Stoichiometry and stability of caldesmon in native thin filaments from sheep aorta smooth muscle.

Ca2(+)-regulated native thin filaments were extracted from sheep aorta smooth muscle. The caldesmon content determined by quantitative gel electrophoresis was 0.06 caldesmon molecule/actin monomer (1 caldesmon molecule per 16.3 actin monomers). Dissociation of caldesmon and tropomyosin from the thin filament and the depolymerization of actin was measured by sedimenting diluted thin filaments. Actin critical concentration was 0.05 microM at 10.1 and 0.13 at 10.05 compared with 0.5 microM for pure F-actin. Tropomyosin was tightly bound, with half-maximal dissociation at less than 0.3 microM thin filaments (actin monomer) under all conditions. Caldesmon dissociation was independent of tropomyosin and not co-operative. The concentration of thin filaments where 50% of the caldesmon was dissociated (CD50) ranged from 0.2 microM (actin monomer) at 10.03 to 8 microM at 10.16 in a 5 mM-MgCl2, pH 7.1, buffer. Mg2+, 25 mM at constant I, increased CD50 4-fold. CD50 was 4-fold greater at 10(-4) M-Ca2+ than at 10(-9) M-Ca2+. Aorta heavy meromyosin (HMM).ADP.Pi complex (2.5 microM excess over thin filaments) strongly antagonized caldesmon dissociation, but skeletal-muscle HMM.ADP.Pi did not. The behaviour of caldesmon in native thin filaments was indistinguishable from caldesmon in reconstituted synthetic thin filaments. The variability of Ca2(+)-sensitivity with conditions observed in thin filament preparations was shown to be related to dissociation of regulatory caldesmon from the thin filament.     

The role of tropomyosin in the interactions of F-actin with caldesmon and actin-binding protein (or filamin)

The interactions of actin filaments with actin-binding protein (filamin) and caldesmon under the influence of tropomyosin were studied in detail using falling-ball viscometry, binding assay and electron microscopy. Caldesmon decreased the binding constant of filamin with F-actin. In contrast, the maximum binding ability of filamin to F-actin was decreased by tropomyosin. The filamin-induced gelation of actin filaments was inhibited by caldesmon. Tropomyosin also inhibited this gelation. The effect of caldesmon became stronger under the influence of tropomyosin. Furthermore, both caldesmon and tropomyosin additionally decreased the filamin binding to F-actin. From these results, caldesmon and tropomyosin appeared to influence filamin binding to F-actin with different modes of actin. In addition, there was no sign of direct interactions between filamin, caldesmon and tropomyosin as judged from gel filtration. Under the influence of caldesmon and tropomyosin, calmodulin conferred Ca2+ sensitivity on the filamin-induced gelation of actin filaments.     

Inhibition of the relative movement of actin and myosin by caldesmon and calponin.

Contractile activity of myosin II in smooth muscle and non-muscle cells requires phosphorylation of myosin by myosin light chain kinase. In addition, these cells have the potential for regulation at the thin filament level by caldesmon and calponin, both of which bind calmodulin. We have investigated this regulation using in vitro motility assays. Caldesmon completely inhibited the movement of actin filaments by either phosphorylated smooth muscle myosin or rabbit skeletal muscle heavy meromyosin. The amount of caldesmon required for inhibition was decreased when tropomyosin is present. Similarly, calponin binding to actin resulted in inhibition of actin filament movement by both smooth muscle myosin and skeletal muscle heavy meromyosin. Tropomyosin had no effect on the amount of calponin needed for inhibition. High concentrations of calmodulin (10 microM) in the presence of calcium completely reversed the inhibition. The nature of the inhibition by the two proteins was markedly different. Increasing caldesmon concentrations resulted in graded inhibition of the movement of actin filaments until complete inhibition of movement was obtained. Calponin inhibited actin sliding in a more "all or none" fashion. As the calponin concentration was increased the number of actin filaments moving was markedly decreased, but the velocity of movement remained near control values.     

The effect of caldesmon and tropomyosin from smooth muscles on the motility of myosin head in ghost muscle fibers

The effects of caldesmon and smooth muscle tropomyosin on the motility of myosin subfragment I (SI) modified by N-(iodoacetyl)-N'-(1-naphtyl-5-sulfo)-ethylenediamine (1.5-IAEDANS) was studied in myosin-, troponin- and tropomyosin-free rabbit ghost muscle fibers using the polarized microphotometry technique. It was found that the fluorescence anisotropy initiated by the 1.5-IAEDANS-SI arrangement in the fibers is higher in the presence of tropomyosin than in its absence. Caldesmon diminishes the fluorescence anisotropy of the fibers. Data from a kinetic analysis suggest that the motility of fluorophores in the presence of tropomyosin in thin filaments is markedly decreased. Caldesmon weakens the effect of tropomyosin on the fluorescent label motility. It was supposed that caldesmon and tropomyosin initiate conformational changes in myosin heads which are accompanied by loosening or strengthening of their bonds with F-actin, respectively. Caldesmon inhibits the effect induced by tropomyosin.     

Three-dimensional image reconstruction of reconstituted smooth muscle thin filaments: effects of caldesmon

Caldesmon inhibits actomyosin ATPase and filament sliding in vitro, and therefore may play a role in modulating smooth and non-muscle motile activities. A bacterially expressed caldesmon fragment, 606C, which consists of the C-terminal 150 amino acids of the intact molecule, possesses the same inhibitory properties as full-length caldesmon and was used in our structural studies to examine caldesmon function. Three-dimensional image reconstruction was carried out from electron micrographs of negatively stained, reconstituted thin filaments consisting of actin and smooth muscle tropomyosin both with and without added 606C. Helically arranged actin monomers and tropomyosin strands were observed in both cases. In the absence of 606C, tropomyosin adopted a position on the inner edge of the outer domain of actin monomers, with an apparent connection to sub-domain 1 of actin. In 606C-containing filaments that inhibited acto-HMM ATPase activity, tropomyosin was found in a different position, in association with the inner domain of actin, away from the majority of strong myosin binding sites. The effect of caldesmon on tropomyosin position therefore differs from that of troponin on skeletal muscle filaments, implying that caldesmon and troponin act by different structural mechanisms.     

Smooth muscle caldesmon. Rapid purification and F-actin cross-linking properties

A method for the rapid purification of caldesmon, an F-actin binding protein of smooth muscle, has been developed. Caldesmon remains native after heating at 90 degrees C, a property that provides the basis for the purification in high yield of both caldesmon and tropomyosin, another heat-stable protein of smooth muscle. Caldesmon purified by this procedure is a highly asymmetric protein with a sedimentation coefficient of approximately 2.7 S and a Stokes radius of about 91 A. The protein exists as two polypeptide chains of Mr = 135,000 and 140,000, with each Mr polypeptide being resolvable into several isoelectric species. Estimates based on densitometry of stained gels suggest that caldesmon is more abundant in smooth muscle than filamin or alpha-actinin. Purified caldesmon bound to F-actin in the pH range 6-8. Binding was unaffected by Ca2+ or Mg2+ at up to millimolar levels. Binding was saturable, with a polypeptide molar ratio of about one caldesmon to six actins at saturation. F-actin binding was not inhibited by saturating levels of tropomyosin. Caldesmon dramatically increased the viscosity of F-actin. Light microscopy and electron microscopy of negatively stained material revealed that caldesmon induced the formation of massive F-actin bundles which contained up to hundreds of filaments. Electron microscopy of sectioned caldesmon-saturated F-actin mixtures revealed large bundles which appeared to include linear arrays of regularly spaced actin filaments cut transversely, exhibiting a center to center spacing of 15 nm. Possible structural implications based on the existence of these structures is presented.     

C-terminal actin-binding sites of smooth muscle caldesmon switch actin between conformational states

Caldesmon is a component of the thin filaments of smooth muscles where it is believed to play an essential role in regulating the thin filaments’ interaction with myosin and hence contractility. We studied the effects of caldesmon and two recombinant fragments CaDH1 (residues 506–793) and CaDH2 (residues 683–767) on the structure of actin–tropomyosin by making measurements of the fluorescence polarisation of probes specifically attached to actin. CaDH1, like the parent molecule caldesmon, is an inhibitor of actin–tropomyosin interaction with myosin whilst CaDH2 is an activator. The F-actin in permeabilised and myosin free rabbit skeletal muscle ‘ghost’ fibres was labelled by tetramethyl rhodamine-isothiocyanate (TRITC)–phalloidin or fluorescein-5′-isothiocyanate (FITC) at lysine 61. Fluorescence polarisation measurements were made and the parameters Φ_A, Φ_E, Θ_1/2 and N were calculated. Φ_A and Φ_E are angles between the fiber axis and the absorption and emission dipoles, respectively; Θ_1/2 is the angle between the F-actin filament axis and the fiber axis; N is the relative number of randomly oriented fluorophores. Actin–tropomyosin interaction with myosin subfragment-1 induced changes in the parameters of the polarised fluorescence that are typical of strong binding of myosin to actin and of the ‘on’ conformational state of actin. Caldesmon and CaDH1 (as well as troponin in the absence of Ca²⁺) diminished the effect of S-1, whereas CaDH2 (as well as troponin in the presence of Ca²⁺) enhanced the effect of S1. Thus the structural evidence correlates with biochemical evidence that C-terminal actin-binding sites of caldesmon can modulate the structural transition of actin monomers between ‘off’ (caldesmon and CaDH1) and ‘on’ (S-1 and CaDH2) states in a manner analogous to troponin.     

The effect of caldesmon on assembly and dynamic properties of actin

Our earlier fluorescence measurements using N-(1-pyrenyl)iodoacetamide-labeled actin revealed that caldesmon interacts with G-actin accelerating its nucleation at low salt concentration and causing polymerization in the absence of sale [Ga?azkiewicz, B., Mossakowska, M., Osińska, H. & Dabrowska, R. (1985) FEBS Lett. 184, 144-149]. In this work the caldesmon-induced process of actin polymerization as well as the dynamic properties of the polymers formed have been investigated with the use of fluorescence, electron paramagnetic resonance (EPR) and electron microscopy techniques. Fluorescence titration of N-(1-pyrenyl)iodoacetamide-labeled actin with caldesmon showed saturation of the polymerization at a 1:3 molar ratio of caldesmon/actin monomer. Parallel pelleting experiments revealed, however, that the process of polymer formation is biphasic and only at higher concentrations of caldesmon does the copolymer contain around one caldesmon/three actin monomers. At low concentration of caldesmon a complex of one caldesmon/nine actin monomers is formed. EPR spectroscopy, using maleimide spin label bound at Cys374 of actin, also indicated that one caldesmon molecule polymerizes nine actin monomers. Taken together, these results might suggest the existence of weak and strong forms of actin binding to caldesmon and detection of only the latter by the fluorescence method. Copolymers of actin and caldesmon are indistinguishable from actin polymerized by salt with respect to their appearance in the electron microscope and their ability to interact with heavy meromyosin, although they are characterized by lower torsional flexibility as indicated by immobilization of spin labels attached to actin.     

Orientation of spin-labeled myosin heads in glycerinated muscle fibers.

We have used electron paramagnetic resonance (EPR) spectra to study spin labels selectively and rigidly attached to myosin heads in glycerinated rabbit psoas muscle fibers. Because the angle between the magnetic field and the principal axis of the probe determines the position of the EPR absorption line, spectra from labeled fibers oriented parallel to the magnetic field yielded directly the distribution of spin label orientations relative to the fiber axis. Two spin labels, having reactivities resembling iodoacetamide (IASL) and maleimide (MSL), were used. In rigor fibers with complete filament overlap, both labels displayed a narrow angular distribution, full width at half maximum approximately 15 degrees, centered at angles of 68 degrees (IASL) and 82 degrees (MSL). Myosin subfragments (heavy meromyosin and subfragment-1) were labeled and allowed to diffuse into fibers. The resulting spectra showed the same sharp angular distribution that was found for the labeled fibers. Thus is appears that virtually all myosin heads in a rigor fiber have the same orientation relative to the fiber axis, and this orientation is determined by the actomyosin bond. Experiments with stretched fibers indicated that the spin labels on the fraction of heads not interacting with actin filaments had a broad angular distribution. Addition of ATP to unstretched fibers under relaxing conditions produced orientational disorder, resulting in a spectrum almost indistinguishable from that of an isotropic distribution of probes. Addition of either an ATP analog (AMPPNP) or pyrophosphate produced partial disorder. That is a fraction of the probes remained sharply oriented as in rigor while a second fraction was in a disordered distribution similar to that of relaxed fibers.     

Interaction between caldesmon and tropomyosin in the presence and absence of smooth muscle actin

Cysteine residues of caldesmon were labeled with the fluorescent reagent N-(1-pyrenyl)maleimide. The number of sulfhydryl (SH) groups in caldesmon was around 3.5 on the basis of reactivity to 5,5'-dithiobis(2-nitrobenzoate); 80% of the SH groups were labeled with pyrene. The fluorescence spectrum from pyrene-caldesmon showed the presence of excited monomer and dimer (excimer). As the ionic strength increased, excimer fluorescence decreased, disappearing at salt concentrations higher than around 50 mM. The labeling of caldesmon with pyrene did not affect its ability to inhibit actin activation of heavy meromyosin Mg-ATPase and the release of this inhibition in the presence of Ca2+-calmodulin. Tropomyosin induced a change in the fluorescence spectrum of pyrene-caldesmon, indicating a conformational change associated with the interaction between caldesmon and tropomyosin. The affinity of caldesmon to tropomyosin was dependent on ionic strength. The binding constant was 5 x 10(6) M-1 in low salt, and the affinity was 20-fold less at ionic strengths close to physiological conditions. In the presence of actin, the affinity of caldesmon to tropomyosin was increased 5-fold. The addition of tropomyosin also changed the fluorescence spectrum of pyrene-caldesmon bound to actin filaments. The change in the conformation of tropomyosin, caused by the interaction between caldesmon and tropomyosin, was studied with pyrene-labeled tropomyosin. Fluorescence change was evident when unlabeled caldesmon was added to pyrene-tropomyosin bound to actin. These data suggest that the interaction between caldesmon and tropomyosin on the actin filament is associated with conformational changes on these thin filament associated proteins. These conformational changes may modulate the ability of thin filament to interact with myosin heads.     

Three-dimensional reconstruction of caldesmon-containing smooth muscle thin filaments

Caldesmon is known to inhibit actomyosin ATPase and filament sliding in vitro, and may play a role in modulating smooth muscle contraction as well as in diverse cellular processes including cytokinesis and exocytosis. However, the structural basis of caldesmon action has not previously been apparent. We have recorded electron microscope images of negatively stained thin filaments containing caldesmon and tropomyosin which were isolated from chicken gizzard smooth muscle in EGTA. Three-dimensional helical reconstructions of these filaments show actin monomers whose bilobed shape and connectivity are very similar to those previously seen in reconstructions of frozen-hydrated skeletal muscle thin filaments. In addition, a continuous thin strand of density follows the long-pitch actin helices, in contact with the inner domain of each actin monomer. Gizzard thin filaments treated with Ca2+/calmodulin, which dissociated caldesmon but not tropomyosin, have also been reconstructed. Under these conditions, reconstructions also reveal a bilobed actin monomer, as well as a continuous surface strand that appears to have moved to a position closer to the outer domain of actin. The strands seen in both EGTA- and Ca2+/calmodulin-treated filaments thus presumably represent tropomyosin. It appears that caldesmon can fix tropomyosin in a particular position on actin in the absence of calcium. An influence of caldesmon on tropomyosin position might, in principle, account for caldesmon's ability to modulate actomyosin interaction in both smooth muscles and non-muscle cells.     

Caldesmon specifically inhibits the effect of tropomyosin on actomyosin system in platelet

Caldesmon, a calmodulin and actin binding protein, has been shown to exist in platelet. In this report, it is shown that caldesmon specifically inhibits the effect of tropomyosin to enhance the actomyosin ATPase activity in platelet. Platelet tropomyosin enhances the MgATPase activity of platelet actomyosin. This effect is abolished by platelet caldesmon. In the absence of tropomyosin, however, caldesmon has no effect on the ATPase activity. The inhibition is not due to displacement of the binding of tropomyosin to F-actin by caldesmon. The result indicates that caldesmon is the specific inhibitor of tropomyosin in resting platelet.     

Mechanism for the inhibition of acto-heavy meromyosin ATPase by the actin/calmodulin binding domain of caldesmon.

Caldesmon, an actin/calmodulin binding protein, inhibits acto-heavy meromyosin (HMM) ATPase, while it increases the binding of HMM to actin, presumably mediated through an interaction between the myosin subfragment 2 region of HMM and caldesmon, which is bound to actin. In order to study the mechanism for the inhibition of acto-HM ATPase, we utilized the chymotryptic fragment of caldesmon (38-kDa fragment), which possesses the actin/calmodulin binding region but lacks the myosin binding portion. The 38-kDa fragment inhibits the actin-activated HMM ATPase to the same extent as does the intact caldesmon molecule. In the absence of tropomyosin, the 38-kDa fragment decreased the KATPase and Kbinding without any effect on the Vmax. However, when the actin filament contained bound tropomyosin, the caldesmon fragment caused a 2-3-fold decrease in the Vmax, in addition to lowering the KATPase and the Kbinding. The 38-kDa fragment-induced inhibition is partially reversed by calmodulin at a 10:1 molar ratio to caldesmon fragment; the reversal was more remarkable in 100 mM ionic strength at 37 degrees C than in 20 or 50 mM at 25 degrees C. Results from these experiments demonstrate that the 38-kDa domain of caldesmon fragment of myosin head to actin; however, when the actin filament contains bound tropomyosin, caldesmon fragment affects not only the binding of HMM to/actin but also the catalytic step in the ATPase cycle. The interaction between the 38-kDa domain of caldesmon and tropomyosin-actin is likely to play a role in the regulation of actomyosin ATPase and contraction in smooth muscle.     

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.     

Immunocytochemical demonstration of caldesmon and actin in thyroid glands of rats

Summary The distribution of caldesmon (a calmodulin-binding, F-actin interacting protein; Sobue et al. 1982) and actin was studied in the rat thyroid gland by means of light-microscopic immunocytochemistry, and the fine-structural distribution of actin filaments was examined by use of heavy meromyosin (HMM). Caldesmon and actin were demonstrated in the apical cytoplasm of almost all the follicle epithelial cells in normal as well as TSH-treated animals. Immunoreactivities for both caldesmon and actin showed almost the same pattern in localization. The smooth muscle cells of the blood vessels were also positive for caldesmon and actin. By electron microscopy, numerous actin filaments decorated by HMM and running perpendicularly or randomly to the apical surface were recognized in the apical cytoplasm of the follicle epithelial cell. These results suggest that caldesmon and actin, in conjugation with calmodulin, play a role in the regulation of cellular activity such as exocytosis and endocytosis in the apical portion of the follicle epithelial cell.This study was supported by grants from the Ministry of Education, Science and Culture, Japan     

The effects of caldesmon on smooth muscle heavy actomeromyosin ATPase activity and binding of heavy meromyosin to actin

Caldesmon was purified to homogeneity from both chicken gizzard and bovine aortic smooth muscles. Caldesmon purified from bovine aorta was slightly larger than caldesmon purified from chicken gizzards (Mr = 140,000) when the two were compared electrophoretically. Caldesmon bound tightly to actin saturating at a molar ratio of 1 caldesmon monomer per 6.6 actin monomers. Ca2+-calmodulin appeared to reduce the affinity of caldesmon for actin. Caldesmon was also a potent inhibitor of heavy actomeromyosin ATPase activity producing a maximal effect at a ratio of 1 caldesmon monomer per 7-10 actin monomers. This effect was also antagonized by Ca2+-calmodulin. While caldesmon inhibited heavy actomeromyosin ATPase activity, it greatly enhanced binding of both unphosphorylated and phosphorylated heavy meromyosin to actin in the presence of MgATP, reducing the Kd for binding by a factor of 40 for each form of heavy meromyosin. Although we did identify a Ca2+-calmodulin-stimulated "caldesmon kinase" activity in caldesmon preparations purified under nondenaturing conditions, we observed no effect of phosphorylation (2 mol of PO4/mol of caldesmon) on the capacity to inhibit heavy actomeromyosin ATPase activity. Our results suggest that caldesmon could serve some role in smooth muscle function by enhancing cross-bridge affinity while inhibiting actomyosin ATPase activity.     

X-ray diffraction studies on oriented gels of vertebrate smooth muscle thin filaments.

The ATPase activity of acto-myosin subfragment 1 (S1) at low ratios of S1 to actin in the presence of tropomyosin is dependent on the tropomyosin source and ionic conditions. Whereas skeletal muscle tropomyosin causes a 60% inhibitory effect at all ionic strengths, the effect of smooth muscle tropomyosin was found to be dependent on the ionic strength. At low ionic strength (20 mM) smooth muscle tropomyosin inhibits the ATPase activity by 60%, while at high ionic strength (120 mM) it potentiates the ATPase activity three- to five-fold. Therefore, the difference in the effect of smooth muscle and skeletal muscle tropomyosin on the acto-S1 ATPase activity was due to a greater fraction of the tropomyosin-actin complex being turned on in the absence of S1 with smooth muscle tropomyosin than with skeletal muscle tropomyosin. Using well-oriented gels of actin and of reconstituted specimens from vertebrate smooth muscle thin filament proteins suitable for X-ray diffraction, we localized the position of tropomyosin on actin under different levels of acto-S1 ATPase activity. By analysing the equatorial X-ray pattern of the oriented specimens in combination with solution scattering experiments, we conclude that tropomyosin is located at a binding radius of about 3.5 nm on the f-actin helix under all conditions studied. Furthermore, we find no evidence that the azimuthal position of tropomyosin is different for smooth muscle tropomyosin at various ionic strengths, or vertebrate tropomyosin, since the second actin layer-line intensity (at 17.9 nm axial and 4.3 nm radial spacing), which was shown in skeletal muscle to be a sensitive measure of this parameter, remains strong and unchanged. Differences in the ATPase activity are not necessarily correlated with different positions of tropomyosin on f-actin. The same conclusion is drawn from our observations that, although the regulatory protein caldesmon inhibits the ATPase activity in native and reconstituted vertebrate smooth muscle thin filaments at a molar ratio of actin/tropomyosin/caldesmon of 28:7:1, the second actin layer-line remains strong. Only adding caldesmon in excess reduces the intensity of the second actin layer-line, from which the binding radius of caldesmon can be estimated to be about 4 nm. The lack of predominant meridional reflections in oriented specimens, with caldesmon present, suggests that caldesmon does not project away from the thin filament as troponin molecules in vertebrate striated muscle in agreement with electron micrographs of smooth muscle thin filaments. In freshly prepared native smooth muscle thin filaments we observed a Ca(2+)-sensitive reversible bundling effect.(ABSTRACT TRUNCATED AT 400 WORDS)     

The effect of caldesmon on actin-myosin interaction in skeletal muscle fibers

The effects of caldesmon on structural and dynamic properties of phalloidin-rhodamine-labeled F-actin in single skeletal muscle fibers were investigated by polarized microphotometry. The binding of caldesmon to F-actin in glycerinated fibers reduced the alterations of thin filaments structure and dynamics that occur upon the transition of the fibers from rigor to relaxing conditions. In fibers devoid of myosin and regulatory proteins (ghost fibers) the binding of caldesmon to F-actin precluded structural changes in actin filaments induced by skeletal muscle myosin subfragment 1 and smooth muscle tropomyosin. These results suggest that the restraint for the alteration of actin structure and dynamics upon binding of myosin heads and/or tropomyosin evoked by caldesmon can be related to its inhibitory effect on actin-myosin interaction.     

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.     

Calcium-dependent interaction of actin filaments with actin binding protein in the presence of calmodulin and caldesmon

Caldesmon, calmodulin-, and actin-binding protein of chicken gizzard did not affect the process of polymerization of actin induced by 0.1 M KCl. Caldesmon binds to F-actin, thus inhibiting the gelation action of actin binding protein (ABP; filamin). Low shear viscosity and flow birefringence measurements revealed that in a system of calmodulin, caldesmon, ABP, and F-actin, gelation occurs in the presence of micromolar Ca2+ concentrations, but not in the absence of Ca2+. Electron microscopic observations showed the Ca2+-dependent formation of actin bundles in this system. These results were interpreted by the flip-flop mechanism: in the presence of Ca2+, a calmodulin-caldesmon complex is released from actin filaments on which ABP exerts its gelating action. On the other hand, in the absence of Ca2+, caldesmon remains bound to actin filaments, thus preventing the action of ABP.