Effect of caldesmon on the ATPase activity and the binding of smooth and skeletal myosin subfragments to actin

We have previously shown that inhibition of the ATPase activity of skeletal muscle myosin subfragment 1 (S1) by caldesmon is correlated with the inhibition of S1 binding in the presence of ATP or pyrophosphate (Chalovich, J., Cornelius, P., and Benson, C. (1987) J. Biol Chem. 262, 5711-5716). In contrast, Lash et al. (Lash, J., Sellers, J., and Hathaway, D. (1986) J. Biol. Chem. 261, 16155-16160) have shown that the inhibition of ATPase activity of smooth muscle heavy meromyosin (HMM) by caldesmon is correlated with an increase in the binding of HMM to actin in the presence of ATP. We now show, in agreement, that caldesmon does increase the binding of smooth muscle HMM to actin-tropomyosin while decreasing the ATPase activity. The effect of caldesmon on the binding of smooth HMM is reversed by Ca2+-calmodulin. Caldesmon strengthens the binding of smooth S1.ATP and skeletal HMM.ATP to actin-tropomyosin but to a lesser extent than smooth HMM.ATP. Furthermore, this increase in binding of smooth S1.ATP and skeletal HMM.ATP does not parallel the inhibition of ATPase activity. In contrast, in the absence of ATP, all smooth and skeletal myosin subfragments compete with caldesmon for binding to actin. Thus, the effect that caldesmon has on the binding of myosin subfragments to actin-tropomyosin depends on the source of myosin, the type of subfragment, and the nucleotide present. The inhibition of actin-activated ATP hydrolysis by caldesmon, however, is not greatly different for different smooth and skeletal myosin subfragments. Evidence is presented that caldesmon inhibits actin-activated ATP hydrolysis by attenuating the productive interaction between myosin and actin that normally accelerates ATP hydrolysis. The increased binding seen by some myosin subfragments, in the presence of ATP, may be due to binding of these subfragments to a nonproductive site on actin-caldesmon. The subfragments which show an increase in binding in the presence of ATP and caldesmon appear to bind directly to caldesmon as demonstrated by affinity chromatography.     

Characterization of caldesmon binding to myosin

Caldesmon inhibits the binding of skeletal muscle subfragment-1 (S-1).ATP to actin but enhances the binding of smooth muscle heavy meromyosin (HMM).ATP to actin. This effect results from the direct binding of caldesmon to myosin in the order of affinity: smooth muscle HMM greater than skeletal muscle HMM greater than smooth muscle S-1 greater than skeletal muscle S-1 (Hemric, M. E., and Chalovich, J. M. (1988) J. Biol. Chem. 263, 1878-1885). We now show that the difference between skeletal muscle HMM and S-1 is due to the presence of the S-2 region in HMM and is unrelated to light chain composition or to two-headed versus single-headed binding. Differences between the binding of smooth and skeletal muscle myosin subfragments to actin do not result from the lack of light chain 2 in skeletal muscle S-1. In the presence of ATP, caldesmon binds to smooth muscle myosin filaments with a stoichiometry of 1:1 (K = 1 x 10(6) M-1). Similar results were obtained for the binding of caldesmon to smooth muscle rod as well as the binding of the purified myosin-binding fragment of caldesmon to smooth muscle myosin. The binding of caldesmon to intact myosin is ATP sensitive. The interaction of caldesmon with myosin is apparently specific and sensitive to the structure of both proteins.     

Actin-caldesmon-myosin-subfragment-1 ternary complex viewed by electron microscopy. Competitive actin binding region for caldesmon and myosin subfragment-1

An earlier electron microscopic study using different caldesmon forms complexed with actin revealed that the aggregates produced display regular periodic striation after antibody labeling of the 35-kDa caldesmon fragment. This approach provides further evidence that a caldesmon fragment, even as small as 15 kDa, can induce actin filaments to assemble into bundles. The observed difference in the compactness of these structures, depending on the use of the 15-kDa fragment instead of the 35-kDa fragment, suggests the existence of more than one actin-binding site in the caldesmon molecule. In this study, the caldesmon-induced process of F-actin association was investigated in the presence of skeletal myosin subfragment-1, using light-scattering methods, cosedimentation experiment and electron microscopic techniques. We show that the actin-caldesmon association is partially destabilized in the presence of subfragment-1 and this leads to a ternary complex formation. Immunogold labelling of the actin filaments still reveals the presence of caldesmon within this structure. This latter result strengthens the hypothesis that actin has a site(s) able to bind both caldesmon and myosin subfragment-1, as detected by recent NMR observations. This evidence is discussed with respect to the regulatory function of caldesmon during smooth muscle contraction.     

Dissociation of the effect of caldesmon on the ATPase activity and on the binding of smooth heavy meromyosin to actin by partial digestion of caldesmon

We have proposed earlier that caldesmon inhibits the actin-activated ATPase activity of smooth muscle heavy meromyosin (HMM) by inhibiting the binding of the HMM.ATP complex to the productive site of actin (Hemric, M. E., and Chalovich, J. M. (1988) J. Biol. Chem. 263, 1868-1885). This has been difficult to prove directly because caldesmon also binds to HMM and it is difficult to distinguish the actin-caldesmon-HMM complex from the actin-caldesmon complex in binding studies. We have eliminated the interaction between caldesmon and smooth HMM by digestion of caldesmon with chymotrypsin. This cleaved caldesmon inhibits the actin-activated ATPase rate of smooth HMM and this inhibition is correlated with a decrease in the binding of HMM.ATP to actin. Therefore, caldesmon functions by inhibiting the binding of the myosin-ATP complex to actin regardless of the source of myosin. We have also isolated the myosin-binding region of caldesmon and have performed a partial sequence. Comparison of this sequence with the derived sequence of caldesmon demonstrates, unequivocally, that the myosin-binding region of caldesmon begins at the amino terminus and extends beyond the first Cys residue.     

A mosaic multiple-binding model for the binding of caldesmon and myosin subfragment-1 to actin.

Binding of caldesmon to actin causes a decrease in the quantity of bound myosin and results in a reduction in the rate of actin-activated adenosine triphosphate hydrolysis. It is generally assumed that the binding of caldesmon and myosin to actin is a pure competitive interaction. However, recent binding studies of enzyme digested caldesmon subfragments directed at mapping the actin binding site of caldesmon have shown that a small 8-kD fragment around the COOH-terminal can compete directly with the myosin subfragment 1 (S-1) binding to actin; at least one other fragment that binds to actin does not inhibit the actin-activated adenosine triphosphate activity of myosin. That is, only a part of the caldesmon sequence may be responsible for directly blocking the binding of S-1 to actin. This prompts us to question the actual mode of binding of intact caldesmon and myosin S-1 to actin: whether the entire intact caldesmon molecule is competing with S-1 binding (pure competitive model) or just a small part of it (mosaic multiple-binding model). To answer this question, we measured the amount of myosin S-1 and caldesmon bound per actin monomer as a function of the total concentration of S-1 added to the system at constant concentrations of actin and caldesmon. A formalism for calculating the titration data based on the pure competitive model and a mosaic multiple-binding model was then developed. When compared with theoretical calculations, it is found that the binding of caldesmon and S-1 to actin cannot be pure competitive if no cooperativity exists between S-1 and caldesmon.(ABSTRACT TRUNCATED AT 250 WORDS)     

Caldesmon reduces the apparent rate of binding of myosin S1 to actin-tropomyosin

Equilibrium measurements of the rate of binding of caldesmon and myosin S1 to actin-tropomyosin from different laboratories have yielded different results and have led to different models of caldesmon function. An alternate approach to answering these questions is to study the kinetics of binding of both caldesmon and S1 to actin. We observed that caldesmon decreased the rate of binding of S1 to actin in a concentration-dependent manner. The inhibition of the rate of S1 binding was enhanced by tropomyosin, but the effect of tropomyosin on the binding was small. Premixing actin with S1 reduced the amplitude (extent) of caldesmon binding in proportion to the fraction of actin that contained bound S1, but the rate of binding of caldesmon to free sites was not greatly altered. No evidence for a stable caldesmon-actin-tropomyosin-S1 complex was observed, although S1 did apparently bind to gaps between caldesmon molecules. These results indicate that experiments involving caldesmon, actin, tropomyosin, and myosin are inherently complex. When the concentration of either S1 or caldesmon is varied, the amount of the other component bound to actin-tropomyosin cannot be assumed to remain fixed. The results are not readily explained by a mechanism in which caldesmon acts only by stabilizing an inactive state of actin-tropomyosin. The results support regulatory mechanisms that involve changes in the actin-S1 interaction.     

Disulfide cross-linking of caldesmon to actin.

Treatment of a solution of actin and smooth muscle caldesmon with 5,5'-dithiobis(2-nitrobenzoic acid) results in the formation of a disulfide cross-link between the C-terminal penultimate residue Cys-374 of actin and Cys-580 in caldesmon's C-terminal actin-binding region. Therefore, these 2 residues are close in the actin-caldesmon complex. Since myosin also binds to actin in the vicinity of Cys-374 and since caldesmon inhibits actomyosin ATPase activity by the reduction of myosin binding to actin, then the inhibition might be by caldesmon sterically hindering or blocking myosin's interaction with actin. [Ca2+]Calmodulin, which reverses the inhibition of the ATPase activity, decreases the yield of the cross-linked species, suggesting a weakening of the caldesmon-actin interaction in the cross-linked region. It is possible to maximally cross-link one caldesmon molecule/every three actin monomers, in the absence or presence of tropomyosin, clearly ruling out an elongated, end-to-end alignment of caldesmon on the actin filament in vitro, and raising the possibility that the N-terminal part of caldesmon projects out from the filament. Reaction of 5,5'-dithiobis(2-nitrobenzoic acid)-modified actin with caldesmon leads to the same disulfide cross-linked product between actin and caldesmon Cys-580, enabling the specific labeling of the other caldesmon cysteine, residue 153, in the N-terminal part of caldesmon with a spectroscopic probe.     

Characterization of a caldesmon fragment that competes with myosin-ATP binding to actin.

The protein caldesmon inhibits actin-activated ATP hydrolysis of myosin and inhibits the binding of myosin.ATP to actin. A fragment isolated from a chymotryptic digest of caldesmon contains features of the intact molecule that make it useful as a selective inhibitor of the binding of myosin.ATP complexes to actin without having the complexity of binding to myosin. The COOH-terminal 20 kDa region of caldesmon binds to actin with one-sixth the affinity of caldesmon with a stoichiometry of binding of one fragment per two actin monomers. This contrasts with the 1:6-9 stoichiometry of intact caldesmon. The binding of the 20 kDa fragments to actin is totally reversed by Ca(2+)-calmodulin and, like intact caldesmon, the 20 kDa fragments are competitive with the binding of myosin subfragments to actin. This competition with myosin binding is largely responsible for the inhibition of ATP hydrolysis, although both the fragments and intact caldesmon also reverse the potentiation of ATPase activity caused by tropomyosin. These polypeptides are useful both in defining the function of caldesmon and in studying the role of weakly bound cross-bridges in muscle.     

The binding of caldesmon to actin and its effect on the ATPase activity of soluble myosin subfragments in the presence and absence of tropomyosin

The binding of 125I- and 14C-caldesmon to actin and actin-tropomyosin was studied using a cosedimentation technique and was analyzed by the method of McGhee and von Hippel [1974) J. Mol. Biol. 86, 469-489) for the binding of large ligands to a homogeneous lattice. The binding was adequately described by a single class of binding sites with a stoichiometry between 1:7 and 1:10. The binding exhibited a small degree of positive cooperativity (omega = 5-6) which was the same in the presence and absence of tropomyosin. The association constant for the binding of caldesmon to an isolated binding site was enhanced, from about 6 X 10(5) to about 1.4 X 10(6) M-1, by the presence of smooth muscle tropomyosin. Caldesmon inhibited the actin-activated ATPase activity of skeletal myosin subfragment 1 in both the absence and presence of tropomyosin. Maximum inhibition of ATPase activity occurred when one caldesmon molecule bound to seven actin monomers. A greater degree of inhibition was observed in the presence of tropomyosin than in the absence. This greater inhibition cannot be explained totally by the increased strength of binding of caldesmon to actin in the presence of tropomyosin. Finally, Ca2+-calmodulin completely reversed the binding of caldesmon to actin.     

Binding of caldesmon to smooth muscle myosin

Caldesmon, a major calmodulin binding protein, was found to bind smooth muscle myosin. Addition of caldesmon to smooth muscle myosin induced the formation of small aggregates of myosin in the absence of Ca2+-calmodulin, but not in the presence of Ca2+-calmodulin. The binding site of myosin was studied by using caldesmon-Sepharose 4B affinity chromatography. Subfragment 1 was not retained by the column, while heavy meromyosin and subfragment 2 were bound to the caldesmon affinity column in the absence of Ca2+-calmodulin but not in its presence. It was therefore concluded that the binding site of caldesmon on myosin molecule was the subfragment 2 region and that binding of caldesmon to myosin was abolished in the presence of Ca2+ and calmodulin. Cross-linking of actin and myosin mediated by caldesmon was studied. While actomyosin was completely dissociated in the presence of Mg2+-ATP, the addition of caldesmon caused aggregation of the actomyosin. By low speed centrifugation at which actomyosin alone was not precipitated in the presence of Mg2+-ATP, the aggregate induced by caldesmon was precipitated and the composition of the precipitate was found to be actin, caldesmon, and myosin. In the presence of Mg2+-ATP, pure actin did not bind to a myosin-Sepharose 4B affinity column, while all of the actin was retained when the actin/caldesmon mixture was applied to the column. These results indicate that caldesmon can cross-link actin and myosin.     

Influence of ionic strength,actin state,and caldesmon construct size on the number of actin monomers in a caldesmon binding site

There is no consensus on the mechanism of inhibition of actin-myosin ATPase activity by caldesmon. Various models are based on different assumptions for the number of actin monomers that constitute a caldesmon binding site. Differences in binding behavior may be due to variations in the assay, the range of caldesmon concentrations, the type of caldesmon, and the method of data analysis used. We have evaluated these factors by measuring binding in the presence and absence of tropomyosin with both intact caldesmon and a recombinant 35 kDa actin binding fragment and with actin initially in the polymerized state or monomeric state. In all cases caldesmon binding could be simulated with a model having one class of binding sites. However, the number of actin monomers constituting a site was variable. Binding to F-actin at 165 mM ionic strength was best described with 7 actin monomers per site. When caldesmon bound to actin during the polymerization of G-actin, the size of the binding site was 3. Binding of the expressed truncated fragment, Cad35, could be described with 3 monomers per site. A simple interpretation of the data is that caldesmon binds tightly to 2-3 actin monomers. Additional parts of caldesmon bind less tightly to actin, causing caldesmon to cover approximately 7 actin monomers. The appendix contains an analysis of several binding curves with multiple binding site models. There is no compelling evidence for two classes of binding sites.     

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.     

Phosphorylation of caldesmon by cdc2 kinase

A recent report that mitosis-specific phosphorylation causes the nonmuscle caldesmon to dissociate from microfilaments (Yamashiro, S., Yamakita, Y., Ishikawa, R., and Matsumura, F. (1990) Nature 344, 675-678) suggests that this process may contribute to the major structural reorganization of the eukaryotic cell at mitosis. In this study we have demonstrated that smooth muscle caldesmon is phosphorylated in vitro by cdc2 kinase from mitotic phase HeLa cells to 1.2 mol of phosphate/mol of caldesmon. Tryptic maps showed three major phosphorylated spots and approximately equal amounts of phosphorylated Ser and Thr were identified. F-actin or calmodulin in the presence of Ca2+ blocks the phosphorylation of caldesmon. Phosphorylation of caldesmon greatly reduced its binding to F-actin. The phosphorylation sites were located in a 10,000-Da CnBr fragment at the COOH-terminal end of the caldesmon molecule known to house the binding sites for actin and calmodulin (Bartegi A., Fattoum, A., Derancourt, J., and Kassab, R. (1990) J. Biol. Chem. 265, 15231-15238). Our finding supports the model that phosphorylation of caldesmon by cdc2 kinase at mitosis may contribute to the disassembly of the microfilament bundles during prophase.     

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.     

Effect of caldesmon on the type of conformation changes in F-actin induced by the binding of myosin 1 subfragment

The effect of caldesmon on the conformational changes of F-actin caused by myosin subfragment 1 (S-1) binding was studied, using the polarized microfluorimetry method. It was demonstrated that the polarized fluorescence of rhodaminil-phalloin specifically bound to F-actin of pure actin filaments as well as of tropomyosin-containing actin filaments changes as a result of binding to S-1. The nature of these changes depends on the presence of caldesmon in the filaments. Caldesmon was supposed to modify the conformational changes in F-actin induced by S-1.     

Actomyosin cross-linking by caldesmon in non-muscle cells

The role of myosin-binding in cytoskeletal arrangement of non-muscle low molecular weight caldesmon (l-caldesmon) was studied. The N-terminal myosin-binding domain of caldesmon N152 colocalized with myosin in transiently transfected chicken fibroblasts. When added exogenously to the Triton-insoluble cytoskeleton, N152 enhanced l-caldesmon displacement by exogenous C-terminal actin-binding fragment (H1). Thus, a significant fraction of l-caldesmon cross-links actin and myosin. In contrast, in epithelioid HeLa cells most of l-caldesmon was only actin-bound as H1 alone was enough for its displacement. Phosphorylation by mitogen-activated protein kinase reduced the capability of H1 to displace endogenous l-caldesmon, suggesting it may represent a regulatory mechanism for actin-caldesmon interaction in vivo.     

Interaction of caldesmon and myosin subfragment 1 with the C-terminus of actin.

The interactions of caldesmon and S1 with the C-terminus of actin were examined in co-sedimentation experiments using proteolytically truncated actin. It is shown that removal of 6 residues from the C-terminus of actin reduces the binding of caldesmon by about 50% while improving the binding of S1 to actin. We also show that S1 protects actin's C-terminus from enzymatic cleavage. Both S1 and caldesmon binding to actin are decreased in the presence of an actin C-terminal peptide. These results emphasize the importance of the C-terminus of actin in binding to S1 and caldesmon.     

Modes of caldesmon binding to actin: sites of caldesmon contact and modulation of interactions by phosphorylation

Smooth muscle caldesmon binds actin and inhibits actomyosin ATPase activity. Phosphorylation of caldesmon by extracellular signal-regulated kinase (ERK) reverses this inhibitory effect and weakens actin binding. To better understand this function, we have examined the phosphorylation-dependent contact sites of caldesmon on actin by low dose electron microscopy and three-dimensional reconstruction of actin filaments decorated with a C-terminal fragment, hH32K, of human caldesmon containing the principal actin-binding domains. Helical reconstruction of negatively stained filaments demonstrated that hH32K is located on the inner portion of actin subdomain 1, traversing its upper surface toward the C-terminal segment of actin, and forms a bridge to the neighboring actin monomer of the adjacent long pitch helical strand by connecting to its subdomain 3. Such lateral binding was supported by cross-linking experiments using a mutant isoform, which was capable of cross-linking actin subunits. Upon ERK phosphorylation, however, the mutant no longer cross-linked actin to polymers. Three-dimensional reconstruction of ERK-phosphorylated hH32K indeed indicated loss of the interstrand connectivity. These results, together with fluorescence quenching data, are consistent with a phosphorylation-dependent conformational change that moves the C-terminal end segment of caldesmon near the phosphorylation site but not the upstream region around Cys(595), away from F-actin, thus neutralizing its inhibitory effect on actomyosin interactions. The binding pattern of hH32K suggests a mechanism by which unphosphorylated, but not ERK-phosphorylated, caldesmon could stabilize actin filaments and resist F-actin severing or depolymerization in both smooth muscle and nonmuscle cells.     

Localization and characterization of a 7.3-kDa region of caldesmon which reversibly inhibits actomyosin ATPase activity.

Cleavage of caldesmon with chymotrypsin yields a series of fragments which bind both calmodulin and actin and inhibit the binding of myosin subfragments to actin and the subsequent stimulation of ATPase activity. Several of these fragments have been purified by cation exchange chromatography and their amino-terminal sequences determined. The smallest fragment has a molecular mass of about 7.3 kDa and extends from Leu597 to Phe665. This polypeptide inhibits the actin-activated ATPase of myosin S-1; this inhibition is augmented by smooth muscle tropomyosin and relieved by Ca(2+)-calmodulin. The binding of the 7.3-kDa fragment to actin is competitive with the binding of S-1 to actin. Thus, this polypeptide has several of the important features characteristic of intact caldesmon. However, although an intact caldesmon molecule covers between six and nine actin monomers, the 7.3-kDa fragment binds to actin in a 1:1 complex. Comparison of this fragment with others suggests that a small region of caldesmon is responsible for at least part of the interaction with both calmodulin and actin.     

Caldesmon inhibits skeletal actomyosin subfragment-1 ATPase activity and the binding of myosin subfragment-1 to actin

Smooth muscle contraction is controlled in part by the state of phosphorylation of myosin. A recently discovered actin and calmodulin-binding protein, named caldesmon, may also be involved in regulation of smooth muscle contraction. Caldesmon cross-links actin filaments and also inhibits actin-activated ATP hydrolysis by myosin, particularly in the presence of tropomyosin. We have studied the effect of caldesmon on the rate of hydrolysis of ATP by skeletal muscle myosin subfragment-1, a system in which phosphorylation of the myosin is not important in regulation. Caldesmon is a very effective inhibitor of ATP hydrolysis giving up to 95% inhibition. At low ionic strength (approximately 20 mM) this effect does not require smooth muscle tropomyosin, whereas at high ionic strength (approximately 120 mM) tropomyosin enhances the inhibitory activity of caldesmon at low caldesmon concentrations. Cross-linking of actin is not essential for inhibition of ATP hydrolysis to occur since at high ionic strength there is very little cross-linking as determined by a low speed sedimentation assay. Under all conditions examined, the decrease in the rate of ATP hydrolysis is accompanied by a decrease in the binding of myosin subfragment-1 to actin. Furthermore, caldesmon weakens the equilibrium binding of myosin subfragment-1 to actin in the presence of pyrophosphate. We conclude that caldesmon has a general weakening effect on the binding of skeletal muscle myosin subfragment-1 to actin and that this weakening in binding may be responsible for inhibition of ATP hydrolysis.