Characterization of the actin binding site on smooth muscle filamin.

We have isolated an NH2-terminal fragment of filamin (M(r) = 70,000) after digestion with Staphylococus aureus V8 protease. This fragment was shown to interact with filamentous actin in cosedimentation assays. Using cross-reactive anti-peptides antibodies directed against the strongly conserved 27-mer sequence of alpha-actinin, already implicated as an actin binding site (Kuhlman, P. A., Hemmings, L., and Critchley, D. R. (1992) FEBS Lett. 304, 201-206), we obtained evidence suggesting that the homologous sequence of filamin (121-147 sequence) is the major element in the interaction with actin. In particular, we used enzyme-linked immunosorbent assay experiments, in conjunction with a synthetic peptide approach, and found that the hydrophobic part of the 27-mer peptide (141-147 sequence) is largely involved in actin binding. Thus, the filamin sequence 121-147 (or the alpha-actinin sequence 108-134) and the actin counterpart composed of residues 112-125 and 360-372 (we have already implicated) could constitute the main interface between actin and these cytoskeletal proteins. However, the divergent behavior of filamin and alpha-actinin toward conformational changes of actin argues in favor of distinctive interfaces. Finally, the ionic strength dependence of the filamin-actin interaction, in contrast to that with alpha-actinin, strongly suggests that, besides hydrophobic interactions conferred by the 27-mer sequence, more hydrophilic region(s) of filamin participate(s) in the binding.

Turkey gizzard caldesmon: complete sequence of a C-terminal thrombic fragment that binds actin, tropomyosin and calmodulin.

We have determined, by protein chemistry methods, the complete amino acid sequence of a thrombic fragment, "CaD35", which contains the C-terminal 274 residues of turkey gizzard caldesmon. Residues 1-96 of CaD35 comprise an actin-binding subfragment which resembles the tropomyosin-binding segment of troponin T. Residues 111-128 and 255-272 may form basic, amphipathic helices that interact with calmodulin. Residues 251-253 (Ser-Ser-Ser) may be phosphorylated. Chymotryptic CaD35, obtained from chicken gizzard caldesmon, nearly identical in sequence to the turkey gizzard fragment, but contains an additional 32 amino acid residues at its N terminus.

Conformational change of turkey-gizzard caldesmon induced by specific chemical modification with carbodiimide.

Water soluble 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide was used to internally cross-link carboxyl and lysyl groups of caldesmon. The modification did not involve the two cysteines of the molecule which were previously labelled with N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine. The modified caldesmon exhibited a smaller Stokes radius (4.0 nm instead of 6.3 nm) and its electrophoretic mobility corresponded to an apparent molecular mass of approximately 82 kDa, appreciably lower than that of the native molecule (120 kDa), but more similar to the reported true molecular mass of 86,974 Da of chicken-gizzard caldesmon (Bryan, J., Imai, M., Lee, R., Moore, P., Cook. R. G. & Lin, W. (1989) J. Biol. Chem. 264, 13,873-13,879). Comparative circular dichroism analysis indicated a decrease of the alpha-helix content from 43% to 36% resulting from the chemical modification. The 1H-NMR spectra of the native and modified caldesmon showed that the covalent cross-linking affected mainly the central and N-terminal parts of the molecule. The C-terminal part, rich in aromatic amino acids, was unmodified by the carbodiimide treatment. This was also corroborated by the continued ability of the modified caldesmon to bind to actin and calmodulin, and by the property of the 90-kDa proteolytic N-terminal fragment to give an internally cross-linked species of 60 kDa. Using electron microscopy, the modified protein was shown to have a more compact shape and a reduced capacity to induce tight and long F-actin bundles. These conformational changes were obtained when the carbodiimide reaction was conducted at pH 6.0 and were not observed at pH 8.0. This suggests that local variation of the pH might affect the conformation of caldesmon which changes from an elongated to more compact shape, stabilized by electrostatic interactions. It is proposed that the flexibility of caldesmon might be involved in the regulatory function of this protein in the smooth muscle and might favour tightly packed F-actin bundles or weaker interactions between actin filaments.

Structural study of gizzard caldesmon and its interaction with actin. Binding involves residues of actin also recognised by myosin subfragment 1.

The interaction between actin and caldesmon that is associated with the inhibition of actomyosin ATPase activity in smooth muscle has been studied using 1H-NMR spectroscopy. Binding studies using the intact molecules were complemented by the use of thrombic cleavage fragments of both turkey and chicken gizzard caldesmon as well as defined peptides of actin, in order to investigate the conformational properties of caldesmon and to localise regions of the primary structures that participate in protein-protein contacts. The binding of caldesmon is shown to involve distinct segments on the N-terminal region (residues 1-44) of actin, as previously observed for the inhibitory component of the thin filament of striated muscle, troponin I [Levine et al. (1988) Eur. J. Biochem. 153, 389-397]. The comparable structural properties of these tissue-specific inhibitors of actomyosin ATPase and the similarities in their mode of interaction at the N-terminal region of actin suggest common aspects to the structural mechanism for thin-filament regulation in smooth and striated muscle. Unlike the inhibitory interaction of troponin I, however, the binding of caldesmon to the N-terminal region of actin directly involves groups within residues 20-41 of actin that are also recognised by myosin subfragment 1. The complementary segment of caldesmon has been localised to a 15-kDa thrombic fragment (residues 483-578) derived from the N-terminal portion of a 35-kDa proteolytic cleavage product from the C-terminal of caldesmon whose interaction with actin is modulated by calmodulin. The results are discussed in relation to the calcium-mediated mechanism for thin-filament regulation in smooth and striated muscle.

Complexes between 15 kDa caldesmon fragment and actin investigated by immuno-electron microscopy.

The regulatory system of smooth muscle thin filaments is thought to involve a major calcium-calmodulin and actin binding protein: caldesmon. A dissective approach was used to isolate a 35 kDa C-terminal fragment of the molecule and to produce antibodies reacting against both the intact and the 15 kDa N-terminal end of this parental fragment. While this purified 15 kDa caldesmon fragment demonstrates a weak actin association, we observed that it cross-links actin filaments into loose bundles. These structures were labelled with a selective antibody and showed regular periodic striation with repeats of approximately 40 nm. This work brings additional information to previous reports using an actin and calmodulin binding 25 kDa C-terminal fragment of the caldesmon molecule [(1989) J. Biol. Chem. 264, 2869-2875]. We demonstrate that a purified fragment corresponding to a sequence smaller than 96 amino acids, which contains no cystein residue, is able to interact with actin at a single site which is not the calmodulin modulated.

New subfragment 1 of skeletal muscle myosin obtained by thrombin cleavage.

The head of the myosin molecule (i.e., subfragment 1 with a heavy chain of 95 kDa) is usually obtained by chymotryptic cleavage in the presence of a divalent cation chelator. In the present work, we used another specific proteolytic enzyme, thrombin, to produce a limited cut within the myosin molecule, resulting in a new species of N-terminal fragment. Treatment of skeletal muscle myosin yielded a 97-kDa split heavy chain associated with intact light chains, corresponding to a single cut. The ATPase activities of this new S-1 derivative were slightly affected by the breakdown. It recognized actin in an ATP-dependent manner, as expected, with an affinity 2-5 times higher than that of the usual chymotryptic S-1 preparation but with a very different electron microscopic pattern. Functional differences are noted, and we involve them more precisely in relation to possible structural aspects of the additional C-terminal segment extending the usual S-1 heavy chain from 95 to 97 kDa.

Functional characterization of skeletal F-actin labeled on the NH2-terminal segment of residues 1-28.

Rabbit skeletal alpha-actin was covalently labeled in the filamentous state by the fluorescent nucleophile, N-(5-sulfo-1-naphthyl)ethylenediamine (EDANS) in the presence of the carboxyl group activator 1-(3-dimethyl-aminopropyl)-3-ethylcarbodiimide (EDC). The coupling reaction was continued until the incorporation of nearly 1 mol EDANS/mol actin. After limited proteolytic digestion of the labeled protein and chromatographic identification of the EDANS-peptides, about 80% of the attached fluorophore was found on the actin segment of residues 1-28, most probably within the N-terminal acidic region of residues 1-7. A minor labeling site was located on the segment that consists of residues 40-113. No label was incorporated into the COOH-terminal moiety consisting of residues 113-375. The isolated EDANS-G-actin undergoes polymerization in the presence of salts but at a rate significantly greater than unlabeled actin. The EDANS-F-actin could be complexed to skeletal chymotryptic myosin subfragment 1 (S-1) and to tropomyosin. The complex formed between EDANS-F-actin and S-1 could not be further crosslinked by EDC but the two proteins were readily joined by glutaraldehyde as observed for native actin-S-1, suggesting that the EDANS-substituted carboxyl site is also involved in the EDC crosslinking of native actin to S-1. Moreover, the EDANS labeling of F-actin resulted in a 20-fold increase in the Km of the actin-activated Mg2+.ATPase of S-1. Thus, this labeling, while it did not much affect the rigor actin-S-1 interaction, changes the actin binding to the S-1-nucleotide complexes significantly. The selective introduction of a variety of spectral probes, like EDANS, or other classes of fluorophores, on the N-terminal region of actin, through the reported carbodiimide coupling reaction, would provide several different derivatives valuable for assessing the functional role of the negatively charged N-terminus of actin during its interaction with myosin and other actin-binding proteins.

Caldesmon structure and function: sequence analysis of a 35 kilodalton actin- and calmodulin-binding fragment from the C-terminus of the turkey gizzard protein.

We have determined the amino acid sequence of a 35 kDa proteolytic fragment ("CaD35") derived from the C-terminus of turkey gizzard caldesmon. This 239-residue peptide contains binding sites for actin and calmodulin. Residues 1-96 of CaD35 comprise "CaD15", an actin-binding subfragment which we previously showed to resemble the tropomyosin-binding segment of troponin T. The remainder of the CaD35 sequence shows no significant similarity to other proteins. Residues 111-128 may form a basic, amphipathic helix which interacts with calmodulin.

Amino acid sequence of a 15 kilodalton actin-binding fragment of turkey gizzard caldesmon: similarity with dystrophin, tropomyosin and the tropomyosin-binding region of troponin T.

We have determined the amino acid sequence of a 15 kDa actin-binding fragment of turkey gizzard caldesmon. The 96-residue fragment contains 29 acidic and 29 basic residues, and is predicted to have an extended helical conformation stabilized by numerous internal salt bridges. CaD15 bears some resemblance to dystrophin, tropomyosin and several other proteins, but is most strikingly similar to the tropomyosin-binding segment of troponin T.

Functional sequences of the myosin head.

Muscle contraction originates from the sliding of myosin filaments on actin filaments, the energy for which is supplied by the hydrolysis of adenosine-5-triphosphate (ATP) by myosin. The nucleotide first binds to the acto-myosin complex in the myosin head (or subfragment-1), producing a conformational change which induces actin dissociation. The release of phosphate (Pi) then allows a return to the strong actin-myosin association, corresponding to the rigor state. We discuss here certain controversial points arising from current concepts of the actin and nucleotide binding regions at the amino acid sequence level within the subfragment-1 heavy chain. We consider the actin and nucleotide binding regions to be two distinct sites (for each of these regions) one of which is shared competitively between actin and the nucleotide. In our model the cyclical actin-S1 association-dissociation steps correspond to different ATP, actin and ADP affinities for the same amino acid sequence of the S1 heavy chain, contributing alternatively to a single hydrolytic nucleotide site or a strong actin site. We propose the existence of a flexible segment that forms or dismantles the nucleotide or actin sites. The large region (amino acids 540-707) overlapping the actin-myosin interface appears to be the main flexible region of the S1 molecule and we propose that this particular sequence plays a key role in the dissociation pathway of the actin-myosin complex and in the conversion of chemical energy into the mechanical energy of contraction.

The actin-myosin subfragment-1 complex stabilized by phenyldiglyoxal.

Nuclear magnetic resonance studies have revealed the importance of arginine residues in the actin-myosin interface (Moir, A. J. G., and Levine, B. A. (1986) J. Inorg. Chem. 27, 271-278). In the present study, we tested the involvement of these residues in the rigor complex between actin and subfragment-1 (S1) by chemical cross-linking experiments using phenyldiglyoxal. Two kinds of linkages were observed, one within the S1 heavy chain itself (120-kDa product) and the other between actin and the S1 heavy chain (200-kDa product). The phenyldiglyoxal had an effect similar to that of phenylglyoxal on S1 ATPase activities. We also show that phenyldiglyoxal (of 0.6-0.8 nm arm length) cross-links an arginine residue of the 50-kDa domain to one in the 20-kDa domain of the S1 heavy chain in the absence of actin or to an arginine in actin when actin is present. The presence of Mg2+, adenosine 5'-diphosphate or 5'-adenylyl imidodiphosphate suppressed the intermolecular linkage with actin, and favored the intramolecular cross-link, (i.e. between 50-kDa and 20-kDa fragments). We propose that the same arginyl residue in the N-terminal part of the 50-kDa domain can be cross-linked to a nearby arginine in either the 20-kDa domain or the actin molecule. In accordance with the amino acid sequence of each protein this also implies that the actin-myosin interaction involves arginine residues located either after residue 28 of the N-terminal part of actin, since this actin region is devoid of arginine residues, or in the N-terminal portion of the 50-kDa domain, i.e. between residues 239 and 455.

A 35-kilodalton fragment from gizzard smooth muscle caldesmon that induces F-actin bundles.

Specific thrombin proteolysis of native 120-kDa gizzard caldesmon gave rise to a major cleavage into an N-terminal 90-kDa and a C-terminal 35-kDa fragment. Fluorescent labeling, cosedimentation, passage through an affinity column, and carbodiimide crosslinking with actin revealed that the 35-kDa purified segment of the molecule contains the actin and the calcium-calmodulin binding regions. Electron microscopic analysis of its actin complex demonstrated that the 35-kDa segment possesses the bundling properties of the intact molecule. Thus, a possible pathway for the expression of the caldesmon regulatory function during smooth muscle contraction would be a conformational change twisting the helicoïdal structure of the actin filament, which occurs when the 35-kDa caldesmon portion binds to it.

Identification of a 15 kilodalton actin binding region on gizzard caldesmon probed by chemical cross-linking.

Fluorescent labeling, limited proteolysis, amino acid sequence determinations, affinity chromatography and specific chemical crosslinking were used to determine the smallest fragment of gizzard caldesmon that interacts with actin. The time course of cleavage with thrombin or submaxillaris arginase-C protease indicates that 90kDa and 35kDa fragments are the two major pieces of the 120kDa native protein. Amino acid sequence determination indicates that the 90kDa fragment is the N-terminal portion of the molecule. Further degradation gave rise to a 15kDa product whose N-terminal amino acid sequence was determined within the first 28 amino acids. Carbodiimide crosslinking with actin revealed that the 15kDa part of the molecule is probably not involved in the actin binding process but may participate in a twisting of the F-actin filament and be responsible of the caldesmon regulatory function during smooth muscle contraction.

The internal crosslinking of the S1 heavy chain from smooth muscle probed by dibromobimane.

The reaction of the crosslinker dibromobimane has recently revealed a functionally important internal loop structure within the skeletal myosin S1 heavy chain where Cys-522 of the 50K domain and Cys-707 (SH1) of the 20K region are spatially juxtaposed. Here we have studied the possible relevance of this topological feature to the architecture and transducing activity of the myosin head in general, by extending the dibromobimane modification to smooth muscle myosin. Treatment of chicken gizzard myosin S1 with dibromobimane resulted in intramolecular crosslinking between the C-terminal 25K and central 50K segments of the S1 heavy chain. The data suggest a conservation at the 50K-25K interface of smooth muscle S1 heavy chain and the importance of the neighboring SH1 region, whose conformation may play an important role in energy transduction by the myosin head.

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.

Specific interactions of the alkali light chain 1 in skeletal myosin heads probed by chemical cross-linking.

We have investigated the enzymatic properties of the 120K cross-linked heavy-chain-light-chain derivative formed upon reaction of chymotryptic myosin subfragment 1 (S-1) isoenzymes with the bis(imido esters) dimethyl 3,3'-dithiobis(propionimidate) and dimethyl suberimidate. The formation of the 120K product was accompanied for S-1(A1) but not for S-1(A2) by a loss of the actin-activated ATPase without alteration of the Ca2+-ATPase whereas the Mg2+-ATPase was increased 2-fold. Up to 70%, the inhibition of the acto-S-1(A1) ATPase activity was closely correlated with the extent of cross-linking of the A1 light chain; this activity could be largely restored upon cleavage of the cross-link using the reversible cross-linker dimethyl 3,3'-dithiobis(propionimidate). The covalent link affected the acto-S-1(A1) Mg2+-ATPase activity by reducing 3-fold the Vmax and increasing 2-fold the Kapp. On reacting for the first time the hydrophobic, carboxyl group directed cross-linker N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline (EEDQ) with the acto-S-1(A1 + A2) complex, we found that the N-terminal tail of the A1 light chain was cross-linked to actin to an extent much larger than observed earlier with the water-soluble 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide; like the latter agent, EEDQ elicited the covalent union of the A1 subunit to the COOH-terminal part of actin. This cross-linker appears to be a valuable chemical probe of the F-actin-A1 light-chain interaction.(ABSTRACT TRUNCATED AT 250 WORDS)

Properties of the alkali light-chain-20-kilodalton fragment complex from skeletal myosin heads.

We have developed a rapid and reproducible procedure widely applicable to the preparation of pure aqueous solutions of the complex between an alkali light chain and the COOH-terminal heavy-chain fragments of skeletal myosin chymotryptic subfragment 1 (S-1) split by various proteases. It was founded on the remarkable ethanol solubility of these complexes. A systematic study of the ethanol fractionation of the tryptic (27K-50K-20K)-S-1 (A2) showed the NH2-terminal 27K fragment to behave like a specific protein entity being quantitatively precipitated at a relatively low ethanol concentration. Only the 20K peptide-A2 complex remained in solution when the S-1 derivative was treated with exactly 4 volumes of ethanol in the presence of 6 M guanidinium chloride. At a lower ethanol concentration, a soluble mixture of 50K and 20K peptides together with the light chain was obtained. The isolated 20K fragment-A2 system containing a 1:1 molar ratio of each component was investigated by biochemical and 1H nuclear magnetic resonance (NMR) techniques to highlight its structure and the interaction of the 20K heavy-chain segment with F-actin and with the light chain. During the treatment of the complex with alpha-chymotrypsin, only the 20K peptide was fragmented in contrast to its stability within the whole S-1. The binding of F-actin to the complex led, however, to a strong inhibition of its chymotryptic degradation. 1-Ethyl-3-[3-(dimethylamino)propyl]carbodiimide cross-linking of F-actin to the complex produced covalent actin-20K peptide only, the amount of which was lower relative to that observed with the entire split S-1.(ABSTRACT TRUNCATED AT 250 WORDS)

Abolition of ATPase activities of skeletal myosin subfragment 1 by a new selective proteolytic cleavage within the 50-kilodalton heavy chain segment.

We have isolated and chemically characterized several 5-thio-2-nitrobenzoate-subfragment 1 derivatives (TNB-S-1) generated by the reaction of 5,5'-dithiobis(2-nitrobenzoic acid) (DNTB, up to 10-fold molar excess) with native S-1, N-acetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine-S-1 (AEDANS-S-1), and N,N'-p-phenylenedimaleimide-S-1 (pPDM-S-1) at 4 degrees C, pH 8.0. The reaction of the reagent with AEDANS-S-1, which has a blocked -SH1 group, induced the formation of an intramolecular cystine disulfide between two vicinal -SH groups in S-1; in contrast, the treatment of pPDM-S-1 with DTNB resulted in the formation of TNB mixed disulfides only. The incorporation of the TNB groups (up to 3 mol/mol of S-1) into the native or premodified S-1 led to a local conformational change in the 50K heavy chain region that was fully reversed upon disulfide reduction. Exploiting this peculiarity of the DTNB-modified S-1's, we have realized a highly selective proteolysis of the S-1 heavy chain by thrombin and chymotrypsin, which do not act at all on the normal S-1. The 95K heavy chain was cut by thrombin into two fragments with apparent masses of 68K and 30K, whereas the "connector segments" and the light chains were unaffected. The two new fragments were issued from a primary peptide-bound cleavage between Lys-560 and Ser-561 within the amino acid sequence of the 50K region (M. Elzinga, personal communication).(ABSTRACT TRUNCATED AT 250 WORDS)

Transient kinetics of adenosine 5'-triphosphate hydrolysis by covalently cross-linked actomyosin complex in water and 40% ethylene glycol by the rapid flow quench method.

The initial steps of the ATPase of covalently cross-linked actomyosin subfragment 1 (acto-SF-1) were studied by the rapid flow quench method, and the results obtained were compared with those with reversible (i.e., non-cross-linked) acto-SF-1 and SF-1 under identical conditions. Cross-linked acto-SF-1 plus [gamma-32P]ATP reaction mixture milliseconds old was quenched either in a large excess of unlabeled ATP (ATP chase) or in acid (Pi burst). The conditions were pH 8 and 15 degrees C at 5 mM or 0.15 M KCl and with or without 40% ethylene glycol. In 40% ethylene glycol (5 mM KCl), as with SF-1 and reversible acto-SF-1, the ATP chase was used to titrate active sites and to study the kinetics of ATP binding. Unlike those with SF-1 or reversible acto-SF-1, saturation kinetics were not obtained. The second-order rate constant for ATP binding was 3.1 X 10(6) M-1 s-1 for cross-linked acto-SF-1, 1.8 X 10(6) M-1 s-1 for reversible acto-SF-1, and 2 X 10(6) M-1 s-1 for SF-1. In Pi burst experiments, a transient phase could not be discerned. Because of a high kcat, cross-linked acto-SF-1 was difficult to study in aqueous solution, but at 5 mM KCl, the ATP chase and Pi burst curves were similar to those obtained in 40% ethylene glycol. At 0.15 M KCl the ATP chase curve was difficult to interpret (small amplitude), and there was a small Pi burst.(ABSTRACT TRUNCATED AT 250 WORDS)