A kinetic model for the molecular basis of the contractile activity of Acanthamoeba myosins IA and IB

Acanthamoeba myosins IA and IB are single-headed, monomeric molecules consisting of one heavy chain and one light chain. Both have high actin-activated Mg2+-ATPase activity, when the heavy chain is phosphorylated, but neither seems to be able to form the bipolar filaments that are generally thought to be required for actomyosin-dependent contractility. In this paper, we show that, at fixed F-actin concentration, the actin-activated Mg2+-ATPase activities of myosins IA and IB increase about 5-fold in specific activity in a cooperative manner as the myosin concentration is increased. The myosin concentration range over which this cooperative change occurs depends on the actin concentration. More myosin I is required for the cooperative increase in activity at high concentrations of F-actin. The cooperative increase in specific activity at limiting actin concentrations is caused by a decrease in the KATPase for F-actin. The high and low KATPase states of the myosin have about the same Vmax at infinite actin concentration. Both myosins are completely bound to the F-actin long before the Vmax values are reached. Therefore, much of the actin activation must be the result of interactions between F-actin and actomyosin. These kinetic data can be explained by a model in which the cooperative shift of myosin I from the high KATPase to the low KATPase state results from the cross-linking of actin filaments by myosin I. Cross-linking might occur either through two actin-binding sites on a single molecule or by dimers or oligomers of myosin I induced to form by the interaction of myosin I monomers with the actin filaments. The ability of Acanthamoeba myosins IA and IB to cross-link actin filaments is demonstrated in the accompanying paper (Fujisaki, H., Albanesi, J.P., and Korn, E.D. (1985) J. Biol. Chem. 260, 11183-11189).     

Experimental evidence for the contractile activities of Acanthamoeba myosins IA and IB

The low-shear viscosity of 5-30 microM F-actin was greatly increased by the addition of 0.1-0.5 microM unphosphorylated Acanthamoeba myosins IA and IB. The increase in viscosity was about the same in 2 mM ADP as in the absence of free nucleotide but was much less in 2 mM ATP. The single-headed monomolecular Acanthamoeba myosins were as effective as an equal molar concentration of two-headed muscle heavy meromyosin and much more effective than single-headed muscle myosin subfragment-1. These results suggest that Acanthamoeba myosins IA and IB can cross-link actin filaments as proposed in the accompanying paper (Albanesi, J. P., Fujisaki, H., and Korn, E. D. (1985) J. Biol. Chem. 260, 11174-11179) to explain the actin-dependent cooperative increase in actin-activated Mg2+-ATPase activity as a function of the concentration of myosin I. Superprecipitation occurred when phosphorylated myosin IA or IB was mixed with F-actin. In addition to myosin I heavy chain phosphorylation, superprecipitation required Mg2+ and ATP. ATP hydrolysis was linear during the time course of the superprecipitation, and inhibitors of ATP hydrolysis inhibited superprecipitation. A small, dense contracted gel was formed when the reaction was carried out in a cuvette, and a birefringent actomyosin thread resulted from superprecipitation in a microcapillary. The rate and extent of superprecipitation depended on the actin and myosin I concentrations with maximum superprecipitation occurring at an actin:myosin ratio of 7:1. These results provide strong evidence for the ability of Acanthamoeba myosins IA and IB to perform contractile and motile functions.     

ATPase activities and actin-binding properties of subfragments of Acanthamoeba myosin IA

Previous studies had led to the conclusion that the globular, single-headed myosins IA and IB from Acanthamoeba castellanii contain two actin-binding sites: one associated with the catalytic site and whose binding to F-actin activates the Mg2+-ATPase activity and a second site whose binding results in the cross-linking of actin filaments and makes the actin-activated ATPase activity positively cooperative with respect to myosin I concentration. We have now prepared a 100,000-Da NH2-terminal peptide and a 30,000-Da COOH-terminal peptide by alpha-chymotryptic digestion of the myosin IA heavy chain. The intact 17,000-Da light chain remained associated with the 100,000-Da fragment, which also contained the serine residue that must be phosphorylated for expression of actin-activated ATPase activity by native myosin IA. The 30,000-Da peptide, which contained 34% glycine and 21% proline, bound to F-actin with a KD less than 0.5 microM in the presence or absence of ATP but had no ATPase activity. The 100,000-Da peptide bound to F-actin with KD = 0.4-0.8 microM in the presence of 2 mM MgATP and KD less than 0.01 microM in the absence of MgATP. In contrast to native myosin IA, neither peptide cross-linked actin filaments. The phosphorylated 100,000-Da peptide had actin-activated ATPase activity with the same Vmax as that of native phosphorylated myosin IA but this activity displayed simple, noncooperative hyperbolic dependence on the actin concentration in contrast to the complex cooperative kinetics observed with native myosin IA. These results provide direct experimental evidence for the presence of two actin-binding sites on myosin IA, as was suggested by enzyme kinetic and filament cross-linking data, and also for the previously proposed mechanism by which monomeric myosins I could support contractile activities.     

Regulation of the actin-activated ATPase activity of Acanthamoeba myosin I by cross-linking actin filaments

The actin-activated Mg2+-ATPase activity of phosphorylated Acanthamoeba myosin I was previously shown to be cooperatively dependent on the myosin concentration (Albanesi, J. P., Fujisaki, H., and Korn, E. D. (1985) J. Biol. Chem. 260, 11174-11179). This observation was rationalized by assuming that myosin I contains a high-affinity and a low-affinity F-actin-binding site and that binding at the low-affinity site is responsible for the actin-activated ATPase activity. Therefore, enzymatic activity would correlate with the cross-linking of actin filaments by myosin I, and the cooperative increase in specific activity at high myosin:actin ratios would result from the fact that cross-linking by one myosin molecule would increase the effective F-actin concentration for neighboring myosin molecules. This model predicts that high specific activity should occur at myosin:actin ratios below that required for cooperative interactions if the actin filaments are cross-linked by catalytically inert cross-linking proteins. This prediction has been confirmed by cross-linking actin filaments with either of three gelation factors isolated from Acanthamoeba, one of which has not been previously described, or by enzymatically inactive unphosphorylated Acanthamoeba myosin I.     

Purification and characterization of a third isoform of myosin I from Acanthamoeba castellanii

A third isoform of myosin I has been isolated from Acanthamoeba and designated myosin IC. Peptide maps and immunoassays indicate that myosin IC is not a modified form of myosin IA, IB, or II. However, myosin IC has most of the distinctive properties of a myosin I. It is a globular protein of native Mr approximately 162,000, apparently composed of a single 130-kDa heavy chain and a pair of 14-kDa light chains. It is soluble in MgATP at low ionic strength, conditions favoring filament assembly by myosin II. Myosin IC has high Ca2+- and (K+,EDTA)-ATPase activities. Its low Mg2+-ATPase activity is stimulated to a maximum rate of 20 s-1 by the addition of F-actin if its heavy chain has been phosphorylated by myosin I heavy chain kinase. The dependence of the Mg2+-ATPase activity of myosin IC on F-actin concentration is triphasic; and, at fixed concentrations of F-action, this activity increases cooperatively as the concentration of myosin IC is increased. These unusual kinetics were first demonstrated for myosins IA and IB and shown to be due to the presence of two actin-binding sites on each heavy chain which enable those myosins I to cross-link actin filaments. Myosin IC is also capable of cross-linking F-actin, which, together with the kinetics of its actin-activated Mg2+-ATPase activity, suggests that it, like myosins IA and IB, possesses two independent actin-binding domains.     

Cooperative dependence of the actin-activated Mg2+-ATPase activity of Acanthamoeba myosin II on the extent of filament phosphorylation

The actin-activated Mg2+-ATPase of myosin II from Acanthamoeba castellanii is regulated by phosphorylation of 3 serine residues at the tip of the tail of each of its two heavy chains; only dephosphorylated myosin II is active, whereas the phosphorylated and dephosphorylated forms have identical Ca2+-ATPase activities and Mg2+-ATPase activities in the absence of F-actin. We have now chemically modified phosphorylated and dephosphorylated myosin II with N-ethylmaleimide (NEM). The modification occurred principally at a single site within the NH2-terminal 73,000 Da of the globular head of the heavy chain. NEM-myosin II bound to F-actin and formed filaments normally, but the Ca2+- and Mg2+-ATPase activities of phosphorylated and dephosphorylated myosin II and the actin-activated Mg2+-ATPase activity of NEM-dephosphorylated myosin II were inhibited. Only filamentous myosin II has actin-activated Mg2+-ATPase activity. Native phosphorylated myosin II acquired actin-activated Mg2+-ATPase activity when it was co-polymerized with NEM-inactivated dephosphorylated myosin II, and the increase in its activity was cooperatively dependent on the fraction of NEM-dephosphorylated myosin II in the filaments. From this result, we conclude that the specific activity of each molecule within a filament is independent of its own state of phosphorylation, but is highly cooperatively dependent upon the state of phosphorylation of the filament as a whole. This enables the actin-activated Mg2+-ATPase activity of myosin II filaments to respond rapidly and extensively to small changes in the level of their phosphorylation.     

Localization of the actin-binding sites of Acanthamoeba myosin IB and effect of limited proteolysis on its actin-activated Mg2+-ATPase activity

Acanthamoeba myosin IB contains a 125-kDa heavy chain that has high actin-activated Mg2+-ATPase activity when 1 serine residue is phosphorylated. The heavy chain contains two F-actin-binding sites, one associated with the catalytic site and a second which allows myosin IB to cross-link actin filaments but has no direct effect on catalytic activity. Tryptic digestion of the heavy chain initially produces an NH2-terminal 62-kDa peptide that contains the ATP-binding site and the regulatory phosphorylation site, and a COOH-terminal 68-kDa peptide. F-actin, in the absence of ATP, protects this site and tryptic cleavage then produces an NH2-terminal 80-kDa peptide. Both the 62- and the 80-kDa peptides retain the (NH+4,EDTA)-ATPase activity of native myosin IB and both bind to F-actin in an ATP-sensitive manner. However, only the 80-kDa peptide retains a major portion of the actin-activated Mg2+-ATPase activity. This activity requires phosphorylation of the 80-kDa peptide by myosin I heavy chain kinase but, in contrast to the activity of intact myosin IB, it has a simple, hyperbolic dependence on the concentration of F-actin. Also unlike myosin IB, the 80-kDa peptide cannot cross-link F-actin filaments indicating the presence of only a single actin-binding site. These results allow the assignment of the actin-binding site involved in catalytic activity to the region near, and possibly on both sides of, the tryptic cleavage site 62 kDa from the NH2 terminus, and the second actin-binding site to the COOH-terminal 45-kDa domain. Thus, the NH2-terminal 80 kDa of the myosin IB heavy chain is functionally similar to the 93-kDa subfragment 1 of muscle myosin and most likely has a similar organization of functional domains.     

Purification from Dictyostelium discoideum of a low-molecular-weight myosin that resembles myosin I from Acanthamoeba castellanii

A low-molecular-weight myosin has been purified 1500-fold from extracts of Dictyostelium discoideum, based on the increase in K+,EDTA-ATPase specific activity. The purified enzyme resembles the single-headed, low-molecular-weight myosins IA and IB from Acanthamoeba castellanii, and differs from the conventional two-headed, high-molecular-weight myosin previously isolated from Dictyostelium, in several ways. It has higher K+,EDTA-ATPase activity than Ca2+-ATPase activity; it has a native molecular mass of about 150,000 and a single heavy chain of about 117,000; the 117,000-dalton heavy chain is phosphorylated by Acanthamoeba myosin I heavy chain kinase; phosphorylation of its heavy chain enhances its actin-activated Mg2+-ATPase activity; and the 117,000-dalton heavy chain reacts with antibodies raised against the heavy chain of Acanthamoeba myosin IA. None of these properties is shared by the low-molecular-weight active fragment that can be produced by chymotryptic digestion of conventional Dictyostelium myosin. We conclude that Dictyostelium contains an enzyme of the myosin I type previously isolated only from Acanthamoeba.     

Purification and characterization of a myosin I heavy chain kinase from Acanthamoeba castellanii

In previous work from this laboratory, a partially purified protein kinase from the soil amoeba Acanthamoeba castellanii was shown to phosphorylate the heavy chain of the two single-headed Acanthamoeba myosin isoenzymes, myosin IA and IB, resulting in a 10- to 20-fold increase in their actin-activated Mg2+-ATPase activities (Maruta, H., and Korn, E.D. (1977) J. Biol. Chem. 252, 8329-8332). A myosin I heavy chain kinase has now been purified to near homogeneity from Acanthamoeba by chromatography on DE-52 cellulose, phosphocellulose, and Procion red dye, followed by chromatography on histone-Sepharose. Myosin I heavy chain kinase contains a single polypeptide of 107,000 Da by electrophoretic analysis. Molecular sieve chromatography yields a Stokes radius of 4.1 nm, consistent with a molecular weight of 107,000 for a native protein with a frictional ratio of approximately 1.3:1. The kinase catalyzes the incorporation of 0.9 to 1.0 mol of phosphate into the heavy chain of both myosins IA and IB. Phosphoserine has been shown to be the phosphorylated amino acid in myosin IB. The kinase has highest specific activity toward myosin IA and IB, about 3-4 mumol of phosphate incorporated/min/mg (30 degrees C) at concentrations of myosin I that are well below saturating levels. The kinase also phosphorylates histone 2A, isolated smooth muscle light chains, and, to a very small extent, casein, but has no activity toward phosvitin or myosin II, a third Acanthamoeba myosin isoenzyme with a very different structure from myosin IA and IB. Myosin I heavy chain kinase requires Mg2+ but is not dependent on Ca2+, Ca2+/calmodulin, or cAMP for activity. The kinase undergoes an apparent autophosphorylation.     

The effect of actin and phosphorylation on the tryptic cleavage pattern of Acanthamoeba myosin IA

The Mg2+-ATPase activity of Acanthamoeba myosin IA is activated by F-actin only when the myosin heavy chain is phosphorylated at a single residue. In order to gain insight into the conformational changes that may be responsible for the effects of F-actin and phosphorylation on myosin I ATPase, we have studied their effects on the proteolysis of the myosin IA heavy chain by trypsin. Trypsin initially cleaves the unphosphorylated, 140-kDa heavy chain of Acanthamoeba myosin IA at sites 38 and 112 kDa from its NH2 terminus and secondarily at sites 64 and 91 kDa from the NH2 terminus. F-actin has no effect on tryptic cleavage at the 91- and 112-kDa sites, but does protect the 38-kDa site and the 64-kDa site. Phosphorylation (which occurs very near the 38-kDa site) has no detectable effect on the tryptic cleavage pattern in the absence of F-actin or on F-actin protection of the 64-kDa site, but significantly enhances F-actin protection of the 38-kDa site. Protection of the 64-kDa site is probably due to direct steric blocking because F-actin binds to this region of the heavy chain. The protection of the 38-kDa site by F-actin may be the result of conformational changes in this region of the heavy chain induced by F-actin binding near the 64-kDa site and by phosphorylation. The conformational changes in the heavy chain of myosin IA that are detected by alterations in its susceptibility to proteolysis are likely to be related to the conformational changes that are involved in the phosphorylation-regulated actin-activated Mg2+-ATPase activities of Acanthamoeba myosins IA and IB.     

Functional consequences of the proteolytic removal of regulatory serines from the nonhelical tailpiece of Acanthamoeba myosin II

The actin-activated Mg2(+)-ATPase activity of myosin II from Acanthamoeba castellanii is regulated by phosphorylation of 3 serines in its 29-residue, nonhelical, COOH-terminal tailpiece, i.e., serines-1489, -1494, and -1499 or, in reverse order, residues 11, 16, and 21 from the COOH terminus. To investigate the essential requirements for regulation, myosin II filaments in the presence of F-actin were digested by arginine-specific submaxillary gland protease. Two-dimensional peptide mapping of purified, cleaved myosin II showed that the two most terminal phosphorylation sites, serines-1494 and -1499, had been removed. Cleaved dephosphorylated myosin II retained full actin-activated Mg2(+)-ATPase activity (with no change in Vmax or Kapp) and the ability to form filaments similar to those of the native enzyme. However, higher Mg2+ concentrations were required for both filament formation and maximal ATPase activity. The one remaining regulatory serine in the cleaved myosin II was phosphorylatable by myosin II heavy-chain kinase, and phosphorylation inactivated the actin-activated Mg2(+)-ATPase activity, as in the case of the native myosin II. Also as in the case of the native myosin II, phosphorylated cleaved myosin II inhibited the actin-activated Mg2(+)-ATPase activity of dephosphorylated cleaved myosin II when the two were copolymerized. These results suggest that at least 18 of the 29 residues in the nonhelical tailpiece of the heavy chain are not required for either actin-activated Mg2(+)-ATPase activity or filament formation and that phosphorylation of Ser-1489 is sufficient to regulate the actin-activated Mg2(+)-ATPase activity of myosin II.     

Quantification and localization of phosphorylated myosin I isoforms in Acanthamoeba castellanii

The actin-activated Mg(2+)-ATPase activities of the three myosin I isoforms in Acanthamoeba castellanii are significantly expressed only after phosphorylation of a single site in the myosin I heavy chain. Synthetic phosphorylated and unphosphorylated peptides corresponding to the phosphorylation site sequences, which differ for the three myosin I isoforms, were used to raise isoform-specific antibodies that recognized only the phosphorylated myosin I or the total myosin I isoform (phosphorylated and unphosphorylated), respectively. With these antisera, the amounts of total and phosphorylated isoform were quantified, the phosphomyosin I isoforms localized, and the compartmental distribution of the phosphomyosin isoforms determined. Myosin IA, which was almost entirely in the actin-rich cortex, was 70- 100% phosphorylated and particularly enriched under phagocytic cups. Myosins IB and IC were predominantly associated with plasma membranes and large vacuole membranes, where they were only 10-20% phosphorylated, whereas cytoplasmic myosins IB and IC, like cytoplasmic myosin IA, were mostly phosphorylated (60-100%). Moreover, phosphomyosin IB was concentrated in actively motile regions of the plasma membrane. More than 20-fold more phosphomyosin IC and 10-fold more F-actin were associated with the membranes of contracting contractile vacuoles (CV) than of filling CVs. As the total amount of CV-associated myosin IC remained constant, it must be phosphorylated at the start of CV contraction. These data extend previous proposals for the specific functions of myosin I isozymes in Acanthamoeba (Baines, I.C., H. Brzeska, and E.D. Korn. 1992. J. Cell Biol. 119: 1193-1203): phosphomyosin IA in phagocytosis, phosphomyosin IB in phagocytosis and pinocytosis, and phosphomyosin IC in contraction of the CV.     

Filament formation and actin-activated ATPase activity are abolished by proteolytic removal of a small peptide from the tip of the tail of the heavy chain of Acanthamoeba myosin II

Actin-activated Mg2+-ATPase activity of myosin II from Acanthamoeba castellanii is regulated by phosphorylation of three serine residues located at the carboxyl-terminal end of each of the two 185,000-Da heavy chains; the phosphorylated molecule has full Ca2+-ATPase activity but no actin-activated Mg2+-ATPase activity. Under controlled conditions, chymotrypsin removes a small peptide containing all three phosphorylation sites from the ends of the myosin II heavy chains producing a molecule with heavy chains of 175,000 Da and undigested light chains. The length of the myosin II tail decreased from 89 to 76 nm. Chymotrypsin-cleaved myosin II has complete Ca2+-ATPase activity but no actin-activated Mg2+-ATPase activity under standard assay conditions and binds to F-actin as well as undigested myosin II in the absence, but not in the presence, of MgATP. In the presence of MgCl2, undigested myosin II forms biopolar filaments but chymotrypsin-cleaved myosin II forms only parallel (monopolar) dimers, as assessed by analytical ultra-centrifugation and rotary shadow electron microscopy. We conclude that the short segment very near the end of the myosin II tail that contains the three phosphorylatable serines is necessary for the formation of biopolar filaments and, probably as a consequence of filament formation, for the high-affinity binding of myosin II to F-actin in the presence of ATP and the actin-activated Mg2+-ATPase activity of native myosin II. This supports our previous conclusion that actin-activated Mg2+-ATPase of native myosin II is expressed only when the enzyme is in bipolar filaments with the proper conformation as determined by the state of phosphorylation of the heavy chains.     

Substrate specificity of Acanthamoeba myosin I heavy chain kinase as determined with synthetic peptides

Phosphorylation of a single threonine (myosin IA) or serine (myosins IB and IC) in the heavy chains of the Acanthamoeba myosin I isozymes is required for expression of their actin-activated Mg2(+)-ATPase activities. We now report that the synthetic peptide Gly-Arg-Gly-Arg-Ser-Ser-Val-Tyr-Ser, which corresponds to the phosphorylated region of Acanthamoeba myosin IC, is a good substrate for myosin I heavy chain kinase: Km = 54 microM, and Vmax = 15 mumols/min.mg. The same serine is phosphorylated as in the native substrate (residue 6 in the above sequence), and kinase activity with the synthetic peptide as substrate is also stimulated by phosphatidylserine-enhanced autophosphorylation of the kinase. These results indicate that all of the essential sequence determinants of kinase specificity are contained within this 9-residue peptide. With the peptide as substrate, we found that another acidic phospholipid, phosphatidylinositol, also enhances autophosphorylation of the kinase whereas the neutral phospholipids phosphatidylcholine and phosphatidylethanolamine do not. By comparing the Km and Vmax values for a series of synthetic peptide substrates, we established that 1 basic amino acid is essential on the NH2-terminal side of the phosphorylation site, and two are preferable, and that a tyrosine is essential 2 residues away on the COOH-terminal side. There is a slight preference for arginines over lysines. All of these local sequence specificity determinants are present in the three native substrates, Acanthamoeba myosins IA, IB, and IC, and in two Dictyostelium myosin I isozymes that are putative substrates for the kinase. Similar sequences do not occur in the myosins I from intestinal brush border, which is not a substrate for the Acanthamoeba kinase.     

Acanthamoeba cofactor protein is a heavy chain kinase required for actin activation of the Mg2+-ATPase activity of Acanthamoeba myosin I.

We have purified a cofactor protein previously shown (Pollard, T. D., and Korn, E. D. (1973) J. Biol. Chem. 248, 4691-4697) to be required for actin activation of the Mg2+-ATPase activity of Acanthamoeba myosin I. The purified cofactor protein is a novel myosin kinase that phosphorylates the single heavy chain, but neither of the two light chains, of Acanthamoeba myosin I. Phosphorylation of Acanthamoeba myosin I by the purified cofactor protein requires ATP and Mg2+ but is Ca2+-independent. The Mg2+-ATPase activity of phosphorylated Acanthamoeba myosin I is highly activated by F-actin in the absence of cofactor protein. Actin-activated Mg2+-ATPase activity is lost when phosphorylated Acanthamoeba myosin I is dephosphorylated by platelet phosphatase. Phosphorylation and dephosphorylation have no effect on the (K+,EDTA)-ATPase and Ca2+-ATPase activities of Acanthamoeba myosin I. These results show that cofactor protein is an Acanthamoeba myosin I heavy chain kinase and that phosphorylation of the heavy chain of this myosin is required for actin activation of its Mg2+-ATPase activity.     

Effects of phosphorylation, magnesium, and filament assembly on actin-activated ATPase of pig urinary bladder myosin

The relationship between the light-chain phosphorylation and the actin-activated ATPase activity of pig urinary bladder myosin was either linear or nonlinear depending on the free Mg2+ concentration. Varying the free [Mg2+] in the presence of 50 mM ionic strength (I) had a biphasic effect on the actin-activated ATPase. In 100 mM I, the activity increased on raising the free [Mg2+]. The activity of the phosphorylated myosin was 3-23-fold higher than that of the unphosphorylated myosin at all concentrations of free Mg2+, pH, and temperature used in this study. The increase in the turbidity and sedimentability of both phosphorylated and unphosphorylated myosins on raising the free [Mg2+] was associated with a rise in the actin-activated ATPase activity. However, myosin light-chain phosphorylation still had a remarkable effect on the actin activation. The myosin polymers formed under these conditions were sedimented by centrifugation. Experiments performed with myosin polymers formed in mixtures of unphosphorylated and phosphorylated myosins showed that the presence of phosphorylated myosin in these mixtures had a slight effect on the sedimentation of the unphosphorylated myosin but it had no effect on the actin-activated ATP hydrolysis. Electron microscopy showed that the unphosphorylated myosin formed unorganized aggregates while phosphorylated myosin molecules assembled into bipolar filaments with tapered ends. These data show that although the unphosphorylated and phosphorylated myosins have the same level of sedimentability and turbidity, the filament assembly present only with the phosphorylated myosin can be associated with the maximal actin activation of Mg-ATPase.     

Myosin surface loop 4 modulates inhibition of actomyosin 1b ATPase activity by tropomyosin

Structural studies of the class I myosin, MyoE, led to the predictions that loop 4, a surface loop near the actin-binding region that is longer in class I myosins than in other myosin subclasses, might limit binding of myosins I to actin when actin-binding proteins, like tropomyosin, are present, and might account for the exclusion of myosin I from stress fibers. To test these hypotheses, mutant molecules of the related mammalian class I myosin, Myo1b, in which loop 4 was truncated (from an amino acid sequence of RMNGLDES to NGLD) or replaced with the shorter and distinct loop 4 found in Dictyostelium myosin II (GAGEGA), were expressed in vitro and their interaction with actin and with actin-tropomyosin was tested. Saturating amounts of expressed fibroblast tropomyosin-2 resulted in a decrease in the maximum actin-activated Mg2+-ATPase activity of wild-type Myo1b but had little or no effect on the actin-activated Mg2+-ATPase activity of the two mutants. In motility assays, few actin filaments bound tightly to Myo1b-WT-coated cover slips when tropomyosin-2 was present, whereas actin filaments both bound and were translocated by Myo1b-NGLD or Myo1b-GAGEGA in both the presence and absence of tropomyosin-2. When expressed in mammalian cells, like the wild type, the mutant myosins were largely excluded from tropomyosin-containing actin filaments, indicating that in the cell additional factors besides loop 4 determine targeting of myosins I to specific subpopulations of actin filaments.     

Ca(2+)-dependent inhibition of actin-activated myosin ATPase activity by S100C (S100A11), a novel member of the S100 protein family

S100C (S100A11, calgizzarin) inhibits the actin-activated myosin Mg(2+)-ATPase activity of smooth muscle in a dose-dependent manner: its half-maximal effect occurs at a S100C/actin molar ratio of 0.05 and its maximal effect occurs at a ratio of 0.20. Furthermore, S100C was found to bind to actin with a stoichiometry of 1:6-7 in the presence of Ca(2+), with an affinity of 1 x 10(-6) M determined by cosedimentation assays. Other Ca(2+)-binding proteins such as S100A1, S100A2, S100B, and calmodulin did not inhibit actin-activated myosin Mg(2+)-ATPase activity. Calmodulin, S100A1, and S100B reversed the inhibitory effect of calponin in a Ca(2+)-dependent manner, S100A2 had no effect, and S100C had additional inhibitory effects. The results suggest that S100C might be involved in the regulation of actin-activated myosin Mg(2+)-ATPase activity through its Ca(2+)-dependent interaction with actin filaments.     

Nonlinear dependence of actin-activated Mg2+-ATPase activity on the extent of phosphorylation of gizzard myosin and H-meromyosin

1. The actin-activated Mg2+-ATPase activity of gizzard HMM increased in proportion to the square of the extent of LC phosphorylation. This result indicates that the LCs of HMM are randomly phosphorylated, and the phosphorylation of both heads of HMM is required for the activation of HMM Mg2+-ATPase by F-actin. 2. In 75 mM KCl, the Mg2+-ATPase activity of gizzard myosin was activated by F-actin only slightly when a half of the total LC was phosphorylated. From 1 to 2 mol LC phosphorylation, the activity was enhanced by F-actin almost linearly. In 30 mM KCl, the activity of acto-gizzard myosin increased sigmoidally with increase in the extent of LC phosphorylation. On electron microscopy, side-by-side aggregates of myosin filaments were observed in 30 mM KCl, but not in 75 mM KCl. It was suggested that the activation of the Mg2+-ATPase activity of acto-gizzard myosin LC phosphorylation is modified by formation of myosin filaments and their aggregates. 3. The relationship between the actin-activated Mg2+-ATPase activity of HMM or myosin and the extent of LC phosphorylation was unaffected by tropomyosin.     

Limited proteolysis reveals a structural difference in the globular head domains of dephosphorylated and phosphorylated Acanthamoeba myosin II.

Phosphorylation at three sites at the tip of the tail of myosin II from Acanthamoeba castellanii inactivates the actin-activated Mg(2+)-ATPase activity of filamentous myosin and the in vitro motility activity of both monomeric and filamentous myosin. To seek a structural explanation for these effects, we examined the susceptibilities of dephosphorylated and phosphorylated myosins II to endoproteinases. Endoproteinase Arg-C cleaved myosin II preferentially at two sites in the globular head, Lys-621 and Arg-638, producing an NH2-terminal fragment of about 67,000 Da and a COOH-terminal fragment of about 112,000 Da. Dephosphorylated monomers and filaments were cleaved about 3 times more rapidly than their phosphorylated counterparts principally because of a much greater rate of cleavage at Arg-638; the ratio of cleavage at Arg-638:Lys-621 was about 3 for dephosphorylated myosins and about 0.5 for phosphorylated myosins. These data demonstrate that phosphorylation at the tip of the tail of Acanthamoeba myosin II causes a conformational change in the globular head that contains the catalytic sites; therefore, this conformational change may be related to the different catalytic and motile activities of the dephosphorylated and phosphorylated enzymes.