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.     

Requirement of the 20-kDa light chain for the papain-resistant conformation of gizzard myosin

The limited chymotryptic digestion of unphosphorylated gizzard myosin in 0.15 M NaCl converted a papain-insensitive myosin in ATP to a papain-sensitive one. This conversion without phosphorylation of its 20-kDa light chain was accompanied with truncation of a 200-kDa heavy chain to a 195-kDa fragment and with the degradation of a 20-kDa light chain. Papain also yielded the 195-kDa fragment from the heavy chain, irrespective of the presence or absence of ATP. However, the ATP-induced protection of unphosphorylated myosin from the papain-digestion disappeared concurrently with degradation of the 20-kDa light chain by papain rather than the truncation of heavy chain. Papers from two laboratories [Onishi, H. & Watanabe, S. (1984) J. Biochem. (Tokyo) 95, 903-905; Kumon, A., Yasuda, S., Murakami, N., and Matsumura, S. (1984) Eur. J. Biochem. 140, 265-271] have reported that the ATP-protection of unphosphorylated myosin against papain is not observed after the 20-kDa light chain has been phosphorylated. The present results might indicate that the ATP-induced protection is also abolished through the chymotryptic degradation of the 20-kDa light chain.     

Complete primary structure of a scallop striated muscle myosin heavy chain. Sequence comparison with other heavy chains reveals regions that might be critical for regulation

We have determined the primary structure of the myosin heavy chain (MHC) of the striated adductor muscle of the scallop Aequipecten irradians by cloning and sequencing its cDNA. It is the first heavy chain sequence obtained in a directly Ca(2+)-regulated myosin. The 1938-amino acid sequence has an overall structure similar to other MHCs. The subfragment-1 region of the scallop MHC has a 59-62% sequence identity with sarcomeric and a 52-53% identity with nonsarcomeric (smooth and metazoan nonmuscle) MHCs. The heavy chain component of the regulatory domain (Kwon, H., Goodwin, E. B., Nyitray, L., Berliner, E., O'Neall-Hennessey, E., Melandri, F. D., and Szent-Gy?rgyi, A. G. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 4771-4775) starts at either Leu-755 or Val-760. Ca(2+)-sensitive Trp residues (Wells, C., Warriner, K. E., and Bagshaw, C. R. (1985) Biochem. J. 231, 31-38) are located near the C-terminal end of this segment (residues 818-827). More detailed sequence comparison with other MHCs reveals that the 50-kDa domain and the N-terminal two-thirds of the 20-kDa domain differ substantially between sarcomeric and nonsarcomeric myosins. In contrast, in the light chain binding region of the regulatory domain (residues 784-844) the scallop sequence shows greater homology with regulated myosins (smooth muscle, nonmuscle, and invertebrate striated muscles) than with unregulated ones (vertebrate skeletal and heart muscles). The N-terminal 25-kDa domain also contains several residues which are preserved only in regulated myosins. These results indicate that certain heavy chain sites might be critical for regulation. The rod has features typical of sarcomeric myosins. It is 52-60% and 30-33% homologous with sarcomeric and nonsarcomeric MHCs, respectively. A Ser-rich tailpiece (residues 1918-1938) is apparently nonhelical.     

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.     

Chemical identification of serine 181 at the ATP-binding site of myosin as a residue esterified selectively by the fluorescent reagent 9-anthroylnitrile

The esterification reagent 9-anthroylnitrile (ANN) reacts with a serine residue in the NH2-terminal 23-kDa peptide segment of myosin subfragment-1 heavy chain to yield a fluorescent S1 derivative labeled by the anthroyl group (Hiratsuka, T. (1989) J. Biol. Chem. 264, 18188-18194). The labeling was highly selective and accelerated by nucleotides. In the present study, to determine the exact location of the labeled serine residue, the labeled 23-kDa peptide fragment was isolated. The subsequent extensive proteolytic digestion of the peptide fragment yielded two labeled peptides, a pentapeptide and its precursor nonapeptide. Amino acid sequence and composition analyses of both labeled peptides revealed that the anthroyl group is attached to Ser-181 involved in the phosphate binding loop for ATP (Smith, C. A., and Rayment, I. (1996) Biochemistry 35, 5404-5417). We concluded that ANN can esterify Ser-181 selectively out of over 40 serine residues in the subfragment 1 heavy chain. Thus ANN is proved to be a valuable fluorescent tool to identify peptides containing the phosphate binding loop of S1 and to detect the conformational changes around this loop.     

The heavy chain of macrophage myosin is phosphorylated at the tip of the tail

Myosin purified from rabbit alveolar macrophages has been shown previously to be phosphorylated on the rod portion of the heavy chain and on the 20-kDa light chains (Trotter, J.A. (1982) Biochem Biophys. Res. Commun. 106, 1071-1077). Phosphorylation of the 20-kDa light chains by endogenous kinase activity is associated with a significant enhancement of the actin-activated MgATPase activity (Trotter, J.A., and Adelstein, R.S. (1979) J. Biol. Chem. 254, 8781-8785), whereas the function of heavy-chain phosphorylation is unknown. The isolated heavy chains of myosin purified from freshly harvested cells contain between 0.4 and 1.5 mol of PO4/mol of heavy chain, all esterified to serine residues. Using myosin phosphorylated by incubating living unstimulated macrophages in the presence of 32Pi, two-dimensional thin-layer mapping of tryptic peptides derived from heavy chains yields four phosphopeptides, which are phosphorylated to different extents. Limited trypsin digestion of similar radioactive myosin removes all radioactivity from the heavy chain while reducing its apparent molecular mass by less than 10 kDa. It is concluded that the heavy chain of macrophage myosin is phosphorylated on as many as four serines within 10 kDa of the tip of the tail.     

Preparation of a phospholipid-insensitive, autophosphorylation-activated catalytic fragment of Acanthamoeba myosin I heavy chain kinase.

The actin-activated Mg(2+)-ATPase activity of Acanthamoeba myosin I depends on phosphorylation of its single heavy chain. The activity of the myosin I heavy chain kinase is increased about 50-fold by autophosphorylation, and the rate of kinase autophosphorylation is enhanced about 20-fold by acidic phospholipids independent of the presence of Ca2+ (Brzeska, H., Lynch, T. J., and Korn, E. D. (1990) J. Biol. Chem. 265, 3591-3594). In this paper, we show that chymotryptic digestion of the kinase produces a 54-kDa fragment which contains three to four of the approximately 11 original phosphorylation sites and whose activity is greatly stimulated by autophosphorylation. However, both the rate of autophosphorylation and the kinase activity of the 54-kDa fragment are independent of phospholipid and comparable to those of intact kinase in the presence of phospholipid. These data imply that the (probably NH2-terminal) region(s) removed by proteolysis is necessary for phospholipid-sensitive inhibition of autophosphorylation of sites residing within the (probably COOH-terminal) 54-kDa fragment. The 54-kDa fragment contains the catalytic site of the kinase as well as three to four sites whose phosphorylation is necessary for full expression of kinase activity. The middle region of the kinase molecule contains proline-rich regions that are similar to the COOH-terminal tail of the kinase substrate, Acanthamoeba myosin I.     

Comparative structure of the protease-sensitive regions of the subfragment-1 heavy chain from smooth and skeletal myosins

The heavy chain fragments generated by restricted proteolysis of the smooth chicken gizzard myosin subfragment-1 (S-1) with trypsin, Staphylococcus aureus V8 protease, and chymotrypsin were isolated and submitted to partial amino acid sequencing. The comparison between the smooth and striated muscle myosin sequences permitted the unambiguous structural characterization of the two protease-vulnerable segments joining the three putative domain-like regions of the smooth head heavy chain. The smooth carboxyl-terminal connector is a serine-rich region located around positions 632-640 of the rabbit skeletal sequence and would represent the "A" site that is conformationally sensitive to the myosin 10 S-6 transition and to its interaction with actin (Ikebe, M., and Hartshorne, D. J. (1986) Biochemistry 25, 6177-6185). A third site which undergoes a nucleotide-dependent chymotryptic cleavage which inactivates the Mg2+-ATPase (Okamoto, Y., and Sekine, T. (1981) J. Biochem. (Tokyo) 90, 833-842, 843-849) was identified at Trp-31/Ser-32. It is vicinal to Lys-34 that is monomethylated in the skeletal heavy chain but not at all in the smooth sequence. However, the two trimethyl lysine residues present in the skeletal sequence are conserved in the same regions of the smooth S-1 and may play a general functional role in myosin. The smooth central 50-kDa segment could be selectively destroyed by a mild tryptic digestion in the absence of any unfolding agent, with a concomitant inhibition of the ATPase activities. This feature is in line with the proposed domain structure of the S-1 heavy chain and also suggests a relationship between the specific biochemical properties of the smooth S-1 and the particular conformation of its 50-kDa region.     

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.     

Proteolytic fragmentation of brain myosin and localisation of the heavy-chain phosphorylation site

The heavy chains and the 19-kDa and 20-kDa light chains of bovine brain myosin can by phosphorylated. To localise the site of heavy-chain phosphorylation, the myosin was initially subjected to digestion with chymotrypsin and papain under a variety of conditions and the fragments thus produced were identified. Irrespective of the ionic strength, i.e. whether the myosin was monomeric or filamentous, chymotryptic digestion produced two major fragments of 68 kDa and 140 kDa; the 140-kDa fragment was further digested by papain to yield a 120-kDa and a 23-kDa fragment. These fragments were characterised by (a) a gel overlay technique using 125I-labelled light chains, which showed that the 140-kDa and 23-kDa polypeptides contain the light-chain-binding sites; (b) using myosin photoaffinity labelled at the active site with [3H]UTP, which showed that the 68-kDa fragment contained the catalytic site, and (c) electron microscopy, using rotary shadowing and negative-staining techniques, which demonstrated that after chymotryptic digestion the myosin head remains attached to the tail whereas on papain digestion isolated heads and tails were observed. Thus the 120-kDa polypeptide derived from the 140-kDa fragment is the tail of the myosin, and the 68-kDa fragment containing the catalytic site and the 23-kDa fragment, with the light-chain-binding sites, form the head (S1) portion of the myosin. When [32P]-phosphorylated brain myosin was digested with chymotrypsin and papain it was shown that the heavy-chain phosphorylation site is located in a 5-kDa peptide at the C-terminal end of the heavy chain, i.e. the end of the myosin tail. Using hydrodynamic and electron microscopic techniques, no significant effect of either light-chain or heavy-chain phosphorylation on the stability of brain myosin filaments was observed, even in the presence of MgATP. Brain myosin filaments appear to be more stable than those of other non-muscle myosins. Light-chain phosphorylation did, however, have an effect on the conformation of brain myosin, for example in the presence of MgATP non-phosphorylated myosin molecules were induced to fold into a very compact folded state.     

Conformational transitions in the myosin head induced by temperature, nucleotide and actin. Studies on subfragment-1 of myosins from rabbit and frog fast skeletal muscle with a limited proteolysis method

Tryptic digestion patterns reveal a close similarity of the substructure of frog subfragment-1 (S1) to that established for rabbit S1. The 97-kDa heavy chain of chymotryptic S1 of frog myosin is preferentially cleaved into three fragments with apparent molecular masses of 29 kDa, 49 kDa and 20 kDa. These fragments correspond to the 27-kDa, 50-kDa and 20-kDa fragments of rabbit S1, respectively; this is indicated by the sequence of their appearance during digestion, by the suppression by actin of the generation of the 49-kDa and 20-kDa peptides, and by a nucleotide-promoted cleavage of the 29-kDa peptide to a 24-kDa fragment and the 49-kDa peptide to a 44-kDa fragment, analogous to the nucleotide-promoted cleavage of the 27-kDa and 50-kDa fragments of rabbit S1 to the 22-kDa and 45-kDa peptides. The same changes in the digestion patterns as those produced by the presence of nucleotide (ATP or its beta,gamma-imido analog AdoP P[NH]P) at 25 degrees C were observed when the digestion was carried out at 0 degrees C in the absence of nucleotide. The low-temperature-induced changes were particularly well seen in the preparations from frog myosin. The presence of ATP or AdoP P[NH]P at 0 degrees C enhanced, whereas the complex formation with actin prevented, the low-temperature-induced changes. The results are consistent with there being two fundamental conformational states of the myosin head in an equilibrium that is dependent on the temperature, the nucleotide bound at the active site, and the presence or absence of actin.     

Amino acid sequence of a segment of the Acanthamoeba myosin II heavy chain containing all three regulatory phosphorylation sites

The actin-activated Mg2+-ATPase activity of myosin II from the soil amoeba Acanthamoeba castellanii is regulated by phosphorylation of 3 serine residues on the myosin II heavy chain. Partial chymotryptic digestion of 32P-labeled myosin II cleaves from the tail end of the myosin II heavy chain a small peptide which contains all three phosphorylation sites. During purification the phosphorylated peptide is resolved into several different species as a result of heterogeneity both in phosphate content and in size (probably due to chymotryptic cleavage at the carboxyl terminus). However, all forms of the peptide have an identical amino terminus. The sequence of the first 58 residues of the peptide is: N-S-A-L-E-S-D-K-Q-I10-L-E-D-E-I-G-D-L-H- E20-K-N-K-Q-L-Q-A-K-I-A30-Q-L-Q-D-E-I-D-G-T- P40-S-S-R-G-G-S-T-R-G-A50-S-A-R-G-A-S-V-R. The phosphorylated serines are at positions 46, 51, and 56. The first 36 residues of the sequence display a repeating 3-4-3-4 pattern of hydrophobic residues suggesting that this section of the peptide forms an alpha-helical coiled-coil structure. A -Gly-Thr-Pro sequence at residues 38-40 disrupts the alpha-helix and, at the same point, the repeating pattern of non-polar residues is lost. It is likely that the residues extending from Gly-38 to the end of the myosin II tail, which include the 3 phosphorylatable serines, form a randomly coiled or small globular structure. This is the first report of the sequence around the regulatory phosphorylation sites on any myosin heavy chain.     

Direct chemical evidence that serine 180 in the glycine-rich loop of myosin binds to ATP

The photochemical reaction of MgADP-vanadate with the active site of myosin has been used to place a serine at the binding site for the gamma-phosphate of ATP. Irradiation of the MgADP-vanadate myosin subfragment 1 transition state-like complex with UV light specifically photooxidizes the hydroxyl group of a serine residue to an aldehyde (Cremo, C. R., Grammer, J. C., and Yount, R. G. (1988) Biochemistry 27, 8415-8420). Reduction of photooxidized myosin with Na-B3H4 gave only 3H-labeled serine. Here, subsequent extensive proteolytic digestion of 3H-labeled myosin subfragment 1 with trypsin and thermolysin yielded two 3H-labeled peptides, both of which contained the sequence Gly-Glu-Ser-Gly-Ala-Gly-Lys-Thr, in which all the 3H was associated with the serine. This sequence is conserved in all myosin heavy chains sequenced to date and corresponds to residues 178-185 in the rabbit myosin heavy chain (Tong, S. W., and Elzinga, M. (1983) J. Biol. Chem. 21, 13100-13110). These results place Ser-180 at the gamma-phosphate-binding site for ATP and indicate that the glycine-rich loop around the serine provides essential elements of the phosphate-binding site for ATP in all myosin molecules. Such a role was previously suggested based on the common sequence Gly-X-X-X-X-Gly-Lys-Thr/Ser, found in myosin and many other nucleotide-binding enzymes (Walker, J. E., Saraste, M., Runswick, M. H., and Gay, N. J. (1982) EMBO J. 1, 945-951).     

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.     

Serine-324 of myosin's heavy chain is photoaffinity-labeled by 3'(2')-O-(4-benzoylbenzoyl)adenosine triphosphate

A portion of the active site of rabbit skeletal myosin near the ribose ring of ATP can be labeled by the photoaffinity analogue 3'(2')-O-(4-benzoylbenzoyl)adenosine triphosphate (Bz2ATP). The specificity of the photolabeling was assured by first trapping [14C]Bz2ATP at the active site by use of thiol cross-linking agents [Mahmood, R., Cremo, C., Nakamaye, K., & Yount, R. (1987) J. Biol. Chem. 262, 14479-14486]. Five radioactive peptides were isolated by high-performance liquid chromatography after extensive trypsin and subtilisin digestion of photolabeled myosin subfragment 1. Four of these peptides were sequenced by Edman techniques, and all originated from a region with the sequence Gly-Glu-Ile-Thr-Val-Pro-Ser-Ile-Asp-Asp-Gln, which corresponds to rabbit myosin heavy chain residues 318-328. The fifth labeled peptide had an amino acid composition appropriate for residues 312-328. Amino acid composition, radiochemical analysis, and sequence data indicate that Ser-324 is the major amino acid residue photolabeled by Bz2ATP. Spectrophotometric evidence indicates that the benzophenone carbonyl group has inserted into a C-H bond from either the alpha- or beta-carbon of serine. These results place Ser-324 at a distance of 6-7 A from the 3'(2') ribose oxygens of ATP bound at the active site of myosin.     

Localization of the human complement component C3 binding site on the IgG heavy chain

The location of the covalent binding site of the third component of complement (C3) on the IgG heavy chain was determined by sequence analysis of peptides generated by cyanogen bromide digestion of C3-IgG adducts. Activation of the alternative pathway by incubation of heat-aggregated human IgG1 with fresh normal human plasma formed covalent adducts of C3b-IgG. CNBr peptides of these adducts were transferred to a polyvinylidene difluoride membrane, and amino-terminal sequences were determined. A 40-kDa dipeptide containing the covalent bond was identified by labeling the free thiol group (generated during activation of the internal thioester of C3b) with iodo[1-14C]acetamide and analyzed by amino acid sequencing. The resulting double sequence suggested an adduct with NH2 termini at residue 938 (pro-C3 numbering) of C3 (75 residues NH2-terminal to the thioester) and residue 84 in the variable region of the IgG heavy chain. These results combined with results from hydroxylamine treatment (splits ester linkage between C3b and IgG) imply that this adduct peptide consists of a 22-kDa C3 fragment and an 18-kDa IgG fragment. Therefore, C3 binds covalently within the region extending from the last 20 residues of the variable region through the first 20 residues of CH2.     

The primary structure of skeletal muscle myosin heavy chain: II. Sequence of the 50 kDa fragment of subfragment-1

The complete amino acid sequence of the 50 kDa fragment of subfragment-1 from adult chicken pectoralis muscle myosin was determined. It contained 431 residues including an epsilon-N-trimethyllysine at position 346. The 431-residue sequence corresponds to the sequence of residues 206 to 639 of chicken embryonic breast muscle myosin heavy chain which was predicted from the nucleotide sequence of the cDNA by Molina et al. [Molina, M. I., Kropp, K.E., Gulick, J., & Robbins, J. (1987) J. Biol. Chem. 262, 6478-6488]. Comparing the two sequences, 23 amino acid substitutions and three deletions/insertions are recognized.     

Photocross-linking from dinitrophenylated SH1 in myosin head. II. Cross-linked site on 50-kDa fragment

We reported in the preceding paper [Muno, D., et al. (1987) J. Biochem. 101, 661-669] that the dinitrophenyl group exclusively introduced to SH1 on the 20-kDa fragment of myosin subfragment 1 was cross-linked to the 50-kDa fragment by irradiation, and that limited trypsinolysis of the cross-linked S1 generated an 83-kDa peptide, a cross-linking product between the 20- and 50-kDa fragments. This paper will deal with the location of the cross-linked residue on the 50-kDa fragment. When the 83-kDa fragment labeled at SH2 with a fluorogenic SH reagent was subjected to bromocyanolysis, a main fluorescent band, which implied a cross-linked peptide, appeared in the position with an apparent molecular mass of 18.5-kDa on SDS-PAGE. On the other hand, another cross-linked peptide was obtained from a complete tryptic digest of a 83-kDa fragment rich fraction. Amino acid sequence analysis of the two cross-linked peptides revealed that the DNP moiety attached at SH1 was cross-linked with a residue in the segment of the heavy chain spanning the 485-493 region from the N-terminus of the heavy chain.     

Effect of nucleotide on interaction of the 567-578 segment of myosin heavy chain with actin

To probe the effect of nucleotide on the formation of ionic contacts between actin and the 567-578 residue loop of the heavy chain of rabbit skeletal muscle myosin subfragment 1 (S1), the complexes between F-actin and proteolytic derivatives of S1 were submitted to chemical cross-linking with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide. We have shown that in the absence of nucleotide both 45 kDa and 5 kDa tryptic derivatives of the central 50 kDa heavy chain fragment of S1 can be cross-linked to actin, whereas in the presence of MgADP.AlF4, only the 5 kDa fragment is involved in cross-linking reaction. By the identification of the N-terminal sequence of the 5-kDa fragment, we have found that trypsin splits the 50 kDa heavy chain fragment between Lys-572 and Gly-573, the residues located within the 567-578 loop. Using S1 preparations cleaved with elastase, we could show that the residue of 567-578 loop that can be cross-linked to actin in the presence of MgADP.AlF4 is Lys-574. The observed nucleotide-dependent changes of the actin-subfragment 1 interface indicate that the 567-578 residue loop of skeletal muscle myosin participates in the communication between the nucleotide and actin binding sites.     

Properties of the C-terminal domain of 4.1 proteins.

At the C-terminus of all known 4.1 proteins is a sequence domain unique to these proteins, known as the C-terminal domain (CTD). Mammalian CTDs are associated with a growing number of protein-protein interactions, although such activities have yet to be associated with invertebrate CTDs. Mammalian CTDs are generally defined by sequence alignment as encoded by exons 18-21. Comparison of known vertebrate 4.1 proteins with invertebrate (Caenorhabditis elegans and Drosophila melanogaster) 4.1 proteins indicates that mammalian 4.1 exon 19 represents a vertebrate adaptation that extends the sequence of the CTD with a Ser/Thr-rich sequence. The CTD was first described as a 22/24-kDa domain by chymotryptic digestion of erythrocyte 4.1 (4.1R) [Leto, T.L. & Marchesi, V.T. (1984) J. Biol. Chem. 259, 4603-4608]. Here we show that in 4.1R the 22/24-kDa fragment is not stable but rapidly processed to a 15-kDa fragment by chymotrypsin. The 15-kDa fragment is extremely stable, being resistant to overnight digestion in chymotrypsin on ice. Analysis of this fragment indicates that it is derived from residues 709-858 (SwissProt accession no. P48193), and represents the CTD of 4.1R. The fragment behaves as a globular monomer in solution. Secondary-structure predictions indicate that this domain is composed of five or six beta strands with an alpha helix before the most C-terminal of these. Together these data indicate that the CTD probably represents an independent folding structure which has gained function since the divergence of vertebrates from invertebrates.