Effect of nucleotide structure on cardiac myosin subfragment 1 transient kinetics

Transient kinetic data of the hydrolysis of several nucleotides (TTP, CTP, UTP, GTP) by cardiac myosin subfragment 1 (S1) were analyzed to obtain values for the equilibrium constant for nucleotide binding and rate constants for the S1-nucleotide isomerization and the subsequent nucleotide hydrolysis as well as the magnitudes of the relative fluorescence enhancements of the myosin that occur upon isomerization and hydrolysis. These data are compared with data from a previous study with ATP. Nucleotide binding is found to be relatively insensitive to nucleotide ring structure, being affected most by the group at position C6. Isomerization and hydrolysis are more sensitive to nucleotide structure, being inhibited by the presence of a bulky group at position C2. Kinetic parameters decrease as follows: for binding, GTP greater than UTP approximately TTP greater than ATP greater than CTP; for isomerization, ATP greater than UTP approximately TTP approximately CTP greater than GTP; for hydrolysis, ATP greater than TTP greater than CTP approximately UTP greater than GTP. Fluorescence enhancements appear to be most dependent upon the relative values of the individual rate constants.     

Proteolysis and binding of myosin subfragment 1 to actin

Rates of proteolytic cleavage of myosin subfragment 1 were measured in the absence and presence of different amounts of actin. The rates of tryptic digestion at the 50K/20K junction and papain digestion at the 25K/50K junction of the myosin head were progressively inhibited with increasing substoichiometric molar ratios of actin to myosin subfragment 1. The percentage inhibitions of digestion reactions corresponded precisely to the molar compositions of actin-subfragment 1 solutions and demonstrated that equimolar complexes of these proteins were responsible for the observed changes in the proteolysis of myosin heads.     

Nucleotide-induced states of myosin subfragment 1 cross-linked to actin

Actomyosin interactions and the properties of weakly bound states in carbodiimide-cross-linked complexes of actin and myosin subfragment 1 (S-1) were probed in tryptic digestion, fluorescence, and thiol modification experiments. Limited proteolysis showed that the 50/20K junction on S-1 was protected in cross-linked acto-S-1 from trypsin even under high-salt conditions in the presence of MgADP, MgAMPPNP, and MgPPi (mu = 0.5 M). The same junction was exposed to trypsin by MgATP and MgATP gamma S but mainly on S-1 cross-linked via its 50K fragment to actin. p-Phenylenedimaleimide-bridged S-1, when cross-linked to actin, yielded similar tryptic cleavage patterns to those of cross-linked S-1 in the presence of MgATP. By using p-nitrophenylenemaleimide, it was found that the essential thiols of cross-linked S-1 were exposed to labeling in the presence of MgATP and MgATP gamma S in a state-specific manner. In contrast to this, the reactive thiols were protected from modification in the presence of MgADP, MgAMPPNP, and MgPPi at mu = 0.5 M. These modifications were compared with similar reactions on isolated S-1. Experiments with pyrene-actin cross-linked to S-1 showed enhancement of fluorescence intensity upon additions of MgATP and MgATP gamma S, indicating the release of the pyrene probe on actin from the sphere of S-1 influence. The results of this study contrast the "open" structure of weakly bound actomyosin states to the "tight" conformation of rigor complexes.     

Polymerization of G-actin by myosin subfragment 1

The polymerization of actin from rabbit skeletal muscle by myosin subfragment 1 (S-1) from the same source was studied in the depolymerizing G-actin buffer. The polymerization reactions were monitored in light-scattering experiments over a wide range of actin/S-1 molar rations. In contrast to the well resolved nucleation-elongation steps of actin assembly by KC1 and Mg2+, the association of actin in the presence of S-1 did not reveal any lag in the polymerization reaction. Light scattering titrations of actin with S-1 and vice versa showed saturation of the polymerization reaction at stoichiometric 1:1 ratios of actin to S-1. Ultracentrifugation experiments confirmed that only stoichiometric amounts of actin were incorporated into a 1:1 acto-S-1 polymer even at high actin/S-1 ratios. These polymers were indistinguishable from standard complexes of S-1 with F-actin as judged by electron microscopy, light scattering measurements, and fluorescence changes observed while using actin covalently labeled with N-(1-pyrenyl)iodoacetamide. F-actin obtained by polymerization of G-actin by S-1 could initiate rapid assembly of G-actin in the presence of 10 mM KC1 and 0.5 mM MgCl2 and showed normal activation of MgATPase hydrolysis by myosin.     

Identification of two segments, separated by approximately 45 kilodaltons, of the myosin subfragment 1 heavy chain that can be cross-linked to the SH-1 thiol

The thiol-specific photoactivatable reagent 4-(2-iodoacetamido)benzophenone (BPIA) can be selectively incorporated into the SH-1 of myosin subfragment 1 (S1), and upon photolysis an intramolecular cross-link is formed between SH-1 and the N-terminal 25-kDa region of S1. If a Mg2+-nucleotide is present during photolysis, cross-links can be formed either with the 25-kDa or with the central 50-kDa region [Lu, R. C., Moo, L., & Wong, A. G. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 6392-6396]. Heavy chains with these two types of intramolecular cross-links and un-cross-linked heavy chain have different mobility on sodium dodecyl sulfate (NaDodSO4)-polyacrylamide gels and therefore can be purified electrophoretically. Each type of heavy chain was cleaved with Staphylococcus aureus protease, chymotrypsin, or lysyl endopeptidase. The cleavage points were determined on the basis of the molecular weights of weights of peptides containing the N-terminus, which was identified with the use of an antibody. Locations of the cross-links were deduced by comparing the peptide maps of cross-linked and un-cross-linked heavy chains. The results indicate that the segment located about 12-16 kDa from the N-terminus of the heavy chain can be cross-linked to SH-1 via BPIA independently of the presence of a nucleotide, whereas the segment located 57-60 kDa from the N-terminus can be cross-linked to SH-1 only in the presence of a Mg2+-nucleotide. With use of the avidin-biotin system, it has been shown that SH-1 is located 13 nm from the head/rod junction [Sutoh, K., Yamamoto, K., & Wakabayashi, T. (1984) J. Mol. Biol. 178, 323-339]. Since BPIA spans less than 1 nm, our results show that two regions, separated by approximately 400 amino acid residues and located in the 25- and 50-kDa domains of S1, respectively, are also part of the head structure about 12-14 nm from the head/rod junction.     

The interdomain motions in myosin subfragment 1.

The interdomain motions in myosin subfragment 1 (S1) were studied by steady-state and time-resolved fluorescence of tryptophan residues and N-(iodoacetyl)-N'-(5-sulfo-1-naphtyl)ethylenediamine (AEDANS) attached to Cys178 of alkali light chain 1 (A1) exchanged into S1. The efficiency of fluorescence resonance energy transfer (FRET) from tryptophan residues of motor domain to AEDANS at A1 decreased dramatically after addition of ATP to S1A1-AEDANS. The efficiency of FRET calculated from the crystal structure of chicken S1 corresponded to the experimental one measured in the presence of ATP. The results showed that AEDANS at Cys178 of A1 became more mobile and distant from the motor domain of S1 upon ATP binding. These findings led to the suggestion that a release of the products of ATP hydrolysis and power stroke might be associated with movement of light chain-binding domain towards the N-terminal domain of S1.     

Proteolytic fragmentation of myosin: location of SH-1 and SH-2 thiols.

The heavy chain fragmentation pattern of native myosin when digested by proteolytic enzymes is influenced by such conditions as the nature of the proteolytic agent, ionic strength and presence or absence of divalent cations. HMM and S-1 produced by digestion of 14CNEM-labelled myosin under various conditions were analyzed by sodium dodecyl-sulfate polyacrylamide gel electrophoresis. Purified samples of these species were digested under controlled conditions by chymotrypsin and trypsin and a comparison of the observed heavy chain fragmentation patterns led to a sequential arrangement of the proteolytic fragments. The main features of this arrangement are the following: a 21K molecular weight tryptic peptide is found at the N-terminal side of myosin heavy chain. Adjacent to it is a 48K peptide, then a 19.5K peptide containing the two SH-1 and SH-2 thiols. These three peptides constitute the heavy chain of S-1. Adjacent to this S-1 heavy chain is a tryptic (and also chymotryptic) 40K peptide. The rest of the HMM heavy chain on the C-terminus is a sequence susceptible to both chymotrypsin and trypsin attack yielding an undefined number of small peptides.     

Structural characterization of beta-cardiac myosin subfragment 1 in solution

beta-cardiac myosin subfragment 1 (betaS1) tertiary structure and dynamics were characterized with proteolytic digestion, nucleotide analogue trapping kinetics, and intrinsic fluorescence changes accompanying nucleotide binding. Proteolysis of betaS1 produces the 25, 50, and 20 kDa fragments and a new cut within the 50-kDa fragment at Arg369. F-actin inhibits cleavage of the 50-kDa fragment and fails to inhibit cleavage at the 50/20 kDa junction, suggesting betaS1 presents an actoS1 conformation fundamentally different from skeletal S1. Time-dependent changes in Mg(2+)-ATPase accompanying proteolysis identifies cleavage points that lie within the energy transduction pathway. The nucleotide analogue trapping kinetics reveal the presence of a reversible weakly actin attached state. Comparison of nucleotide analogue induced betaS1 structures with the transient structures occurring during ATPase indicates analogue induced and transient structures are in a one-to-one correspondence. Tryptophan fluorescence enhancement accompanies the binding or trapping of nucleotide or nucleotide analogues. Isolation of Trp508 fluorescence shows it is an ATP-sensitive tryptophan and that its vicinity changes conformation sequentially with the transient intermediates accompanying ATPase. These studies elucidate energy transduction and suggest how mutations of betaS1 implicated in disease might undermine function, stability, or efficiency.     

Interactions of myosin subfragment 1 isozymes with G-actin

The polymerization of G-actin by myosin subfragment 1 (S-1) isozymes, S-1(A1) and S-1(A2), and their proteolytically cleaved forms was studied by light-scattering, fluorescence, and analytical ultracentrifugation techniques. As reported previously, S-1(A1) polymerized G-actin rapidly while S-1(A2) could hardly promote the assembly reaction (Chaussepied & Kasprzak, 1989a; Chen and Reisler, 1990). This difference between the isozymes of S-1 was traced to the very poor, if any, ability of G-actin-S-1(A2) complexes to nucleate the assembly of actin filaments. The formation of G-actin-S-1(A2) complexes was verified in sedimentation velocity experiments and by fluorescence measurements using pyrene-labeled actin. The G-actin-S-1(A2) complexes supported the growth of actin filaments and accelerated the polymerization of actin in solutions seeded with MgCl2-, KCl-, and S-1(A1)-generated nuclei. The growth rates of actin-S-1(A2) filaments were markedly slower than those for actin-S-1(A1) filaments. Proteolytic cleavage of S-1 isozymes at the 50/20-kDa junction of the heavy chain greatly decreased their binding to G-actin and thus inhibited the polymerization of actin by S-1(A1). These results are discussed in the context of G-actin-S-1 interactions.     

Incorporation of 6-carboxyfluorescein into myosin subfragment 1

We describe for the first time the introduction of a label into the "50K" domain of myosin subfragment 1 (S-1), and we investigate the properties of this fluorescent modification in relation to the ATPase and actin-binding activities, both residing in the myosin head. The labeling consists of a major incorporation of 6-carboxyfluorescein into the "50K" domain of S-1. Using different conditions for tryptic digestion that allowed a fragmentation of the "50K" domain with a loss of 5 kilodaltons (kDa) leading to a final product of 45 kDa, we have shown that the fluorescent dye remains in the 45-kDa final product. By studying cross-linking as a function of time, we have demonstrated that the "50K" domain and the 45-kDa fluorescent peptide are equally cross-linkable to actin. We have also investigated the K+EDTA-, Ca2+-, Mg2+-, and actin-activated ATPase activities of this modified S-1 and after purification observed no enzymatic changes.     

Intramolecular cross-linking of myosin subfragment 1 with bimane

We previously showed that the fluorescent inter-thiol cross-linker dibromobimane (DBB) [Kosower, N. S., Kosower, E. M., Newton, G. L., & Ranney, H. M. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 3382-3386] cross-links two [50 and 20 kilodaltons (kDa)] of the three major fragments of myosin subfragment 1 (S-1); on intact S-1, DBB quenches tryptophans and inhibits all ATPases [Mornet, D., Ue, K., & Morales, M. F. (1985) Proc. Natl. Acad. Sci. U.S.A. 82, 1658-1662]. Here we characterize the modification chemically: DBB cross-links Cys-522 (50 kDa) with Cys-707 (20 kDa), thereby sealing a large preexisting heavy-chain loop containing important functionalities. Cross-linking rate is insensitive to nucleotides, but apparently sterically, either monobromobimane or DBB reduces Ca2+-ATPase to low, nonzero levels.     

Alcohol-induced biphasic inhibition of myosin subfragment 1 K-EDTA-ATPase

Butanol-induced inhibition of K-EDTA-ATPase of myosin subfragment 1 proceeded by biphasic kinetics, consisting of rapid and slow inactivations. The extent of the rapid inactivation, which was estimated by extrapolating the process of slow inactivation to zero time of the incubation period, was saturated with butanol concentration. Recovery of activity by dilution in the rapid phase indicates that the rapid process is reversible. The slow inactivation was concomitant with a partial denaturation of the 50 kDa domain of S1, which was detected by limited tryptic digestion. Other alcohols (methanol, ethanol, propanol and hexanol) also inhibited the K-EDTA-ATPase in the rapid phase. The Ki decreased with an increase in the number of methylene groups of alcohol. When K-EDTA-ATPase activity in the rapid phase was plotted against viscosity, surface tension or dielectric constant, the curves were different for each of the various alcohol solutions. The rapid inactivation appears to be caused by a binding of the alkyl group to S1, rather than by solvent effects. The kinetics of rapid butanol inhibitions indicate that butanol reduces the maximum activity of ATPase but enhances an apparent affinity of S1 with ATP. These indications suggest that alcohol stabilizes S1.KATP intermediate. The rapid K-EDTA-ATPase inhibition was observed at the same alcohol concentration where S1 Mg-ATPase was activated.     

Nucleotide-induced changes in the proteolytically sensitive regions of myosin subfragment 1

Limited proteolytic digestions of myosin subfragment 1 (S-1) with elastase, subtilisin, papain, and thermolysin yield fragments that correspond within 1-2K daltons to the 25K, 50K, and 20K fragments produced by trypsin. While papain and thermolysin cut preferentially at the 26K/70K junction, elastase and subtilisin cleave both the 26K/70K and the 75K/22K junctions in S-1. Using the above proteases as conformational probes, we have previously demonstrated that the binding of actin is sensed at both the 26K/50K and the 50K/22K junctions [Applegate, D., & Reisler, E. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 7109-7112]. We report here that the binding of nucleotides at the active site is also sensed at both junctions. Both 2 mM MgADP and 5 mM MgATP slow the rate of elastase and subtilisin cleavage of the 95K heavy chain. With elastase, the 3-fold decrease in the rate of cleavage induced by nucleotides is evidenced at both the 26K/50K and the 50K/22K junctions. The analysis of subtilisin digestions is complicated by Mg nucleotide induced cleavage at a new site to produce a 91K fragment. Using N-methyl-6-anilinonaphthalene-2-sulfonyl chloride (MnsCl) to fluorescently label the 26K peptide, we demonstrate that the additional cleavage site is approximately 4K daltons from the N-terminal portion of the 95K heavy chain.(ABSTRACT TRUNCATED AT 250 WORDS)     

MgATPase activity of myosin subfragment 1. The dimer is more active than the monomer

The MgATPase activity of the rabbit skeletal myosin subfragment 1 (S1), in the steady state, was measured by means of the intrinsic fluorescence of tryptophan. This technique gave results similar to those obtained by other methods (linked or radioactive assays). The activity was measured under conditions that effect the monomer/dimer ratio. It is shown that there is a close correlation between MgATPase activity and the proportion of dimer. At 20 degrees C, for pH 6.9 to 8.1 and for [KCl] less than or equal to 1 M, the observed activity (kobs) can be linearly related to the proportion of dimer (Ed/Eo) by: kobs(s-1) = 0.016-7 X 10(-3)[KCl] + 0.031(Ed/Eo), where [KCl] is expressed in M. We deduce that, at 20 degrees C and for [KCl] = 0 M, the activity of the monomer is kmobs = 0.016 s-1 (Ed/Eo = 0) and that of the dimer kdobs = 0.047 s-1 (Ed/Eo = 1), i.e. a ratio kdobs/kmobs approximately equal to 3. Beyond pH approximately equal to 8.3, the activities of both the monomer and the dimer increased steeply with increasing pH value. In the standard conditions (pH 8.0, [KCl] = 0 to 100 mM), S1 is mainly in the form of a dimer, and such conditions are not appropriate for study of the S1 monomer. For studying the pure monomer, the conditions required at 20 degrees C and in bis-Tris-propane are: S1 concentration approximately equal to 0.2 mg/ml, pH 6.9 to 7.8, [KCl] approximately equal to 300 mM. For studying the pure dimer, the conditions required are: S1 concentration greater than or equal to 0.2 mg/ml, pH 7.8 to 8.1 and [KCl] approximately equal to 0. In both cases the MgATP concentration is about 50 microM. Finally, if great care is taken concerning the age of the S1 solutions and the evaluation of the proportion of dimer, the values of kobs are extremely precise: the uncertainty regarding the values of kobs, as determined by means of intrinsic fluorescence, does not exceed +/- 0.001 s-1. Beyond this error bar conditions are uncontrolled.     

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.     

Subunit interactions in myosin subfragment 1. Subunit scrambling is independent of catalytic center involvement

Evidence is presented that, under conditions of 4.7 M NH4Cl and 10 mM Mg-ATP where no subunit dissociation can be detected by transport methods, a dynamic equilibrium exists in subfragment 1 between the associated and dissociated subunits. This is readily discerned by the formation of hybrid subfragment 1 species when a subfragment 1 isozyme is incubated with excess free light chains of the alternate isozyme. A similar process occurs with p-N,N'-phenylenedimaleimide (pPDM)-modified subfragment 1 containing [14C]Mg-ADP, but in this case, although extensive amounts of hybrid are formed, no loss of the trapped nucleotide is observed. Subunit scrambling without loss of the trapped nucleotide is apparent from incubating pPDM-SF1(A2)-[14C]Mg-ADP with unmodified SF1(A1) under similar conditions since the mixture subsequently contains SF1(A1), SF1(A2)h, pPDM-SF1(A1)h-[14C]Mg-ADP and pPDM-SF1(A2)-[14C]Mg-ADP. These data show that the nucleotide trapped in the presumptive active site does not escape during the dissociation-reassociation cycle, and suggest that the ATPase site resides solely on the heavy chain.     

A method to exchange alkali light chains on myosin subfragment 1

Exchange of bound alkali light chains on myosin by free alkali light chains is described. It was found that the yield of hybrid obtained was dependent on the incubation time in 4.7 M NH4Cl at pH 9.5. 60% recovery of S1(A1) from S1(A2) was obtained using only a 2-fold molar excess of A1 over S1(A2).     

Limited trypsinolysis changes in structural dynamics of myosin subfragment 1

The effects of limited trypsinolysis of myosin subfragment 1 (S1) on its structural dynamics were investigated by using the method of transient electric birefringence. Conversion of S1 by trypsin to produce S1 (T) did not change the specific Kerr constant [(8.1 +/- 0.3) X 10(-7) and (8.0 +/- 0.3) X 10(-7) cm2/statvolt2 for S1(T) and S1, respectively] or the degree of alignment in a weak electric field, suggesting that the size of S1 and its permanent electric dipole moment are not modified by trypsin. On the other hand, the relaxation time for the field-free rotation, after achieving a steady-state birefringence signal, was reduced from 316 ns for S1 to 269 ns for S1(T), at 3.7 degrees C, suggesting that trypsinolysis increases the flexibility of the connections between S1 segments or introduces additional segmental motions. For both S1 and S1(T), the rate of decay for a steady-state signal was independent of the field strength, between 3.34 and 20.3 statvolt/cm. Shortening the duration of the weak electric field pulses to 0.35 microseconds, so that steady-state signals were not achieved, decreased the relaxation times for S1 and S1(T) to 240 and 210 ns, respectively, which is consistent with the segmented flexible S1 structure proposed earlier [Highsmith, S., & Eden, D. (1986) Biochemistry 25, 2237]. When the strength of the electric field was increased to above 10 statvolt/cm, in order to make the interaction energy for the S1(T) electric dipole moment in the electric field greater than the thermal energy, the relaxation time after a 0.35-microseconds pulse decreased from 210 to 170 ns as the field was increased from 7 to 20 statvolt/cm. (ABSTRACT TRUNCATED AT 250 WORDS)