A novel regulatory effect of myosin light chain kinase from smooth muscle on the ATP-dependent interaction between actin and myosin.

The actin-binding activity of myosin light chain kinase (MLCK) from smooth muscle was studied with special reference to the ATP-dependent interaction between actin and myosin. MLCK in the presence of calmodulin endowed sensitivity to Ca2+ on the movement of actin filaments on phosphorylated myosin from smooth muscle that was fixed on a coverslip. This regulatory effect was not attributable to the kinase activity of MLCK but could be explained by its actin-binding activity. The importance of the actin-binding activity was further substantiated by results of an experiment with Nitellopsis actin-cables in which MLCK regulated the interaction under conditions where MLCK was exclusively associated with the actin-cables.     

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.     

Inhibition of the ATP-dependent interaction of actin and myosin by the catalytic domain of the myosin light chain kinase of smooth muscle: possible involvement in smooth muscle relaxation

Myosin light chain kinase (MLCK) phosphorylates the light chain of smooth muscle myosin enabling its interaction with actin. This interaction initiates smooth muscle contraction. MLCK has another role that is not attributable to its phosphorylating activity, i.e., it inhibits the ATP-dependent movement of actin filaments on a glass surface coated with phosphorylated myosin. To analyze the inhibitory effect of MLCK, the catalytic domain of MLCK was obtained with or without the regulatory sequence adjacent to the C-terminal of the domain, and the inhibitory effect of the domain was examined by the movement of actin filaments. All the domains work so as to inhibit actin filament movement whether or not the regulatory sequence is included. When the domain includes the regulatory sequence, calmodulin in the presence of calcium abolishes the inhibition. Since the phosphorylation reaction is not involved in regulating the movement by MLCK, and a catalytic fragment that shows no kinase activity also inhibits movement, the kinase activity is not related to inhibition. Higher concentrations of MLCK inhibit the binding of actin filaments to myosin-coated surfaces as well as their movement. We discuss the dual roles of the domain, the phosphorylation of myosin that allows myosin to cross-bridge with actin and a novel function that breaks cross-bridging.     

Light chain phosphorylation regulates the movement of smooth muscle myosin on actin filaments

In smooth muscles there is no organized sarcomere structure wherein the relative movement of myosin filaments and actin filaments has been documented during contraction. Using the recently developed in vitro assay for myosin-coated bead movement (Sheetz, M.P., and J.A. Spudich, 1983, Nature (Lond.)., 303:31-35), we were able to quantitate the rate of movement of both phosphorylated and unphosphorylated smooth muscle myosin on ordered actin filaments derived from the giant alga, Nitella. We found that movement of turkey gizzard smooth muscle myosin on actin filaments depended upon the phosphorylation of the 20-kD myosin light chains. About 95% of the beads coated with phosphorylated myosin moved at velocities between 0.15 and 0.4 micron/s, depending upon the preparation. With unphosphorylated myosin, only 3% of the beads moved and then at a velocity of only approximately 0.01-0.04 micron/s. The effects of phosphorylation were fully reversible after dephosphorylation with a phosphatase prepared from smooth muscle. Analysis of the velocity of movement as a function of phosphorylation level indicated that phosphorylation of both heads of a myosin molecule was required for movement and that unphosphorylated myosin appears to decrease the rate of movement of phosphorylated myosin. Mixing of phosphorylated smooth muscle myosin with skeletal muscle myosin which moves at 2 microns/s resulted in a decreased rate of bead movement, suggesting that the more slowly cycling smooth muscle myosin is primarily determining the velocity of movement in such mixtures.     

Functional role of the C-terminal domain of smooth muscle myosin light chain kinase on the phosphorylation of smooth muscle myosin

Smooth muscle myosin light chain kinase (MLCK) is known to bind to thin filaments and myosin filaments. Telokin, an independently expressed protein with an identical amino acid sequence to that of the C-terminal domain of MLCK, has been shown to bind to unphosphorylated smooth muscle myosin. Thus, the functional significance of the C-terminal domain and the molecular morphology of MLCK were examined in detail. The C-terminal domain was removed from MLCK by alpha-chymotryptic digestion, and the activity of the digested MLCK was measured using myosin or the isolated 20-kDa light chain (LC20) as a substrate. The results showed that the digestion increased K(m) for myosin 3-fold whereas it did not change the value for LC20. In addition, telokin inhibited the phosphorylation of myosin by MLCK by increasing K(m) but only slightly increased K(m) for LC20. Electron microscopy indicated that MLCK was an elongated molecule but was flexible so as to form folded conformations. MLCK was crosslinked to unphosphorylated heavy meromyosin with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide in the absence of Ca(2+)/calmodulin (CaM), and electron microscopic observation of the products revealed that the MLCK molecule bound to the head-tail junction of heavy meromyosin. These results suggest that MLCK binds to the head-tail junction of unphosphorylated myosin through its C-terminal domain, where LC20 can be promptly phosphorylated through its catalytic domain following the Ca(2+)/CaM-dependent activation.     

Calcium regulation of porcine aortic myosin

Calcium regulation of actin-activated porcine aortic myosin MgATPase was studied. The MgATPase of the purified actomyosin was stimulated about 10-fold by 0.1 mM Ca2+. The 20,000 molecular weight light chain subunit (LC20) of myosin was phosphorylated by an endogenous kinase that required Ca2+. Half-maximal activation of both kinase and ATPase occurred at about 0.9 microM Ca2+. Phosphorylated and unphosphorylated myosins, free of actin, kinase, and phosphatase, were purified by gel filtration. The MgATPase of phosphorylated myosin was activated by rabbit skeletal muscle actin; unphosphorylated myosin was actin activated to a much lesser extent. Actin activation was maximal in the presence of Ca2+. Regulation of the aortic myosin MgATPase seems to involve both direct interaction of calcium with phosphorylated myosin and calcium activation of the myosin kinase. The MgATPase of trypsin-treated actomyosin did not require Ca2+ for full activity. The trypsin-treated actomyosin was devoid of LC20. When purified unphosphorylated aortic myosin was treated with trypsin, the LC20, was cleaved and the MgATPase, which was not appreciably actin activated before exposure to protease, was increased and was activated by skeletal muscle actin. After incubation of this light chain-depleted myosin with light chain from rabbit skeletal muscle myosin, the actin activation but not the increased activity, was abolished. Unphosphorylated LC20 seems to inhibit actin activation in this smooth muscle.     

Phosphorylation of vascular smooth muscle caldesmon by endogenous kinase.

Caldesmon was phosphorylated up to 1.2 molPi/mol using a partially purified endogenous kinase fraction. The phosphorylation site was within the C-terminal 99 amino acids. We were also able to phosphorylate caldesmon incorporated into native and synthetic smooth muscle thin filaments. Phosphorylation did not alter caldesmon binding to actin or inhibition of actomyosin ATPase. It also did not change Ca2+ sensitivity in native thin filaments. Phosphorylated caldesmon bound to myosin less than unphosphorylated caldesmon, especially when the myosin was also not phosphorylated. This work did not support the hypothesis that caldesmon function is modulated by phosphorylation.     

Activation of smooth muscle myosin Mg2+-ATPase by native thin filaments and actin/tropomyosin

Application of the myosin competition test (Lehman, W., and Szent-Gy?rgyi, A. G. (1975) J. Gen. Physiol. 66, 1-30) to chicken gizzard actomyosin indicated that this smooth muscle contains a thin filament-linked regulatory mechanism. Chicken gizzard thin filaments, isolated as described previously (Marston, S. B., and Lehman, W. (1985) Biochem. J. 231, 517-522), consisted almost exclusively of actin, tropomyosin, caldesmon, and an unidentified 32-kilodalton polypeptide in molar ratios of 1:1/6:1/26:1/17, respectively. When reconstituted with phosphorylated gizzard myosin, these thin filaments conferred Ca2+ sensitivity (67.8 +/- 2.1%; n = 5) on the myosin Mg2+-ATPase. On the other hand, no Ca2+ sensitivity of the myosin Mg2+-ATPase was observed when purified gizzard actin or actin plus tropomyosin was reconstituted with phosphorylated gizzard myosin. Native thin filaments were rendered essentially free of caldesmon and the 32-kilodalton polypeptide by extraction with 25 mM MgCl2. When reconstituted with phosphorylated gizzard myosin, caldesmon-free thin filaments and native thin filaments exhibited approximately the same Ca2+ sensitivity (45.1 and 42.7%, respectively). The observed Ca2+ sensitivity appears, therefore, not to be due to caldesmon. Only trace amounts of two Ca2+-binding proteins could be detected in native thin filaments. These were identified as calmodulin (present at a molar ratio to actin of 1:733) and the 20-kilodalton light chain of myosin (present at a molar ratio to actin of 1:270). The Ca2+ sensitivity observed in an in vitro system reconstituted from gizzard thin filaments and either skeletal myosin or phosphorylated gizzard myosin is due, therefore, to calmodulin and/or an unidentified minor protein component of the thin filaments which may be an actin-binding protein involved in regulating actin filament structure in a Ca2+-dependent manner.     

Catalytic fragment of protein kinase C exhibits altered substrate specificity toward smooth muscle myosin light chain.

Smooth muscle myosin light chain (LC) can be phosphorylated by myosin light chain kinase (MLCK) at Ser19 and Thr18 and by protein kinase C (PKC) at Thr9 and Ser1 or Ser2 under the in vitro assay conditions. Conversion of PKC to the spontaneously active protein kinase M (PKM) by proteolysis resulted in a change in the substrate specificity of the kinase. PKM phosphorylated both sets of sites in LC recognized by MLCK and PKC as analyzed by peptide mapping analysis. The PKM-catalyzed phosphorylation of these sites was not greatly affected by a MLCK inhibitor, ML-9, nor by the activators of MLCK, Ca2+ and calmodulin.     

Inhibitory effect of the catalytic domain of myosin light chain kinase on actin-myosin interaction: insight into the mode of inhibition.

The catalytic domain of myosin light chain kinase (MLCK) not only exerts kinase activity to phosphorylate the 20 kDa light chain but also inhibits the actin-myosin interaction. The site of action of this novel role of the domain has been suggested to be myosin [Okagaki et al. (1999) J. Biochem. 125, 619-626]. In this study, we have analyzed the amino acid sequences of MLCK and myosin that are involved in the inhibition. The ATP-binding peptide of Gly526-Lys548 of chicken gizzard MLCK exerted the inhibitory effect on the movement of actin filaments on a myosin-coated glass surface. However, the peptide that neighbors the sequence failed to inhibit the movement. The inhibition of the ATP-binding peptide was confirmed by measuring ATPase activities of the myosin. The inhibition by parent MLCK of the movement was relieved by the 20 kDa light chain, but not by the 17 kDa myosin light chain. The peptide of the 20 kDa light chain sequence of Ser1-Glu29 also relieved the inhibition. Thus, the interaction of the ATP-binding sequence with the 20 kDa light chain sequence should cause the inhibition of the actin-myosin interaction. Concerning the regulation of the inhibition, calmodulin relieved the inhibitory effect of MLCK on the movement of actin filaments. The calmodulin-binding peptide (Ala796 Ser815) prevented the relief, suggesting the involvement of this sequence. Thus, the mode of regulation by Ca2+ and calmodulin of the novel role of the catalytic domain is similar, but not identical, to the mode of regulation of the kinase activity of the domain.     

Stimulation of the interaction between actin and myosin by Physarum caldesmon-like protein and smooth muscle caldesmon.

We have purified an actin-binding protein from the plasmodia of a lower eukaryote, Physarum polycephalum, with an apparent molecular mass of 210,000 daltons on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. This protein bound to actin filaments with a stoichiometry of 1:7-8 in a Ca(2+)-calmodulin-dependent manner. Antibody raised against caldesmon from smooth muscle cross-reacted with the 210-kDa protein. In vitro motility assay revealed that the 210-kDa protein increased the sliding velocity of actin filaments on Physarum myosin. The 210-kDa protein more than doubled the actin-activated ATPase activity of Physarum myosin under comparative conditions of in vitro motility assay. Further increases in the concentration of the 210-kDa protein decreased its stimulatory effects. Ca(2+)-calmodulin prevented the stimulatory effects of the 210-kDa protein. Unexpectedly, smooth muscle caldesmon also increased the sliding velocity of actin filaments on smooth muscle myosin at lower concentrations. The well-known inhibitory effect of smooth muscle caldesmon on the actin-myosin interaction was observed with this motility assay when the concentration of the caldesmon was increased further. The stimulatory and inhibitory effects were confirmed by measurements of actin-activated ATPase activity of smooth muscle myosin. From estimations of the intracellular concentrations of the 210-kDa protein and smooth muscle caldesmon in vivo, it appears that effects of the former and the latter on actin-myosin interactions in vivo are stimulatory and inhibitory, respectively.     

Motility of myosin V regulated by the dissociation of single calmodulin

Myosin V is a calmodulin-binding motor protein. The dissociation of single calmodulin molecules from individual myosin V molecules at 1 microM Ca(2+) correlates with a reduction in sliding velocity in an in vitro motility assay. The dissociation of two calmodulin molecules at 5 microM Ca(2+) correlates with a detachment of actin filaments from myosin V. To mimic the regulation of myosin V motility by Ca(2+) in a cell, caged Ca(2+) coupled with a UV flash system was used to produce Ca(2+) transients. During the Ca(2+) transient, myosin V goes through the functional cycle of reduced sliding velocity, actin detachment and reattachment followed by the recovery of the sliding velocity. These results indicate that myosin V motility is regulated by Ca(2+) through a reduction in actin-binding affinity resulting from the dissociation of single calmodulin molecules.     

A novel regulatory protein that affects the functions of caldesmon and myosin light chain kinase.

A caldesmon (CaD)-binding protein of about 65 kDa (by SDS-PAGE) was purified from smooth muscle of chicken gizzard. The 65-kDa protein prevented the inhibitory effect of CaD on the ATP-dependent interaction between actin and myosin. Unlike the case with calmodulin (CaM), Ca2+ was not required for this effect. As reported in the preceding communication, myosin light chain kinase (MLCK), another well characterized protein that binds CaM, has CaD-like activity that modulates the interaction by binding to actin. The 65-kDa protein was also effective in relieving the modulation, while leaving unaffected the kinase activity that phosphorylates the light chain of smooth muscle myosin.     

Direct observation of molecular motility by light microscopy

We used video-fluorescence microscopy to directly observe the sliding movement of single fluorescently labeled actin filaments along myosin fixed on a glass surface. Single actin filaments labeled with phalloidin-tetramethyl-rhodamine, which stabilizes the filament structure of actin, could be seen very clearly and continuously for at least 60 min in 02-free solution, and the sensitivity was high enough to see very short actin filaments less than 40 nm long that contained less than eight dye molecules. The actin filaments were observed to move along double-headed and, similarly, single-headed myosin filaments on which the density of the heads varied widely in the presence of ATP, showing that the cooperative interaction between the two heads of the myosin molecule is not essential to produce the sliding movement. The velocity of actin filament independent of filament length (greater than 1 micron) was almost unchanged until the density of myosin heads along the thick filament was decreased from six heads/14.3 nm to 1 head/34 nm. This result suggests that five to ten heads are sufficient to support the maximum sliding velocity of actin filaments (5 micron/s) under unloaded conditions. In order for five to ten myosin heads to achieve the observed maximum velocity, the sliding distance of actin filaments during one ATP cycle must be more than 60 nm.     

The effects of caldesmon on the ATPase activities of rabbit skeletal-muscle myosin.

We studied the effects of caldesmon, a major actin- and calmodulin-binding protein found in a variety of muscle and non-muscle tissues, on the various ATPase activities of skeletal-muscle myosin. Caldesmon inhibited the actin-activated myosin Mg2+-ATPase, and this inhibition was enhanced by tropomyosin. In the presence of the troponin complex and tropomyosin, caldesmon inhibited the Ca2+-dependent actomyosin Mg2+-ATPase; this inhibition could be partly overcome by Ca2+/calmodulin. Caldesmon, phosphorylated to the extent of approximately 4 mol of Pi/mol of caldesmon, inhibited the actin-activated myosin Mg2+-ATPase to the same extent as did non-phosphorylated caldesmon. Both inhibitions could be overcome by Ca2+/calmodulin. Caldesmon also inhibited the Mg2+-ATPase activity of skeletal-muscle myosin in the absence of actin; this inhibition also could be overcome by Ca2+/calmodulin. Caldesmon inhibited the Ca2+-ATPase activity of skeletal-muscle myosin in the presence or absence of actin, at both low (0.1 M-KCl) and high (0.3 M-KCl) ionic strength. Finally, caldesmon inhibited the skeletal-muscle myosin K+/EDTA-ATPase at 0.1 M-KCl, but not at 0.3 M-KCl. Addition of actin resulted in no inhibition of this ATPase by caldesmon at either 0.1 M- or 0.3 M-KCl. These observations suggest that caldesmon may function in the regulation of actin-myosin interactions in striated muscle and thereby modulate the contractile state of the muscle. The demonstration that caldesmon inhibits a variety of myosin ATPase activities in the absence of actin indicates a direct effect of caldesmon on myosin. The inhibition of the actin-activated Mg2+-ATPase activity of myosin (the physiological activity) may not be due therefore simply to the binding of caldesmon to the actin filament causing blockage of myosin-cross-bridge-actin interaction.     

Phosphorylation of smooth muscle myosin heads regulates the head-induced movement of tropomyosin

It has been shown that skeletal and smooth muscle myosin heads binding to actin results in the movement of smooth muscle tropomyosin, as revealed by a change in fluorescence resonance energy transfer between a fluorescence donor on tropomyosin and an acceptor on actin (Graceffa, P. (1999) Biochemistry 38, 11984-11992). In this work, tropomyosin movement was similarly monitored as a function of unphosphorylated and phosphorylated smooth muscle myosin double-headed fragment smHMM. In the absence of nucleotide and at low myosin head/actin ratios, only phosphorylated heads induced a change in energy transfer. In the presence of ADP, the effect of head phosphorylation was even more dramatic, in that at all levels of myosin head/actin, phosphorylation was necessary to affect energy transfer. It is proposed that the regulation of tropomyosin position on actin by phosphorylation of myosin heads plays a key role in the regulation of smooth muscle contraction. In contrast, actin-bound caldesmon was not moved by myosin heads at low head/actin ratios, as uncovered by fluorescence resonance energy transfer and disulfide cross-linking between caldesmon and actin. At higher head concentration caldesmon was dissociated from actin, consistent with the multiple binding model for the binding of caldesmon and myosin heads to actin (Chen, Y., and Chalovich, J. M. (1992) Biophys. J. 63, 1063-1070).     

Phosphorylation of caldesmon by protein kinase C

Protein kinase C catalyzes phosphorylation of caldesmon, an F-actin binding protein of smooth muscle, in the presence of Ca2+ and phospholipid. Protein kinase C incorporates about 8 mol of phosphate/mol of chicken gizzard caldesmon. When calmodulin was added in the medium, there was an inhibition of phosphorylation. The fully phosphorylated, but not unphosphorylated, caldesmon inhibited myosin light chain kinase activity. The possibility that protein kinase C plays some role in smooth muscle contractile system through caldesmon, warrants further attention.     

Olfactory adenylate cyclase of the rat. Stimulation by odorants and inhibition by Ca2+.

The Ca2+-dependent regulation of the activation of myosin MgATPase by vascular-smooth-muscle thin filaments involves caldesmon. This effect may be due to the direct interaction of caldesmon with a Ca2+-binding protein such as calmodulin or phosphorylation of caldesmon by a Ca2+-dependent kinase. I have found that Ca2+ switches on aorta thin filaments in less than 10 s, whereas the caldesmon in the thin filaments is phosphorylated only slowly (half-time greater than 10 min) and the maximum phosphorylation is very low (1 molecule per 7 molecules of caldesmon). I conclude that the phosphorylation of caldesmon hypothesis is untenable.     

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.     

Comparative maps of motion and assembly of filamentous actin and myosin II in migrating cells

To understand the mechanism of cell migration, one needs to know how the parts of the motile machinery of the cell are assembled and how they move with respect to each other. Actin and myosin II are thought to be the major structural and force-generating components of this machinery (Mitchison and Cramer, 1996; Parent, 2004). The movement of myosin II along actin filaments is thought to generate contractile force contributing to cell translocation, but the relative motion of the two proteins has not been investigated. We use fluorescence speckle and conventional fluorescence microscopy, image analysis, and computer tracking techniques to generate comparative velocity and assembly maps of actin and myosin II over the entire cell in a simple model system of persistently migrating fish epidermal keratocytes. The results demonstrate contrasting polarized assembly patterns of the two components, indicate force generation at the lamellipodium-cell body transition zone, and suggest a mechanism of anisotropic network contraction via sliding of myosin II assemblies along divergent actin filaments.