcium/calmodulin-dependent protein kinase II. Of note, the 204-kDa smooth muscle myosin heavy chain but not the 200-kDa heavy chain isoform was phosphorylated by casein kinase II. Partial sequence of the tryptic phosphopeptides generated following phosphorylation by casein kinase II yielded Val-Ile-Glu-Asn-Ala-Asp-Gly-Ser*-Glu-Glu-Glu-Val. The Ser* represents the Ser(PO4) which is in an acidic environment, as is typical for casein kinase II phosphorylation sites. By comparison with the deduced amino acid sequence for rabbit uterine smooth muscle myosin (Nagai, R., Kuro-o, M., Babij, P., and Periasamy, M. (1989) J. Biol. Chem. 264, 9734-9737), we have localized the phosphorylated serine residue to the non-helical tail of the 204-kDa isoform of the smooth muscle myosin heavy chain. The ability of the 204-kDa isoform, but not the 200-kDa isoform, to serve as a substrate for casein kinase II suggests that these two isoforms can be regulated differentially.     

Acanthamoeba myosin I heavy chain kinase is activated by phosphatidylserine-enhanced phosphorylation

The actin-activated Mg2(+)-ATPase activities of myosins I from Acanthamoeba castellanii are fully expressed only when a single amino acid on their heavy chain is phosphorylated by myosin I heavy chain kinase. Here we show that kinase isolated by a procedure designed to minimize its phosphorylation during purification can incorporate up to 7.5 mol of phosphate/mol of enzyme when incubated with ATP, possibly by autophosphorylation. The rate of phosphorylation is enhanced about 20-fold by phosphatidylserine but is unaffected by calcium ions. Phosphorylation increases the rate at which the kinase phosphorylates the regulatory site of myosin I by about 50-fold. These results suggest that (auto?)phosphorylation may regulate the activity of myosin I heavy chain kinase in vivo. The stimulation of kinase phosphorylation by phosphatidylserine (other phospholipids have not yet been tested) is of particular interest because myosin I has been shown to be tightly associated with membranes, especially the plasma membrane.     

Identification of two phosphorylated threonines in the tail region of Dictyostelium myosin II

We have previously purified and characterized a Dictyostelium myosin II heavy chain kinase which phosphorylates threonine residues (C?té, G. P., and Bukiejko, U. (1987) J. Biol. Chem. 262, 1065-1072). The phosphorylated threonines are located within a 34-kDa fragment which can be selectively cleaved from the carboxyl terminal end of the Dictyostelium myosin II tail. Tryptic and chymotryptic digests of the 34-kDa fragment phosphorylated with the kinase have now been performed and the resulting phosphopeptides isolated and sequenced. Two phosphorylated threonine residues have been identified, corresponding to residues 1833 and 2029 in the complete amino acid sequence of the Dictyostelium myosin II heavy chain. These amino acids are 87 and 283 residues, respectively, distant from the carboxyl terminus of the Dictyostelium myosin II heavy chain and are present in sections of the tail which seem to be alpha-helical coiled coils. In contrast, the three Acanthamoeba myosin II heavy chain phosphorylation sites are located within 10 residues of each other in a small globular domain at the carboxyl terminal tip of the tail (C?té, G. P., Robinson, E. A., Appella, E., and Korn, E. D. (1984) J. Biol. Chem. 259, 12781-12787). This suggests that the mechanism by which heavy chain phosphorylation inhibits the actin-activated ATPase activity and filament-forming properties of the two myosins may be quite different.     

N-terminal region of gizzard myosin heavy chain is critical for the ATPase activity

Two different HMM species of gizzard myosin were prepared under conditions such that the phosphorylation of light chain was fully maintained. They were different in the N-terminal structure of the heavy chain but not in the light chain composition. A significant decrease in the Mg2+-ATPase activity was observed in one class of HMM which was proteolytically cleaved intramolecularly at site 1, 5 K daltons from the masked N terminus. Another class of HMM without the cleavage at site 1 showed ATPase activity similar to that of myosin. The decrease in ATPase activity was not caused by denaturation since similar amounts of initial burst of Pi liberation were observed with both HMMs and myosin. Kinetic and substructure analyses of HMM revealed that the activity change depended solely on the cleavage at site 1. The N-terminal region of gizzard myosin heavy chain may thus have an important role in maintaining the active site structure.     

Filament formation and actin-activated ATPase activity are abolished by proteolytic removal of a small peptide from the tip of the tail of the heavy chain of Acanthamoeba myosin II

Actin-activated Mg2+-ATPase activity of myosin II from Acanthamoeba castellanii is regulated by phosphorylation of three serine residues located at the carboxyl-terminal end of each of the two 185,000-Da heavy chains; the phosphorylated molecule has full Ca2+-ATPase activity but no actin-activated Mg2+-ATPase activity. Under controlled conditions, chymotrypsin removes a small peptide containing all three phosphorylation sites from the ends of the myosin II heavy chains producing a molecule with heavy chains of 175,000 Da and undigested light chains. The length of the myosin II tail decreased from 89 to 76 nm. Chymotrypsin-cleaved myosin II has complete Ca2+-ATPase activity but no actin-activated Mg2+-ATPase activity under standard assay conditions and binds to F-actin as well as undigested myosin II in the absence, but not in the presence, of MgATP. In the presence of MgCl2, undigested myosin II forms biopolar filaments but chymotrypsin-cleaved myosin II forms only parallel (monopolar) dimers, as assessed by analytical ultra-centrifugation and rotary shadow electron microscopy. We conclude that the short segment very near the end of the myosin II tail that contains the three phosphorylatable serines is necessary for the formation of biopolar filaments and, probably as a consequence of filament formation, for the high-affinity binding of myosin II to F-actin in the presence of ATP and the actin-activated Mg2+-ATPase activity of native myosin II. This supports our previous conclusion that actin-activated Mg2+-ATPase of native myosin II is expressed only when the enzyme is in bipolar filaments with the proper conformation as determined by the state of phosphorylation of the heavy chains.     

Characterization of sarcomeric myosin heavy chain genes

Myosin heavy chain is encoded by a large multigene family. Using pMHC-25, a recombinant cDNA clone isolated from the rat myogenic cell line L6E9, four members of this family in the rat have been isolated and shown to be tissue-specific and developmentally regulated. The coding regions of these genes share regions of homology interspaced with regions of non-homology. Detailed analysis of one embryonic and one adult myosin heavy chain gene shows that the coding sequences are interrupted by numerous intervening sequences whose number, size, and distribution do not appear to be conserved in the same organism or between species.     

Caenorhabditis elegans UNC-45 is a component of muscle thick filaments and colocalizes with myosin heavy chain B, but not myosin heavy chain A

In the nematode Caenorhabditis elegans, animals mutant in the gene encoding the protein product of the unc-45 gene (UNC-45) have disorganized muscle thick filaments in body wall muscles. Although UNC-45 contains tetratricopeptide repeats (TPR) as well as limited similarity to fungal proteins, no biochemical role has yet been found. UNC-45 reporters are expressed exclusively in muscle cells, and a functional reporter fusion is localized in the body wall muscles in a pattern identical to thick filament A-bands. UNC-45 colocalizes with myosin heavy chain (MHC) B in wild-type worms as well as in temperature-sensitive (ts) unc-45 mutants, but not in a mutant in which MHC B is absent. Surprisingly, UNC-45 localization is also not seen in MHC B mutants, in which the level of MHC A is increased, resulting in near-normal muscle thick filament structure. Thus, filament assembly can be independent of UNC-45. UNC-45 shows a localization pattern identical to and dependent on MHC B and a function that appears to be MHC B-dependent. We propose that UNC-45 is a peripheral component of muscle thick filaments due to its localization with MHC B. The role of UNC-45 in thick filament assembly seems restricted to a cofactor for assembly or stabilization of MHC B.     

A canonical sequence organization at the 5'-end of the myosin heavy chain genes

The sequences encoding the 5'-ends of three chicken fast-white myosin heavy chain (MHC) genes have been determined. When compared with the sequences of two other MHC genes it is apparent that both the exon and intron positions are conserved. All exon sequences are highly conserved; there is absolute amino acid conservation in the second and third exons. In addition, while the first and third introns diverge among the genes, the second intron is highly conserved between the five. This intron contains a 24-bp sequence that is repeated twice in one of the introns and once in the other four. Analyses indicate that this sequence, which is partially homologous to 7SL RNA, appears to be largely restricted to the MHC gene family. Analysis of the 5'-flanking sequences show that while small homologies are present between some of the genes, they have extensively diverged in this region.     

The analysis of a chicken myosin heavy chain cDNA clone

A cDNA library has been constructed in the plasmid pBR322 using a large size class of RNA derived from chicken embryonic leg muscle as the template material. A clone containing a 2350-base pair insert was selected and identified as coding for the myosin heavy chain sequence, based upon its ability to hybridize to genomic myosin heavy chain clones, and by direct nucleotide sequencing. Cross-hybridization experiments with myosin heavy chain genomic clones, and mRNAs derived from different muscle types were used to explore the heterogeneity of the various myosin heavy chain isoforms at the level of the coding sequences. Although extensive sequence homology with the other isoforms was observed, a fast white isoform-specific subclone was constructed, and used to demonstrate that different genes code for the adult and embryonic fast white myosin heavy chain proteins.     

Characterization of the carp myosin heavy chain multigene family

We isolated partial coding sequences for 29 carp myosin heavy chain genes (MyoHCs) and determined the nucleotide sequences around the region encoding the loop 2 of the myosin molecule. The predicted amino acid sequences from the isolated genes all showed very high similarity to those of skeletal and cardiac muscles from higher vertebrates, but not to those of smooth and non-muscle counterparts. Among all clones isolated, carp MyoHC10, MyoHCI-1-3 and MyoHC30 showed exon-nucleotide sequences identical to those of cDNAs encoding the loop 2 region of the 10 degrees C-, intermediate- and 30 degrees C-type fast skeletal isoforms [Hirayama and Watabe, Euro. J. Biochem. 246 (1997) 380-387]. The loop 2 of 28 types of carp MyoHCs was encoded by two exons separated by an intron corresponding to that of the 16th in higher vertebrate MyoHCs, whilst this intron was not found in carp MyoHC30. Although carp MyoHC30 had a gene organization different from those of higher vertebrates and other carp MyoHCs, its predicted amino acid sequence for loop 2 showed the highest homology to those of higher vertebrates among carp MyoHCs. In the 28 carp MyoHCs containing the intron, a combination of different nucleotide sequences for the two resulted in 14 distinct series for the combined coding sequence. These different nucleotide sequences encoded nine distinct amino acid sequences. Phylogenetic analysis for the present loop 2 and light meromyosin previously reported for carp MyoHCs [Imai et al., J. Exp. Biol. 200 (1997) 27-34] revealed that carp MyoHCs have recently diverged and are more closely related to each other than to MyoHCs from other species.     

Cross-linking of native myosin forms oligomers of myosin heavy chain dimers

Chemical cross-linking of native myosin in 0.6 M NaCl with p-phenylene bis maleimide or glutaraldehyde resulted in rapid formation of myosin heavy chain dimers and their oligomers. Monomers and odd-number oligomers disappeared after the prolonged treatment with these reagents. When denatured myosin was cross-linking, myosin heavy chain monomers and odd-number oligomers remained after the prolonged treatment, although dimers and their even-number oligomers were abundant. For high molecular weight markers, myosin heavy chain oligomers formed from denatured myosin with glutaraldehyde or p-phenylene bis maleimide are recommended.