The two pathways for oxygen exchange by actomyosin and myofibrils and their dependence on temperature

At an intermediate stage in the hydrolysis of MgATP by actomyosin there is an exchange of oxygen between water and the terminal phosphoryl group of MgATP, tightly bound to the myosin active site. This intermediate oxygen exchange results from the reversible hydrolysis of the bound MgATP. The rate of the exchange cycle (hydrolysis and the reverse) is assumed to be determined by the rate of reverse hydrolysis; and the average time available for exchange is determined by the post-exchange reaction that immediately follows the cycle. Past analytical studies of the exchange, using actomyosin mixtures and myofibrils at room temperature, have revealed two pathways for hydrolysis, operating at a comparable flux but differing greatly in the extent of exchange they support. It is shown here that these pathways also appear over a range of temperatures from 5 to 30 degrees C and that temperature had little effect on their relative fluxes. At each temperature, the flux ratio (%) for the low exchange pathway: high exchange pathway was near 50:50 for actomyosin mixtures and 60:40 for myofibrils. Apparently, the rate-limiting steps that determine the fluxes of the two pathways have a similar temperature dependence. However, the analysis indicates that one or both of the steps that determine the extent of exchange (reverse-hydrolysis and/or the post-exchange reaction) shows a different temperature dependence for the two pathways. We interpret this to reflect a difference in the temperature dependence of the post-exchange reaction, which we propose is exceedingly fast and independent of actin concentration along the low exchange route, but slow and dependent on the actin concentration along the high exchange route. Thus at all temperatures over a broad range of actin concentration there are two pathways of comparable flux that differ primarily in the time available for exchange.     

Oxygen-exchange studies on the pathways for magnesium adenosine 5'-triphosphate hydrolysis by actomyosin

At an intermediate stage in the hydrolysis of magnesium adenosine 5'-phosphate (MgATP) by myosin or actomyosin, there is an exchange of oxygen between water and the P gamma group of enzyme-bound nucleotide. Starting with [P gamma-18O]ATP as substrate, the exchange is revealed in the [18O]Pi species that are ultimately released as product into the reaction medium. An analysis of the distribution of these labeled Pi species, which contain 3, 2, 1, or none of the 18O atoms originally on the P gamma of ATP, is used to probe intermediate stages of the hydrolytic mechanism. In recent years, studies of this kind by several groups have shown that more than one pathway of hydrolysis operates. The work reported here demonstrates that two of these pathways are spurious; one is a "nonexchanging MgATPase" that is present in fresh myosin preparations; the other is an induced slow exchange that develops in myosin during storage (-20 degrees C) and subsequent aging (4 degrees C). However, after correction for these artifacts, two normal pathways for actomyosin hydrolysis remain. These normal pathways differ in the mode of interaction between actin and myosin in the course of hydrolysis; one is the Lymn-Taylor pathway where oxygen exchange occurs at a stage when actin and myosin are dissociated; the other is a pathway in which actin and myosin are associated during oxygen exchange. Each of these two pathways contributes an equal amount of Pi to the product pool. Thus, on average, each myosin head uses each of these pathways half the time. The findings suggest, e.g., that during contraction, myosin can dissociate from the actin filament only during every other cycle of MgATP hydrolysis or that only half the heads, at any one time, can exchange oxygen while free of the actin filament.     

Translational motion of actin filaments in the presence of heavy meromyosin and MgATP as measured by Doppler broadening of laser light scattering

Intensity fluctuations of laser light scattering were utilized in order to follow enhancement of translational motion of the actin-heavy meromyosin (HMM) complex in extremely dilute solutions accompanied by the hydrolysis of MgATP. Such enhancement was anticipated on the basis of the idea that active streaming along actin filaments should be associated with their mechanochemical reactivity. Native tropomyosin was added in order to stabilize actin in its filamentous form, thus allowing the reduction of actin concentration below 50 micrograms/ml to enable free movement of neighboring filaments and yet give a reliable signal. Analysis of the data in terms of Doppler broadening led to an approximate evaluation of the average velocity of translation of the mobile filaments. This velocity was found to increase with increasing HMM concentration up to a maximum attained at a molar ratio HMM/actin of 1:2, and then decreased. Total intensity measurements indicate that the mobile scatterer is actually a complex of HMM with an isolated actin filament. HMM subfragment-1 was found to be ineffective. These results suggest that cooperation between the two myosin heads is necessary for efficient induction of active streaming along isolated actin filaments.     

Evaluation of mechanical parameters of the mechanochemically 'active state' of actin filaments on the basis of purely chemical data

Oosawa and his collaborators (cf. F. Oosawa, Biophys. Chem. 11 (1980) 443), employing various optical techniques, have shown that the flexibility of actin filaments increases upon interacting with the enzymatically active myosin fragments, particularly heavy meromyosin (HMM). It has been reported (S. Hitchock, L. Carlsson and U. Lindberg, Cell 7 (1976) 53) that HMM can accelerate the DNase 1-induced depolymerization of F-actin, provided MgATP is also present. Since, as we have demonstrated (cf. J. Borejdo myosin, is endowed with mechanochemical capability, we made an attempt to correlate the enhanced rate of depolymerization with the decrease in rigidity of the G-G bonds in F-actin. On the basis of the chemical kinetic data of Hitchcock et al. we could derive the approximate value of the HMM-MgATP-induced change in rigidity which is a mechanical molecular parameter. Since interaction between HMM or HMM subfragment-1 and F-actin in the presence of MgATP leads to the movement of the myosin heads along the actin filaments, it is argued that the enzymic behavior of this system should not be analyzed on the basis of simple, equilibrium, complex formation.     

Intermediate oxygen exchange catalyzed by the actin-activated skeletal myosin adenosinetriphosphatase

Considerable effort has been devoted to understanding the mechanism of 18O exchange in skinned skeletal and insect muscle fibers. However, a full understanding of the mechanism of 18O exchange in muscle fibers requires an understanding of the mechanism of 18O exchange in the simpler in vitro systems employing myosin subfragment 1 (S-1) and heavy meromyosin (HMM). In the present study, using both S-1 and S-1 covalently cross-linked to actin, we show first that over a wide range of temperature, ionic strength, and actin concentration there is only one pathway of 18O exchange with S-1. This is also the case with HMM except at very low ionic strength and low actin concentration, and even here, the data can be explained if 20% of the HMM is denatured in such a way that it shows no 18O exchange. Our results also show that actin markedly decreases the rate of 18O exchange. If it is assumed that Pi release is rate limiting, the four-state kinetic model of the actomyosin ATPase cannot fit these 18O exchange data. However, if it is assumed that the ATP hydrolysis step is rate limiting and Pi release is very fast, the four-state kinetic model can qualitatively fit these data although the fit is not perfect. A better fit to the 18O exchange data can be obtained with the six-state kinetic model of the actomyosin ATPase, but this fit requires the assumption that, at saturating actin concentration, the rate of Pi rotation is about 9-fold slower than the rate of reversal of the ATP hydrolysis step.     

Interaction between actin and HMM

It is shown that the interaction between actin and HMM results in a rapid precipitation of acto-HMM gel upon addition of MgATP. This is a simple demonstration of the idea that the formation of myosin filaments is not essential for mechanochemical reaction (muscle contraction) to occur and that the soluble myosin heads are competent to interact with actin to produce mechanical effect. Our findings also strongly support earlier suggestion that each head of one HMM molecule is able to bind to a different actin filament.     

Mechanism of oxygen exchange in actin-activated hydrolysis of adenosine triphosphate by myosin subfragment 1.

The gamma-phosphoryl groups of two intermediates (M-ATP and M-ADP-P1) in the pathway of MgATP hydrolysis by myosin undergo extensive oxygen exchange with water. Actin activates the overall rate of hydrolysis at a rate-limiting step which follows these exchange reactions. Thus, actin, by decreasing the turnover time of hydrolysis, would be expected to proportionately decrease the time available for oxygen exchange. Using subfragment 1 of myosin, the turnover time of hydrolysis can be varied over a wide range by changing the concentration of actin. An estimate for the rate constant of exchange can then be obtained by relating these turnover times to measured values for oxygen exchange (incorporation of 18O from H218O into the inorganic phosphate (Pi) released by hydrolysis). The results of such an experiment, with turnover times between 0.2 and 25 s, indicate that, for each gamma-phosphoryl group, one oxygen from the medium is added rapidly (to cleave the phosphoryl group or form a pentacoordinate phosphroyl complex); two more oxygens exchange with a rate constant, kc, of about 1 s-1; and a fourth oxygen exchanges slowly with ke about 0.2 s-1. The higher value is about 18 times smaller than the rate constant, 5-3, for the reverse cleavage step of the myosin pathway, which is postulated to be responsible for oxygen exchange. The data, then, indicate that the rate-limiting step for oxygen exchange is not k-3, but may be the rate of rotation of oxygens around the phosphorus atom, with one oxygen severely restricted by its binding to the active site. The finding that kc differs for the four oxygens in each phosphate group is related to past observations on myosin-catalyzed oxygen exchange.     

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.     

Induction of contractile activity by rigor complexes in myofibrils

The relation between ATPase rate and substrate concentration was investigated for myofibrils with varying amounts of added HMM. There was a biphasic, 3 to 5-fold increase in ATPase in the absence of Ca⁺⁺. In the absence of added HMM, the peak activity occurred at ≤ 0.1 mM MgATP. With increasing concentrations of HMM, the position and magnitude of the ATPase peak shifted to larger substrate concentrations and higher rates. The cofactor activity of regulated actin in myofibrils is activated to a similar degree by Ca⁺⁺ as by HMM (rigor links). SDS gel electrophoretic patterns of myofibrils mixed with HMM indicated the soluble HMM binds to myofibrils at 0.1 mM MgATP and is dissociated at higher MgATP concentrations. Thus, in well-regulated myofibrils in the absence of Ca⁺⁺ actin cofactor activity can be activated by rigor complexes.     

The binding of myosin heads on heavy meromyosin and assembled myosin to actin in the presence of nucleotides. Measurements by the proteolytic rates method

The initial rates of tryptic digestion at the 50/20-kDa junction in myosin and myosin subfragment 1 were determined for the free proteins and their complexes with actin in the presence and absence of MgATP. The proteolytic reactions were carried out at 24 degrees C and under ionic strength conditions (mu) adjusted to 35, 60, and 130 mM. The percentages of myosin heads and myosin subfragment 1 bound to actin in the presence of MgATP were calculated from the rates of proteolysis for each set of digestion experiments. In all cases, the myosin heads in the synthetic filaments showed greater binding to actin than myosin subfragment 1. This binding difference was most prominent (3-fold) at mu = 130 mM. The binding of heavy meromyosin (HMM) to actin in the presence of MgADP was measured at 4 degrees C by ultracentrifugation and the proteolytic rates methods. Ultracentrifugation experiments determined the fraction of HMM molecules bound to actin in the presence of MgADP, whereas the proteolytic measurements yielded the information on the fraction of HMM heads bound to actin. Taken together, these measurements show that a significant fraction of HMM is bound to actin with only one head in the presence of MgADP under ionic conditions of 180 and 280 mM.     

Tryptic digestion of rabbit skeletal myofibrils: an enzymatic probe of myosin cross-bridges

Tryptic digestion of rabbit skeletal myofibrils under physiological ionic strength and pH conditions was used as a probe of cross-bridge interaction with actin in the presence of nucleotides and pyrophosphate. Under rigor conditions, digestion of myofibrils at 24 degrees C results in the formation of 25K, 110K [heavy meromyosin (HMM)], and light meromyosin (LMM) fragments as the main reaction products. Very little if any 50K peptide is generated in such digestions. In the presence of magnesium pyrophosphate, magnesium 5'-adenylyl imidodiphosphate (MgAMPPNP), and MgATP, the main cleavage proceeds at two positions, 25K and 75K from the N-terminal portion of myosin, yielding the 25K, 50K, and 150K species. The relative amounts of the 50K, 110K, and 150K peptides and the rates of myosin heavy-chain digestion in the presence of pyrophosphate and AMPPNP indicate partial dissociation of myosin from actin. Direct centrifugation measurements of the binding of HMM and subfragment 1 (S-1) to actin in myofibrils confirm that cross-bridges partition between attached and detached states in the presence of these ligands. In the presence of MgADP, HMM and S-1 remain attached to actin at 24 degrees C. However, tryptic digestion of myofibrils containing MgADP is consistent with the existence of a mixed population of attached and detached cross-bridges, suggesting that only one head on each myosin molecule is attached to actin. As shown by tryptic digestion of myofibrils and the measurements of HMM and S-1 binding to actin, nucleotide- and pyrophosphate-induced dissociation of cross-bridges is more pronounced at 4 than at 24 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)     

N-ethylmaleimide-modified heavy meromyosin. A probe for actomyosin interactions

Treatment of rabbit skeletal muscle heavy meromyosin (HMM) with the sulfhydryl reagent N-ethylmaleimide (NEM) produces a species of HMM which remains tightly bound to actin in the presence of MgATP. NEM-HMM forms characteristic "arrowhead" complexes with actin which persist despite rinses with MgATP. NEM-HMM inhibits the actin activation of native HMM-ATPase activity, the superprecipitation of actomyosin, the contraction of glycerinated muscle myofibrils, and the contraction of cytoplasmic strands of the soil amoeba Chaos carolinensis. However, NEM-HMM does not interfere with in vitro microtubule polymerization or beating of demembranated cilia.     

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.     

Novel Mode of Cooperative Binding between Myosin and Mg-actin Filaments in the Presence of Low Concentrations of ATP

Cooperative interaction between myosin and actin filaments has been detected by a number of different methods, and has been suggested to have some role in force generation by the actomyosin motor. In this study, we observed the binding of myosin to actin filaments directly using fluorescence microscopy to analyze the mechanism of the cooperative interaction in more detail. For this purpose, we prepared fluorescently labeled heavy meromyosin (HMM) of rabbit skeletal muscle myosin and Dictyostelium myosin II. Both types of HMMs formed fluorescent clusters along actin filaments when added at substoichiometric amounts. Quantitative analysis of the fluorescence intensity of the HMM clusters revealed that there are two distinct types of cooperative binding. The stronger form was observed along Ca²⁺-actin filaments with substoichiometric amounts of bound phalloidin, in which the density of HMM molecules in the clusters was comparable to full decoration. The novel, weaker form was observed along Mg²⁺-actin filaments with and without stoichiometric amounts of phalloidin. HMM density in the clusters of the weaker form was several-fold lower than full decoration. The weak cooperative binding required sub-micromolar ATP, and did not occur in the absence of nucleotides or in the presence of ADP and ADP-Vi. The G680V mutant of Dictyostelium HMM, which over-occupies the ADP-Pi bound state in the presence of actin filaments and ATP, also formed clusters along Mg²⁺-actin filaments, suggesting that the weak cooperative binding of HMM to actin filaments occurs or initiates at an intermediate state of the actomyosin-ADP-Pi complex other than that attained by adding ADP-Vi.     

Muscle contraction: a mechanism of energy transduction

A mechanism of muscle contraction is presented in which energy from the hydrolysis of MgATP is transferred directly to conformational strain in a flexible segment of the myosin head. That segment is proximal to both the active site and the subfragment 1—subfragment 2 hinge (the portion of the myosin molecule that connects each of its two enzymatically active globular heads to the long thin helical body). This proximity allows configurational changes at the active site, which are an intrinsic part of the enzymatic mechanism, to impose a localized strain, or distortion, near the hinge. The energy, trapped in the protein this way, is subsequently used for mechanical work when other enzymatically-induced conformational changes free the strained segment of the myosin head to unbend. As this happens, the head rotates and the distal end (opposite the hinge) attaches to the actin filament and pulls on it. In this mechanism, actin interacts with myosin in two different ways: (1) at the active site where it activates a step in the hydrolysis of MgATP that frees the head to rotate; (2) at the distal end of myosin, where it forms the grip through which the rotating head pulls on the actin filament. The first interaction allows actin to initiate primary movement of the myosin head; the second directs the force and allows the movement of the head to be used for the sliding motion of the actin and myosin filaments during contraction. In this model, there are also two different energy transfers: one occurs in the transduction process itself when energy from hydrolysis is trapped as conformational distortion in the hinge region; the other occurs, reversibly, when actin and myosin form and then break the distal grip; in this second transfer there is no net energy change in the course of a cycle. A chemical mechanism is suggested to explain actin-activation of hydrolysis at the active site-hinge region.     

Calcium-sensitive binding of heavy meromyosin to regulated actin requires light chain 2 and the head-tail junction

Sedimentation in a preparative ultracentrifuge was used to determine the affinity of heavy meromyosin, HMM, for regulated actin, F-actin plus troponin-tropomyosin, in the presence of MgATP at pH 7.0, 20 degrees C, and mu = 18 mM. HMM was prepared from vertebrate striated muscle myosin by a mild chymotryptic digestion. This HMM contained 85-90% intact 19 000-dalton light chains, LC2. In the presence of calcium, 90% of the HMM bound to regulated actin with an association constant of (2-4) X 10(4) M-1. In the absence of calcium, while one-third of the HMM bound with an affinity similar to that observed in the presence of calcium, the rest bound much more weakly. It was not possible to accurately determine the association constant for this weakly binding HMM, but a 20-fold reduction in affinity is consistent with the binding data. The binding of single-headed heavy meromyosin to regulated actin was similarly sensitive to the calcium concentration. Since removal of calcium inhibits the regulated actin-activated ATPase of HMM greater than 20-fold, troponin-tropomyosin must be capable of inhibiting both the binding of HMM to regulated actin and a step which occurs after binding but prior to product release. Removal of LC2 increased the fraction of HMM with calcium-insensitive binding, and adding LC2 back to this depleted HMM restored most of the calcium sensitivity. Chymotryptic cleavage of LC2 to a 17 000-dalton fragment destroyed the calcium-sensitive binding of HMM to regulated actin. Phosphorylation of LC2, however, had no detectable effect on this binding. Thus, the calcium-sensitive binding of HMM to regulated actin requires that both the head-tail junction and the N-terminal part of LC2 be intact. Binding studies with cross-linked regulated actins and kinetic measurements of the rates of change in turbidity demonstrate that this calcium sensitivity is due to calcium binding to troponin and not to LC2.     

The binding of smooth muscle heavy meromyosin to actin in the presence of ATP. Effect of phosphorylation

Phosphorylation of the 20,000-dalton light chains of smooth muscle heavy meromyosin (HMM) from turkey gizzards results in a large increase in the actin-activated MgATPase activity over that observed with unphosphorylated HMM. In an attempt to define which step in the kinetic cycle is affected by phosphorylation, we have measured the binding of both unphosphorylated and phosphorylated HMM to actin in the presence of ATP using sedimentation. There was only a 4-fold difference in the actin binding constants of unphosphorylated HMM (5.35 x 10(3) M-1) and fully phosphorylated HMM (2.35 x 10(4) M-1). In contrast, the maximum rate of the actin-activated MgATPase activity (Vmax) of phosphorylated HMM was 25 times greater than that for unphosphorylated HMM. These data rule out a mechanism whereby the unphosphorylated light chain of myosin regulates actin-myosin interaction by directly or indirectly blocking the binding of HMM to actin. This implies that some step in the kinetic cycle other than the binding of HMM to actin must be regulated. We have also measured the rate constant for ATP hydrolysis (the initial phosphate burst) under the same conditions and found that this step was very fast compared to the steady state ATPase rate and was unaffected by phosphorylation. This suggests that the step which is regulated by phosphorylation is either phosphate release or a step preceding phosphate release but following ATP hydrolysis.     

Inhibition of actin-tropomyosin activation of myosin MgATPase activity by the smooth muscle regulatory protein caldesmon.

Caldesmon inhibition of actin-tropomyosin activation of myosin MgATPase activity was investigated. greater than 90% inhibition of ATPase activation correlated with 0.035-0.1 caldesmon bound per actin monomer over a wide range of conditions. Caldesmon inhibited sheep aorta actin-tropomyosin activation of skeletal muscle heavy meromyosin (HMM) by 85%, but had no effect on the binding affinity of HMM.ADP.Pi to actin. At ratios of 2 and 0.12 subfragment 1 (S1):1 actin, addition of caldesmon inhibited the ATPase activation by up to 95%, but did not alter the fraction of S1.ADP.Pi associated with actin-tropomyosin. We concluded that caldesmon inhibited actomyosin ATPase by slowing the rate-limiting step of the activation pathway. At concentrations comparable to the ATPase measurements, S1 displaced caldesmon from native thin filaments both in the absence (rigor) and the presence of MgATP. We therefore concluded that caldesmon could displace S1.ADP.Pi from actin-tropomyosin only under exceptional circumstances. An expressed mutant of caldesmon comprising just the C-terminal 99 amino acids bound actin 10 times weaker than whole caldesmon but otherwise inhibited actin-tropomyosin activation with the same potency and same mechanism as intact caldesmon. Thus, the entire inhibitory function of caldesmon resides in its extreme C terminus.     

Inhibition of sliding movement of F-actin by crosslinking emphasizes the role of actin structure in the mechanism of motility

The effects of crosslinking of monomeric and polymeric actin with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC), disuccinimidyl suberate (DSS) and glutaraldehyde on the interaction with heavy meromyosin (HMM) in solution and on the sliding movement on glass-attached HMM were examined. The Vmax values of actin-activated HMM ATPase decreased in the following order: intact actin = EDC F-actin greater than DSS actin greater than glutaraldehyde F-actin = glutaraldehyde G-actin greater than EDC G-actin. The affinity of actin for HMM in the presence of ATP decreased in the following order: DSS actin greater than glutaraldehyde F-actin = glutaraldehyde G-actin greater than intact actin greater than EDC F-actin greater than EDC G-actin. However, sliding movement was inhibited only in the case of glutaraldehyde-crosslinked F and G-actin and EDC-crosslinked G-actin. Interestingly, after copolymerization of "non-motile" glutaraldehyde or EDC-crosslinked monomers with "motile" monomers of intact actin sliding of the copolymers was observed and its rate was independent of the type of crosslinked monomer, i.e. of the manner of their interaction with HMM. These data strongly indicate that inhibition of the sliding of actin by crosslinking cannot be explained entirely by changes in the Vmax value or affinity for myosin heads. We conclude that movement is generated by interaction of myosin with segments of F-actin containing a number of intact monomers, and the mechanism of inhibition involves an effect of the crosslinkers on the structure of F-actin itself.     

Crosslinking of trypsin digested acto-heavy meromyosin as a probe of the affinity of the two myosin heads to actin

The interaction of the two heads of the myosin molecule with actin was studied by tryptic digestion of HMM in the presence of actin, followed by crosslinking the two nicked heavy chains with Nbs2 at the S2 region. In view of the protection by actin of the 50/60 kDa junction against proteolysis, the percentage of the heads interacting with actin was estimated from the proportion of the 110 kDa to the 60 kDa digestion product. Under conditions such that about 50% of HMM heads were protected by actin (at an actin to HMM head molar ratio of 1:1 in the absence of nucleotide, or 3:1 in the presence of 5 mM ADP), the crosslinking of the digestion products yielded a 230 kDa (110 + 110 kDa), 125 kDa (60 + 60 kDa) and 175 kDa (60 + 110 kDa) species. Since the latter should be the only crosslinking product when only one head of HMM molecule is protected by actin, it is concluded that there is no preferential binding of one of the two HMM heads to actin in the presence of ADP or at equimolar actin to myosin heads ratio.