Interhead fluorescence energy transfer between probes attached to translationally equivalent sites on the regulatory light chains of scallop myosin

Interhead fluorescence energy transfer studies between probes located at translationally equivalent sites on the two heads of scallop myosin indicates that the distance between such sites is no less than 50 A. Regulatory light chains, possessing either one (Mercenaria, chicken gizzard) or two (Loligo, rabbit skeletal) sulfhydryl groups, were modified either with 1,5-IAEDANS (N'-iodoacetyl-N'-(1-sulfo-5-n-naphthyl)ethylenediamine), as energy transfer donor, or with IAF (5-(iodoacetamido)fluorescein) or DABMI (4-dimethylaminophenylazophenyl-4'-maleimide), as energy transfer acceptor. The sulfhydryl groups on these light chains are located at different positions within the regulatory light-chain primary sequence; this enables one to probe a variety of locations, with respect to regulatory light-chain topology, on each myosin head. These independently modified regulatory light chains were added back to desensitized scallop myosin under a variety of conditions, including biphasic re-addition, the aim being to maximize the number of interhead energy transfer couples present. The efficiency of energy transfer was determined on the same samples by both steady-state and time-decay techniques. Results obtained by these two techniques were in good agreement with each other and indicated that the efficiency of energy transfer did not exceed 20% in any of the hybrids studied. Transfer efficiencies were invariant, irrespective of the presence or absence of MgATP, calcium or actin, either separately or in combination. Results using heavy meromyosin at low ionic strength were identical. It is shown that these results, in conjunction with the results of recent crosslinking studies performed on comparable myosin hybrids, may place certain restrictions on the configurations of the two heads of myosin.     

Position of Mercenaria regulatory light-chain Cys50 site on the surface of myosin visualized by electron microscopy

Mercenaria regulatory light-chains, specifically labelled at cysteine 50 with N-iodoacetyl-N'-biotinylhexylenediamine, were rebound to regulatory light-chain denuded scallop myosin, and the hybrid myosin formed was decorated with avidin. These hybrid myosins were visualized by rotary-shadowing electron microscopy. Three distinct images of avidin-decorated hybrid myosin molecules were obtained. These comprise singly decorated molecules, where the avidin is bound symmetrically or asymmetrically with respect to the two heads of myosin, in addition to "figures-of-five", where two myosin molecules associate with a centrally placed avidin molecule. Analysis of these images indicates that the Mercenaria regulatory light-chain Cys50 site is located 15 to 35 A from the head-rod junction when the light-chain is bound in situ to myosin. Implications with respect to head topology and probe studies are discussed.     

Electron microscopic evidence for the myosin head lever arm mechanism in hydrated myosin filaments using the gas environmental chamber

Muscle contraction results from an attachment–detachment cycle between the myosin heads extending from myosin filaments and the sites on actin filaments. The myosin head first attaches to actin together with the products of ATP hydrolysis, performs a power stroke associated with release of hydrolysis products, and detaches from actin upon binding with new ATP. The detached myosin head then hydrolyses ATP, and performs a recovery stroke to restore its initial position. The strokes have been suggested to result from rotation of the lever arm domain around the converter domain, while the catalytic domain remains rigid. To ascertain the validity of the lever arm hypothesis in muscle, we recorded ATP-induced movement at different regions within individual myosin heads in hydrated myosin filaments, using the gas environmental chamber attached to the electron microscope. The myosin head were position-marked with gold particles using three different site-directed antibodies. The amplitude of ATP-induced movement at the actin binding site in the catalytic domain was similar to that at the boundary between the catalytic and converter domains, but was definitely larger than that at the regulatory light chain in the lever arm domain. These results are consistent with the myosin head lever arm mechanism in muscle contraction if some assumptions are made.     

Dynamic modulation of the regulatory domain of myosin heads by pH, ionic strength, and RLC phosphorylation in synthetic myosin filaments

The position of the myosin head with respect to the filament backbone is thought to be a function of pH, ionic strength (micro) and the extent of regulatory light chain (RLC) phosphorylation [Harrington (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 5066-5070]. The object of this study is to examine the dynamics of the proximal part of the myosin head (regulatory domain) which accompany the changes in head disposition. The essential light chain was labeled at Cys177 with the indanedione spin-label followed by the exchange of the labeled proteins into myosin. The mobility of the labeled domain was investigated with saturation transfer electron paramagnetic resonance in reconstituted, synthetic myosin filaments. We have found that the release of the heads from the myosin filament surface by reduction of electrostatic charge is accompanied by a 2-fold increase in the mobility of the regulatory domain. Phosphorylation of the RLC by myosin light chain kinase resulted in a smaller 1. 5-fold increase of motion, establishing that the head disordering observed by electron microscopy [Levine et al. (1996) Biophys. J. 71, 898-907] is due to increased mobility of the heads. This result indirectly supports the hypothesis that the RLC phosphorylation effect on potentiation of force arises from a release of heads from the filament surface and a shift of the heads toward actin.     

A new model for the surface arrangement of myosin molecules in tarantula thick filaments

Three-dimensional reconstructions of the negatively stained thick filaments of tarantula muscle with a resolution of 50 A have previously suggested that the helical tracks of myosin heads are zigzagged, short diagonal ridges being connected by nearly axial links. However, surface views of lower contour levels reveal an additional J-shaped feature approximately the size and shape of a myosin head.We have modelled the surface array of myosin heads on the filaments using as a building block a model of a two-headed regulated myosin molecule in which the regulatory light chains of the two heads together form a compact head-tail junction. Four parameters defining the radius, orientation and rotation of each myosin molecule were varied. In addition, the heads were allowed independently to bend in a plane perpendicular to the coiled-coil tail at three sites, and to tilt with respect to the tail and to twist at one of these sites. After low-pass filtering, models were aligned with the reconstruction, scored by cross-correlation and refined by simulated annealing.Comparison of the geometry of the reconstruction and the distance between domains in the myosin molecule narrowed the choice of models to two main classes. A good match to the reconstruction was obtained with a model in which each ridge is formed from the motor domain of a head pointing to the bare zone together with the head-tail junction of a neighbouring molecule. The heads pointing to the Z-disc intermittently occupy the J-position. Each motor domain interacts with the essential and regulatory light chains of the neighbouring heads. A near-radial spoke in the reconstruction connecting the backbone to one end of the ridge can be identified as the start of the coiled-coil tail.     

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

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

Proximity relationships between sites on myosin and actin. Resonance energy transfer determination of the following distances, using a hybrid myosin: those between Cys-55 on the Mercenaria regulatory light chain, SH-1 on the Aequipecten myosin heavy chain, and Cys-374 of actin

Resonance energy transfer measurements have been made on hybrid myosins in order to map distances between sites on the regulatory light chain, heavy chain, and actin as well as to assess potential conformational changes of functional importance. Using scallop (Aequipecten) myosin hybrid molecules possessing clam (Mercenaria) regulatory light chains, we have been able to map the distance between Cys-55 on the regulatory light chain and the fast-reacting thiol on the myosin heavy chain (SH-1). This distance is shown to be approximately 6.4 nm, and it is not altered by the presence or absence of Ca2+, MgATP, or actin. Experiments performed at low ionc strength on heavy meromyosin (HMM) derived from these hybrid myosins gave results similar to those performed on the soluble parent myosin preparations. The distances between Cys-374 on actin and each of the above sites were also measured. Mercenaria regulatory light-chain Cys-55, within the hybrid myosin molecule, was found to be greater than 8.0 nm away from actin Cys-374. Scallop heavy-chain SH-1 is shown to be approximately 4.5 nm away from actin Cys-374, in broad agreement with earlier measurements made by others in nonregulatory myosins. The significance of our results is discussed with respect to putative conformational changes within the region of the heavy chain connecting SH-1 to the N-terminal region of the light chain.     

Cross-linking between translationally equivalent sites on the two heads of myosin. Relationship to energy transfer results between the same pair of sites

Mercenaria myosin and scallop pure hybrid myosin possessing Mercenaria regulatory light chains were reacted with various concentrations of 4-4'-dimaleimidylstilbene-2-2'-disulfonic acid (DMSDS). Regulatory light chain homodimers are formed with great efficiency (20-50%). Dimers incorporating essential light chains were not formed upon reaction of DMSDS with Mercenaria myosin but some (less than 5%) essential light chain homodimers were obtained in the case of scallop hybrid myosin, probably occurring through relatively specific intermolecular associations within small myosin aggregates. Results were invariant, irrespective of the presence or absence of calcium and/or ATP. No radioactivity is incorporated into regulatory light chain homodimers upon post-labeling DMSDS-reacted myosin with 14C-labeled N-ethylmaleimide, irrespective of the original labeling ratio of DMSDS to myosin heads. This indicates the absence of free sulfhydryl groups in the regulatory light chain homodimer and suggests, therefore, that DMSDS links the two light chains together between translationally equivalent residues (Cys-50 of the Mercenaria regulatory light chain). These results imply that translationally equivalent sites on the two heads of myosin can come within 18 A of each other, the span of reacted DMSDS. Because energy transfer results between identical pairs of translationally equivalent sites on hybrid myosins indicated a low efficiency of energy transfer between these sites (Chantler, P.D., and Tao, T. (1986) J. Mol. Biol. 192, 87-99), it would appear that even though the two cysteines can come within 18 A of each other, their mean separation is much greater than this distance (greater than 50 A), a result consistent with a considerable flexibility of the two myosin heads with respect to each other.     

Movement of smooth muscle tropomyosin by myosin heads.

It has been proposed that during the activation of muscle contraction the initial binding of myosin heads to the actin thin filament contributes to switching on the thin filament and that this might involve the movement of actin-bound tropomyosin. The movement of smooth muscle tropomyosin on actin was investigated in this work by measuring the change in distance between specific residues on tropomyosin and actin by fluorescence resonance energy transfer (FRET) as a function of myosin head binding to actin. An energy transfer acceptor was attached to Cys374 of actin and a donor to the tropomyosin heterodimer at either Cys36 of the beta-chain or Cys190 of the alpha-chain. FRET changed for the donor at both positions of tropomyosin upon addition of skeletal or smooth muscle myosin heads, indicating a movement of the whole tropomyosin molecule. The changes in FRET were hyperbolic and saturated at about one head per seven actin subunits, indicating that each head cooperatively affects several tropomyosin molecules, presumably via tropomyosin's end-to-end interaction. ATP, which dissociates myosin from actin, completely reversed the changes in FRET induced by heads, whereas in the presence of ADP the effect of heads was the same as in its absence. The results indicate that myosin with and without ADP, intermediates in the myosin ATPase hydrolytic pathway, are effective regulators of tropomyosin position, which might play a role in the regulation of smooth muscle contraction.     

Calcium regulation of muscle contraction.

Calcium triggers contraction by reaction with regulatory proteins that in the absence of calcium prevent interaction of actin and myosin. Two different regulatory systems are found in different muscles. In actin-linked regulation troponin and tropomyosin regulate actin by blocking sites on actin required for complex formation with myosin; in myosin-linked regulation sites on myosin are blocked in the absence of calcium. The major features of actin control are as follows: there is a requirement for tropomyosin and for a troponin complex having three different subunits with different functions; the actin displays a cooperative behavior; and a movement of tropomyosin occurs controlled by the calcium binding on troponin. Myosin regulation is controlled by a regulatory subunit that can be dissociated in scallop myosin reversibly by removing divalent cations with EDTA. Myosin control can function with pure actin in the absence of tropomyosin. Calcium binding and regulation of molluscan myosins depend on the presence of regulatory light chains. It is proposed that the light chains function by sterically blocking myosin sites in the absence of calcium, and that the "off" state of myosin requires cooperation between the two myosin heads. Both myosin control and actin control are widely distributed in different organisms. Many invertebrates have muscles with both types of regulation. Actin control is absent in the muscles of molluscs and in several minor phyla that lack troponin. Myosin control is not found in striated vertebrate muscles and in the fast muscles of crustacean decapods, although regulatory light chains are present. While in vivo myosin control may not be excluded from vertebrate striated muscles, myosin control may be absent as a result of mutations of the myosin heavy chain.     

Interaction of nonpolymerizable actins with myosin.

Polymerization of G-actin in the presence of salt and phalloidin was blocked by treatment of G-actin with m-maleimidobenzoic acid N-hydroxysuccinimide ester (MBS) (designated as m-actin). The actin dimer produced by chemical crosslinking of F-actin with N,N'-p-phenylenedimaleimide did not polymerize and was still dimeric or tetrameric after further treatment with MBS (designated as d-actin). The m- and d-actins retained the ability to bind to myosin heads with apparent dissociation constants of 3-8 x 10(-6) and 3-5 x 10(-7) M, respectively. d-Actin formed a 1:1 actin monomer-myosin head complex. However, m-actin formed a 2:1 m-actin-head complex, suggesting the presence of at least two latent actin-binding sites on a myosin head. ATP weakens only 2- to 6-fold the binding of these complexes. One of two m-actins on a myosin head was replaced by d-actin. Native F-actin blocked the binding of both m- and d-actins to myosin heads in the presence and absence of ATP, although the affinities of myosin head for MBS-treated actins and F-actin are similar in the presence of ATP. These results suggest that there are at least three actin binding sites on a myosin head: one is responsible for binding of F-, m-, and d-actins, the second for binding of F- and m-actins, and the third for binding of F-actin at least in the presence of ATP. F-Actin binding to the third site may in some way block the first and second binding sites.     

Properties of caldesmon isolated from chicken gizzard.

Chicken gizzard smooth muscle contains two major calmodulin-binding proteins: caldesmon (11.1 microM; Mr 141 000) and myosin light-chain kinase (4.6 microM; Mr 136 000), both of which are associated with the contractile apparatus. The amino acid composition of caldesmon is distinct from that of myosin light-chain kinase and is characterized by a very high glutamic acid content (25.5%), high contents of lysine (13.6%) and arginine (10.3%), and a low aromatic amino acid content (2.4%). Caldesmon lacked myosin light-chain kinase and phosphatase activities and did not compete with either myosin light-chain kinase or cyclic nucleotide phosphodiesterase (both calmodulin-dependent enzymes) for available calmodulin, suggesting that calmodulin may have distinct binding sites for caldesmon on the one hand and myosin light-chain kinase and cyclic nucleotide phosphodiesterase on the other. Consistent with the lack of effect of caldesmon on myosin phosphorylation, caldesmon did not affect the assembly or disassembly of myosin filaments in vitro. As previously shown [Ngai & Walsh (1984) J. Biol. Chem. 259, 13656-13659], caldesmon can be reversibly phosphorylated. The phosphorylation and dephosphorylation of caldesmon were further characterized and the Ca2+/calmodulin-dependent caldesmon kinase was purified; kinase activity correlated with a protein of subunit Mr 93 000. Caldesmon was not a substrate of myosin light-chain kinase or phosphorylase kinase, both calmodulin-activated protein kinases.     

MgATP binding changes neither the shape nor the flexibility of the heads of single myosin molecules.

The structural mechanism by which myosin heads exert force is unknown. One possibility is that the tight binding of the heads to actin drives them into a force-generating configuration. Another possibility is that the force-generating conformational change is inherent to the myosin heads. In this case the heads would make force by changing their shape according to the species of nucleotide in their active sites, the tight attachment to actin serving only to provide traction. To test this latter possibility, we used negative stain electron microscopy to search for a MgATP-induced shape change in the heads of single myosin molecules. We compared the heads of 10S smooth muscle myosin monomers (wherein MgATP is trapped at the active site) with the MgATP-free heads of 6S monomers. We found that to a resolution of about 2 nm, MgATP binding to the unrestrained myosin head does not drive it to change its shape or its flexibility. This result suggests that the head makes force by virtue of an induced fit to actin.     

On the relationship between distance information derived from cross-linking and from resonance energy transfer, with specific reference to sites located on myosin heads.

The techniques of fluorescence resonance energy transfer (FRET) and cross-linking can provide complementary information concerning the relative separation of a pair of sites. Cross-linking experiments provide an assessment of the distance of closest approach between a pair of sites. FRET measurements, by contrast, yield information about the average distance between the pair of sites. We have taken advantage of hybrid myosins to understand the relationship between distances obtained for a pair of equivalent sites, one on each myosin head, using both FRET (steady-state and time-decay) and cross-linking techniques. The rigid cross-linker, 4-4'-dimaleimidyl-stilbene-2-2'-disulfonic acid (DMSDS), can efficiently cross-link the two myosin regulatory light-chains, each at residue Cys50 of the Mercenaria regulatory light chain (Chantler, P.D., and S. M. Bower. 1988. J. Biol. Chem. 263:938-944), indicating that these sites can come within 18 +/- 2 A of each other. In a complementary set of experiments, steady-state and time-decay measurements using fluorescence donor/acceptor pairs located at these same sites indicate transfer efficiencies of somewhat less than 20%, suggesting an average separation of greater than 50 A between sites (Chantler, P. D., and T. Tao. 1986. J. Mol. Biol. 192:87-99). Here, we present theoretical calculations which show that efficient cross-linking can be achieved readily in dynamic systems such as the heads of myosin, even though the necessary subpopulation of proximate molecules at any instant may be below the detection limits of time-decay-FRET.(ABSTRACT TRUNCATED AT 250 WORDS)     

Locking regulatory myosin in the off-state with trifluoperazine

Scallop striated adductor muscle myosin is a regulatory myosin, its activity being controlled directly through calcium binding. Here, we show that millimolar concentrations of trifluoperazine were effective at removal of all regulatory light chains from scallop myosin or myofibrils. More important, 200 microM trifluoperazine, a concentration 10-fold less than that required for light-chain removal, resulted in the reversible elimination of actin-activated and intrinsic ATPase activities. Unlike desensitization induced by metal ion chelation, which leads to an elevation of activity in the absence of calcium concurrent with regulatory light-chain removal, trifluoperazine caused a decline in actin-activated MgATPase activity both in the presence and absence of calcium. Procedures were equally effective with respect to scallop myosin, myofibrils, subfragment-1, or desensitized myofibrils. Increased alpha-helicity could be induced in the isolated essential light chain through addition of 100-200 microM trifluoperazine. We propose that micromolar concentrations of trifluoperazine disrupt regulation by binding to a single high-affinity site located in the C-terminal domain of the essential light chain, which locks scallop myosin in a conformation resembling the off-state. At millimolar trifluoperazine concentrations, additional binding sites on both light chains would be filled, leading to regulatory light-chain displacement.     

Calcium sensitivity of contractile proteins from chicken gizzard muscle.

Actin, myosin, and "native" tropomyosin (NTM) were separately isolated from chicken gizzard muscle and rabbit skeletal muscle. With various combinations of the isolated contractile proteins, Mg-ATPase activity and superprecipitation activity were measured. It was thus found that gizzard myosin and gizzard NTM behaved differently from skeletal myosin and skeletal NTM, whereas gizzard actin functioned in the same wasy as skeletal actin. It was also found that gizzard myosin preparations were often Ca-sensitive, that is, that the two activities of gizzard myosin plus actin without NTM were activated by low concentrations of Ca2+. The Mg-ATPase activity of a Ca-insensitive preparation of gizzard myosin was not activated by actin even in the presence of Ca2+. When Ca-sensitive gizzard myosin was incubated with ATP (and Mg2+) in the presence of Ca2+, a light-chain component of gizzard myosin was phosphorylated. The light-chain phosphorylation also occurred when Ca-insensitive myosin was incubated with gizzard NTM and ATP (plus Mg2+) in the presence of Ca2+. In either case, the light-chain phosphorylation required Ca2+. Phosphorylated gizzard myosin in combination with actin was able to exhibit superprecipitation, and Mg-ATPase of the phosphorylated gizzard myosin was activated by actin; the actin activation and superprecipitation were found to occur even in the absence of Ca2+ and NTM or tropomyosin. The phosphorylated light-chain component was found to be dephosphorylated by a partially purified preparation of gizzard myosin light-chain phosphatase. Gizzard myosin thus dephosphorylated behaved exactly like untreated Ca-insensitive gizzard myosin; in combination with actin, it did not superprecipitate either in the presence of Ca2+ or in its absence, but did superprecipitated in the presence of NTM and Ca2+. Ca-activated hydrolysis of ATP catalyzed by gizzard myosin B proceeded at a reduced rate after removal of Ca2+ (by adding EGTA), whereas that catalyzed by a combination of actin, gizzard myosin, and gizzard NTM proceeded at the same rate even after removal of Ca2+. However, addition of a partially purified preparation of gizzard myosin light-chain phosphatase was found to make the recombined system behave like myosin B. Based on these findings, it appears that myosin light-chain kinase and myosin light-chain phosphatase can function as regulatory proteins for contraction and relaxation, respectively, of gizzard muscle.     

Proteolytic fragmentation of brain myosin and localisation of the heavy-chain phosphorylation site

The heavy chains and the 19-kDa and 20-kDa light chains of bovine brain myosin can by phosphorylated. To localise the site of heavy-chain phosphorylation, the myosin was initially subjected to digestion with chymotrypsin and papain under a variety of conditions and the fragments thus produced were identified. Irrespective of the ionic strength, i.e. whether the myosin was monomeric or filamentous, chymotryptic digestion produced two major fragments of 68 kDa and 140 kDa; the 140-kDa fragment was further digested by papain to yield a 120-kDa and a 23-kDa fragment. These fragments were characterised by (a) a gel overlay technique using 125I-labelled light chains, which showed that the 140-kDa and 23-kDa polypeptides contain the light-chain-binding sites; (b) using myosin photoaffinity labelled at the active site with [3H]UTP, which showed that the 68-kDa fragment contained the catalytic site, and (c) electron microscopy, using rotary shadowing and negative-staining techniques, which demonstrated that after chymotryptic digestion the myosin head remains attached to the tail whereas on papain digestion isolated heads and tails were observed. Thus the 120-kDa polypeptide derived from the 140-kDa fragment is the tail of the myosin, and the 68-kDa fragment containing the catalytic site and the 23-kDa fragment, with the light-chain-binding sites, form the head (S1) portion of the myosin. When [32P]-phosphorylated brain myosin was digested with chymotrypsin and papain it was shown that the heavy-chain phosphorylation site is located in a 5-kDa peptide at the C-terminal end of the heavy chain, i.e. the end of the myosin tail. Using hydrodynamic and electron microscopic techniques, no significant effect of either light-chain or heavy-chain phosphorylation on the stability of brain myosin filaments was observed, even in the presence of MgATP. Brain myosin filaments appear to be more stable than those of other non-muscle myosins. Light-chain phosphorylation did, however, have an effect on the conformation of brain myosin, for example in the presence of MgATP non-phosphorylated myosin molecules were induced to fold into a very compact folded state.     

Modeling Smooth Muscle Myosin's Two Heads: Long-Lived Enzymatic Roles and Phosphorylation-Dependent Equilibria

Smooth muscle myosin has two heads, each capable of interacting with actin to generate force and/or motion as it hydrolyzes ATP. These heads are inhibited when their associated regulatory light chain is unphosphorylated (0P), becoming active and hydrolyzing ATP maximally when phosphorylated (2P). Interestingly, with only one of the two regulatory light chains phosphorylated (1P), smooth muscle myosin is active but its ATPase rate is <2P. To explain published 1P single ATP turnover and steady-state ATPase activities, we propose a kinetic model in which 1P myosin exists in an equilibrium between being fully active (2P) and inhibited (0P). Based on the single ATP turnover data, we also propose that each 2P head adopts a hydrolytic role distinct from its partner at any point in time, i.e., one head strongly binds actin and hydrolyzes ATP at its actin-activated rate while the other weakly binds actin. Surprisingly, the heads switch roles slowly (<0.1 s⁻¹), suggesting that their activities are not independent. The phosphorylation-dependent equilibrium between active and inhibited states and the hydrolytic role that each head adopts during its interaction with actin may have implications for understanding regulation and mechanical performance of other members of the myosin family of molecular motors.     

Cryo-atomic force microscopy of unphosphorylated and thiophosphorylated single smooth muscle myosin molecules

The purpose of this study was to determine whether steric blockage of one head by the second head of native two-headed myosin was responsible for the inactivity of nonphosphorylated two-headed myosin compared with the high activity of single-headed myosin, as suggested on the basis of electron microscopy of two-dimensional crystals of heavy meromyosin (Wendt, T., Taylor, D., Messier, T., Trybus, K. M., and Taylor, K. A. (1999) J. Cell Biol. 147, 1385-1390; and Wendt, T., Taylor, D., Trybus, K. M., and Taylor, K. (2001) Proc. Natl. Acad. Sci. U. S. A. 98, 4361-4366). Our earlier cryo-atomic force microscopy (cryo-AFM) (Zhang, Y., Shao, Z., Somlyo, A. P., and Somlyo, A. V. (1997) Biophys. J. 72, 1308-1318) indicates that thiophosphorylation of the regulatory light chain increases the separation of the two heads of a single myosin molecule, but the thermodynamic probability of steric hindrance by strong binding between the two heads was not determined. We now report this probability determined by cryo-AFM of single whole myosin molecules shown to have normal low ATPase activity (0.007 s-1). We found that the thermodynamic probability of the relative head positions of nonphosphorylated myosin was approximately equal between separated heads as compared with closely apposed heads (energy difference of 0.24 kT (where k is a Boltzman constant and T is the absolute temperature)), and thiophosphorylation increased the number of molecules having separated heads (energy advantage of -1.2 kT (where k is a Boltzman constant and I is the absolute temperature)). Our results do not support the suggestion that strong binding of one head to the other stabilizes the blocked conformation against thermal fluctuations resulting in steric blockage that can account for the low activity of nonphosphorylated two-headed myosin.     

Three-dimensional reconstruction of tarantula myosin filaments suggests how phosphorylation may regulate myosin activity

Muscle contraction involves the interaction of the myosin heads of the thick filaments with actin subunits of the thin filaments. Relaxation occurs when this interaction is blocked by molecular switches on these filaments. In many muscles, myosin-linked regulation involves phosphorylation of the myosin regulatory light chains (RLCs). Electron microscopy of vertebrate smooth muscle myosin molecules (regulated by phosphorylation) has provided insight into the relaxed structure, revealing that myosin is switched off by intramolecular interactions between its two heads, the free head and the blocked head. Three-dimensional reconstruction of frozen-hydrated specimens revealed that this asymmetric head interaction is also present in native thick filaments of tarantula striated muscle. Our goal in this study was to elucidate the structural features of the tarantula filament involved in phosphorylation-based regulation. A new reconstruction revealed intra- and intermolecular myosin interactions in addition to those seen previously. To help interpret the interactions, we sequenced the tarantula RLC and fitted an atomic model of the myosin head that included the predicted RLC atomic structure and an S2 (subfragment 2) crystal structure to the reconstruction. The fitting suggests one intramolecular interaction, between the cardiomyopathy loop of the free head and its own S2, and two intermolecular interactions, between the cardiac loop of the free head and the essential light chain of the blocked head and between the Leu305-Gln327 interaction loop of the free head and the N-terminal fragment of the RLC of the blocked head. These interactions, added to those previously described, would help switch off the thick filament. Molecular dynamics simulations suggest how phosphorylation could increase the helical content of the RLC N-terminus, weakening these interactions, thus releasing both heads and activating the thick filament.