Actin and temperature effects on the cross-linking of the SH1-SH2 helix in myosin subfragment 1

Past biochemical work on myosin subfragment 1 (S1) has shown that the bent alpha-helix containing the reactive thiols SH1 (Cys(707)) and SH2 (Cys(697)) changes upon nucleotide and actin binding. In this study, we investigated the conformational dynamics of the SH1-SH2 helix in two actin-bound states of myosin and examined the effect of temperature on this helix, using five cross-linking reagents that are 5-15 A in length. Actin inhibited the cross-linking of SH1 to SH2 on both S1 and S1.MgADP for all of the reagents. Because the rate of SH2 modification was not altered by actin, the inhibition of cross-linking must result from a strong stabilization of the SH1-SH2 helix in the actin-bound states of S1. The dynamics of the helix is also influenced by temperature. At 25 degrees C, the rate constants for cross-linking in S1 alone are low, with values of approximately 0.010 min(-1) for all of the reagents. At 4 degrees C, the rate constants, except for the shortest reagent, range between 0.030 and 0.070 min(-1). The rate constants for SH2 modification in SH1-modified S1 show the opposite trend; they increase with the increases in temperature. The greater cross-linking at the lower temperature indicates destabilization of the SH1-SH2 helix at 4 degrees C. These results are discussed in terms of conformational dynamics of the SH1-SH2 helix.     

Is SH1-SH2-cross-linked myosin subfragment 1 a structural analog of the weakly-bound state of myosin?

Myosin subfragment 1 (S1) with SH1 (Cys(707)) and SH2 (Cys(697)) groups cross-linked by p-phenylenedimaleimide (pPDM-S1) is thought to be an analog of the weakly bound states of myosin bound to actin. The structural properties of pPDM-S1 were compared in this study to those of S1.ADP.BeF(x) and S1.ADP.AlF(4)(-), i.e., the established structural analogs of the myosin weakly bound states. To distinguish between the conformational effects of SH1-SH2 cross-linking and those due to their monofunctional modification, we used S1 with the SH1 and SH2 groups labeled with N-phenylmaleimide (NPM-S1) as a control in our experiments. The state of the nucleotide pocket was probed using a hydrophobic fluorescent dye, 3-[4-(3-phenyl-2-pyrazolin-1-yl)benzene-1-sulfonylamido]phen ylboronic acid (PPBA). Differential scanning calorimetry (DSC) was used to study the thermal stability of S1. By both methods the conformational state of pPDM-S1 was different from that of unmodified S1 in the S1.ADP.BeF(x) and S1.ADP.AlF(4)(-) complexes and closer to that of nucleotide-free S1. Moreover, BeF(x) and AlF(4)(-) binding failed to induce conformational changes in pPDM-S1 similar to those observed in unmodified S1. Surprisingly, when pPDM cross-linking was performed on S1.ADP.BeF(x) complex, ADP.BeF(x) protected to some extent the nucleotide pocket of S1 from the effects of pPDM modification. NPM-S1 behaved similarly to pPDM-S1 in our experiments. Overall, this work presents new evidence that the conformational state of pPDM-S1 is different from that of the weakly bound state analogs, S1.ADP.BeF(x) and S1.ADP.AlF(4)(-). The similar structural effects of pPDM cross-linking of SH1 and SH2 groups and their monofunctional labeling with NPM are ascribed to the inhibitory effects of these modifications on the flexibility/mobility of the SH1-SH2 helix.     

Conformational dynamics of the SH1-SH2 helix in the transition states of myosin subfragment-1

The alpha-helix containing the thiols, SH1 (Cys-707) and SH2 (Cys-697), has been proposed to be one of the structural elements responsible for the transduction of conformational changes in the myosin head (subfragment-1 (S1)). Previous studies, using a method that isolated and measured the rate of the SH1-SH2 cross-linking step, showed that this helix undergoes ligand-induced conformational changes. However, because of long incubation times required for the formation of the transition state complexes (S1.ADP.BeF(x), S1.ADP.AlF(4)-, and S1.ADP.V(i)), this method could not be used to determine the cross-linking rate constants for such states. In this study, kinetic data from the SH1-SH2 cross-linking reaction were analyzed by computational methods to extract rate constants for the two-step mechanism. For S1.ADP.BeF(x), the results obtained were similar to those for S1.ATPgammaS. For reactions involving S1.ADP.AlF(4)- and S1.ADP.V(i), the first step (SH1 modification) is rate limiting; consequently, only lower limits could be established for the rate constants of the cross-linking step. Nevertheless, these results show that the cross-linking rate constants in the transition state complexes are increased at least 20-fold for all the reagents, including the shortest one, compared with nucleotide-free S1. Thus, the SH1-SH2 helix appears to be destabilized in the post-hydrolysis state.     

Thiol-specific cross-linkers of variable length reveal a similar separation of SH1 and SH2 in myosin subfragment 1 in the presence and absence of MgADP.

A series of thiol-specific cross-linking reagents were prepared for studying the kinetics of cross-linking between SH1 (Cys(707)) and SH2 (Cys(697)) in rabbit skeletal muscle myosin subfragment 1. The reagents were of the type RSS(CH(2))(n)()SSR, with R = 3-carboxy-4-nitrophenyl and n = 3, 6, 7, 8, 9, 10, and 12, spanning distances from 9 to 20 A. The reactions were monitored spectrophotometrically by measuring the release of 2-nitro-5-thiobenzoate. Reaction rates for modification of SH1 (k(1)) and for cross-linking (k(2)) were measured by the decrease of the K(+)(EDTA)-ATPase activity and the decrease of the Ca(2+)-ATPase activity, respectively, and corrected for the different reactivities of C(n). Cross-linking rates in the presence and absence of MgADP showed similar dependence on the length of the reagents: While the cross-linking rates for n = 3 or n = 6 were close to those for n = 0 (Ellman's reagent), those for n = 7 and 8 were significantly increased. Thus the distance between SH1 and SH2 appears to be equal in both states and can be estimated as >/=15 A, based on the length of the reagent with n = 8 in stretched conformation. Under rigor conditions, reactivity of SH1 differed significantly from that in the presence of MgADP, presumably because of shielding through a lipophilic domain. Similarly, the cross-linking rates k(2) for C(3), C(6), and C(7) in the absence of MgADP were ca. 15 times lower than in the presence of MgADP, suggesting a change in the structure of the SH2 region that depends on nucleotide binding. The results are discussed in terms of recent X-ray structures of S1 and S1-MgADP [Rayment et al. (1993) Science 261, 50-58; Gulick et al. (1997) Biochemistry 36, 11619-11628].     

Conformational flexibility of the Cys 697-Cys 707 segment of myosin subfragment-1. Distance distributions by frequency-domain fluorometry

The separation between Cys 697 (SH1) and Cys 707 (SH2) of the heavy chain of myosin subfragment-1 was previously measured by fluorescence resonance energy transfer with a donor linked to SH1 and an acceptor to SH2. In the present study the distribution of the distances between the two thiols was recovered from frequency-domain fluorometry. In the native state and in the presence of ligands such as MgADP, pyrophosphate, orthovanadate (Vi) and actin, we found wide distributions of the separations between SH1 and SH2 (11-16 A) comparable to that found in the random-coil state (20 A). These results suggest that the SH1-SH2 segment has a high degree of conformational flexibility even in native S1. The flexibility is not much affected by the physiological state of S1. However, the ligands MgADP, Vi and MgADP + Vi decrease significantly the mean SH1-SH2 distance from 27 to 17 A with the effect of MgADP+ Vi being the most pronounced. The anisotropy decay of donor-labeled S1 is biphasic with two rotational correlation times. The long component is decreased by these ligands from 289 to 93 ns, suggesting a more compact symmetric structure of S1 in the presence of the ligands. The complex S1(MgADP)Vi has been shown to be a stable analogue of S1(MgADP)Pi, an unstable intermediate that is generated in the actomyosin ATPase cycle during muscle contraction. Since the power stroke of muscle is accompanied by release of Pi from S1(MgADP)Pi, the present results are consistent with a model in which force generation can be accompanied by transition of S1 from a highly symmetric or compact structure to a more extended structure.     

MgADP-induced changes in the structure of myosin S1 near the ATPase-related thiol SH1 probed by cross-linking

The structural consequences of MgADP binding at the vicinity of the ATPase-related thiol SH1 (Cys-707) have been examined by subjecting myosin subfragment 1, premodified at SH2 (Cys-697) with N-ethylmaleimide (NEM), to reaction with the bifunctional reagent p-phenylenedimaleimide (pPDM) in the presence and absence of MgADP. By monitoring the changes in the Ca2(+)-ATPase activity as a function of reaction time, it appears that the reagent rapidly modifies SH1 irrespective of whether MgADP is present or not. In the absence of nucleotide, only extremely low levels of cross-linking to the 50-kDa middle segment of S1 can be detected, while in the presence of MgADP substantial cross-linking to this segment is observed. A similar cross-link is also formed if MgADP is added subsequent to the reaction of the SH2-NEM-pre-modified S1 with pPDM in the absence of nucleotide. Isolation of the labeled tryptic peptide from the cross-linked adduct formed with [14C]pPDM, and subsequent partial sequence analyses, indicates that the cross-link is made from SH1 to Cys-522. Moreover, it appears that this cross-link results in the trapping of MgADP in this S1 species. These data suggest that the binding of MgADP results in a change in the structure of S1 in the vicinity of the SH1 thiol relative to the 50-kDa "domain" which enables Cys-522 to adopt the appropriate configuration to enable it to be cross-linked to SH1 by pPDM.     

Three distinct actin-attached structural states of myosin in muscle fibers

We have used thiol cross-linking and electron paramagnetic resonance (EPR) to resolve structural transitions of myosin's light chain domain (LCD) and catalytic domain (CD) that are associated with force generation. Spin labels were incorporated into the LCD of muscle fibers by exchanging spin-labeled regulatory light chain for endogenous regulatory light chain, with full retention of function. To trap myosin in a structural state analogous to the elusive posthydrolysis ternary complex A.M'.D.P, we used pPDM to cross-link SH1 (Cys(707)) to SH2 (Cys(697)) on the CD. LCD orientation and dynamics were measured in three biochemical states: relaxation (A.M.T), SH1-SH2 cross-linked (A.M'.D.P analog), and rigor (A.M.D). EPR showed that the LCD of cross-linked fibers has an orientational distribution intermediate between relaxation and rigor, and saturation transfer EPR revealed slow rotational dynamics indistinguishable from that of rigor. Similar results were obtained for the CD using a bifunctional spin label to cross-link SH1-SH2, but the CD was more disordered than the LCD. We conclude that SH1-SH2 cross-linking traps a state in which both the CD and LCD are intermediate between relaxation (highly disordered and microsecond dynamics) and rigor (highly ordered and rigid), supporting the hypothesis that the cross-linked state is an A.M'D.P analog on the force generation pathway.     

Effect of nucleotide binding on the proximity of the essential sulfhydryl groups of myosin. Chemical probing of movement of residues during conformational transitions.

The reaction of myosin with three bifunctional sulfhydryl reagents of differing cross-linking span is reported. In the absence of nucleotide only p-N,N'-phenylenedimaleimide with a cross-linking span of 12-14 A can bridge between the two essential sulfhydryls of myosin. The other two reagents, 2,4-dinitro-1,5-difluorobenzene and 4,4'-difluoro-3,3'-dinitrodiphenyl sulfone with cross-linking spans of 3-5 and 7-10 A, respectively, react under identical conditions with the SH1 sulfhydryl but do not bridge to the SH2 group. In the presence of MgADP, both p-N,N'-phenylenedimaleimide and 4,4'-difluoro-3,3'-dinitrodiphenyl sulfone bridge across the SH1 and SH2 groups indicating a closer proximity of these two sulfhydryls in the presence of bound nucleotide. These results are discussed in relation to the conformational change induced in myosin by binding of the nucleotide.     

UV-induced vanadate-dependent modification and cleavage of skeletal myosin subfragment 1 heavy chain. 1. Evidence for active site modification

Ultraviolet irradiation above 300 nm of the stable MgADP-orthovanadate (Vi)-myosin subfragment 1 (S1) complex resulted in covalent modification of the S1 and in the rapid release of trapped MgADP and Vi. This photomodified S1 had Ca2+ATPase activity 4-5-fold higher than that of the non-irradiated control S1, while the K+EDTA-ATPase activity was below 10% of controls. There was a linear correlation between the activation of the Ca2+ATPase and the release of both ADP and Vi with irradiation time. Analysis of the total number of thiols and the ability of photomodified S1 to retrap MgADP by cross-linking SH1 and SH2 with various bifunctional thiol reagents indicated that the photomodification did not involve these reactive thiols. Irradiation of the S1-MgADP-Vi complex caused a large increase in absorbance of the enzyme at 270 nm which was correlated with the release of Vi from the active site, suggesting an aromatic amino acid(s) was (were) involved. However, analysis by three different methods showed no loss of tryptophan. All the irradiation-dependent phenomena could be prevented by replacing Mg2+ with either Co2+, Mn2+, or Ni2+. Unlike previous irradiation studies of Vi-dynein complexes [Lee-Eiford, A., Ow, R. A., & Gibbons, I. R. (1986) J. Biol. Chem. 261, 2337-2342], no peptide bonds were cleaved in photomodified S1. Photomodified S1 was able to retrap MgADP-Vi at levels similar to unmodified S1. Upon irradiation of the photomodified S1-MgADP-Vi complex, MgADP and Vi were again released from the active site, resulting in heavy chain cleavage to form NH2-terminal 21-kDa and COOH-terminal 74-kDa peptides. All evidence indicates that this new photomodification and subsequent chain cleavage occur specifically at the active site.     

The myosin SH2-50-kilodalton fragment cross-link: location and consequences

Some of us recently described a new interthiol cross-link which occurs in the skeletal myosin subfragment 1-MgADP complex between the reactive sulfhydryl group "SH2" (Cys-697) and a thiol (named SH chi) of the 50-kilodalton (kDa) central domain of the heavy chain; this link leads to the entrapment of the nucleotide at the active site [Chaussepied, P., Mornet, D., & Kassab, R. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 2037-2041]. In the present study, we identify SH chi as Cys-540 of the 50-kDa fragment. The portion of the heavy chain including this residue and also extending to Cys-522 that is cross-linkable to the "SH1" thiol [Ue, K. (1987) Biochemistry 26, 1889-1894] is near the SH2-SH1 region. Furthermore, various spectral and enzymatic properties of the (Cys697-Cys540)-N,N'-p-phenylenedimaleimide (pPDM)-cross-linked myosin chymotryptic subfragment 1 (S-1) were established and compared to those for the well-known (SH1-SH2)-pPDM-cross-linked S-1. The circular dichroism spectra of the new derivative were similar to those of native S-1 complexed to MgADP. At 15 mM ionic strength, (Cys697-Cys540)-S-1 binds very strongly to unregulated actin (Ka = 7 X 10(6) M-1), and the actin binding is very weakly affected by ionic strength. Joining actin with the (Cys697-Cys540)-S-1 heavy chain, using 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide, produces different species than does joining unmodified S-1 with actin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies of ligand-induced conformational perturbations in myosin subfragment 1. An examination of the environment about the SH2 and SH1 thiols using a photoprobe

The effect of ligand binding on the environment near the SH2 and SH1 thiols in myosin subfragment 1 has been investigated by photocross-linking after specific labeling of these thiols individually with 4-(N-maleimido)benzophenone (MBP). On photolysis, cross-linking occurred from SH2-MBP to the middle 50-kDa segment, and subsequent immunopeptide mapping revealed that the cross-link was made to a peptide stretch 31-32 kDa from the N terminus in the absence of MgADP, whereas in its presence the cross-link occurred at about 60-61 kDa from the N terminus. Photolysis of SH1-MBP in the absence of MgADP resulted in a major cross-link to the 27-kDa N-terminal segment and minor cross-links to the 50-kDa middle segment. In the presence of MgADP, no new cross-link occurred but the amount of cross-linking to the 50-kDa segment increased at the expense of the other. Immunopeptide mapping indicated that the regions in the 27- and 50-kDa peptides that were cross-linked to SH1-MBP are at about 14-16 and 55-56 kDa from the N terminus respectively. These results indicate that when nucleotide binds to S1, SH2 is displaced relative to the 50-kDa segment, whereas the local environment around SH1 does not change significantly because photolysis in the presence of MgADP resulted in a change at the site of cross-linking for SH2-MBP but caused only a redistribution of the relative amounts of the cross-links formed from SH1-MBP.     

Identification by site-directed mutagenesis and chemical modification of three vicinal cysteine residues in rat mitochondrial carnitine/acylcarnitine transporter

The proximity of the Cys residues present in the mitochondrial rat carnitine/acylcarnitine carrier (CAC) primary structure was studied by using site-directed mutagenesis in combination with chemical modification. CAC mutants, in which one or more Cys residues had been replaced with Ser, were overexpressed in Escherichia coli and reconstituted into liposomes. The effect of SH oxidizing, cross-linking, and coordinating reagents was evaluated on the carnitine/carnitine exchange catalyzed by the recombinant reconstituted CAC proteins. All the tested reagents efficiently inhibited the wild-type CAC. The inhibitory effect of diamide, Cu(2+)-phenanthroline, or phenylarsine oxide was largely reduced or abolished by the double substitutions C136S/C155S, C58S/C136S, and C58S/C155S. The decrease in sensitivity to these reagents was much lower in double mutants in which Cys(23) was substituted with Cys(136) or Cys(155). No decrease in inhibition was found when Cys(89) and/or Cys(283) were replaced with Ser. Sb(3+), which coordinates three cysteines, inhibited only the Cys replacement mutants containing cysteines 58, 136, and 155 of the six native cysteines. In addition, the mutant C23S/C89S/C155S/C283S, in which double tandem fXa recognition sites were inserted in positions 65-72, i.e. between Cys(58) and Cys(136), was not cleaved into two fragments by fXa protease after treatment with diamide. These results are interpreted in light of the homology model of CAC based on the available x-ray structure of the ADP/ATP carrier. They indicate that Cys(58), Cys(136), and Cys(155) become close in the tertiary structure of the CAC during its catalytic cycle.     

Studies on the role of sulfhydryls in the myosin ATPase. Characterization of the site of modification by the bifunctional sulfhydryl reagent p-N,N'-phenylenedimaleimide

Myosin has been modified with near stoichiometric amounts of the bifunctional reagent [14C]p-N,N'-phenylenedimaleimide (pPDM) in the presence of MgADP under conditions which abolish its ATPase activity. Subsequent carboxymethylation and CNBr cleavage results in the 14C label being associated with a single polypeptide of Mr approximately 10,000. Amino acid composition and partial sequence analysis of this peptide showed that it corresponded to the peptide containing -SH1 and -SH2 sequenced by Elzinga and Collins (Elzinga, M., and Collins, J.H. (1977) Proc. Natl. Acad. Sci. U.S.A. 74, 4281-4284) and to the peptide labeled at -SH1 or -SH2 by N-ethylmaleimide by Kunz et al. (Kunz, P.A., Walser, J.T., Watterson, J.G., and Schaub, M.C. (1977) FEBS Lett. 83, 137-140). These data indicating that pPDM does label the -SH1- and -SH2-containing region in myosin by covalently bridging them and shows that in the presence of MgADP these thiols can approach to within 12 to 14 A.     

Stepwise modulation of ATPase activity, nucleotide trapping, and sliding motility of myosin S1 by modification of the thiol region with residues of increasing size

Rabbit muscle myosin S1 was modified either at SH1 alone or at both SH1 and SH2, using a series of alkylthiolating reagents of increasing size, designed for correlating gradually changing structural disturbances in the thiol region with functional impairments in the myosin head. The reagents were of the type H(CH(2))(n)()-S-NTB, (NTB = 2-nitro-5-thiobenzoate) (n = 1, 2, 5, 8, 9, 10, 11, and 12). Modification of only SH1 led to the expected activation of the Ca(2+)-ATPase, but only with small reagents, while reagents with n > or = 10 caused inhibition of the Ca(2+)-ATPase. Modification of both SH1 and SH2 showed the expected inhibition of Ca(2+)-ATPase but likewise allowed considerable residual Ca(2+)-ATPase activity if the residues were small. Trapping of the nucleotide, known to occur with cross-linking reagents, was seen also with monovalent reagents, provided their length exceeded n = 9 or 10. All S1 derivatives prepared in this study possessed an affinity for actin comparable to native S1 but lacked sliding motility in in vitro motility assays. The biochemical data of this study can be related to existing models of myosin S1 and recent structural data [Houdusse, A., Kalabokis, V. N., Himmel, D., Szent-Gy?rgyi, A. G., and Cohen, C. (1999) Cell 97, 459-470] by making the assumptions that modification at SH1 prevents the formation of the SH1 helix mandatory for the transmission of conformational energy and that mobility of the thiol region is a prerequisite for ATPase activity. Immobilization of the thiol region by residues of increasing size apparently leads to lower enzyme activity and, finally, to inhibition of nucleotide exchange.     

Effects of interchain disulfide cross-links on the trypsin cleavage pattern and conformation of myosin subfragment 2

The ability of 5,5'-dithiobis(2-nitrobenzoate) (Nbs2) to produce interchain disulfide cross-links in both the long and short forms of myosin subfragment 2 (S2) and the conformational effects of these cross-links have been investigated. Short S2 (residues 3-287) contains two pairs of Cys residues at positions 66 and 108, and long S2 (residues 1-440) contains an additional pair at position 410. The reaction kinetics of each form of S2 with Nbs2 was biphasic. During the fast kinetic phase the reaction resulted in un-cross-linked species having Nbs-blocked Cys. During the slow phase disulfide-cross-linked species were formed via interchain S-Nbs/SH exchange. For short S2, Cys-66 appeared to react without forming disulfide cross-links, and the Cys- 108 pair reacted with partial cross-linking. For long S2, the Cys-66 pair appeared to react with partial cross-linking, and the Cys pairs at 108 and 410 reacted with complete cross-linking. Mild tryptic digestion of disulfide-cross-linked long S2, under conditions that resulted in partial production of short S2 from un-cross-linked LS2, produced peptides T1a and T1b (residues 1 to approximately 360), with one and two disulfide cross-links, respectively. Further digestion of cross-linked long S2 or cross-linked short S2 resulted in the same shorter fragment, T2, with an NH2-terminus beginning at 103 consistent with a sequence of residues 103-287. Circular dichroism studies on long S2 indicated that the presence of disulfide cross-links changed the thermal unfolding profile of the helix.(ABSTRACT TRUNCATED AT 250 WORDS)     

Atomic structure of scallop myosin subfragment S1 complexed with MgADP: a novel conformation of the myosin head.

The crystal structure of a proteolytic subfragment from scallop striated muscle myosin, complexed with MgADP, has been solved at 2.5 A resolution and reveals an unusual conformation of the myosin head. The converter and the lever arm are in very different positions from those in either the pre-power stroke or near-rigor state structures; moreover, in contrast to these structures, the SH1 helix is seen to be unwound. Here we compare the overall organization of the myosin head in these three states and show how the conformation of three flexible "joints" produces rearrangements of the four major subdomains in the myosin head with different bound nucleotides. We believe that this novel structure represents one of the prehydrolysis ("ATP") states of the contractile cycle in which the myosin heads stay detached from actin.     

ATP-induced opposite changes in the local environments around Cys(697) (SH2) and Cys(707) (SH1) of the myosin motor domain revealed by the prodan fluorescence.

To obtain a consistent view of the nucleotide-induced conformational changes around Cys(697) (SH2) and Cys(707) (SH1) in skeletal myosin subfragment-1 (S-1), the two thiols were labeled with the same environmentally sensitive fluorophore, 6-acyl-2-dimethylaminonaphthalene group, using 6-acryloyl-2-dimethylaminonaphthalene (acrylodan, AD) and 6-bromoacetyl-2-dimethylaminonaphthalene (BD), respectively. The resultant fluorescent derivatives, AD-S-1 and BD-S-1, have the same fluorophore at either SH2 or SH1, which was verified by inspections of changes in the ATPases and the localization of fluorescence after tryptic digestion and CNBr cleavage for the two derivatives. Especially, AD was found to be a very useful fluorescent reagent that readily reacts with only SH2 of S-1. Measurements of the nucleotide-induced changes in fluorescence emission spectra of AD-S-1 and BD-S-1 suggested that during ATP hydrolysis the environment around the fluorophore at SH2 is very distinct from that around the fluorophore at SH1, being defined as that the former has the hydrophobic and closed characteristics, whereas the latter has the hydrophilic and open ones. The KI quenching study of the fluorescence of the two S-1 derivatives confirmed these results. The most straightforward interpretation for the present results is that during ATP hydrolysis, the helix containing SH2 is buried in hydrophobic side chains and rather reinforced, whereas the adjacent helix containing SH1 moves away from its stabilizing tertiary structural environment.     

Differential behavior of two cysteine residues on the myosin head in muscle fibers

We have previously shown that the orientation of (iodoacetamido)tetramethylrhodamine labels on SH1 thiol of S-1 moieties changes when MgADP is added to the fibers in rigor [Borejdo, J., Assulin, O., Ando, T., & Putnam, S. (1982) J. Mol. Biol. 158, 391-414. Burghardt, T.P., Ando, T., & Borejdo, J. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 7515-7519]. Here we report the results of experiments in which the SH2 of S-1 was labeled with maleimidorhodamine. The specificity of modification of thiols was checked by measuring the stoichiometry of attached dye, by determining the extent of the decrease in EDTA (K+)- and Ca2+-ATPase activities, and by the localization of the dyes on peptides containing SH1 and/or SH2. Labeled S-1 was diffused into single glycerinated fibers of rabbit psoas muscle, and the orientation of chromophores was measured by fluorescence detected dichroism. The dye attached to SH1 was oriented at 65 degrees with respect to the fiber axis in rigor and at 51 degrees in the presence of MgADP, regardless of whether SH2 was modified or not. The dye on SH2 was oriented near 42 degrees both in the presence and in the absence of ADP, regardless of whether SH1 was modified or not. Our results show that rhodamine oriented differently when attached to SH2 compared with when attached to SH1 and that in the former placement it was not sensitive to MgADP. We think this indicates that the SH2-containing region has a mobility different from that of the SH1-containing region, i.e., that this is evidence for internal flexibility of S-1.     

Nucleotide-induced change of the interaction between the 20- and 26-kilodalton heavy-chain segments of myosin adenosinetriphosphatase revealed by chemical cross-linking via the reactive thiol SH2

When myosin subfragment 1 (S-1) reacts with the bifunctional reagents with cross-linking spans of 3-4.5 A, p-nitrophenyl iodoacetate and p-nitrophenyl bromoacetate, the 20-kilodalton (20-kDa) segment of the heavy chain is cross-linked to the 26-kDa segment via the reactive thiol SH2. The well-defined reactive lysyl residue Lys-83 of the 26-kDa segment was not involved in the cross-linking. The cross-linking was completely abolished by nucleotides. Taking into account the recent report that SH2 is cross-linked to a thiol of the 50-kDa segment of S-1 using a reagent with a cross-linking span of 2 A [Chaussepied, P., Mornet, D., & Kassab, R. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 2037-2041], present results suggest that SH2 of S-1 lies close to both the 26- and 50-kDa segments of the heavy chain. The data also encourage us to confirm our previous suggestion that the ATPase site of S-1 residues at or near the region where all three segments of 26, 50, and 20 kDa are contiguous [Hiratsuka, T. (1984) J. Biochem. (Tokyo) 96, 269-272; Hiratsuka, T. (1985) J. Biochem. (Tokyo) 97, 71-78].