Studies on the amino groups of myosin ATPase. III. Effect of nucleotides on the fluorescence of beta-naphthoquinone-4-sulfonate bound to amino groups of myosin.

beta-Naphthoquinone-4-sulfonate was used for chemical modification of amino groups of myosin. The reagent was found to affect also the sulfhydryl groups if the reaction was not prevented by previous disulfide exchange with cystamine. When cystamine protection was employed the ATPase (ATP phosphohydrolase, EC3.6.1.3) activity was enhanced in the presence of Mg2+ and decreased in the presence of K+ or Ca2+, a pattern typical of myosin with blocked essential amino groups. On addition of ATP or ADP a blueshift was observed in the fluorescent emission spectrum of beta-naphthoquinone-4-sulfonate bound by myosin, presumably owing to conformational changes in the environment of essential amino groups induced by the binding of nucleotides.     

Fluorescent and colored trinitrophenylated analogs of ATP and GTP.

Fluorescent and colored trinitrophenylated (TNP) analogs of ATP and GTP can interact with nucleotide-requiring enzymes and proteins as a substitute for the parent nucleotide. These analogs have strong binding affinities for most nucleotide-requiring systems. Their bindings are easily detected by absorption and fluorescence changes in the visible region. Recent years have seen dramatic developments in the application of the TNP nucleotide analogs as spectroscopic probes for the study on the nucleotide-interacting properties of various enzymes and proteins including their mutants. This review is intended as a broad overview of currently extensively used applications of the nucleotide analogs in various biological systems.     

Studies on the amino groups of myosin ATPase. Trinitrophenylation of reactive lysyl residue in ventricular and atrial myosins

Myosin and heavy meromyosin from ventricular, atrial, and skeletal muscle were purified and trinitrophenylated by 2,4,6-trinitrobenzene sulfonate. The trinitrophenylation reaction followed a complex kinetics consisting of a fast and slow reaction in all preparations studied. Reactive lysine residues were trinitrophenylated during the fast reaction with a concomitant decrease in K⁺ (EDTA)-activated ATPase and an increase in Mg²⁺-stimulated ATPase activities of myosin. The extent of increase in Mg²⁺-mediated ATPase was the highest with skeletal and the lowest with atrial myosin. The trinitrophenylation of the less reactive lysyl residues continued during the slow reaction. The rate constants of the reactions and the number of reactive lysine residues were evaluated by computer analyses of the trinitrophenylation curves. Two reactive lysine residues were found in skeletal and ventricular myosins while their number in atrial myosin was somewhat lower. The rate of trinitrophenylation in skeletal muscle myosin or heavy meromyosin was always higher than in the two cardiac myosin isozymes. Addition of KCl increased the trinitrophenylation of both highly reactive and slowly reactive lysyl residues in all of the three heavy meromyosins, however, the effect was more profound with cardiac heavy meromyosins. Addition of MgADP induced spectral changes in trinitrophenylated skeletal but not in cardiac myosins. Similar changes occurred in skeletal and to a lesser degree in ventricular heavy meromyosin, but no definite spectral changes were observed in atrial heavy meromyosin. The findings suggest that structural differences exist around the reactive lysyl residue in the head portion of the three myosins.     

The mechanism of skeletal muscle myosin ATPase. Interaction of myosin active center with ATP and with ADP

The kinetics of the fluorescence enhancement and the transient release of H+ caused by the binding of ADP to the active center of myosin has been compared to that caused by myosin-ATP interaction. The results show that both the time courses of the fluorescence enhancement and the transient H+ release caused by ADP binding, like that caused by ATP hydrolysis in the initial burst, are monophasic exponential processes. The fact that the rates of these two processes are also equal suggests that they both reflect the same mechanistic event in the mechanism of ADP binding. The kinetics of ADP binding as measured by the fluorescence enhancement and the H+ release is different from that of ATP. This is in agreement with our previous finding that the enhancement of fluorescence and the transient release of H+, in the case of ATP, reflect the initial burst of ATP hydrolysis, whereas in the case of ADP, they represent a conformational change in the myosin-ADP complex. The magnitude of the H+ transient caused by the initial burst is approximately equal to that caused by ADP binding. The amplitude of the fluorescence enhancement caused by ADP binding is equal to one-third of that caused by the initial burst.     

Acridine orange inhibition of the ATPase activity of myosin and its fragments

The cation dye acridine orange (AO) was shown to inhibit ATPase activity of myosin, DTNB-myosin and heavy meromyosin and not to influence that of EDTA-S-1 at low ionic force. The inhibiting effect is concerned with the presence of KCl in solution. The allosteric influence of AO on myosin ATPase activity is discussed and dependence of this effect on charge distribution on the surface of the protein molecule is considered.     

Kinetic properties of dynein ATPase from Tetrahymena pyriformis. The initial phosphate burst of dynein ATPase and its interaction with ATP analogs.

1. Dynein was extracted with 0.5 M KCl from Tetrahymena axonemes. SDS-gel electrophoresis of the extract indicated that about 50% of the extracted protein had a molecular weight of about 3.5 X 10(5), and that 90% of the proteins with this weight had been extracted. 2. The ATPase [EC 3.6.1.3] reaction of the KCl-extracted dynein fraction was enhanced by 60-80% by addition of the outer doublet fraction. It showed an initial burst of Pi liberation of about 1 mol per mol of proteins with a molecular weight of 3.5 X 10(5). 3. We examined the interaction of the dynein-tubulin system from Tetrahymena cilia with ten ATP analogs [2'-dATP, 3'-dATP, epsilonATP, FTP, 8-NH(CH3)-ATP, 8,3'-S-cyclo-ATP, 8-Br-ATP, 8-OCH3-ATP, 8-SCH3-ATP, and AMPPNP]. Among them, 2'-dATP and 3'-dATP were good substrates for dynein ATPase, as they induced the dissociation of dynein arms from the B-tubule of outer doublets, the sliding movement between outer doublets, and the bending movement of axonemes. The other analogs did not induce the dissociation or the sliding movement. 4. Among the ATP analogs tested, only 2'-dATP and 3'-dATP induced the reorientation of cilia on the Triton model of Tetrahymena; the reorientation rates were smaller than that induced by ATP.     

Studies of myosin and its proteolytic fragments by laser Raman spectroscopy.

Two bands in the Raman spectrum of myosin, at 1,304 cm-1 and 1,270 cm-1, are attributable to alpha-helical structure. The first of these, also present in the spectrum of light meromyosin (LMM) but not in that of subfragment-1 (S-1), is assigned to the coiled-coil tail region of myosin; the second, seen in spectra of S-1 or heavy meromyosin (HMM), is largely absent from the spectrum of light meromyosin and is likely to correspond to the alpha-helical segments of the head region. When myosin or LMM aggregates, spectral bands attributable to backbone and sidechain groups sharpen suggesting a reduction in motional freedom. This sharpening is particularly apparent in the 902 cm-1 C--C stretching mode. Mg2+ broadens and shifts the peak at 1,244 cm-1 to 1,237 cm-1 and diminishes the intensity from 1,230 to 1,240 cm-1, changes which appear to be associated the S-1 region. MgPPi produces changes in the 1,300 cm-1 region attributable to alpha-helical regions in coiled-coil structures suggesting that MgPPi affects not only S-1, but also some part of the myosin rod.     

The effect of denervation upon the functional properties of myosin and its fragments.

A study has been made of some structural and enzymatic properties of myosin and its fragments from denervated white muscles of rabbit in the course of atrophy using different methods: UV-luminiscence, flow birefringence, electromicroscopy, viscosimetry and enzymatic measurements. All the studied parameters had a tendency to decrease; at prolonged observation some properties were partially restored. Considerable changes of structural properties of LMM were revealed: the ability of LMM from denervated muscle to form high-ordered structures which is characteristic of LMM from normal muscle decreased considerably.     

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.     

Distinct structures of ATP and GTP complexes in the myosin ATPase

The active site of the myosin subfragment-1 ATPase was affinity-labeled with ribose-modified fluorescent analogs of ADP, dADP, CDP, UDP, IDP, and GDP in combination with vanadate, forming a stable myosin-nucleoside diphosphate-vanadate complex that is analogous to the normal myosin-ADP-Pi intermediate [Hiratsuka, T. (1984) J. Biochem. 96, 147-154]. Labeled enzyme was isolated free of unbound analog and vanadate, and fluorescent properties of the fluorophore at the active site were examined. Fluorescence emission and acrylamide quenching studies revealed that the hydrophobicity of environment around the fluorophore and the degree of its burial in the protein vary with the base structure of NDP. It was found that the fluorophore of ADP analog is most buried into the protein, while that of the GDP analog is least buried. The results suggest that the deep burial of ATP into the myosin active site is essential for muscle contraction.     

Effect of bridging the two essential thiols of myosin on its spectral and actin-binding properties.

The circular dichroic and fluorescent spectral properties of the myosin head (subfragment I (SFI)) modified by covalently bridging the two essential thiol groups have been examined. CD spectra of SFI with the two thiols linked through reaction with a bifunctional reagent, N, N'- p-phenylenedimaleimide, show enhancement of the 282-nm minimum similar to that observed for the long-lived kinetic intermediate (Mg**MgADP-Pi) formed during the ATP cleavage reaction. No significant perturbation of the CD band at 282 nm is seen on blocking both thiol groups with the monofunctional reagent N-ethylmaleimide. The fluorescence emission maximum also shifts to lower wavelengths following covalent bridging (from 343 to 340 nm), but no change in fluorescent intensity has been detected. Formation of the covalent bridge completely inhibits interaction of the modified protein with F-actin. These results suggest that the local conformational state of the polypeptide chain formed on bridging the two thiol groups exhibits certain similarities with the state produced following binding of MgATP to native myosin.     

The mechanism of the skeletal muscle myosin ATPase. I. Identity of the myosin active sites.

In the present study, the question of whether the two myosin active sites are identical with respect to ATP binding and hydrolysis was reinvestigated. The stoichiometry of ATP binding to myosin, heavy meromyosin, and subfragment-1 was determined by measuring the fluorescence enhancement caused by the binding of MgATP. The amount of irreversible ATP binding and the magnitude of the initial ATP hydrolysis (initial Pi burst) was determined by measuring [gamma-32P]ATP hydrolysis with and without a cold ATP chase in a three-syringe quenched flow apparatus. The results show that, under a wide variety of experimental conditions: 1) the stoichiometry of ATP binding ranges from 0.8 to 1 mol of ATP/myosin active site for myosin, heavy meromyosin, and subfragment-1, 2) 80 to 100% of this ATP binding is irreversible, 3) 70 to 90% of the irreversibly bound ATP is hydrolyzed in the initial Pi burst, 4) the first order rate constant for the rate-limiting step in ATP hydrolysis by heavy meromyosin is equal to the steady state heavy meromyosin ATPase rate only if the latter is calculated on the basis of two active sites per heavy meromyosin molecule. It is concluded that the two active sites of myosin are identical with respect to ATP binding and hydrolysis.     

The reversal of the myosin and actomyosin ATPase reactions and the free energy of ATP binding to myosin

Evidence is presented that both myosin and actomyosin in presence of Mg²⁺ and KCl catalyze an incorporation of ³²P_i into ATP. The rate with actomyosin is about $\text{1}\text{500}$ the rate of ATP hydrolysis; the rate with myosin is less than $\text{1}\text{100}$ of that with actomyosin. With myosin, but not with actomyosin, an apparent initial “burst” of ³²P_i incorporation into ATP is observed. Actin binding thus promotes ATP dissociation. The data with myosin allow estimation of both the amount of enzyme-bound [³²P]-ATP present and the rate constant, k_?1, for dissociation of the myosin· ATP. From these results and other data a ?ΔG^o for ATP binding to myosin of 12–13 kcal/mole may be estimated, with a much lower ?ΔG^o for hydrolysis of enzyme-bound ATP. Protein conformational change accompanying ATP binding appears to be the principal means of capture of energy from the overall reaction of ATP cleavage.     

Studies on photophosphorylation utilizing methylene diphosphonate analogs of ADP and ATP.

Spinach chloroplasts were able to photophosphorylate the ADP analog alpha,beta-methylene adenosine 5'-diphosphate (AOPCP). Phosphorylation of AOPCP was catalyzed by chloroplasts that were washed or dialyzed to remove free endogenous nucleotides. In the presence of glucose, hexokinase, AOPCP and 32Pi, the 32P label was incorporated into alpha,beta-methylene adenosine 5'-triphosphate (AOPCPOP). In contrast to photophosphorylation of AOPCP, the ATP analog AOPCPOP was a poor substrate for the ATP-Pi exchange reaction and its hydrolysis was neither stimulated by light and dithiothreitol nor inhibited by Dio-9. Photophosphorylation of AOPCP was inhibited by the alpha,beta- and beta,gamma-substituted methylene analogs of ATP, while phosphorylation of ADP was unaffected by them. The ATP-Pi exchange was also unaffected by both ATP analogs, while the weak AOPCPOP-Pi exchange was inhibited by the beta,gamma-methylene analog of ATP. Direct interaction of methylene analogs with the chloroplast coupling factor ATPase was indicated by the enzymatic hydrolysis of AOPCPOP on polyacrylamide gels.     

The sulfhydryl groups involved in the active site of myosin B adenosinetriphosphatase. IV. Structure around the Sa thiol group.

The structure of a tryptic peptide containing one specific sulfhydryl group (Sa), which is responsible for the activation of Mg2+-ATPase of myosin B and is present in the light meromyosin region of the myosin molecule, was studied. The amino acid sequence was deduced to be Thr (or Ser)-Asn-Ala-Ala-Cys-Ala-Ala-Leu-Asp-Lys-Lys. In addition, a space-filling model around Sa was built up by comparing Sa-peptide with the amino acid sequence around Cys 190 of alpha-tropomyosin, and the high reactivity of Sa with N-ethylmaleimide is considered based on this model.