Structural stability of fish myosin subfragment-1

1. Tryptic cleavage of fish myosin subfragment-1 (S-1) revealed its similar substructure of heavy chain to that of rabbit S-1. 2. The structural stability of fish S-1 was studied by thermal denaturation method, and a rapid polymerization of inactivated fish S-1, detected by turbidity increase, was characteristic. 3. The light-chain release and tryptic susceptibility increase upon heating were significant with fish S-1.     

Binding of magnesium to myosin subfragment-1 ATPase

Tyr 180 of chicken breast muscle alkali light chain A1 was nitrated with tetranitromethane. The nitroA1 was incorporated into chicken breast muscle subfragment-1 (S-1) by exchange with the intrinsic alkali light chain. In the presence of adenylylimidodiphosphate (AMPPNP) or ADP, the S-1 containing nitroA1 showed a difference visible absorption spectrum by Mg2+ or Ca2+. The difference spectrum has a trough around 435 nm, indicating a blue shift of the absorption spectrum due to the nitrophenol chromophore of the modified A1. The plot of delta A at 435 nm versus concentration of free Mg2+ fitted a single binding curve, independent of the total concentration of AMPPNP. These results reveal that free Mg2+ binds to the active site of S-1 ATPase, but not as Mg-AMPPNP complex. The dissociation constants of magnesium from S-1 complex were different with the two nucleotides and were 1.25 X 10(-8) M and 1.24 X 10(-7) with AMPPNP and ADP, respectively. The difference spectrum was also obtained in the presence of ATP. The delta epsilon value after adding ATP changed with the ATPase reaction. The steady state rate of S-1 ATPase was measured at various concentrations of free Mg2+. The dissociation constant of magnesium from the steady state complex, EPADP(a), was estimated as 6 X 10(-8) M. These results suggest that the affinity of magnesium at the active site of ATPase changes with the intermediate states of ATPase reaction. The affinity of calcium was lower than that of magnesium.     

Binding of myosin subfragment-1 to F-actin.

During a part of the hydrolytic cycle, myosin head (S1) carries no nucleotide and binds strongly to an actin filament forming a rigor bond. At saturating concentration of S1 in rigor, S1 is well known to form 1:1 complex with actin. However, we have provided evidence that under certain conditions S1 could also form a complex with 2 actin monomers in a filament (Andreev, O.A. & Borejdo, J. (1991) Biochem. Biophys. Res. Comm. 177, 350-356). This view was recently challenged by Carlier & Didry (Carlier, M-F. & Didry, D. (1992) Biochem. Biophys. Res. Comm. 183, 970-974) who interpreted our data by suggesting that F-actin underwent a simple depolymerization and implied that, when only actin in the F-form was scored, the real stoichiometry in our experiments was 1:1. We show here that under conditions of our experiments less than 8% of actin was depolymerized. Moreover, we have repeated the experiments in the presence of phalloidin and show that under these conditions too, when S1 was added slowly to a fixed concentration of F-actin, it formed a different complex with F-actin than when it was added quickly. This confirms our original conclusion that S1 can bind actin in two different ways and shows that depolymerization of F-actin is not responsible for this finding.     

Betaine protects urea-induced denaturation of myosin subfragment-1

We have demonstrated previously that urea inhibits the activity and alters the tertiary structure of skeletal muscle myosin in a biphasic manner. This was attributed to differential effects on its globular and filamentous portion. The inhibition of catalytic activity was counteracted by methylamines. With the aim of comprehending the effects of urea on the catalytic (globular) portion of myosin, this study examines the effects of urea and the countereffects of betaine on the catalytic activity and structure of myosin subfragment-1. It is shown that urea inactivates subfragment-1 in parallel with its ability to induce exposure of the enzyme hydrophobic domains, as assessed using intrinsic and extrinsic fluorescence. Both effects are counteracted by betaine, which alone does not significantly affect subfragment-1. Urea also enhances the accessibility of thiol groups, promotes aggregation and decreases the alpha-helix content of S1, effects that are also counteracted by betaine. We conclude that urea-induced inactivation of the enzyme is caused by partial unfolding of the myosin catalytic domain.     

Bundling of myosin subfragment-1-decorated actin filaments

We have reported previously that rabbit skeletal myosin subfragment-1 (S-1) assembles actin filaments into bundles. The rate of this reaction can be estimated roughly from the initial rate (Vo) of the accompanying turbidity increase ("super-opalescence") of the acto-S-1 solution. Vo is a function of the molar ratio (r) of S-1 to actin, with a peak at r = 1/6 to 1/7 and minimum around r = 1. In the present paper we report a different type of opalescence (we call it "hyper-opalescence") of acto-S-1 solutions, which also resulted from bundle formation. Adjacent filaments in the bundles had a distance of approximately 180 A. Hyper-opalescence occurred at r approximately equal to 1 when KCOOCH3 was used instead of KCl. By comparing the effects of ADP, epsilon-ADP, tropomyosin or ionic strength upon the super- and hyper-opalescence, we concluded that the two types of S-1-induced actin bundling had different molecular mechanisms. The hyper-opalescence type of bundling seemed to be induced by S-1, which was not complexed with actin in the manner of conventional rigor binding. The presence of the regulatory light chain did not affect hyper-opalescence (or super-opalescence), since there were no significant differences between papain S-1 and chymotryptic S-1 with respect to these phenomena.     

Transient kinetic analysis of N-phenylmaleimide-reacted myosin subfragment-1

Alkylation of myosin's Cys-707 (SH1) and Cys-697 (SH2) has profound consequences for myosin's ability to interact with actin and hydrolyze MgATP. Pre-steady-state measurements of myosin-S1 alkylated at SH1 and SH2 by N-phenylmaleimide (NPM) in the presence of ATP were taken to identify the steps of the reaction that are altered. It was found that the rate constant most affected by this modification is the apparent rate of the ATP hydrolysis step. This rate constant is reduced 20000-fold, an effect comparable in magnitude to the effect of the same modification on the binding of MgATP to S1 or acto-S1 [Xie, L., and Schoenberg, M. (1998) Biochemistry 37, 8048]. In contrast, the rate constants of phosphate release and dissociation of acto-S1 by ATP were reduced <20-fold. For unmodified S1, the enhancement of fluorescence seen after addition of ATP had the same rate constant as the ATP hydrolysis step (S1.ATP if S1.ADP.Pi) measured by single-turnover experiments in a quench-flow experiment. This is consistent with results previously observed [Johnson, K. A., and Taylor, E. W. (1978) Biochemistry 17, 3432]. However, NPM-modified S1 exhibited virtually no fluorescence enhancement upon ATP binding. This provides further evidence that M.ATP is the predominant intermediate of NPM-S1-catalyzed ATP hydrolysis.     

Fluorescence energy transfer between subfragment-1 and actin points in the rigor complex of actosubfragment-1.

The fast-reacting thiol (SH1) of myosin subfragment-1 (S-1) was covalently and specifically labeled with (iodoacetamido)fluorescein (IAF), while Cys-373 of actin was also covalently and preferentially labeled with N-(iodoacetyl)-N'-(1-sulfo-5-naphthyl)ethylenediamine (1,5-IAEDANS). The method of fluorescence energy transfer was used to examine the spatial proximity between the two sites, i.e., SH1 and Cys-373, in the rigor complex of acto-S-1. Approximately 30% fluorescence energy transfer was observed from the 1,5-IAEDANS on actin as a donor to the IAF on S-1 as an acceptor in their rigor complex; under certain assumptions this corresponds to a distance of ca. 6.0 nm.     

Nucleotide- and temperature-induced changes in myosin subfragment-1 structure.

The effects of nucleotide binding and temperature on the internal structural dynamics of myosin subfragment 1 (S1) were monitored by intrinsic tryptophan phosphorescence lifetime and fluorescence anisotropy measurements. Changes in the global conformation of S1 were monitored by measuring its rate of rotational diffusion using transient electric birefringence techniques. At 5 degrees C, the binding of MgADP, MgADP,P and MgADP,V (vanadate) progressively reduce the rotational freedom of S1 tryptophans, producing what appear to be increasingly more rigidified S1-nucleotide structures. The changes in the luminescence properties of the tryptophans suggest that at least one is located at the interface of two S1 subdomains. Increasing the temperature from 0 to 25 degrees C increases the apparent internal mobility of S1 tryptophans in all cases and, in addition, a reversible temperature-dependent transition centered near 15 degrees C was observed for S1, S1-MgADP and S1-MgADP,P, but not for S1-MgADP,V. The rotational diffusion constants of S1 and S1-MgADP were measured at temperatures between 0 and 25 degrees C. After adjusting for the temperature and viscosity of the solvent, the data indicate that the thermally induced transition at 15 degrees C comprises local conformational changes, but no global conformational change. Structural features of S1-MgADP,P, which may relate to its role in force generation while bound to actin, are presented.     

Preparation of subfragment-1 from abalone smooth muscle myosin

Myosin subfragment-1 (S1), which has one heavy chain (HC) (93 kDa) and two light chains (LC1 and LC2), was prepared by papain digestion of myosin from abalone-smooth muscle in the presence of Ca2+. The Ca-sensitivity of abalone S1 itself was not lost completely (about 30%). The tryptic digestion of S1 showed that in the presence of EDTA, S1 HC was split into 68, 55, and 23 kDa fragments, as in the presence of Ca2+, but 23 kDa was further degraded into 19 kDa. In contrast to the result in the presence of Ca2+, LCs disappeared in the early stage of reaction and Ca-ATPase activity decreased rapidly to about 70% of that of intact S1. This rapid decrease of Ca-ATPase activity seemed to be accompanied with the digestion of LCs. Therefore, LCs contribute to the protection of 23 kDa fragment from further digestion, to the maintenance of Ca-ATPase activity by stabilizing the structure of S1 to some extent in the presence of Ca2+. Since F-actin suppressed the cleavage of S1 HC to 68 and 23 kDa during tryptic digestion, it might be that 23 and 68 kDa corresponded to 20 kDa (C-terminal fragment) and to 50 + 25 kDa (N-terminal fragment) of skeletal myosin S1, respectively.     

Caldesmon inhibits skeletal actomyosin subfragment-1 ATPase activity and the binding of myosin subfragment-1 to actin

Smooth muscle contraction is controlled in part by the state of phosphorylation of myosin. A recently discovered actin and calmodulin-binding protein, named caldesmon, may also be involved in regulation of smooth muscle contraction. Caldesmon cross-links actin filaments and also inhibits actin-activated ATP hydrolysis by myosin, particularly in the presence of tropomyosin. We have studied the effect of caldesmon on the rate of hydrolysis of ATP by skeletal muscle myosin subfragment-1, a system in which phosphorylation of the myosin is not important in regulation. Caldesmon is a very effective inhibitor of ATP hydrolysis giving up to 95% inhibition. At low ionic strength (approximately 20 mM) this effect does not require smooth muscle tropomyosin, whereas at high ionic strength (approximately 120 mM) tropomyosin enhances the inhibitory activity of caldesmon at low caldesmon concentrations. Cross-linking of actin is not essential for inhibition of ATP hydrolysis to occur since at high ionic strength there is very little cross-linking as determined by a low speed sedimentation assay. Under all conditions examined, the decrease in the rate of ATP hydrolysis is accompanied by a decrease in the binding of myosin subfragment-1 to actin. Furthermore, caldesmon weakens the equilibrium binding of myosin subfragment-1 to actin in the presence of pyrophosphate. We conclude that caldesmon has a general weakening effect on the binding of skeletal muscle myosin subfragment-1 to actin and that this weakening in binding may be responsible for inhibition of ATP hydrolysis.     

Two different preparations of subfragment-1 from scallop adductor myosin

Chymotryptic digestion of scallop myosin yielded two different preparations of subfragment-1, having the following features. The major product from chymotryptic digestion of scallop myosin was subfragment-1 (S1) either in Ca-medium or in EDTA-medium. However, the S1 preparations obtained from the digestion in Ca-medium, abbreviated as Ca-S1(CT), had both types of light chain subunits (regulatory light chains (R-LC) and essential light chains (SH-LC], and 100 Kdaltons (Kd) heavy chain subfragments (HCs), whereas the S1 preparations obtained from the digestion in EDTA-medium, ED-S1(CT), had no R-LC, partially fragmented SH-LC (SH-LC), and 90 Kd HCs. On the other hand, Ca-S1(CT) and ED-S1(CT) were practically identical with each other in ATPase activity and in actin-binding ability. The two S1 preparations were also identical in that the Mg-ATPase activity of both S1 and acto-S1 was insensitive to calcium ions. Ca-S1(CT), which contained both R-LC and SH-LC in a stoichiometric amount, was further digested with trypsin, which is known to cleave rabbit skeletal myosin not only at the head-tail junction but also in the head. The tryptic digestion of Ca-S1(CT) appeared, in terms of the SDS-gel electrophoretic pattern, to occur at a much faster rate in Ca-medium than in EDTA-medium, and with a different digestion profile. It is therefore suggested that association of R-LC induces changes in the heavy chain conformation which result in an increase in the proteolytic digestibility of heavy chains and in an alteration of the site of proteolytic cleavage on heavy chains.     

Effect of high hydrostatic pressure on chicken myosin subfragment-1

Hydrostatic pressure-induced structural changes in subfragment-1 (S1) of myosin molecule were studied. ATP-induced emission spectra of S1 were used to detect global structural change of S1 by pressure treatment. The fluorescence intensity of unpressurized S1 increased by addition of ATP. The increment of fluorescence of pressurized S1 up to 150 MPa was almost the same as control, whereas it became smaller above 200 MPa. ATP binding ability of S1 examined using 1, N⁶-ethenoadenosine 5′-diphosphate (-ADP) indicated that the binding of -ADP to S1 decreased in the range of 250–300 MPa. S1 pressurized below 250 MPa and unpressurized S1 similarly bound to F-actin, although binding of S1 pressurized above 250 MPa decreased. Electron microscopic observation revealed arrowhead structure in control acto-S1, while disordered arrowhead structure was observed in acto-S1 prepared from pressurized S1 at 300 MPa. S1 pressurized below 250 MPa retained the same actin activated ATPase activity as the control, whereas the activity decreased to 60% at 300 MPa. Pressure treated S1 was easily cleaved by tryptic digestion into three domains, i.e. 27 kDa (N-terminal), 50 and 20 kDa (C-terminal) fragments, which were the same as those in unpressurized one. It is concluded that pressure-induced global structural changes of S1 begin to occur about 150 MPa, and the local structural changes in ATPase and actin binding sites followed with elevating pressure to 250–300 MPa.     

Changes of carp myosin subfragment-1 induced by temperature acclimation

Summary Heavy meromyosin subfragment-1 (S1) was prepared by -chymotrypsin from myosin of carp acclimated to either 10°C or 30°C for a minimum of 5 weeks. The objective of these studies was to document thermally-induced changes in the myosin molecule and to extend previous observations. Ca²⁺- and K⁺ (EDTA)-ATPase activities of cold-acclimated carp S1 were 1.1 and 0.8 mol P_i·min^-1·mg^-1, respectively, and these values did not differ significantly from those of warm-acclimated carp. The inactivation rate constant (K_D) of S1 from cold-acclimated carp was 32.1x10^-4· s^-1, compared to 13.2x10^-4·s^-1 for warm-acclimated carp. The maximum initial velocity of acto-S1 Mg²⁺-ATPase activity at pH 7.0 in 0.05 M KCl was 9.3 s^-1 with cold-acclimated carp, about 3.7 times higher than that for warm-acclimated carp. However, no significant difference was observed in the apparent affinity of S1 to actin. Peptides maps of the heavy chain of S1 were different and suggested distinct isoforms for the myosins from warm- and cold-acclimated muscle.Abbreviations ATPase adenosine 5-triphosphatase - DTNB 5,5-dithiobis (2-nitrobenzoic acid) - DTT dithiothreitol - EDTA ethylenediaminetetraacetic acid - EGTA ethyleneglycol bis (-aminoethylether)-N,N,N,N-tetraacetic acid - K _D inactivation rate constant - K _m apparent dissociation constant - P _i inorganic -phosphate - PMSF phenylmethane-sulfonyl fluoride - S ₁ heavy meromyosin subfragment-1 - SDS sodium dodecyl sulfate - SDS-PAGE SDS-polyacrylamide gel electrophoresis - TPCK N-tosyl-l-phenylalanyl chloromethyl ketone - V _max maximum initial velocity     

Interaction of myosin subfragment-1 with F- and G-actin in equilibrium.

The structural changes of the F-actin-myosin head (S1) complex during the cross-bridge cycle are essential in muscle contraction. Although a large body of evidence has accumulated showing that the actin: S1 stoichiometry in the decorated F-actin-S1 filament is 1:1 at saturation by S1, a recent report by Andreev and Borejdo (1991, Biochem. Biophys. Res. Comm. 177, 350-356) indicated that under some conditions, the actin: S1 stoichiometry could be 2:1 at saturation by S1. Because of the important implications of this result in the mechanism of acto-myosin motility, we have re-investigated this issue. It is shown here that evidence for the 2:1 stoichiometry was circumstantial and was only observed under conditions where 50% of the actin was F-actin, i.e. at a total actin concentration twice as large as the critical concentration. The interaction of S1 with both F- and G-actin in dynamic equilibrium is studied in detail. The present data fully support the 1:1 actin: S1 stoichiometry in the decorated filament at saturation by S1.     

Skeletal muscle myosin subfragment-1 induces bundle formation by actin filaments

As is well known, the light scattering intensity of F-actin solutions increases immediately upon formation of the rigor complex with subfragment-1 (S-1). We have found that after the initial rise in scattering, there is a further gradual increase in scattering (we call it "super-opalescence"). Fluorescence and electron microscopic observations of acto-S-1 solutions showed that super-opalescence results from formation of actin filament bundles once S-1 binds to F-actin. The actin bundles possessed transverse stripes with a periodicity of about 350 A, which suggested that in the bundles actin filaments are arranged in parallel register. The rate of the initial process of bundle formation (i.e. side-by-side dimerization) could be approximately estimated by measuring the initial rate of super-opalescence (V0). V0 had a maximum (V0m) at a molar ratio of S-1 to actin of 1;6-1;7, regardless of the actin concentration, pH (6-8.5), Mg2+ concentration (up to 5 mM), or ionic strength (up to 0.3 M KC1). Lower pH, higher Mg2+ concentration, and higher ionic strength increased V0m; V0 was proportional to the square of the actin concentration, regardless of the solution conditions.