Presence Of MgADP Research Articles

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.

Three conformational states of scallop myosin S1.

We have determined the structure of the intact scallop myosin head, containing both the motor domain and the lever arm, in the nucleotide-free state and in the presence of MgADP.V04, corresponding to the transition state. These two new structures, together with the previously determined structure of scallop S1 complexed with MgADP (which we interpret as a detached ATP state), reveal three conformations of an intact S1 obtained from a single isoform. These studies, together with new crystallization results, show how the conformation of the motor depends on the nucleotide content of the active site. The resolution of the two new structures ( approximately 4 A) is sufficient to establish the relative positions of the subdomains and the overall conformation of the joints within the motor domain as well as the position of the lever arm. Comparison of available crystal structures from different myosin isoforms and truncated constructs in either the nucleotide-free or transition states indicates that the major features within the motor domain are relatively invariant in both these states. In contrast, the position of the lever arm varies significantly between different isoforms. These results indicate that the heavy-chain helix is pliant at the junction between the converter and the lever arm and that factors other than the precise position of the converter can influence the position of the lever arm. It is possible that this pliant junction in the myosin head contributes to the compliance known to be present in the crossbridge.

Interaction of Myosin LYS-553 with the C-Terminus and DNase I-Binding Loop of Actin Examined by Fluorescence Resonance Energy Transfer

Fluorescence resonance energy transfer (FRET) experiments were carried out in the absence of nucleotide (rigor) or in the presence of MgADP between fluorescent donor probes (IAEDANS (5((((2-iodoacetyl)amino)ethyl)amino)-naphthalene-1-sulfonic acid) at Cys-374 or DANSYL (5-dimethylamino naphthalene-1-(N-(5-aminopentyl))sulfonamide) at Gln-41 of actin and acceptor molecules (FHS (6-[fluorescein-5(and 6)-carboxamido] hexanoic acid succinimidyl ester) at Lys-553 of skeletal muscle myosin subfragment 1. The critical Förster distance (R0) was determined to be 44 and 38 Å for the IAEDANS–FHS and DANSYL–FHS donor–acceptor pairs, respectively. The efficiency of energy transfer between the acceptor molecules at Lys-553 of myosin and donor probes at Cys-374 or Gln-41 of actin was calculated to be 0.78 ± 0.01 or 0.94 ± 0.01, respectively, corresponding to distances of 35.6 ± 0.4 Å and 24.0 ± 1.6 Å, respectively. MgADP had no significant effect on the distances observed in rigor. Thus, rearrangements in the acto-myosin interface are likely to occur elsewhere than in the lower 50-kDa subdomain of myosin as its affinity for actin is weakened by MgADP binding.

Interactions of GroEL/GroES with a Heterodimeric Intermediate during α2β2 Assembly of Mitochondrial Branched-chain α-Ketoacid Dehydrogenase: cis CAPPING OF THE NATIVE-LIKE 86-kDa INTERMEDIATE BY GroES

We showed previously that the interaction of an alphabeta heterodimeric intermediate with GroEL/GroES is essential for efficient alpha(2)beta(2) assembly of human mitochondrial branched-chain alpha-ketoacid dehydrogenase. In the present study, we further characterized the mode of interaction between the chaperonins and the native-like alphabeta heterodimer. The alphabeta heterodimer, as an intact entity, was found to bind to GroEL at a 1:1 stoichiometry with a K(D) of 1.1 x 10(-)(7) m. The 1:1 molar ratio of the GroEL-alphabeta complex was confirmed by the ability of the complex to bind a stoichiometric amount of denatured lysozyme in the trans cavity. Surprisingly, in the presence of Mg-ADP, GroES was able to cap the GroEL-alphabeta complex in cis, despite the size of 86 kDa of the heterodimer (with a His(6) tag and a linker). Incubation of the GroEL-alphabeta complex with Mg-ATP, but not AMP-PNP, resulted in the release of alpha monomers. In the presence of Mg-ATP, the beta subunit was also released but was unable to assemble with the alpha subunit, and rebound to GroEL. The apparent differential subunit release from GroEL is explained, in part, by the significantly higher binding affinity of the beta subunit (K(D) < 4.15 x 10(-9)m) than the alpha (K(D) = 1.6 x 10(-8)m) for GroEL. Incubation of the GroEL-alphabeta complex with Mg-ATP and GroES resulted in dissociation and discharge of both the alpha and beta subunits from GroEL. The beta subunit upon binding to GroEL underwent further folding in the cis cavity sequestered by GroES. This step rendered the beta subunit competent for reassociation with the soluble alpha subunit to produce a new heterodimer. We propose that this mechanism is responsible for the iterative annealing of the kinetically trapped heterodimeric intermediate, leading to an efficient alpha(2)beta(2) assembly of human branched-chain alpha-ketoacid dehydrogenase.

Force responses of skinned molluscan catch muscle following photoliberation of ATP.

Isometric force responses following flash photolysis of caged-ATP were measured from skinned preparations of the catch muscle anterior byssus retractor of Mytilus (ABRM). When fibres were transferred from Ca(2+)-free to Ca(2+)-containing rigor solution (pCa < 4) the force remained low, but flash photolysis produced an extended force increase (half-time, 0.30 +/- 0.07 s, n = 6). When Ca(2+)-activated fibres were transferred to a Ca(2+)-free rigor solution, their force remained at a high level. Flash photolysis produced a rapid force decay (half-time, 0.28 +/- 0.06 s, n = 9) to about 19% of the initial Ca(2+)-activated force. In the presence of 0.5 mM MgADP, the force increase was slowed down by a factor of 3 and the force decay by a factor of 5. These effects of MgADP on crossbridge kinetics are comparable to those observed in vertebrate smooth muscle and are thought to cause "latch", a catch-like state (Fuglsang et al. J Muscle Res Cell Motil 14:666-677, 1993). They are consistent with a model implicating competition between MgADP and MgATP for the nucleotide-binding site on crossbridges. Considering the relatively fast force responses induced by caged-ATP photolysis, even in the presence of MgADP, it appears unlikely that the detachment of crossbridges from the rigor state can account for catch-related processes. In view of the low myosin ATPase under maximal activating conditions (0.6 s-1, Butler et al. Biophys J 75:1904-1914, 1998), neither crossbridge attachment nor detachment of rigor crossbridges seems to be the rate-limiting processes of the crossbridge cycle.

Isolation and properties of the complex between the enhancer binding protein NIFA and the sensor NIFL.

In Azotobacter vinelandii, activation of nif gene expression by the transcriptional regulatory enhancer binding protein NIFA is controlled by the sensor protein NIFL in response to changes in levels of oxygen and fixed nitrogen in vivo. NIFL is a novel redox-sensing flavoprotein which is also responsive to adenosine nucleotides in vitro. Inhibition of NIFA activity by NIFL requires stoichiometric amounts of the two proteins, implying that the mechanism of inhibition is by direct protein-protein interaction rather than by catalytic modification of the NIFA protein. The formation of the inhibitory complex between NIFL and NIFA may be regulated by the intracellular ATP/ADP ratio. We show that adenosine nucleotides promote complex formation between purified NIFA and NIFL in vitro, allowing isolation of the NIFL-NIFA complex. The complex can also be isolated from cell extracts containing coexpressed NIFL and NIFA in the presence of MgADP. Removal of the nucleotide causes dissociation of the complex. Experiments with truncated proteins demonstrate that the amino-terminal domain of NIFA and the C-terminal region of NIFL potentiate the ADP-dependent stimulation of NIFL-NIFA complex formation.

The ADP Release Step of the Smooth Muscle Cross-Bridge Cycle Is Not Directly Associated with Force Generation

When smooth muscle myosin subfragment 1 (S1) is bound to actin filaments in vitro, the light chain domain tilts upon release of MgADP, producing a ∼3.5-nm axial motion of the head-rod junction (Whittaker et al., 1995. Nature. 378:748–751). If this motion contributes significantly to the power stroke, rigor tension of smooth muscle should decrease substantially in response to cross-bridge binding of MgADP. To test this prediction, we monitored mechanical properties of permeabilized strips of chicken gizzard muscle in rigor and in the presence of MgADP. For comparison, we also tested psoas and soleus muscle fibers. Any residual bound ADP was minimized by incubation in Mg2+-free rigor solution containing 15mM EDTA. The addition of 2mM MgADP, while keeping ionic strength and free Mg2+ concentration constant, resulted in a slight increase in rigor tension in both gizzard and soleus muscles, but a decrease in psoas muscle. In-phase stiffness monitored during small (<0.1%) 500-Hz sinusoidal length oscillations decreased in all three muscle types when MgADP was added. The changes in force and stiffness with the addition of MgADP were similar at ionic strengths from 50 to 200mM and were reversible. The results with gizzard muscle were similar after thiophosphorylation of the regulatory light chain of myosin. These results suggest that the axial motion of smooth muscle S1 bound to actin, upon dissociation of MgADP, is not associated with force generation. The difference between the present mechanical data and previous structural studies of smooth S1 may be explained if geometrical constraints of the intact contractile filament array alter the motions of the myosin heads.

MgATP-independent hydrogen evolution catalysed by nitrogenase: an explanation for the missing electron(s) in the MgADP–AlF4 transition-state complex

When the MoFe (Kp1) and Fe (Kp2) component proteins of Klebsiella pneumoniae nitrogenase are incubated with MgADP and AlF4(-) in the presence of dithionite as a reducing agent, a stable putative transition-state complex is produced [Yousafzai and Eady (1997) Biochem. J. 326, 637-640]. Surprisingly, the EPR signal associated with reduced Kp2 is not detectable, but Kp1 retains the S=3/2 EPR signal arising from the dithionite reduced state of the MoFe cofactor centre of the protein. This is consistent with the [Fe4S4] centre of the Fe protein in the complex being oxidized, and similar observations have been made with the complex of Azotobacter vinelandii [Spee, Arendsen, Wassink, Marritt, Hagen and Haaker (1998) FEBS Lett. 432, 55-58]. No satisfactory explanation for the fate of the electrons lost by Kp2 has been forthcoming. However, we report here that during the preparation of the MgADP-AlF4 K. pneumoniae complex under argon, H2 was evolved in amounts corresponding to one half of the FeMoco content of the Kp1 (FeMoco is the likely catalytic site of nitrogenase with a composition Mo:Fe7:S9:homocitrate). This is surprising, since activity is observed during incubation in the absence of MgATP, normally regarded as being essential for nitrogenase function, and in the presence of MgADP, a strong competitive inhibitor of nitrogenase. The formation of H2 by nitrogenase in the absence of AlF4(-) was also observed in reaction mixtures containing MgADP but not MgATP. The reaction showed saturation kinetics when Kp1 was titrated with increasing amounts of Kp2 and, at saturation, the amount of H2 formed was stoichiometric with the FeMoco content of Kp1. The dependence of the rate of formation of H2 on [MgADP] was inconsistent with the activity arising from MgATP contamination. We conclude that MgATP is not obligatory for H+ reduction by nitrogenase since MgADP supports a very low rate of hydrogen evolution.

Cooperative binding of ATP and MgADP in the sulfonylurea receptor is modulated by glibenclamide.

The ATP-sensitive potassium (KATP) channels in pancreatic beta cells are critical in the regulation of glucose-induced insulin secretion. Although electrophysiological studies provide clues to the complex control of KATP channels by ATP, MgADP, and pharmacological agents, the molecular mechanism of KATP-channel regulation remains unclear. The KATP channel is a heterooligomeric complex of SUR1 subunits of the ATP-binding-cassette superfamily with two nucleotide-binding folds (NBF1 and NBF2) and the pore-forming Kir6.2 subunits. Here, we report that MgATP and MgADP, but not the Mg salt of gamma-thio-ATP, stabilize the binding of prebound 8-azido-[alpha-32P]ATP to SUR1. Mutation in the Walker A and B motifs of NBF2 of SUR1 abolished this stabilizing effect of MgADP. These results suggest that SUR1 binds 8-azido-ATP strongly at NBF1 and that MgADP, either by direct binding to NBF2 or by hydrolysis of bound MgATP at NBF2, stabilizes prebound 8-azido-ATP binding at NBF1. The sulfonylurea glibenclamide caused release of prebound 8-azido-[alpha-32P]ATP from SUR1 in the presence of MgADP or MgATP in a concentration-dependent manner. This direct biochemical evidence of cooperative interaction in nucleotide binding of the two NBFs of SUR1 suggests that glibenclamide both blocks this cooperative binding of ATP and MgADP and, in cooperation with the MgADP bound at NBF2, causes ATP to be released from NBF1.

Formation of the myosin.ADP.gallium fluoride complex and its solution structure by small-angle synchrotron X-ray scattering.

In the presence of MgADP, a novel phosphate analogue of gallium fluoride (GaFn) forms a ternary complex with the myosin subfragment-1 (S-1), in the same way that has been previously reported with aluminum fluoride (AlF4-), beryllium fluoride (BeFn), scandium fluoride (ScFn), and vanadate (Vi), and this complex formation may mimic different states along the ATPase kinetic pathway. This novel complex has been characterized and compared with other complexes to ascertain whether it forms a transition-state analogue of myosin ATPase. The complex formed quickly, although several times slower than the BeFn complex. The half-life of the myosin.ADP.GaFn complex was about 50 h at 4 degreesC. The formation of the myosin.ADP.GaFn complex was accompanied by an increase in tryptophane fluorescence, similar to that observed upon the addition of ATP, but slightly lower than that of the M**.ADP.Pi complex. Upon addition of GaFn to acto-myosin.ADP, acto-myosin did not dissociate, and the S-1.ADP.GaFn complex was scarcely decomposed by actin, like the AlF4- and ScFn complexes but unlike the BeFn and Vi complexes. The conformations at the localized region of SH1, SH2, and RLR, which are very accessible to the binding of ATP, were studied by fluorescent labeling and chemical modification, and the results suggested that these conformations are very similar to that of the M**.ADP.Pi state. Small-angle X-ray solution scattering showed that the radius of gyration value decreases by about 3 A when S-1 forms an S-1.ADP.GaFn complex, suggesting that the shape of the complex becomes compact or rounded in shape, similar to that in the presence of ATP or complexes with other phosphate analogues, and thus mimics the myosin**.ADP.Pi state closely. The overall results may indicate that the complex mimics a somewhat different transient state from that of other complexes but has a similar global conformation along the ATPase kinetic pathway.

Probing the conformational states of the SH1-SH2 helix in myosin: a cross-linking approach.

Previous biochemical studies have shown that the SH1 (Cys707) and SH2 (Cys697) groups on rabbit skeletal myosin subfragment 1 (S1) can be cross-linked by using reagents of different cross-linking lengths. In the presence of nucleotide, this cross-linking is accelerated. In the crystal structure of S1, the SH1 and SH2 residues are located on an alpha-helix, 19 A apart. Thus, the cross-linking results could be indicative of helix melting or increased flexibility in the presence of nucleotides. Nucleotide-induced changes in this region were examined in this study by monitoring the cross-linking of SH1 and SH2 on S1 with dimaleimide reagents of spans ranging from 5 to 15 A. A method was devised to directly measure the kinetic effects of nucleotides on the rates of cross-linking reactions. The slow and reagent-insensitive rates of the SH1-SH2 cross-linking in the absence of nucleotides reveal that the equipartitioning of the SH1-SH2 helix among states with different SH1-SH2 separations occurs infrequently. In the presence of MgADP, MgATP, and MgATPgammaS, the rates of SH1 and SH2 cross-linking were increased approximately 2-7-fold for the shortest reagent (5-8 A). Rate accelerations were much greater for the longer reagents (9-15 A): 40-50-fold for MgADP, 25-40-fold for MgATP, and 80-270-fold for MgATPgammaS. To account for any nucleotide-dependent differences in the reactivities of the reagents toward SH2, the rates of monofunctional SH2 modification on SH1-labeled S1 were also measured for each reagent. These experiments showed that the nucleotide-induced increases in the rates of SH2 modification were similar for all of the reagents. Thus, the changes observed in the cross-linking rates are due not only to the type of nucleotide bound in the active site but also to the span of the cross-linking reagent. These findings are interpreted in terms of nucleotide-induced shifts in the equilibria among conformational states of the SH1-SH2 helix.

Influence of tightly bound Mg2+ and Ca2+, nucleotides, and phalloidin on the microsecond torsional flexibility of F-actin.

To better understand the relationship between structure and molecular dynamics in F-actin, we have monitored the torsional flexibility of actin filaments as a function of the type of tightly bound divalent cation (Ca2+ or Mg2+) or nucleotide (ATP or ADP), the level of inorganic phosphate and analogues, KCl concentration, and the level of phalloidin. Torsional flexibility on the microsecond time scale was monitored by measuring the steady-state phosphorescence emission anisotropy (rFA) of the triplet probe erythrosin-5-iodoacetamide covalently bound to Cys-374 of skeletal muscle actin; extrapolations to an infinite actin concentration corrected the measured anisotropy values for the influence of variable amounts of rotationally mobile G-actin in solution. The type of tightly bound divalent cation modulated the torsional flexibility of F-actin polymerized in the presence of ATP; filaments with Mg2+ bound (rFA = 0.066) at the active site cleft were more flexible than those with Ca2+ bound (rFA = 0.083). Filaments prepared from G-actin in the presence of MgADP were more flexible (rFA = 0.051) than those polymerized with MgATP; the addition of exogenous inorganic phosphate or beryllium trifluoride to ADP filaments, however, decreased the filament flexibility (increased the anisotropy) to that seen in the presence of MgATP. While variations in KCl concentration from 0 to 150 mM did not modulate the torsional flexibility of the filament, the binding of phalloidin decreased the torsional flexibility of all filaments regardless of the type of cation or nucleotide bound at the active site. These results emphasize the dynamic malleability of the actin filament, the role of the cation-nucleotide complex in modulating the torsional flexibility, and suggest that the structural differences that have previously been seen in electron micrographs of actin filaments manifest themselves as differences in torsional flexibility of the filament.

X-ray diffraction studies on the structural changes of rigor muscles induced by binding of phosphate analogs in the presence of MgADP

To clarify the structure of the ATP hydrolysis intermediates (ADP.P i bound state) formed by actomyosin crossbridges, the effects of various phosphate analogs in the presence of MgADP on the structures of the thin and thick filaments in glycerinated rabbit psoas muscle fibers in the rigor state have been investigated by X-ray diffraction with a short exposure time using synchrotron radiation. When MgADP and phosphate analogs such as metallofluorides (BeF x=3,4 and AlF 4) and vanadate (VO 4(V i)) were added to rigor fibers in the presence of the ATP-depletion backup system, the intensities of the actin-based layer lines were markedly weakened. The greatest effect (∼50% decrease in intensity) was observed in the presence of BeF x among the analogs examined. The intensity distribution of the 5.9 nm actin-based layer line shifted towards that observed in the Ca 2+-activated fibers, while the first actin layer line at ∼1/36.7 nm −1 retained a rigor-like profile with an intensity weakened by ∼50%. The intensity of the equatorial 10 reflection increased while that of the 11 reflection changed little, resulting in only a small increase (∼1.7 fold) in the intensity ratio of the 10 to the 11 reflection. No resting-like pattern appeared upon the addition of MgADP and BeF x . These results indicate that a substantial fraction (∼40%) of the myosin heads dissociate from actin but the detached heads remain in the vicinity of the actin filaments when MgADP and BeF x bind. The states produced by binding phosphate analogs to a rigor muscle differ from the resting-like state produced by adding them to a contracting muscle (Takemori et al., J. Biochem. (Tokyo) 117 (1995) 603–608). Our conclusion put forward to explain the data is that one of the two heads of a crossbridge is detached and the other retains a rigor-like attachment.

Structure of the monomeric actin-myosin head complex as revealed by X-ray solution scattering.

In order to study the structure of a complex of monomeric actin and myosin head (S1) in the presence of nucleotide, non-polymerizable G-actin was prepared by the reaction of G-actin with m-maleimidobenzoic acid N-hydroxysuccinimide ester (MBS) and diazonium(1H)tetrazole (DHT). Although singly-modified MBS-actin forms a 2:1 complex with S1, doubly-modified DHT/MBS-G-actin forms a 1:1 complex with a dissociation constant of approximately 10(-6) M and can activate Mg-ATPase of S1 by 2-fold. Using a synchrotron X-ray source, we have measured X-ray solution scattering from reversible acto-S1 complexes obtained by mixing rabbit skeletal S1 and DHT/MBS-G-actin in the absence of nucleotide or in the presence of MgADP. The Guinier plots of the scattering intensity showed straight lines indicating no large aggregates and gave the radii of gyration of the complexes to be 49 and 46 A in the absence and presence of ADP, respectively. The analysis of the scattering curves showed that a monomeric actin binds to a tip of S1, and that the complex undergoes substantial rearrangement resulting in a more compact structure when it binds ADP.

Structure function relationship of vanadate bound to a single site in chloroplast CF1-ATPase as determined by X-ray absorption

The structure of vanadate, a phosphate analogue which was suggested to function in the presence of tightly bound ADP and divalent cations as a transition state inhibitor of CF1-ATPase, was investigated by X-ray absorption spectroscopy. Analysis of the vanadium K-edge was used for determination of the structure of vanadate bound to a single site in CF1-ATPase containing a single tightly bound ADP. There was a decrease in the intensity of the 1s-3d pre-edge transition and a change in the shape of two other shoulders at the edge region upon binding of vanadate to CF1 in the presence of Mg2+ ions. The changes are due to alteration in the structure of vanadium from tetrahedral to a five-coordinated trigonal bipyramidal geometry. Comparison of the pre-edge peak intensity of ADP-vanadate complex, and model compound resolved by crystallography support the proposed structure of CF1-bound vanadate. 51V NMR measurements were used to verify the pentacoordinated structure of ADP-vanadate complex used as a model in the X-ray absorption studies. The inhibition of a single and multiple site activity by vanadate and by MgADP was measured. Vanadate inhibition of CF1-ATPase activity decreased more than 90 fold in the presence of MgADP. A differential specificity of the inhibition in single and multiple mode of activity was observed. It is suggested that ADP-vanadate binds to the active sites of the enzyme as a pentacoordinated vanadium having approximate trigonal bipyramidal geometry. This structure is analogous to the proposed transition state of the phosphate during the synthesis and the hydrolysis of ATP by CF1.

The essential role of the Walker A motifs of SUR1 in K-ATP channel activation by Mg-ADP and diazoxide.

The ATP-sensitive K-channel (K-ATP channel) plays a key role in insulin secretion from pancreatic beta-cells. It is closed by glucose metabolism, which stimulates insulin secretion, and opened by the drug diazoxide, which inhibits insulin release. Metabolic regulation is mediated by changes in ATP and Mg-ADP, which inhibit and potentiate channel activity, respectively. The beta-cell K-ATP channel consists of a pore-forming subunit, Kir6.2, and a regulatory subunit, SUR1. We have mutated (independently or together) two lysine residues in the Walker A (W(A)) motifs of the first (K719A) and second (K1384M) nucleotide-binding domains (NBDs) of SUR1. These mutations are expected to inhibit nucleotide hydrolysis. Our results indicate that the W(A) lysine of NBD1 (but not NBD2) is essential for activation of K-ATP currents by diazoxide. The potentiatory effects of Mg-ADP required the presence of the W(A) lysines in both NBDs. Mutant currents were slightly more sensitive to ATP than wild-type currents. Metabolic inhibition led to activation of wild-type and K1384M currents, but not K719A or K719A/K1384M currents, suggesting that there may be a factor in addition to ATP and ADP which regulates K-ATP channel activity.

The Effects of Smooth Muscle Calponin on the Strong and Weak Myosin Binding Sites of F-actin

We have investigated the mechanism of inhibition of the actomyosin MgATPase by the smooth muscle protein calponin. We have shown previously the specific interaction of calponin with Glu334 of actin (EL-Mezgueldi, M., Fattoum, A., Derancourt, J., and Kassab, R. (1992) J. Biol. Chem. 267, 15943-15951). This residue is within the sequence 332-334, which has been proposed to be an important part of the strong myosin binding site (Rayment, I., Holden, H. M., Whittaker, M., Yohn, C. B., Lorenz, M., Holmes, K. C., and Milligan, R. A. (1993) Science 261, 58-65). Therefore, we suggested that calponin will affect the strong binding actin-myosin interaction. To test this hypothesis we have investigated the effect of calponin on the strong binding of S-1.MgAMP-PNP (5'-adenylyl imidodiphosphate) and on the weak binding of S-1.MgADP.Pi to actin. We found that an inhibitory concentration of calponin decreased the binding of S-1. MgAMP-PNP to actin but had no effect on the binding of S-1.MgADP.Pi. Similar results were obtained with skeletal muscle and smooth muscle S-1. In competition experiments calponin was found to displace S-1. MgAMP-PNP and S-1.MgADP but not S-1.MgADP.Pi from the actin filament. S-1 displaced calponin from actin in the rigor state, in the presence of MgADP, and in the presence of MgAMP-PNP. We conclude that calponin inhibits the actin activated S-1 ATPase by blocking a strong S-1 binding site on actin and does not block the weak binding site.

Internal flexibility of cardiac myosins

Conventional and saturation transfer electron paramagnetic resonance spectroscopy (EPR and ST EPR) and differential scanning calorimetry (DSC) were used to study the motional dynamics and segmental flexibility of cardiac myosins. Cardiac myosins isolated from bovine and human heart muscle were spin-labelled with isothiocyanate- or maleimide-based probe molecules at the reactive sulfhydryl sites (Cys-697 and Cys-707) of the motor domain. The maleimide probe molecules attached to human cardiac myosin rotated with an effective rotational correlation time of 33 ns which was at least eight times shorter than the rotational correlation time of the same label on skeletal myosin (260 ns). In the presence of MgADP and MgADP plus orthovanadate, flexibility changes in the multisubunit structure of myosins were detected, but this did not lead to changes of the overall rotational property of the myosin heads. Significant difference in the internal flexibility was detected on myosin samples isolated from ischemic tissue, the rotational correlation time decreased to 25 ns. DSC measurements supported the view that addition of nucleotides produced additional loosening in the multisubunit structure of cardiac myosin. It is postulated that there is an intersite communication between the nucleotide binding domain and the 20 kDa subunit where the reactive thiol sites are located.

Analysis of nucleotide binding by a vacuolar proton-translocating adenosine triphosphatase.

The vacuolar-type proton-translocatine adenosine triphosphatase from bovine adrenal secretory granules (chromaffin granules) was purified and reconstituted into proteoliposomes. The binding of nucleotides to the enzyme was studied by quantifying their effects on the rate of inactivation by N-ethylmaleimide (MalNEt) of ATP-dependent proton translocation, and by direct measurement of the binding of [3H]MgADP. The results of these experiments are consistent with a model of the enzyme that had been developed as a result of kinetic experiments, the features of which are that the enzyme exists in two states, each containing three nucleotide-binding sites on catalytic subunits, and that nucleoside diphosphates regulate the enzyme by binding with high affinity to a single site in the inactive T state of the enzyme. Under the conditions of the experiments, MalNEt inactivated the ATPase in a pseudo-first order reaction. Rate constants of inactivation were reduced in the presence of MgADP, MgIDP and free ADP; the kinetics of protection suggested that the two conformational states of the enzyme were inactivated at different rates and also confirmed the existence of two different types of binding site for MgADP. Low nucleotide concentrations afforded partial protection from MalNEt; this was ascribed to binding of nucleotide to the regulatory site causing a shift in the conformational equilibrium towards the T state, which was more slowly inactivated than the unliganded R state of the enzyme. At higher nucleotide concentrations, binding at the catalytic site afforded complete protection from MalNEt. Protection by MgADP[S] and magnesium 2'- and 3'-O-[4-benzoylbenzoyl]adenosine 5'-triphosphate showed simpler kinetics but was also consistent with previously reported kinetic results. Analysis of subunit labelling with [3H]MalNEt showed that the three 72-kDa (catalytic) subunits were alkylated by MalNEt with similar rate constants, consistent with a symmetrical arrangement of the catalytic subunits, in contrast to the situation in F-type ATPases. Analysis of the binding of [3H]MgADP also confirmed the results of kinetic experiments. MgADP was shown to bind to the enzyme with an apparent dissociation constant of about 66 nM; assuming that the nucleotide binds only to the T-state, the true dissociation constant is < 1 nM. Using Blue Native polyacrylamide gel electrophoresis to separate the holo-ATPase from the membrane sector, the stoichiometry of binding was calculated to be 0.6 mol/mol enzyme, confirming the existence of a single regulatory site for MgADP. However, binding of MgADP to the enzyme was much slower than could be accounted for by the measured dissociation constants, suggesting that it is rate limited by a step such as a protein conformational change. Treatment designed to remove endogenous nucleotide had no effect on the rate or extent of binding of MgADP.

Interdoublet Sliding in Bovine Spermatozoa: Its Relationship to Flagellar Motility and the Action of Inhibitory Agents

Interdoublet sliding rates were assessed in bull sperm, utilizing a freeze–thaw procedure to allow axonemal disintegration. The sliding rate at 23°C increased with increasing MgATP concentrations up to 1 mMATP, to plateau at 8 μm/sec. The analyzed interdoublet shear in both live and demembranated (Triton X-100-extracted) bull sperm reactivated with 1 mMATP established maximal microtubule sliding rates at 6 μm/sec during flagellar beating. Therefore,in vitrosliding rates were sufficient to account for the beat in intact flagella. The effect of inhibitors of flagellar motility onin vitrosliding rates was evaluated. While 8 μMvanadate minimally reduced the sliding rate (to ≈ 4 μm/sec), only 0.5 μMvanadate was sufficient to terminate reactivated bull sperm motility. Nickel ion (0.66 mM) terminated all spontaneous motility, while only reducing microtubule sliding rates to ≈ 5.0 μm/sec. Exposing intact bull sperm to theophylline (1 mM), and incubating the subsequently demembranated sperm in cAMP (3 μM), improved flagellar motility, but had little impact on microtubule sliding rates as determined by axonemal disintegration. Furthermore, deactivating live sperm with 2 mMKCN and 4 mM2-deoxy-d-glucose renders the subsequently reactivated sperm immotile (as long as exogenous cAMP is absent). Yet, this treatment only reduced the sliding rate by 38%. Paradoxically, 4 mMMgADP reduced the sliding rates most dramatically (86%), whereas demembranated sperm models retain a strong, coordinated beating pattern in the presence of MgADP. These results demonstrate that there is no direct relationship between interdoublet sliding rates and the capacity for coordinated flagellar beating.