Effects of substrate and substrate analogues on the trinitrophenylation of myosin

The effects of ATP, ATP analogues, Mg²⁺ and actin on the trinitrophenylation of myosin and on the enzymic properties of trinitrophenylated samples were studied.

1. 1. Trinitrophenylation of myosin was inhibited by the presence of ATP and its analogues during the treatment in the order ADP > ATP > pyrophosphate > AMP.

2. 2. The alteration of the enzymic properties due to trinitrophenylation of myosin was prevented by the presence of ATP or ADP and somewhat less by that of pyrophosphate and AMP during trinitrophenylation, but only if Mg²⁺ was also present.

3. 3. Neither the degree of trinitrophenylation nor the enzymic properties of the trinitrophenylated myosin were influenced by the presence of actin during the treatment of myosin.

Reaction of myosin with salicylaldehyde II. Effect of salicylalation on the ATPase activity of myosin

The effect of salicylalation on the biological properties of myosin was studied.

1. 1. The ATPase activity of myosin is affected by salicylalation if the treatment is carried out at higher pH than 6.5. The Mg²⁺-activated ATPase shows a maximal curve with 250–380% maximal activation when 25–70 moles of salicylaldehyde are bound per mole of myosin. The EDTA-activated ATPase decreases with increasing salicylalation. Ca²⁺-activated ATPase shows a small increase with increasing salicylalation.

2. 2. Less salicylaldehyde is bound if the treatment is carried out in the presence of ATP, while that of PP_i does not affect the degree of salicylalation. The enzymic properties of myosins salicylalated in the presence of ATP or PP_i are not different from those of the samples treated in their absence.

3. 3. Salicylalation decreases ATP sensitivity of ATPase and superprecipitation of actomyosins reconstituted from salicylalated myosins only if more than 50 moles of salicylaldehyde are bound per mole myosin.

Kinetics of steady state ATPase activity and rigor complex formation of acto-heavy meromyosin

1. Actin and heavy meromyosin, initially mixed in a Mg-ATP solution, began to form the rigor complex slowly after ATP in the solution had been completely hydrolyzed.

2. This was because the heavy meromyosin-product complex formed via ATP hydrolysis was almost completely dissociated from actin even in the absence of ATP and as soon as this heavy meromyosin-product complex was decomposed, the heavy meromyosin combined with actin forming the rigor complex.

3. Linear plots were obtained when the reciprocal of the excess rate of the actin-accelerated rigor complex formation was plotted against the reciprocal of the added actin concentration as similar with those made on the steady acto-heavy meromyosin ATPase.

4. The V of the rigor complex formation process was about 1/5 of that of the steady acto-heavy meromyosin ATPase activity, showing that the actomyosin ATPase activity could not be explained merely by the actin-accelerated decomposition of the heavy meromyosin-product complex.

5. The same analyses were carried out on myosin subfragment 1.

6. Our results could be explained by considering the two non-identical active sites of myosin, and we propose the following scheme for the actomyosin ATPase.

7. Actin accelerates the rate-limiting bond hydrolysis in the ATPase occurring at one active site of myosin, as well as the rate-limiting decomposition of the heavy meromyosin-product complex formed at another site.     

Trinitrophenylation of rabbit skeletal myosin by 2,4,6-trinitrobenzene sulfonate and treatment of trinitrophenyl myosin with dithiothreitol

Rabbit skeletal myosin was trinitrophenylated with 2,4,6-trinitrobenzene sulfonate (TNBS) in the presence or absence of inorganic pyrophosphate (PP1). When myosin trinitrophenylated either in the presence or absence of PP1 was treated with dithiothreitol (DTT), the absorbance at 345 nm of both trinitrophenylated myosins was decreased, as though the trinitrophenyl groups bound to myosin were removed. The DTT treatment also essentially reversed the inhibition of the EDTA-ATPase and Ca-ATPase activities that was caused by trinitrophenylation of myosin. These effects of trinitrophenylation and of DTT treatment were independent of the presence or absence of PP1 during the trinitrophenylation. In contrast, the PP1-induced formation of a difference spectrum of trinitrophenylated myosin was not affected by the DTT treatment. On the basis of these observations, it is suggested that the "reactive lysine residues," trinitrophenylation of which resulted in inhibition of the ATPase activities, are different from those whose trinitrophenyl groups show an altered spectrum on addition of PP1.     

Effects of tropomyosin, troponin and Ca on the interaction between F-actin and heavy meromyosin

1. In the absence of ATP, H-meromyosin (heavy meromyosin) bound with the F-actin-tropomyosin-troponin complex up to the molar ratio of H-meromyosin to actin of 1:1, independently of the concentration of Ca²⁺.

2. In the presence of free Ca²⁺ above about 1 μM, with an increasing amount of H-meromyosin bound to a fixed amount of the F-actin-tropomyosin-troponin complex, the degree of flow birefringence decreased and the extinction angle increased. The minimum value of the birefringence and the maximum value of the extinction angle were found at the molar ratio of H-meromyosin to actin of 1:2. A further increase of bound H-meromyosin to actin restored both the degree of birefringence and the extinction angle to nearly the same level as the F-actin-tropomyosin-troponin complex only. In the absence of free Ca²⁺, the birefringence did not change with the binding of H-meromyosin.

3. This sensitivity of birefringence to the concentration of Ca²⁺ appeared only in the presence of tropomyosin and troponin. At a fixed ratio of H-meromyosin, actin and tropomyosin, the birefringence in the absence of Ca²⁺ increased with increasing amount of added troponin up to the weight ratio of troponin to actin of 1:6; whereas the birefringence in the presence of Ca²⁺ did not change.

4. At a fixed ratio of H-meromyosin to actin, the birefringence changed with increasing amount of tropomyosin added up to the weight ratio of tropomyosin to actin of 1:6; above this ratio, the birefringence was constant.

5. Subfragment S-1, prepared by the chymotryptic digestion of myosin, bound to F-actin, but the birefringence did not change even in the presence of tropomyosin and troponin.     

Regulation of molluscan actomyosin ATPase activity

The interaction of myosin and actin in many invertebrate muscles is mediated by the direct binding of Ca2+ to myosin, in contrast to modes of regulation in vertebrate skeletal and smooth muscles. Earlier work showed that the binding of skeletal muscle myosin subfragment 1 to the actin-troponin-tropomyosin complex in the presence of ATP is weakened by less than a factor of 2 by removal of Ca2+ although the maximum rate of ATP hydrolysis decreases by 96%. We have now studied the invertebrate type of regulation using heavy meromyosin (HMM) prepared from both the scallop Aequipecten irradians and the squid Loligo pealii. Binding of these HMMs to rabbit skeletal actin was determined by measuring the ATPase activity present in the supernatant after sedimenting acto-HMM in an ultracentrifuge. The HMM of both species bound to actin in the presence of ATP, even in the absence of Ca2+, although the binding constant in the absence of Ca2+ (4.3 X 10(3) M-1) was about 20% of that in the presence of Ca+ (2.2 X 10(4) M-1). Studies of the steady state ATPase activity of these HMMs as a function of actin concentration revealed that the major effect of removing Ca2+ was to decrease the maximum velocity, extrapolated to infinite actin concentration, by 80-85%. Furthermore, at high actin concentrations where most of the HMM was bound to actin, the rate of ATP hydrolysis remained inhibited in the absence of Ca+. Therefore, inhibition of the ATPase rate in the absence of Ca2+ cannot be due simply to an inhibition of the binding of HMM to actin; rather, Ca2+ must also directly alter the kinetics of ATP hydrolysis.     

Association and dissociation of the thick and thin filaments within myofibrils in conditions of “contraction” and “relaxation”

1. The current assumption that the low ATPase activity of relaxed myofibrils is represented by the ATPase activity of myosin which has been set free during the dissociation of actomyosin was investigated. For this purpose, the ATPase activity of relaxed skeletal myofibrils of the rabbit and of the crab Maia squinado has been compared with the activity of contracted fibrils and of purified rabbit myosin in conditions of varying ionic strength, pH and concentrations of MgATP (i.e. MgATP²⁻ + MgHATP⁻) and Mg²⁺.

2. Contraction and relaxation of the fibrils was induced by changing the concentration of Ca²⁺ from about 5×10⁻⁵ to below 1×10⁻⁸ M.

3. In all conditions studied, the ATPase activity of relaxed fibrils was about 6–8 times less than that of the contracted fibrils, but it remained a typical actomyosin ATPase.

4. Quantitatively and qualitatively, this ATPase differs from the ATPase of myosin. For instance, its dependence on pH is the reverse of that of the myosin ATPase.

5. Calculation showed that the fibrils are dissociated by 90% in conditions of relaxation. Since the ATPase activity of myosin was merely some 2% of the actomyosin activity, the major part of the ATPase of fibrils, even at a dissociation of 90%, is bound to show the properties of the ATPase of actomyosin.

6. However, a dissociation of 90% cannot be distinguished from a dissociation of 100% by means of physical methods (viscosity, superprecipitation, resistance to stretch, etc.). This explains why physical methods indicate a “full” dissociation of actomyosin although, enzymatically, the ATPase is still of the actomyosin type.

7. The possible reasons are discussed for the discrepancy between the 100-fold increase in the ATP turnover and the 1000-fold increase in energy turnover of the living muscle during the transition from relaxed to active state. The most probable explanation seems to be an ATPase activity of myosin which is too high by a factor of ten as compared to the energy turnover of living muscle at the resting state. This high activity cannot be caused by a contamination of the myosin by Ca²⁺-insensitive actomyosin.     

Chemical Decoupling of ATPase Activation and Force Production from the Contractile Cycle in Myosin by Steric Hindrance of Lever-Arm Movement

The myosin motor protein generates force in muscle by hydrolyzing Adenosine 5′-triphosphate (ATP) while interacting transiently with actin. Structural evidence suggests the myosin globular head (subfragment 1 or S1) is articulated with semi-rigid catalytic and lever-arm domains joined by a flexible converter domain. According to the prevailing hypothesis for energy transduction, ATP binding and hydrolysis in the catalytic domain drives the relative movement of the lever arm. Actin binding and reversal of the lever-arm movement (power stroke) applies force to actin. These domains interface at the reactive lysine, Lys84, where trinitrophenylation (TNP-Lys84-S1) was observed in this work to block actin activation of myosin ATPase and in vitro sliding of actin over myosin. TNP-Lys84-S1's properties and interactions with actin were examined to determine how trinitrophenylation causes these effects. Weak and strong actin binding, the rate of mantADP release from actomyosin, and actomyosin dissociation by ATP were equivalent in TNP-Lys84-S1 and native S1. Molecular dynamics calculations indicate that lever-arm movement inhibition during ATP hydrolysis and the power stroke is caused by steric clashes between TNP and the converter or lever-arm domains. Together these findings suggest that TNP uncouples actin activation of myosin ATPase and the power stroke from other steps in the contraction cycle by inhibiting the converter and lever-arm domain movements.     

Purification and characterization of myosin from bovine retina.

Myosin has been isolated from bovine retinae and characterised by its ATPase (ATP phosphohydrolase, EC 3.6.1.3) activity, its mobility in sodium dodecyl sulphate polyacrylamide gels and by electron microscopy. The purified myosin shows high ATPase activity in the presence of EDTA or Ca2+ and a low activity in the presence of Mg2+. The Mg2+-dependent ATPase activity is stimulated by rabbit skeletal muscle actin. The presumptive retinal myosin possesses a major component which has a mobility in sodium dodecyl sulphate polyacrylamide gel electrophoresis similar to that of the heavy chain of bovine skeletal muscle myosin. Electron microscopy showed retinal myosin to form bipolar filaments in 0.1 M KCl. It is concluded that the retina possesses a protein with enzymic and structural properties similar to those of muscle myosin.     

Studies on the amino groups of myosin ATPase. Trinitrophenylation of reactive lysyl residue in ventricular and atrial myosins

Myosin and heavy meromyosin from ventricular, atrial, and skeletal muscle were purified and trinitrophenylated by 2,4,6-trinitrobenzene sulfonate. The trinitrophenylation reaction followed a complex kinetics consisting of a fast and slow reaction in all preparations studied. Reactive lysine residues were trinitrophenylated during the fast reaction with a concomitant decrease in K⁺ (EDTA)-activated ATPase and an increase in Mg²⁺-stimulated ATPase activities of myosin. The extent of increase in Mg²⁺-mediated ATPase was the highest with skeletal and the lowest with atrial myosin. The trinitrophenylation of the less reactive lysyl residues continued during the slow reaction. The rate constants of the reactions and the number of reactive lysine residues were evaluated by computer analyses of the trinitrophenylation curves. Two reactive lysine residues were found in skeletal and ventricular myosins while their number in atrial myosin was somewhat lower. The rate of trinitrophenylation in skeletal muscle myosin or heavy meromyosin was always higher than in the two cardiac myosin isozymes. Addition of KCl increased the trinitrophenylation of both highly reactive and slowly reactive lysyl residues in all of the three heavy meromyosins, however, the effect was more profound with cardiac heavy meromyosins. Addition of MgADP induced spectral changes in trinitrophenylated skeletal but not in cardiac myosins. Similar changes occurred in skeletal and to a lesser degree in ventricular heavy meromyosin, but no definite spectral changes were observed in atrial heavy meromyosin. The findings suggest that structural differences exist around the reactive lysyl residue in the head portion of the three myosins.     

Purification and characterization of myosin from bovine retina

Myosin has been isolated from bovine retinae and characterised by its ATPase (ATP phosphohydrolase, EC 3.6.1.3) activity, its mobility in sodium dodecyl sulphate polyacrylamide gels and by electron microscopy. The purified myosin shows high ATPase activity in the presence of EDTA or Ca²⁺ and a low activity in the presence of Mg²⁺. The Mg²⁺-dependent ATPase activity is stimulated by rabbit skeletal muscle actin. The presumptive retinal myosin possesses a major component which has a mobility in sodium dodecyl sulphate polyacrylamide gel electrophoresis similar to that of the heavy chain of bovine skeletal mucle myosin. Electron microscopy showed retinal myosin to form bipolar filaments in 0.1 M KCl. It is concluded that the retina possesses a protein with enzymic and structural properties similar to those of muscle myosin.     

Myosin structure. Proximity measurements by fluorescence energy transfer

The results of energy transfer experiments on the proximity of six sites on the globular head region of myosin are discussed. A large hydrophobic crevice has been detected on each myosin head which is sufficiently large to accommodate six aromatic rings simultaneously. In the crevice is located a thiol residue not involved in activation of myosin Ca²⁺ ATPase and a lysine residue which is specifically trinitrophenylated with 2, 4, 6-trinitrobenzenesulfonic acid. A second sulfhydryl whose modification activates the Ca²⁺ ATPase is located near the hydrophobic thiol site. The tryptophan whose fluorescence is enhanced by ATP binding is sufficiently close to the thiols and lysine residue to quantitatively transfer its energy to probes at these sites. The site of myosin ATPase has been tentatively located as being near the other five sites by energy transfer to or from synthetic chromophoric substrates. Implications of these results on the possibility of determining the location of the myosin light chain and actin binding sites are discussed.     

Identical behavior of the two active sites of myosin with respect to trinitrophenylation.

Myosin and its active subfragments were trinitrophenylated under conditions in which mainly the active site(s) was modified. Proteins modified at the active site(s) could be separated by affinity chromatography on agarose-ATP columns. By two independent methods, ATPase activity measurements and analysis of elution patterns on agarose-ATP columns, it was shown that the introduction of two trinitrophenyl groups per myosin or one per heavy meromyosin subfragment 1 molecule is responsible for the remarkable change in the ATPase activities. Heavy meromyosin subfragment 1 prepared from trinitrophenylated myosin retained the original degree of trinitrophenylation per "active head." The kinetic constant of trinitrophenylation of the epsilon-amino group of lysine at the active site was found to be 2000 S-1-M-1, whereas a much smaller constant of 2.2 S-1-M-1 was obtained for the trinitrophenylation of the unessential lysyl residues of myosin. By using affinity chromatography, we could follow the formation of mono- and ditrinitrophenyl myosin. The amounts of these myosin derivatives at various extents of the reaction corresponded approximately to the calculated amounts, assuming a random and independent trinitrophenylation of the two myosin "heads." It is concluded that in each of the two heads of myosin there is one ATPase active site and these two sites behave in an identical manner with respect to trinitrophenylation.     

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.     

Calcium ion-regulated thin filaments from vascular smooth muscle.

Myosin and actin competition tests indicated the presence of both thin-filament and myosin-linked Ca2+-regulatory systems in pig aorta and turkey gizzard smooth-muscle actomyosin. A thin-filament preparation was obtained from pig aortas. The thin filaments had no significant ATPase activity [1.1 +/- 2.6 nmol/mg per min (mean +/- S.D.)], but they activated skeletal-muscle myosin ATPase up to 25-fold [500 nmol/mg of myosin per min (mean +/- S.D.)] in the presence of 10(-4) M free Ca2+. At 10(-8) M-Ca2+ the thin filaments activated myosin ATPase activity only one-third as much. Thin-filament activation of myosin ATPase activity increased markedly in the range 10(-6)-10(-5) M-Ca2+ and was half maximal at 2.7 x 10(-6) M (pCa2+ 5.6). The skeletal myosin-aorta-thin-filament mixture gave a biphasic ATPase-rate-versus-ATP-concentration curve at 10(-8) M-Ca2+ similar to the curve obtained with skeletal-muscle thin filaments. Thin filaments bound up to 9.5 mumol of Ca2+/g in the presence of MgATP2-. In the range 0.06-27 microM-Ca2+ binding was hyperbolic with an estimated binding constant of (0.56 +/- 0.07) x 10(6) M-1 (mean +/- S.D.) and maximum binding of 8.0 +/- 0.8 mumol/g (mean +/- S.D.). Significantly less Ca2+ bound in the absence of ATP. The thin filaments contained actin, tropomyosin and several other unidentified proteins. 6 M-Urea/polyacrylamide-gel electrophoresis at pH 8.3 showed proteins that behaved like troponin I and troponin C. This was confirmed by forming interspecific complexes between radioactive skeletal-muscle troponin I and troponin C and the aorta thin-filament proteins. The thin filaments contained at least 1.4 mumol of a troponin C-like protein/g and at least 1.1 mumol of a troponin I-like protein/g.     

Mechanism of regulation of cardiac actin-myosin subfragment 1 by troponin-tropomyosin

The effect of Ca2+ on the interaction of bovine cardiac myosin subfragment 1 (S-1) with actin regulated by cardiac troponin-tropomyosin was evaluated. The ratios of actin to troponin and to tropomyosin were adjusted to optimize the Ca2+-dependent regulation of the steady-state actin-activated magnesium adenosinetriphosphatase (MgATPase) rate of myosin S-1. At 25 degrees C, pH 6.9, 16 mM ionic strength, the extrapolated values for maximal adenosine 5'-triphosphate (ATP) turnover rate at saturating actin, Vmax, were 6.5 s-1 in the presence of Ca2+ and 0.24 s-1 in the absence of Ca2+. In contrast to this 27-fold regulation of ATP hydrolysis, there was negligible Ca2+-dependent regulation of cardiac myosin S-1 binding to actin. In the presence of ATP, the dissociation constant of regulated actin and cardiac myosin S-1 was 32 microM in the presence of Ca2+ and 40 microM in the presence of [ethylenebis(oxyethylenenitrilo)]tetraacetic acid. These dissociation constants are indistinguishable from the concentrations of actin needed to reach half-saturation of the myosin S-1 MgATPase rates, 37 microM actin in the presence of Ca2+ and 53 microM in its absence. Although there may be Ca2+-dependent regulation of cross-bridge binding in the intact heart, the present biochemical studies suggest that cardiac regulation critically involves other parts of the cross-bridge cycle, evidenced here by almost complete Ca2+-mediated control of the myosin S-1 MgATPase rate even when the myosin S-1 is actin-bound.     

A coupling factor for photosynthetic phosphorylation from plastids of light- and dark-grown maize

1. Maize chloroplasts contain a trypsin-, dithiothreitol-, and Ca²⁺-activated ATPase. This enzyme, which can serve as a coupling factor for photosynthetic phosphorylation, differs slightly in a few properties but in general resembles a similar one in spinach plastids which was described earlier by others.

2. Maize etioplasts (immature plastids in dark-grown plants) also contain this ATPase, and it is shown that NaCl-EDTA extracts of etioplasts can restore photosynthetic phosphorylation activity to depleted green membranes of chloroplasts.

3. Electron microscopy of maize etioplast and chloroplast membranes demonstrates the presence of protruding knobs, approx. 90 Å in diameter. Removal and reassociation of knobs with membranes can be correlated with the ability to carry on photosynthetic phosphorylation.

4. Most or possibly all of the coupling factor (measured as ATPase) activity of a chloroplast may be present in the etioplast from which it develops. The photosynthetic membrane of the chloroplast can be formed in stages.

5. The significance of these observations is discussed with regard to membrane formation in general and plastid membrane development in particular.     

Effect of myosin DTNB light chain on the actin-myosin interaction in the presence of ATP.

The influence of the DTNB light chain of myosin on its enzymatic activities was examined by studying the superprecipitation of actomyosin and the actin-activated ATPase of heavy meromyosin (HMM) [EC 3.6.1.3]. Although the Ca2+-, Mg2+-, and EDTA-ATPase activities of control and DTNB myosin were practically the same, the superprecipitation of actomyosin prepared from actin and DTNB myosin occurred more slowly than that of control myosin. The apparent binding constant obtained from double-reciprocal plots of actin-activated ATPase of DTNB HMM was lower than that of control HMM. Recombination of DTNB myosin and HMM with DTNB light chains restored the original properties of myosin and HMM. The removal of DTNB light chain from myosin had no effect on the formation of the rigor complex between actin and myosin. These results suggest that the DTNB light chain participates in the interaction of myosin with actin in the presence of ATP.     

Presence of a unit for actin-myosin interaction during the superprecipitation of actomyosin.

The interaction of actin with myosin was studied in the presence of ATP at low ionic strength by means of measurements of the actin-activated ATPase activity of myosin and superprecipitation of actomyosin. At high ATP concentrations the ATPase activities of myosin, heavy meromyosin (HMM) and myosin subfragment 1 (S-1) were activated by actin in the same extent. At low ATP concentrations the myosin ATPase activity was activated about 30-fold by actin, whereas those of HMM and S-1 were stimulated only several-fold. This high actin activation of myosin ATPase was coupled with the occurrence of superprecipitation. The activation of HMM or S-1 ATPase by actin shows a simple hyperbolic dependence on actin concentration, but the myosin ATPase was maximally activated by actin at a 2:1 molar ratio of actin to myosin, and a further increase in the actin concentration had no effect on the activation. These results suggest the presence of a unit for actin-myosin interaction, composed of two actin monomers and one myosin molecule in the filaments.     

Actin-activation of unphosphorylated gizzard myosin

The effect of light chain phosphorylation on the actin-activated ATPase activity and filament stability of gizzard smooth muscle myosin was examined under a variety of conditions. When unphosphorylated and phosphorylated gizzard myosins were monomeric, their MgATPase activities were not activated or only very slightly activated by actin, and when they were filamentous, their MgATPase activities could be stimulated by actin. At pH 7.0, the unphosphorylated myosin in the presence of ATP required 2-3 times as much Mg2+ for filament formation as did the phosphorylated myosin. The amount of stimulation of the unphosphorylated myosin filaments depended upon pH, temperature, and the presence of tropomyosin. At pH 7.0 and 37 degrees C and at pH 6.8 and 25 degrees C, the MgATPase activity of filamentous, unphosphorylated, gizzard myosin was stimulated 10-fold by actin complexed with gizzard tropomyosin. These tropomyosin-actin-activated ATPase activities were 40% of those of the phosphorylated myosin. Under other conditions, pH 7.5 and 37 degrees C and pH 7.0 and 25 degrees C, even though the unphosphorylated myosin was mostly filamentous, its MgATPase activity was stimulated only 4-fold by tropomyosin-actin. Thus, both unphosphorylated and phosphorylated gizzard myosin filaments appear to be active, but the cycling rate of the unphosphorylated myosin is less than that of the phosphorylated myosin. Active unphosphorylated myosin may help explain the ability of smooth muscles to maintain tension in the absence of myosin light chain phosphorylation.