Calponin and tropomyosin interactions.

The interaction between chicken gizzard calponin and tropomyosin was examined using viscosity, light scattering, electron microscopy and affinity chromatography. At neutral pH, 10 mM NaCl and in the absence of Mg2+, calponin induced tropomyosin filaments to form paracrystals thus decreasing the viscosity while increasing dramatically the light scattering of the tropomyosin solution. Electron micrographs of the uranyl acetate stained calponin-tropomyosin complex showed the presence of spindle shaped paracrystals with regular striation patterns and repeating units of about 400 A. Under similar conditions, smooth muscle caldesmon also induced tropomyosin to form paracrystals. To localize the calponin-binding site on tropomyosin, binding of fragments of tropomyosin, generated by chemical and mutational means, to a calponin-affinity column was studied. The COOH-terminal tropomyosin fragment Cn1B(142-281) and the NH2-terminal fragment CSM-beta(1/8/12-227) bound to a calponin-affinity column with an affinity similar to that of intact tropomyosin; while the NH2-terminal fragment, Cn1A(11-127), did not bind, indicating that the calponin-binding site(s) resides within residues 142-227 of tropomyosin. To determine the involvement in calponin binding of the area around Cys-190 of tropomyosin, fragments with cleavage sites near or at Cys-190 were used. Thus, while fragments Cy2(190-284) and CSM-beta(1/8/12-200) bound weakly to the calponin-affinity column, fragment Cy1(1-189) did not. These results demonstrate that calponin binds to tropomyosin between residues 142 and 227, and that the integrity of the region around Cys-190 of tropomyosin is important for strong interaction between the two proteins.     

Affinity and structure of complexes of tropomyosin and caldesmon domains.

The interaction of caldesmon domains with tropomyosin has been studied using x-ray crystallography and an optical biosensor. Only whole caldesmon and the carboxyl-terminal domain of caldesmon (CaD-4, chicken gizzard residues 597-756) bound to tropomyosin with greater than millimolar affinity at 100 and 150 microM salt. Under these conditions the affinities of whole caldesmon and CaD-4 were both in the micromolar range. Data from the x-ray studies showed that whole caldesmon bound to tropomyosin in several places, with the region of tightest interaction being at tropomyosin residues 70-100 and/or 230-260. Studies with CaD-4 revealed that this region corresponded to the strong binding site seen with whole caldesmon. Weaker association of other regions of caldesmon to tropomyosin residues 180-210 and 5-50 was also observed. The results suggest that the carboxyl-terminus of caldesmon binds tightly to tropomyosin and that other regions of caldesmon may interact with tropomyosin tightly only when they are held close to tropomyosin by the carboxyl-terminal domain. Four models are presented to show the possible interactions of caldesmon with tropomyosin.     

Caldesmon, calmodulin and tropomyosin interactions

Binary complex interactions between caldesmon and tropomyosin, and calmodulin and tropomyosin, and ternary complex interaction involving the three proteins were studied using viscosity, electron microscopy, fluorescence and affinity chromatography techniques. In 10 mM NaCl, caldesmon decreased the viscosity of chicken gizzard tropomyosin by 7-8 fold with a concomitant increase in turbidity (A330nm). Electron micrographs showed spindle-shaped particles in the tropomyosin-caldesmon samples. These results suggest side-by-side aggregation of tropomyosin polymers induced by caldesmon. Binding studies in 10 mM NaCl between caldesmon and chicken gizzard tropomyosin labelled with the fluorescent probe N-(1-anilinonaphthyl-4)maleimide (ANM) gave association constants from 5.3.10(6) to 7.9.10(6) M-1 and stoichiometry from 1.0 to 1.4 tropomyosin per caldesmon. Similar binding was observed for rabbit cardiac tropomyosin and caldesmon. Removal of 18 and 11 residues from the COOH ends of the gizzard and cardiac tropomyosin by carboxypeptidase A, respectively, had no significant effect on their binding to caldesmon. In the presence of Ca2+, chicken gizzard tropomyosin bound to a calmodulin-Sepharose-4B column and was eluted with a salt concentration of 140 mM. This interaction was weakened in the absence of Ca2+, and the bound tropomyosin was eluted by 65 mM KCl. ANM-labelled tropomyosin bound calmodulin in the presence of Ca2+ with a binding constant of 3.5.10(6) M-1 and a binding stoichiometry of 1 to 1.4 tropomyosin per calmodulin. In 10 mM NaCl, calmodulin reduced the specific viscosity of chicken gizzard tropomyosin in the presence of Ca2+ by 5 fold, while a 1.5-fold reduction in viscosity was observed in the absence of Ca2+. In either case, no significant increase in turbidity was observed suggesting that calmodulin reduced head-to-tail polymerization of tropomyosin. The interaction of caldesmon with the calmodulin-ANM-tropomyosin complex in the presence and absence of Ca2+ was also examined. The result is consistent with a model that in the absence of Ca2+, calmodulin binds weakly to either caldesmon or tropomyosin and has little effect on the tropomyosin-caldesmon interaction; whereas, Ca2(+)-calmodulin interacts with caldesmon and reduces its affinity to tropomyosin.     

Vascular smooth muscle caldesmon

Caldesmon, a major actin- and calmodulin-binding protein, has been identified in diverse bovine tissues, including smooth and striated muscles and various nonmuscle tissues, by denaturing polyacrylamide gel electrophoresis of tissue homogenates and immunoblotting using rabbit anti-chicken gizzard caldesmon. Caldesmon was purified from vascular smooth muscle (bovine aorta) by heat treatment of a tissue homogenate, ion-exchange chromatography, and affinity chromatography on a column of immobilized calmodulin. The isolated protein shared many properties in common with chicken gizzard caldesmon: immunological cross-reactivity, Ca2+-dependent interaction with calmodulin, Ca2+-independent interaction with F-actin, competition between actin and calmodulin for caldesmon binding only in the presence of Ca2+, and inhibition of the actin-activated Mg2+-ATPase activity of smooth muscle myosin without affecting the phosphorylation state of myosin. Maximal binding of aorta caldesmon to actin occurred at 1 mol of caldesmon: 9-10 mol of actin, and binding was unaffected by tropomyosin. Half-maximal inhibition of the actin-activated myosin Mg2+-ATPase occurred at approximately 1 mol of caldesmon: 12 mol of actin. This inhibition was also unaffected by tropomyosin. Caldesmon had no effect on the Mg2+-ATPase activity of smooth muscle myosin in the absence of actin. Bovine aorta and chicken gizzard caldesmons differed in several respects: Mr (149,000 for bovine aorta caldesmon and 141,000 for chicken gizzard caldesmon), extinction coefficient (E1%280nm = 19.5 and 5.0 for bovine aorta and chicken gizzard caldesmon, respectively), amino acid composition, and one-dimensional peptide maps obtained by limited chymotryptic and Staphylococcus aureus V8 protease digestion. In a competitive enzyme-linked immunosorbent assay, using anti-chicken gizzard caldesmon, a 174-fold molar excess of bovine aorta caldesmon relative to chicken gizzard caldesmon was required for half-maximal inhibition. These studies establish the widespread tissue and species distribution of caldesmon and indicate that vascular smooth muscle caldesmon exhibits physicochemical differences yet structural and functional similarities to caldesmon isolated from chicken gizzard.     

Blockage of AMV reverse transcriptase by antisense oligodeoxynucleotides.

Wild type chicken gizzard caldesmon (756 amino acids) was expressed in a T7 RNA polymerase-based bacterial expression system at a yield of 1 mg pure caldesmon per litre bacterial culture. A mutant composed of amino acids 1-578 was also constructed and expressed. The wild type and mutant caldesmon were purified and compared with native chicken gizzard caldesmon. Native and wild type expressed caldesmon were indistinguishable in assays for inhibition of actin-tropomyosin activation of myosin ATPase, reversal of inhibition by Ca²⁺-calmodulin and binding to actin, actin-tropomyosin, Ca²⁺-calmodulin, tropomyosin and myosin. The mutant missing the C-terminal 178 amino acids had no inhibitory effect and did not bind to actin or Ca²⁺-calmodulin. It bound to tropomyosin with a 5-fold reduced affinity and to myosin with a greater than 10-fold reduced affinity.     

The functional properties of full length and mutant chicken gizzard smooth muscle caldesmon expressed in Escherichia coli

Wild type chicken gizzard caldesmon (756 amino acids) was expressed in a T7 RNA polymerase-based bacterial expression system at a yield of 1 mg pure caldesmon per litre bacterial culture. A mutant composed of amino acids 1-578 was also constructed and expressed. The wild type and mutant caldesmon were purified and compared with native chicken gizzard caldesmon. Native and wild type expressed caldesmon were indistinguishable in assays for inhibition of actin-tropomyosin activation of myosin ATPase, reversal of inhibition by Ca²⁺-calmodulin and binding to actin, actin-tropomyosin, Ca²⁺-calmodulin, tropomyosin and myosin. The mutant missing the C-terminal 178 amino acids had no inhibitory effect and did not bind to actin or Ca²⁺-calmodulin. It bound to tropomyosin with a 5-fold reduced affinity and to myosin with a greater than 10-fold reduced affinity.     

Characterization of the carboxyl-terminal 10-kDa cyanogen bromide fragment of caldesmon as an actin-calmodulin-binding region

A pair of 10-kDa peptides, designated CB-a and CB-b, was isolated by calmodulin-Sepharose chromatography from a total CNBr digest of turkey gizzard caldesmon. CB-a encompasses the COOH-terminal segment of residues 659-756, according to the sequence of adult chicken gizzard caldesmon (Bryan, J., Imai, M., Lee, R., Moore, P., Cook, R.G., and Lin, W.G. (1989) J. Biol. Chem. 264, 13873-13879), whereas CB-b comprises the same structure but was a few amino acids shorter at its COOH terminus. Both peptides cosedimented with F-actin, and their binding was increased by smooth muscle tropomyosin. The Kd values were 1.3 and 0.5 microM, in the absence and presence of tropomyosin, respectively, with a maximum binding capacity of 6.9 actins/mol of peptides. The CB-a/CB-b fragments inhibited, in a tropomyosin-sensitive and Ca2(+)-calmodulin-dependent manner, the skeletal actomyosin subfragment 1 ATPase activity to a level close but not identical to that observed for the parent caldesmon. Ca2(+)-calmodulin was selectively cross-linked to either caldesmon or the CNBr peptides with 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide producing 1:1 covalent complexes that were retained neither by phenyl-Sepharose nor by immobilized calmodulin. Moreover, the cross-linked caldesmon bound weakly to F-actin and did not inhibit the actomyosin subfragment 1 ATPase in the absence of Ca2+. The results suggest that the CB-a/CB-b peptide region contains major regulatory determinants of caldesmon.     

Phosphorylation of smooth muscle caldesmon by mitogen-activated protein (MAP) kinase and expression of MAP kinase in differentiated smooth muscle cells.

Smooth muscle caldesmon was phosphorylated in vitro by sea star p44mpk up to 2.0 mol of phosphate/mol of protein at both Ser and Thr residues. The phosphorylation sites were contained mainly in the COOH-terminal 10-kDa cyanogen bromide fragment which houses the binding sites for calmodulin, tropomyosin, and F-actin. Tryptic peptide maps of 32P-labeled caldesmon by p44mpk and p34cdc2 showed that while both enzymes recognized similar sites of phosphorylation, they have different preferred sites. Phosphorylation of caldesmon attenuated slightly its interaction with actin and had no effect on its binding to calmodulin and tropomyosin. Smooth muscle cell extracts from chicken gizzard and rat aorta contained 42- and 44-kDa proteins, respectively, which were cross-reactive with an antibody to sea star p44mpk. Immunoprecipitates from gizzard and aorta cell extracts, generated with the p44mpk antibody, possessed kinase activities toward myelin basic protein as well as caldesmon. These results suggest that MAP kinase may have functions in the differentiated smooth muscle cells distinct from those involved in the cell cycle.     

Evidence for interaction between smooth muscle tropomyosin and caldesmon

The viscosity of chicken gizzard smooth muscle tropomyosin is enhanced 4.7-fold in the absence of salt and 1.43-fold in 0.1 M salt by the presence of stoichiometric amounts of gizzard caldesmon, indicating that the two proteins interact under these conditions. Since the thin filament regulation of smooth muscle contraction by caldesmon requires the presence of tropomyosin, these results suggest that the direct interaction between tropomyosin and caldesmon on the thin filament plays a role in this regulation.     

Amino acid sequence of chicken gizzard gamma-tropomyosin

Chicken gizzard muscle tropomyosin has been fractionated into its two major components, beta and gamma and the amino acid sequence of the gamma component established by the isolation and sequence analysis of fragments derived from cyanogen bromide cleavage and tryptic digestions. Despite its much slower mobility on sodium dodecyl sulfate-polyacrylamide electrophoretic gels, it has the same polypeptide chain length (284 residues) as the alpha and beta components of rabbit skeletal muscle. Evidence for microheterogeneity of the chicken gizzard component was detected both on electrophoretic gels and in the sequence analysis. The gamma component is more closely related to rabbit skeletal alpha-tropomyosin than to the beta component. While the protein is highly homologous to the rabbit skeletal tropomyosins, significant sequence differences are observed in two regions; between residues 42-83 and 258-284. In the latter region (COOH-terminal) the alterations in sequence are very similar to those seen in platelet tropomyosin when compared with the skeletal proteins.     

Amino acid sequence of chicken gizzard beta-tropomyosin. Comparison of the chicken gizzard, rabbit skeletal, and equine platelet tropomyosins

Chicken gizzard beta-tropomyosin has the same chain length (284 residues) as other muscle tropomyosins, and is most closely related to the beta component of rabbit skeletal muscle. The majority of the amino acid substitutions are restricted to two regions of the structure, residues 185-216 and 258-284. The altered sequences at the COOH-terminal ends (residue 258-284) of the two gizzard components are very similar to each other and to those in platelet tropomyosin and can be correlated with the reduced affinity of interaction of all three tropomyosins with skeletal troponin T and its T1 fragment. The virtually identical NH2-terminal sequences of all four muscle tropomyosin chains indicates that the gizzard proteins' greater ability to polymerize head-to-tail is due to the sequence changes at its COOH terminus. On the other hand, the weaker head-to-tail aggregation of the platelet protein must be due to its NH2-terminal sequence alterations. Examination of the distribution of amino acids and the frequency of their substitution in the a to g positions of the repeating pseudoheptapeptide for all five tropomyosin sequences (four muscle and one platelet) emphasizes the importance of Glu residues at position e. Examination of those features of the muscle sequences implicated in the stabilization of their coiled-coil structures and in their interactions with F-actin suggest only marginal differences among them, with the possible exception of the chicken gizzard gamma component.     

Interaction between chicken gizzard caldesmon and tropomyosin

Chicken gizzard muscle caldesmon has been examined for ability to interact with tropomyosin from chicken gizzard muscle by using fluorescence enhancement of tropomyosin labeled with dansyl chloride (DNS) and affinity chromatography. The binding of caldesmon to tropomyosin was regulated by Ca2+ and calmodulin, i.e., at low ionic strength most of the caldesmon bound to tropomyosin-Sepharose 4B was co-eluted by adding calmodulin only in the presence of Ca2+, but not in its absence. This regulation by Ca2+ and calmodulin was also suggested by fluorescence measurements. Actin- and calmodulin-binding sites on the caldesmon molecule were located in the 38K fragment (Fujii, T., Imai, M., Rosenfeld, G.C., & Bryan, J. (1987) J. Biol. Chem. 262, 2757-2763). When 38K-enriched fraction was applied to the tropomyosin-Sepharose, the 38K fragment was retained by the column and could be eluted by adding Ca2+ and calmodulin.     

Cloning and expression of a smooth muscle caldesmon

Caldesmon is a smooth muscle and nonmuscle regulatory protein that interacts with actin, myosin, tropomyosin, and calmodulin. Two overlapping clones, isolated from a chicken oviduct cDNA plasmid library and a chicken gizzard cDNA lambda NM1149 library, were used to generate a 4108-base pair sequence coding for one caldesmon. Expression of the coding sequence confirms this is one of the large smooth muscle caldesmons. The deduced protein molecular weight is 86.974, significantly less than the molecular weights estimated by sodium dodecyl sulfate gel electrophoresis. The protein has a high content of Gly, Lys, Arg, and Ala; there are two cysteine residues, one at either end of the molecule. Comparison with the Protein Identification Resource database demonstrates a similarity with a tropomyosin binding domain of troponin T, but none with any calmodulin or actin binding proteins. The center of the protein has an 8-fold repeat of a 13 amino acid sequence whose general motif is -Glu3-(Lys/Arg)2-Ala2-Glu2-(Lys/Arg)1-X-(Lys/Arg)1-Ala1-, where X is Glu, Gln, or Ala. Comparison with peptide sequences from a chymotryptic fragment that binds actin and calmodulin places this domain on the C terminus of caldesmon adjacent to the troponin T similarity. A tentative map of the major binding domains is proposed on the basis of available data.     

Effect of the C-terminal actin-binding sites of caldesmon on the interaction of actin with myosin

TRITC-phalloidin or FITC-labeled F-actin of ghost muscle fibers was bound to tropomyosin and C-terminal recombinant fragments of caldesmon CaDH1 (residues 506-793) or CaDH2 (residues 683-767). After that the fibers were decorated with myosin subfragment 1. In the absence of caldesmon fragments, subfragment 1 interaction with F-actin caused changes in parameters of polarized fluorescence, that were typical of "strong" binding of myosin heads to F-actin and of the "switched on" conformational state of actin. CaDH1 inhibited, whereas CaDH2 activated the effect of subfragment 1. It is suggested that C-terminal part of caldesmon may modulate the transition of F-actin subunits from the "switched on" to the "switched off" state.     

Immunochemical evidence for the binding of caldesmon to the NH2-terminal segment of actin

The binding of caldesmon and its actin-binding fragments to actin was studied by using peptide antibodies directed against two actin sites implicated in actomyosin interactions. Antibodies against residues 1-7 on skeletal alpha-actin strongly inhibited the binding of caldesmon to actin and perturbed to a smaller extent the interaction between actin and the actin binding fragments. Carbodiimide coupling of ethylenediamine to the NH2-terminal acidic residues on actin inhibited the binding of caldesmon and its fragments to actin to a similar extent as the (residues 1-7) antibodies. Antibodies against residues 18-28 showed only limited competition with caldesmon for the binding to actin. These results lead to the following conclusions. (i) The NH2-terminal residues on actin play an important role in the binding of caldesmon to actin, (ii) residues 18-28 on actin do not form a major caldesmon interaction site, and (iii) the actin-binding fragments do not contain the full actin-binding interface. These conclusions and other literature data suggest that caldesmon regulates the actomyosin ATPase by competing with myosin.ATP for the NH2-terminal segment on actin.     

Amino acid sequence studies on cyanogen bromide peptides of chicken caldesmon which bind to calmodulin

Three major calmodulin-binding cyanogen bromide peptides (fragments A, B, and D) were isolated from chicken gizzard muscle caldesmon and their amino acid sequences were determined. The molecular masses of fragments A, B, and D were estimated to 16, 12, and 9 kDa, respectively, by SDS-urea polyacrylamide gel electrophoresis. Fragment A was composed of 102 amino acid residues and contained homoserine at the C terminus. The amino acid sequence from the 37th residue of fragment A corresponds to the N-terminal sequence of the 15 kDa peptide which was obtained by thrombin digestion [Mornet, D., Audemard, E., & Derancourt, J. (1988) Biochem. Biophys. Res. Commun. 154, 564-571]. Thrombin 15 kDa peptide binds to F-actin but does not bind to calmodulin. Thus the N-terminal 36 residues and the C-terminal part from the 37th residue of fragment A are supposed to bind to calmodulin and F-actin, respectively. The sequences of fragments B and D were identical, but fragment D was composed of 64 amino acid residues and ended with tryptophan, whereas fragment B was of 98 or 99 amino acid residues and ended with proline. Both fragments B and D are supposed to be the C-terminal peptides of chicken caldesmon. Fragment B had heterogeneous sequences at the C-terminal region. These results can explain the reported heterogeneity of chicken caldesmon in charge and molecular mass.     

The interface between caldesmon domain 4b and subdomain 1 of actin studied by nuclear magnetic resonance spectroscopy

The ability of caldesmon to inhibit actomyosin ATPase activity involves the interaction of three nonsequential segments of caldesmon domain 4 (amino acids 600-756) with actin. Two of these contacts are located in the C-terminal half of this region of caldesmon which has been designated domain 4b (658-756). To investigate the spatial relationship between the two sites and to determine whether their corresponding contacts on actin are sequentially distinct, we have used NMR spectroscopy to compare the actin binding properties of the minimal inhibitory peptide LW30 comprising residues 693-722 with those of the recombinant domain 4b constructs 658C (658-756) and Cg1 (a mutant of 658C in which the sequence (691)Glu-Trp-Leu-Thr-Lys-Thr(696) is changed to Pro-Gly-His-Tyr-Asn-Asn). Cg1 retains dual-sited actin attachment but displays lowered actin affinity. In the presence of tropomyosin, domain 4b-actin contacts were stronger but not qualitatively different, indicating that tropomyosin affected the conformational equilibrium of caldesmon binding. Simultaneous dual-sited attachment of domain 4b to actin is enabled by the conformational properties of the site-spanning sequence common to 658C, Cg1, and LW30 as reflected in the corresponding NOE and other NMR spectral parameters. A backbone turn region ((713)Gly-Asp-Val-Ser(716)) preceded by an extended segment (Ser(702)-Pro-Ala-Pro-Lys-Pro) acts to constrain the relative disposition of the flanking actin contact sites of domain 4b. In tests with a library of actin peptides, only the C-terminus, 350-375, bound to 658C and LW30. The use of Cu(2+) as a paramagnetic spectral probe bound to the unique His-371 provided evidence of a well-defined geometry for the complex between LW30 and actin residues 350-375 with the N-terminal, site B of domain 4b close to the C-terminal residues of actin. The data are discussed in the context of the potentiation of inhibitory activity by tropomyosin.     

Photocrosslinking of calmodulin and/or actin to chicken gizzard caldesmon

The two sulfhydryl groups of chicken gizzard caldesmon were specifically labeled with a photoreactive crosslinker, benzophenone-maleimide, to study its interactions with calmodulin and/or actin. When incubated with F-actin caldesmon crosslinks to a single actin monomer; it can, however, crosslink to up to two calmodulin molecules in the presence, but not in the absence, of Ca2+. Thus caldesmon may have two calmodulin-binding sites, each containing, or being near, one of the two thiol residues. One of these two sites may also be adjacent to the actin-binding site. A calmodulin-binding fragment of caldesmon resulting from cyanogen bromide digestion crosslinks to a single calmodulin molecule, also in a Ca2+-dependent manner. Crosslinking of calmodulin to caldesmon does not prevent the latter from binding F-actin, suggesting that calmodulin and actin do not compete with each other for the same binding site(s) on the caldesmon molecule.     

Properties of carboxypeptidase A-treated chicken gizzard tropomyosin

Chicken gizzard tropomyosin was digested with carboxypeptidase A at the weight ratios of enzyme to substrate 1:200 and 1:50. Removal of about 16 C-terminal amino acid residues per tropomyosin molecule, at lower enzyme concentration, caused reversion of the effect on skeletal actomyosin ATPase activity from activating to inhibiting without an influence on polymerizability and actin-binding ability. Removal of about 26 C-terminal amino acid residues per molecule, at higher enzyme concentration, resulted in loss of polymerizability and actin binding ability. Digestion of gizzard tropomyosin with carboxypeptidase A has no dramatic effect on its binding to troponin T. The results show that not only the existence of head-to-tail overlapping regions but also their length is important for the functional properties of chicken gizzard tropomyosin.     

Identification of the site phosphorylated by casein kinase II in smooth muscle caldesmon

Phosphorylation of avian gizzard caldesmon by casein kinase II was investigated. The enzyme incorporates about 1 mol of phosphate per mol of caldesmon. All sites of phosphorylation are located in short chymotryptic peptides with Mr 25-27 kDa or in the short N-terminal peptide formed after cleavage of chicken gizzard caldesmon at Cys153. The primary structure of the tryptic peptide containing the main site of duck gizzard caldesmon phosphorylation is S-E-V-N-A-Q-N-X-V-A-E-D-E-T-K, where X is an unidentified residue, presumed to be phosphoserine. Thus, Ser73 is the main site phosphorylated by casein kinase II in avian gizzard caldesmon.