Formation and characterization of kinesin.ADP.fluorometal complexes

Recent crystallographic studies of motor proteins showed that the structure of the motor domains of myosin and kinesin are highly conserved. Thus, these motor proteins, which are important for motility, may share a common mechanism for generating energy from ATP hydrolysis. We have previously demonstrated that, in the presence of ADP, myosin forms stable ternary complexes with new phosphate analogues of aluminum fluoride (AlF(4)(-)) and beryllium fluoride (BeF(n)), and these stable complexes mimic the transient state along the ATPase kinetic pathway [Maruta et al. (1993) J. Biol. Chem. 268, 7093-7100]. In this study, we examined the formation of kinesin.ADP.fluorometals ternary complexes and analyzed their characteristics using the fluorescent ATP analogue NBD-ATP (2'(3')-O-[6-(N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino)hexanoyl]-ADP). Our results suggest that these ternary complexes may mimic transient state intermediates in the kinesin ATPase cycle. Thus, the kinesin.ADP.AlF(4)(-) complex resembles the kinesin.ADP state, and the kinesin.ADP.BeF(n) complex mimics the kinesin.ADP.P(i) state.     

Analysis of the conformational change of myosin during ATP hydrolysis using fluorescence resonance energy transfer

In order to elucidate the molecular basis of energy transduction by myosin as a molecular motor, a fluorescent ribose-modified ATP analog 2'(3')-O-[6-(N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino)hexanoyl]-ATP (NBD-ATP), was utilized to study the conformational change of the myosin motor domain during ATP hydrolysis using the fluorescence resonance energy transfer (FRET) method. The FRET efficiency from the fluorescent probe, BD- or AD-labeled at the reactive cysteine residues, SH1 (Cys 707) or SH2 (Cys697), respectively, to the NBD fluorophore in the ATP binding site was measured for several transient intermediates in the ATPase cycle. The FRET efficiency was greater than that using NBD-ADP. The FRETs for the myosin.ADP.AlF4- and myosin.ADP.BeFn ternary complexes, which mimic the M*.ADP.P(i) state and M.ATP state in the ATPase cycle, respectively, were similar to that of NBD-ATP. This suggests that both the SH1 and SH2 regions change their localized conformations to move closer to the ATPase site in the M*.ATP state and M**.ADP.P(i) state than in the M*.ADP state. Furthermore, we measured energy transfer from BD in the essential light chain to NBD in the active site. Assuming the efficiency at different states, myosin adopts a conformation such that the light chain moves closer to the active site by approximately 9 A during the hydrolysis of ATP.     

Transition state complexes of the Klebsiella pneumoniae nitrogenase proteins. Spectroscopic properties of aluminium fluoride-stabilized and beryllium fluoride-stabilized MgADP complexes reveal conformational differences of the Fe protein.

Stable inactive 2 : 1 complexes of the Klebsiella pneumoniae nitrogenase components (Kp2/Kp1) were prepared with ADP or the fluorescent ADP analogue, 2'(3')-O-[N-methylanthraniloyl] ADP and AlF(4)(-) or BeF(3)(-) ions. By analogy with published crystallographic data [Schindelin et al. (1997) Nature 387, 370-376)], we suggest that the metal fluoride ions replaced phosphate at the two ATP-binding sites of the iron protein, Kp2. The beryllium (BeF(x)) and aluminium (AlF(4)(-)) containing complexes are proposed to correspond to the ATP-bound state and the hydrolytic transition states, respectively, by analogy with the equivalent complexes of myosin [Fisher et al. (1995) Biochemistry 34, 8960-8972]. (31)P NMR spectroscopy showed that during the initial stages of complex formation, MgADP bound to the complexed Kp2 in a manner similar to that reported for isolated Kp2. This process was followed by a second step that caused broadening of the (31)P NMR signals and, in the case of the AlF4- complex, slow hydrolysis of some of the excess ADP to AMP and inorganic phosphate. The purified BeFx complex contained 3.8 +/- 0.1 MgADP per mol Kp1. With the AlF(4)(-) complex, MgAMP and adenosine (from MgAMP hydrolysis) replaced part of the bound MgADP although four AlF(4)(-) ions were retained, demonstrating that full occupancy by MgADP is not required for the stability of the complex. The fluorescence emission maximum of 2'(3')-O-[N-methylanthraniloyl] ADP was blue-shifted by 6-8 nm in both metal fluoride complexes and polarization was 6-9 times that of the free analogue. The fluorescence yield of bound 2'(3')-O-[N-methylanthraniloyl] ADP was enhanced by 40% in the AlF(4)(-) complex relative to the solvent but no increase in fluorescence was observed in the BeFx complex. Resonance energy transfer from conserved tyrosine residues located in proximity to the Kp2 nucleotide-binding pocket was marked in the AlF(4)(-) complex but minimal in the BeFx fluoride complex, illustrating a clear conformational difference in the Fe protein of the two complexes. Our data indicate that complex formation during the nitrogenase catalytic cycle is a multistep process involving at least four conformational states of Kp2: similar to the free Fe protein; as initially complexed with detectable (31)P NMR; as detected in mature complexes with no detectable (31)P NMR; in the AlF(4)(-) complex in which an altered tyrosine interaction permits resonance energy transfer with 2'(3')-O-[N-methylanthraniloyl] ADP.     

Conformational and functional characterization of trapped complexes of the P-glycoprotein multidrug transporter

The Pgp (P-glycoprotein) multidrug transporter couples ATP hydrolysis at two cytoplasmic NBDs (nucleotide-binding domains) to the transport of hydrophobic compounds. Orthovanadate (V(i)) and fluoroaluminate (AlF(x)) trap nucleotide in one NBD by forming stable catalytically inactive complexes (Pgp-M2+-ADP-X), which are proposed to resemble the catalytic transition state, whereas the complex formed by beryllium fluoride (BeF(x)) is proposed to resemble the ground state. We studied the trapped complexes formed via incubation of Pgp with ATP (catalytically forward) or ADP (reverse) and V(i), BeF(x) or AlF(x) using Mg2+ or Co2+ as the bivalent cation. Quenching of intrinsic Pgp tryptophan fluorescence by acrylamide, iodide and caesium indicated that conformational changes took place upon formation of the trapped complexes. Trapping with V(i) and ATP led to a 6-fold increase in the acrylamide quenching constant, K(SV), suggesting that large conformational changes take place in the Pgp transmembrane regions on trapping in the forward direction. Trapping with V(i) and ADP gave only a small change in quenching, indicating that the forward- and reverse-trapped complexes are different. TNP (trinitrophenyl)-ATP/TNP-ADP interacted with all of the trapped complexes, however, the fluorescence enhancement differed for the trapped states, suggesting a change in polarity in the nucleotide-binding sites. The nucleotide-binding site of the BeF(x)-trapped complex was much more polar than that of the V(i) and AlF(x) complexes. Functionally, all the trapped complexes were able to bind drugs and TNP-nucleotides with unchanged affinity compared with native Pgp.     

Characterization of stable beryllium fluoride, aluminum fluoride, and vanadate containing myosin subfragment 1-nucleotide complexes.

Beryllium and aluminum fluorides are good phosphate analogues. These compounds, like orthovanadate, form stable complexes with myosin subfragment 1 (S1) in the presence of MgADP. The formation of the stable S1-nucleotide complexes is characterized by the loss of ATPase activity. For the complete loss of ATPase activity there was necessary a higher concentration of aluminum than of beryllium or vanadate. In the presence of MgATP the onset of the inhibition is delayed, which indicates that stable complexes cannot form when a specific site is occupied by the gamma-phosphate of ATP or by P(i) derived from the gamma-phosphate. The half-lives of the S1-MgADP-(BeF3-), S1-MgADP-(AlF4-), and S1-MgADP-Vi complexes at 0 degrees C are 7, 2, and 4 days, respectively. In the presence of actin the rate of decomposition of all of the complexes is significantly enhanced; however, the order of decomposition is reversed, the fastest rate being observed with beryllium and the slowest with aluminum. The formation of the S1-MgADP-(BeF3-) and S1-MgADP-(AlF4-) complexes is accompanied by an increase in tryptophan fluorescence similar to that observed upon addition of MgATP to S1. The fluorescence increase develops rather slowly, by suggesting that the rate-limiting step in the formation of the stable complex is an isomerization. The rate of the fluorescence change accompanying the formation of the Be complex is faster than that for the Al complex. Addition of vanadate to S1 causes a static quenching of the tryptophan fluorescence.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Tryptophan 512 is sensitive to conformational changes in the rigid relay loop of smooth muscle myosin during the MgATPase cycle

To examine the structural basis of the intrinsic fluorescence changes that occur during the MgATPase cycle of myosin, we generated three mutants of smooth muscle myosin motor domain essential light chain (MDE) containing a single conserved tryptophan residue located at Trp-441 (W441-MDE), Trp-512 (W512-MDE), or Trp-597 (W597-MDE). Although W441- and W597-MDE were insensitive to nucleotide binding, the fluorescence intensity of W512-MDE increased in the presence of MgADP-berellium fluoride (BeF(X)) (31%), MgADP-AlF(4)(-) (31%), MgATP (36%), and MgADP (30%) compared with the nucleotide-free environment (rigor), which was similar to the results of wild type-MDE. Thus, Trp-512 may be the sole ATP-sensitive tryptophan residue in myosin. In addition, acrylamide quenching indicated that Trp-512 was more protected from solvent in the presence of MgATP or MgADP-AlF(4)(-) than in the presence of MgADP-BeF(X), MgADP, or in rigor. Furthermore, the degree of energy transfer from Trp-512 to 2'(3')-O-(N-methylanthraniloyl)-labeled nucleotides was greater in the presence of MgADP-BeF(X), MgATP, or MgADP-AlF(4)(-) than MgADP. We conclude that the conformation of the rigid relay loop containing Trp-512 is altered upon MgATP hydrolysis and during the transition from weak to strong actin binding, establishing a communication pathway from the active site to the actin-binding and converter/lever arm regions of myosin during muscle contraction.     

Conformational changes in the unique loops bordering the ATP binding cleft of skeletal muscle myosin mediate energy transduction

Myosin has three highly-conserved, unique loops [B (320-327), M (677-689), and N (127-136)] at the entrance of the ATP binding cleft, and we previously showed that the effects of actin are mediated by a conformational change in loop M [Maruta and Homma (1998) J. Biochem. 124, 528-533]. In the present study, loops M and N were photolabeled respectively with fluorescent probes Mant-8-N(3)-ADP and Mant-2-N(3)-ADP in order to study conformational changes in the loops related to energy transduction. The effect of actin on the conformation of loop N was examined by analyzing fluorescence polarization and acrylamide quenching; the results were then compared with those previously reported for loop M. In contrast to loop M, the fluorescence polarization and the value of K(sv) of the Mant-groups crosslinked to loop N were slightly affected by actin binding. To study conformational changes in loops M and N during the ATPase cycle, FRET was analyzed using TNP-ADP.BeFn and TNP-ADP. AlF(4)(-) as FRET acceptors of Mant fluorescence. The resultant estimated distances between loop M and the active site differed for the Mant-S1.TNP-ADP.BeFn and Mant-S1.TNP-ADP.AlF(4)(-) complexes, whereas the distances between loop N and the active site differed slightly. These findings indicate that the conformation of loop M changes during the ATPase cycle, suggesting that Loop M acts as a signal transducer mediating communication between the ATP- and actin-binding sites. Loop N, by contrast, is not significantly flexible.     

Actin and nucleotide induced conformational changes in the vicinity of Lys553 in myosin subfragment 1.

Bertrand et al. [Bertrand, R., Derancourt, J. & Kassab, R. (1995) Biochemistry 34, 9500-9507] reported that 6-[fluoresceine-5(and 6)-carboxamido] hexanoic acid succinimidyl ester (FHS) selectively modifies Lys553, which is part of the strong actin-binding site of myosin subfragment 1 (S1). We found that the reaction of FHS with Lys533 is accompanied by a decrease in the fluorescence intensity of the reagent. The rate of the FHS reaction increased with increasing pH implying that the unprotonated form of the epsilon-amino group of Lys553 reacts with FHS. Addition of 0.4 M KCl reduced the rate of reaction significantly, which indicates ionic strength-dependent changes in the structure of S1. Limited trypsinolysis of S1 before the FHS reaction also decreased the rate of the reaction showing that the structural integrity of S1 is needed for the reactivity of Lys553. ATP, ADP, ADP.BeF(x), ADP.AlF(4), ADP.V(i) and pyrophosphate significantly decreased the rate of Lys553 labelling, suggesting nucleotide-induced conformational changes in the environment of Lys553. The fluorescence emission spectrum of the Lys553-bound FH moiety and the quenching of its fluorescence by nitromethane was not influenced by nucleotides, implying that the chemical reactivity but not the accessibility of Lys553 was decreased by the nucleotide-induced conformational change. In the presence of ATP when the M(**)ADP.P(i) state of the ATPase cycle is predominantly populated, the reaction rate decreased more than in the case of the S1.ADP.AlF(4)(-) and S1.ADP.V(i) complexes, which are believed to mimic the M(**)ADP.P(i) state. This indicates that the conformation of the S1-ADP.AlF(4)(-) and S1.ADP.V(i) complexes in the vicinity of Lys553 does not resemble the structure of the M(**)ADP.P(i) state. The rate of Lys553 labelling decreased strongly in the presence of actin. The nitromethane quenching of the Lys553-bound FHS was not influenced by actin, which indicates that the reduced reaction rate is not due to steric hindrance caused by the bulky protein but by actin induced conformational changes in the vicinity of Lys553.     

Involvement of the 50-kDa peptide of myosin heads in the ATPase activity revealed by fluorescent modification with 4-fluoro-7-nitrobenz-2-oxa-1,3-diazole

The fluorescent reagent 4-fluoro-7-nitrobenz-2-oxa-1,3-diazole (NBD-F) reacted specifically with 1.9 lysyl residues/mol of the myosin subfragment-1 (S-1) ATPase. When 1.9 lysyl residues were modified, the K+- and Ca2+-ATPase activities were almost completely inhibited, whereas the Mg2+-ATPase activity was increased to 180% of original activity. The actin-activated Mg2+-ATPase activity was decreased to 30% of original activity by this modification. However, affinity of S-1 for actin in the presence of ATP was unchanged. The NBD fluorescence of the modified S-1 was quenched on addition of ATP, suggesting that ATP induced conformational changes around the NBD groups attached to S-1. Tryptic digestion of the modified S-1 revealed that the NBD groups are attached mainly to the 50-kDa peptide of S-1, more precisely the 45-kDa peptide. These results confirm the recent reports that the 50-kDa peptide of S-1 is involved in the myosin ATPase reaction (K?rner, M., Thiem, N. V., Cardinaud, R., and Lacombe, G. (1983) Biochemistry 22, 5843-5847; Hiratsuka, T. (1986) Biochemistry 25, in press).     

Analysis of nucleotide myosin complexes in skeletal muscle fibres by DSC and EPR

The internal dynamics and thermal unfolding of fibre bundles prepared from rabbit psoas muscle has been studied in the presence of nucleotides by differential scanning calorimetry (DSC) and electron paramagnetic resonance (EPR) spectroscopy. Using ADP, adenosine 5'-triphosphate (ATP), AMP.PNP and inorganic phosphate analogue orthovanadate (V(i)), AlF(4)(-) and BeF(3)(-), three intermediate states of the ATP hydrolysis cycle were simulated in glycerinated muscle fibres. In the main transition of the DSC pattern, three overlapping endotherms were detected in rigor, four in strongly as well as weakly binding state of myosin to actin. Deconvolution procedure showed that the transition temperature of 67.5 degrees C was the same for rigor and strong binding state of myosin. In contrast, nucleotide binding induced shift of the melting temperatures of 52 degrees C and 67.5 degrees C, appeared a new fourth peak at 74 and 77 degrees C and produced changes in the calorimetric enthalpies. The changes of the parameters of the peak functions suggest global rearrangements of the internal structure in myosin heads in the intermediate states. In the presence of ADP or ATP plus phosphate analogue orthovanadate or beryllium fluoride, aluminium fluoride, the conventional EPR spectra of spin-labeled muscle fibres showed large changes in the ordering of the probe molecules, and a new distribution of spin labels appeared. ATP plus orthovanadate induced the orientation disorder of myosin heads; the random population of spin labels gave evidence of large local conformational and motional changes in the internal structure of myosin heads. Saturation transfer EPR measurements reported increased rotational mobility of spin labels in the presence of ATP plus phosphate analogues corresponding to weakly binding state of myosin to actin.     

RecA protein-promoted cleavage of LexA repressor in the presence of ADP and structural analogues of inorganic phosphate, the fluoride complexes of aluminum and beryllium

Complexes formed from A13+ or Be2+ and fluoride inhibit the single-stranded DNA-dependent ATPase activity of RecA protein. In contrast, poly(dT)-RecA-ADP complexes, which are inactive for cleavage of LexA protein, become fully active in the presence of AlF4- or BeF3- ions. These data suggest that fluoride complexes of aluminum and beryllium (called herein X) convert RecA-ADP complexes, which bind weakly to single-stranded DNA, into RecA-ADP-X complexes, which bind tightly to single-stranded DNA, the ADP-X moiety behaving as a nonhydrolyzable analogue of ATP. We propose that AlF4- and BeF3- ions act as analogues of inorganic phosphate by binding to the site of the gamma-phosphate of ATP on RecA-ADP complexes, hence mimicking the single-stranded DNA-RecA-ADP-Pi transition state. We conclude that the elementary reaction that switches RecA protein from a high affinity single-stranded DNA binding state to a low affinity single-stranded DNA binding state is not ATP hydrolysis per se but Pi release.     

Distinct natures of beryllium fluoride-bound, aluminum fluoride-bound, and magnesium fluoride-bound stable analogues of an ADP-insensitive phosphoenzyme intermediate of sarcoplasmic reticulum Ca2+-ATPase: changes in catalytic and transport sites during phosphoenzyme hydrolysis

The structural natures of stable analogues for the ADP-insensitive phosphoenzyme (E2P) of Ca(2+)-ATPase formed in sarcoplasmic reticulum vesicles, i.e. the enzymes with bound beryllium fluoride (BeF.E2), bound aluminum fluoride (AlF.E2), and bound magnesium fluoride (MgF.E2), were explored and compared with those of actual E2P formed from P(i) without Ca(2+). Changes in trinitrophenyl-AMP fluorescence revealed that the catalytic site is strongly hydrophobic in BeF.E2 as in E2P but hydrophilic in MgF.E2 and AlF.E2; yet, the three cytoplasmic domains are compactly organized in these states. Thapsigargin, which was shown in the crystal structure to fix the transmembrane helices and, thus, the postulated Ca(2+) release pathway to lumen in a closed state, largely reduced the tryptophan fluorescence in BeF.E2 as in E2P, but only very slightly (hence, the release pathway is likely closed without thapsigargin) in MgF.E2 and AlF.E2 as in dephosphorylated enzyme. Consistently, the completely suppressed Ca(2+)-ATPase activity in BeF-treated vesicles was rapidly restored in the presence of ionophore A23187 but not in its absence by incubation with Ca(2+) (over several millimolar concentrations) at pH 6, and, therefore, lumenal Ca(2+) is accessible to reactivate the enzyme. In contrast, no or only very slow restoration was observed with vesicles treated with MgF and AlF even with A23187. BeF.E2 thus has the features very similar to those characteristic of the E2P ground state, although AlF.E2 and MgF.E2 most likely mimic the transition or product state for the E2P hydrolysis, during which the hydrophobic nature around the phosphorylation site is lost and the Ca(2+) release pathway is closed. The change in hydrophobic nature is probably associated with the change in phosphate geometry from the covalently bound tetrahedral ground state (BeF(3)(-)) to trigonal bipyramidal transition state (AlF(3) or AlF(4)(-)) and further to tetrahedral product state (MgF(4)(2-)), and such change likely rearranges transmembrane helices to prevent access and leakage of lumenal Ca(2+).     

Movement of Cys-697 in myosin ATPase associated with ATP hydrolysis.

To detect movement of Cys-697 (SH2) in myosin subfragment-1 (S-1) associated with ATP hydrolysis, SH2 was labeled with the environmentally sensitive fluorescent analog of maleimide, 2-(4'-maleimidylanilino)naphthalene-6-sulfonic acid (MIANS). Complex formation of S-1 labeled at Cys-697 with MIANS (MIANS-S-1) with adenyl-5'-yl imidodiphosphate and ADP resulted in a significant decrease in the fluorescence intensity of approximately 40 and 30%, respectively. When ATP was added to MIANS-S-1, the fluorescence intensity decreased rapidly by approximately 40%, and this fluorescence level was maintained during the steady state of ATP hydrolysis. As the substrate was used up, the fluorescence intensity increased to approximately 70% of the original value. These results together with model experiments with MIANS-N-acetylcysteine indicate that in the presence of ATP, the MIANS fluorophore attached to SH2 is located in a less hydrophobic environment than is the fluorophore in the absence of ligand and that the hydrolysis of ATP enhances hydrophobicity around the fluorophore. Acrylamide fluorescence quenching studies of MIANS-S-1 confirmed these results, indicating that addition of ATP and ADP to MIANS-S-1 results in an increase in the Stern-Volmer quenching constant of the fluorophore by factors of approximately 3 and 2.5, respectively. The present observations suggest that binding of ATP causes a movement of SH2 toward the protein surface, whereas it goes back into the protein interior after ATP hydrolysis. The results also confirmed previous observations by a chemical cross-linking approach (Hiratsuka, T. (1987) Biochemistry 26, 3168-3173).     

Detection of nucleotide- and F-actin-induced movements in the switch II helix of the skeletal myosin using its differential oxidative cleavage mediated by an iron-EDTA complex disulfide-linked to the strong actin binding site.

We have synthesized the mixed disulfide, S-(2-nitro-5-thiobenzoic acid) cysteaminyl-EDTA, using a rapid procedure and water-soluble chemistry. Its disulfide-thiol exchange reaction with rabbit myosin subfragment-1 (S-1), analyzed by spectrophotometry, ATPase assays, and peptide mapping, led to the incorporation of the cysteaminyl-EDTA group into only Cys 540 on the heavy chain and into the unique cysteine on the alkali light chains. The former thiol, residing in the strong actin binding site, reacted at a much faster rate with a concomitant 3-fold decrease in the V(max) for acto-S-1 ATPase but without change in the essential enzymatic functions of S-1. Upon chelation of Fe(3+) ions to the Cys 540-bound EDTA and incubation of the S-1 derivative-Fe complex with ascorbic acid at pH 7.5, the 95 kDa heavy chain underwent a conformation-dependent, single-cut oxidative fragmentation within 5-15 A of Cys 540. Three pairs of fragments were formed which, after specific fluorescent labeling and SDS-PAGE, could be positioned along the heavy chain sequence as 68 kDa-26 kDa, 62 kDa-32 kDa, and 54 kDa-40 kDa. Densitometric measurements revealed that the yield of the 54 kDa-40 kDa pair of bands, but not that for the two other pairs, was very sensitive to S-1 binding to nucleotides or phosphate analogues as well as to F-actin. In binary complexes, all the former ligands specifically lowered the yield to 40% of S-1 alone, roughly in the following order: ADP = AMP-PNP > ATP = ADP.AlF(4) > ADP.BeF(x)() > PP(i). By contrast, rigor binding to F-actin increased the yield to 130%. In the ternary acto-S-1-ADP complex, the yield was again reduced to 80%, and it fell to 25% in acto-S-1-ADP.AlF(4), the putative transition state analogue complex of the acto-S-1 ATPase. These different quantitative changes reflect distinct ligand-induced conformations of the secondary structure element whose scission generates the 54 kDa-40 kDa species. According to the S-1 crystal structure, this element could be unambiguously assigned to the switch II helix (residues 475-507) whose N-terminus lies 14.2 A from Cys 540 and would include the ligand-responsive cleavage site. This motif is thought to be crucial for the transmission of sub-nanometer structural changes at the ATPase site to both the actin site and the lever arm domain during energy transduction. Our study illustrates this novel, actin site-specific chemical proteolysis of S-1 as a direct probe of the switch II helix conformational transitions in solution most likely associated with the skeletal cross-bridge cycle.     

Synthesis of a novel fluorescent non-nucleotide ATP analogue and its interaction with myosin ATPase

A novel non-nucleotide fluorescent ATP analogue, N-methylanthraniloylamideethyl triphosphate (MANTTP), was designed and synthesized for kinetic studies with ATPases. The interaction of MANTTP with myosin ATPase was characterized. MANTTP was used as a substrate of myosin ATPase, and acceleration of actin-dependent hydrolysis was observed. The fluorescence property of MANTTP was not greatly affected by its binding to the ATPase site of myosin. In contrast, during MANTTP hydrolysis, significant fluorescence resonance energy transfer (FRET) was observed between MANTTP and intrinsic tryptophan residues in the myosin motor domain. Binding of MANTTP and formation of a ternary complex with a myosin-N-methylanthraniloylamideethyl diphosphate (MANTDP)-Pi analogue, which may mimic ATPase transient states, were monitored by FRET. The kinetic parameters of MANTTP binding to myosin and MANTDP release from the ATPase site were determined using a stopped-flow apparatus and compared with those of other ATP analogues. This novel fluorescent ATP analogue was shown to be applicable for kinetic analysis of ATPases.     

Kinetic resolution of a conformational transition and the ATP hydrolysis step using relaxation methods with a Dictyostelium myosin II mutant containing a single tryptophan residue

The fluorescence emission intensity from a conserved tryptophan residue (W501) located in the relay loop (F466 to L516) of the Dicytostelium discoideum myosin II motor domain is sensitive to ATP binding and hydrolysis. The initial binding process is accompanied by a small quench in fluorescence, and this is followed by a large enhancement that appears coincident with the hydrolysis step. Using temperature and pressure jump methods, we show that the enhancement process is kinetically distinct from but coupled to the hydrolysis step. The fluorescence enhancement corresponds to the open-closed transition (k(obs) approximately 1000 s(-1) at 20 degrees C). From the overall steady-state fluorescence signal and the presence or absence of a relaxation transient, we conclude that the ADP state is largely in the open state, while the ADP.AlF(4) state is largely closed. At 20 degrees C the open-closed equilibria for the AMP.PNP and ADP.BeF(x) complexes are close to unity and are readily perturbed by temperature and pressure. In the case of ATP, the equilibrium of this step slightly favors the open state, but coupling to the subsequent hydrolysis step gives rise to a predominantly closed state in the steady state. Pressure jump during steady-state ATP turnover reveals the distinct transients for the rapid open-closed transition and the slower hydrolysis step.     

Fluorescence characterization of structural transitions at the strong actin binding motif in skeletal myosin affinity labeled at cysteine 540 with novel spectroscopic cysteaminyl mixed disulfides

We have synthesized the luminescent and fluorescent lanthanide chelate S-(2-nitro-5-thiobenzoic acid)cysteaminyldiethylenetriaminepentaacetate-5-[(2-aminoethyl)am ino ]naphthalene-1-sulfonic acid as well as the fluorescent analogue S-(2-nitro-5-thiobenzoic acid)cysteaminyl-5-carboxyfluorescein using the procedure we recently described [Bertrand, R., Capony, J.-P., Derancourt, J., and Kassab, R. (1999) Biochemistry 38, 11914-11925]. Both mixed disulfides react with the skeletal myosin motor domain (S-1) as actin site-directed agents and label exclusively and stoichiometrically Cys 540 in the hydrophobic strong actin binding helix-loop-helix motif, causing only a 1.9-2.4-fold decrease in the V(max) for acto-S-1 ATPase. The covalently attached cysteaminyl probe side chain spans maximally 17 and 8 A, respectively, and the fluorophores have different polarity, volume, and flexibility. Thus, they may provide complementary spectroscopic information on the environmental properties of this critical actin binding region. Here, we have analyzed by extrinsic fluorescence spectroscopy S-1 derivatized with the fluorescein label or with the Tb(3+) or Eu(3+) chelate of the other label to assess the conformational transitions precisely occurring at this site upon interaction with F-actin, nucleotides, or phosphate analogues. For either label, specific spectral changes of significant amplitude were obtained, identifying at least two major structural states. One was mediated by rigor binding of F-actin in the absence or presence of MgADP. It was abolished by MgATP, and it was not produced by the binding of nonpolymerizable G-actin. A modeling of the corresponding changes in the intensity and lambda(max) of the fluorescence emission spectra, achieved using the fluorescent adducts of 2-mercaptoethanol in varying concentrations of dimethylformamide, illustrates the predicted apolar nature of the strong acto-S-1 interface. A second state was promoted by the binding of ATP, AMP-PNP, ADP.AlF4, ADP. BeFx, or PP(i). It should be prevalent in the weak acto-S-1 binding complexes. The accompanying fluorescence intensity reduction, observed with each label, in both the absence and presence of F-actin, would result from a specific modification by these ligands of the probe orientation and/or solvent accessibility as suggested by acrylamide quenching experiments. It could represent the spectral manifestation of the predicted allosteric linkage from the ATPase site to the strong actin binding site of S-1 that modulates the acto-S-1 affinity. Our study offers the basis necessary for further detailed spectroscopic investigations on the conformational dynamics in solution of the stereospecific and hydrophobic actin binding motif during the skeletal cross-bridge cycle.     

Spatial proximity of ATP-sensitive tryptophanyl residue(s) and Cys-697 in myosin ATPase.

The reactive thiol Cys-697 (SH2) in myosin ATPase was labeled with a fluorescent analog of maleimide, 2-(4'-maleimidylanilino)naphthalene-6-sulfonic acid (MIANS) (Hiratsuka, T. (1992) J. Biol. Chem. 267, 14941-14948). Although the tryptophan fluorescence of myosin subfragment-1 (S-1) was slightly affected by incorporation of the MIANS fluorophore, the tryptophan fluorescence of the resultant S-1 derivative (MIANS-S-1) was enhanced by ATP in a manner similar to that of unlabeled S-1. The quenching of tryptophan fluorescence of MIANS-S-1 was shown to result from a transfer of the excitation energy from tryptophanyl residue(s) to the MIANS fluorophore attached to SH2, which absorbed and fluoresced maximally at 325 and 418 nm, respectively. The energy transfer measurements were performed in the presence of acrylamide and compared to those performed in the absence of the quencher. The energy transfer efficiencies were found to be unaltered by acrylamide, indicating that the observed fluorescence energy transfer is originated exclusively from the tryptophanyl residue(s) that are not affected by acrylamide, i.e. the ATP-sensitive tryptophanyl residue(s) of S-1 (Torgerson, P. M. (1984) Biochemistry 23, 3002-3007). The distance between the tryptophanyl residue(s) and Cys-697 was calculated to be 27 A assuming a single donor-acceptor pair. Trp-510 is proposed to be one of the ATP-sensitive tryptophanyl residues.