Tubulin exchanges divalent cations at both guanine nucleotide-binding sites

The tubulin heterodimer binds a molecule of GTP at the nonexchangeable nucleotide-binding site (N-site) and either GDP or GTP at the exchangeable nucleotide-binding site (E-site). Mg2+ is known to be tightly linked to the binding of GTP at the E-site (Correia, J. J., Baty, L. T., and Williams, R. C., Jr. (1987) J. Biol. Chem. 262, 17278-17284). Measurements of the exchange of Mn2+ for bound Mg2+ (as monitored by atomic absorption and EPR) demonstrate that tubulin which has GDP at the E-site possesses one high affinity metal-binding site and that tubulin which has GTP at the E-site possesses two such sites. The apparent association constants are 0.7-1.1 x 10(6) M-1 for Mg2+ and approximately 4.1-4.9 x 10(7) M-1 for Mn2+. Divalent cations do bind to GDP at the E-site, but with much lower affinity (2.0-2.3 x 10(3) M-1 for Mg2+ and 3.9-6.6 x 10(3) M-1 for Mn2+). These data suggest that divalent cations are involved in GTP binding to both the N- and E-sites of tubulin. The N-site metal exchanges slowly (kapp = 0.020 min-1), suggesting a mechanism involving protein "breathing" or heterodimer dissociation. The N-site metal exchange rate is independent of the concentration of protein and metal, an observation consistent with the possibility that a dynamic breathing process is the rate-limiting step. The exchange of Mn2+ for Mg2+ has no effect on the secondary structure of tubulin at 4 degrees C or on the ability of tubulin to form microtubules. These results have important consequences for the interpretation of distance measurements within the tubulin dimer using paramagnetic ions. They are also relevant to the detailed mechanism of divalent cation release from microtubules after GTP hydrolysis.     

Nucleotide binding and phosphorylation in microtubule assembly in vitro.

Two non-hydrolyzable analogs of GTP, guanylyl-β,γ-methylene diphosphonate and guanylyl imidodiphosphate, have been found to induce rapid and efficient microtubule assembly in vitro by binding at the exchangeable site (E-site) on tubulin. Characterization of microtubule polymerization by several criteria, including polymerization kinetics, nucleotide binding to depolymerized and polymerized microtubules, and microtubule stability, reveals strong similarities between microtubule assembly induced by GTP and non-hydrolyzable GTP analogs. Nucleoside triphosphates which bind weakly or not at all to tubulin, such as ATP, UTP and CTP, are shown to induce microtubule assembly by means of a nucleoside diphosphate kinase (NDP-kinase, EC 2.7.4.6.) activity which is not intrinsic to tubulin. The NDP-kinase mediates microtubule polymerization by phosphorylating tubulin-bound GDP in situ at the E-site. Although hydrolysis of exchangeably bound GTP occurs, it is found to be uncoupled from the polymerization reaction. The non-exchangeable nucleotide binding site on tubulin (N-site) is not directly involved in microtubule assembly in vitro. The N-site is shown to contain almost exclusively GTP which is not hydrolyzed during microtubule assembly. A scheme is presented in which GTP acts as an allosteric effector at the E-site during microtubule assembly in vitro.     

Evidence for a distinct ligand binding site on tubulin discovered through inhibition by GDP of paclitaxel-induced tubulin assembly in the absence of exogenous GTP

GDP inhibits paclitaxel-induced tubulin assembly without GTP when the tubulin bears GDP in the exchangeable site (E-site). Initially, we thought inhibition was mediated through the E-site, since small amounts of GTP or Mg²⁺, which favors GTP binding to the E-site, reduced inhibition by GDP. We thought trace GTP released from the nonexchangeable site (N-site) by tubulin denaturation was required for polymer nucleation, but microtubule length was unaffected by GDP. Further, enhancing polymer nucleation reduced inhibition by GDP. Other mechanisms involving the E-site were eliminated experimentally. Upon finding that ATP weakly inhibited paclitaxel-induced assembly, we concluded that another ligand binding site was responsible for these inhibitory effects, and we found that GDP was not binding at the taxoid, colchicine, or vinca sites. There may therefore be a lower affinity site on tubulin to which GDP can bind distinct from the E- and N-sites, possibly on α-tubulin, based on molecular modeling studies.     

Binding to tubulin of an allocolchicine spin probe: interaction with the essential SH groups and other active sites

EPR titration of tubulin with an allocolchicine spin probe showed more than one binding site: one high-affinity binding site (Kd = 8 microM), consistent with the Ki found for competition with colchicine, and one or more low-affinity site(s) (Kd higher than 50 microM). No disturbance of the EPR signal of the tubulin-bound allocolchicine spin probe could be observed at room temperature in the presence of other paramagnetic probes: Mn(II) for the binding site of Mg(II), Co(II) for the Zn(II) binding site and Cr(III)GTP for the binding site of the exchangeable GTP. Labelling of tubulin with both the allocolchicine and a SH-group spin probe also showed lack of interaction. The colchicine-binding site is thus sterically isolated from the binding sites for GTP, Mg(II), Zn(II) and the two essential SH-groups. In the tubulin-colchicin complex, all SH-groups could still be labelled with an excess of the SH-reagent, N-ethylmaleimide. Furthermore, colchicine binding was only minimally influenced by the blocking of the two essential SH-groups. However, the rate constant of the reaction of two equivalents of the SH-reagent, a maleimide spin probe, with the tubulin-colchicine complex was only 50% of the rate constant found with uncomplexed tubulin. As direct steric interaction of the essential SH-groups with the colchicine-binding site can be excluded, we can now definitively decide that binding of colchicine to tubulin induces a conformational change, which affects the accessibility of the most reactive SH-groups.     

Energy-transfer studies of the distance between the high-affinity metal binding site and the colchicine and 8-anilino-1-naphthalenesulfonic acid binding sites on calf brain tubulin

The high-affinity metal divalent cation Mg2+, associated with the exchangeable guanosine 5'-triphosphate (GTP) binding site (E site) on purified tubulin, has been replaced by the transition metal ion Co2+ on tubulin as well as on the tubulin-colchicine, tubulin-allocolchicine and tubulin-8-anilino-1-naphthalenesulfonic acid (tubulin-ANS) complexes. While pure native tubulin readily incorporated 0.8 atom of Co2+ per tubulin alpha-beta dimer, incorporation was reduced to 0.4 atom of Co2+ per mole of tubulin when it was complexed with colchicine, indicating that the conformational change induced in tubulin by the binding of colchicine leads to a reduced accessibility of the divalent cation binding site linked to the E site without necessarily changing the intrinsic binding constant. The fluorescence emission spectra of tubulin-bound colchicine, allocolchicine, and ANS displayed a strong overlap with the Co2+ absorption spectrum, identifying these as adequate donor-acceptor pairs. Fluorescence energy-transfer measurements were carried out between tubulin-bound colchicine (or allocolchicine) and ANS as donors and tubulin-complexed Co2+ as acceptor. It was found that the distance between the ANS and the high-affinity divalent cation binding sites is greater than 28 A, while that between the colchicine and the divalent cation binding sites is greater than 24 A.(ABSTRACT TRUNCATED AT 250 WORDS)     

Investigations of equilibrium complexes of myoxin subfragment 1 with the manganous ion and adenosine diphosphate using magnetic resonance techniques.

Electron paramagnetic resonance spectroscopy and water proton relaxation rate (PRR) measurements were used to characterize a complex formed at the myosin subfragment 1 (S1) ATPase site with stoichiometric amounts of Mn(II) and ADP. In the absence of nucleotide, Mn(II) binding at the active site is very weak, although two other classes of sites for Mn(II) on subfragment 1 were identified which are not directly involved in the ATPase reaction. A high affinity Mn(II) site (termed L-site with KL = 3 muM) is associated with a region of the molecule which is susceptible to proteolysis (probably the LC2 light chain subunit) since its stoichiometry depends on the conditions employed for the preparation of subfragment 1 during the papain treatment of myosin. In addition there are a number of weak sites for Mn(II) (termed N-sites) probably associated with anionic groups on the surface of the molecule. In order to study the properties of Mn(II) and ADP bound at the active site by magnetic resonance techniques, subfragment 1 preparations virtually free of the L-site were used, since such an ancillary site competes for the available Mn(II). MnADP binds to subfragment 1 with an apparent dissociation constant, KT, of about 4 muM at 25 degrees. The resultant complex, S1-MnADP, has a low PRR enhancement factor (1.7 at 24.3 MHZ), and its frequency (magnetic field) dependence indicates that this is because there are no readily exchangeable water molecules within the first coordination sphere of Mn(II. Relaxation of the bulk solvent is mediated by protons bound transiently within the outer spheres (4 to 7 A) of the Mn(II). A nitroxide spin label attached to the reactive thiol group of subfragment 1 enhances the solvent PRR, and this property is sensitive to the binding of MgADP to the active site. However, no dipolar spin-spin interaction was detected between the nitroxide group and Mn(II) in the S1-MnADP complex, indicating that the metal ion and thiol group are well separated.     

Tubulin polymerization with ATP is mediated through the exchangeable GTP site

Glycerol-induced tubulin polymerization supported by non-guanine nucleotides was examined. The electrophoretically homogeneous tubulin was devoid of nucleoside diphosphate kinase activity and 95% saturated with exchangeable GDP and nonexchangeable GTP. All purine ribonucleoside 5'-triphosphates were active but no polymerization occurred with CTP or UTP. All polymerization reactions, as a function of nucleotide concentration, were similar: above a minimum (threshold) concentration, as the amount of nucleotide increased the reaction became progressively more rapid and extensive with a progressively shorter nucleation period. Threshold concentrations of ATP, XTP, ITP and GTP were 0.6 mM, 0.3 mM, 30 microM and 7 microM, respectively. Most ribose- and polyphosphate-modified ATP analogs also supported polymerization at high concentrations, but the activity of these analogs relative to ATP was very similar to the activity of cognate GTP analogs relative to GTP. Polymerization with ATP was associated with an ATPase reaction. ATP hydrolysis was potently inhibited by GDP and GTP and altered by antimitotic drugs in parallel with the effects of these agents on GTP hydrolysis. Substantial amounts of [8-14C]GDP bound in the exchangeable site of tubulin were displaced during polymerization with GTP or ATP, but much higher concentrations of ATP were required for equivalent displacement of the tubulin-bound GDP. Polymerization with GTP or ATP was inhibited in a qualitatively similar manner by GDP, with increasing concentrations of GDP causing a progressive prolongation of the nucleation period and reduction in reaction rate and extent. However, complete inhibition of polymerization required that GDP:GTP much greater than 1, but that GDP:ATP much less than 1. Inhibition appeared to be primarily competitive, since with higher triphosphate concentrations higher GDP concentrations were required for comparable inhibition. We conclude that ATP effects on tubulin polymerization are mediated through a feeble interaction at the exchangeable GTP site.     

Tublin: nucleotide binding and enzymic activity

The existence of two distinguishable guanine nucleotide binding sites per molecule of tubulin has been confirmed. One site rapidly exchanges GTP with the medium (E site), the other site binds GDP or GTP very strongly (N site). The GDP bound to the N site can be converted to GTP by transphosphorylase activity using GTP or ATP as the phosphate donor. ATP binds only weakly to the E site, yet it is a better substrate than GTP in the transphosphorylation reaction. The nucleotide used in this reaction therefore comes from the medium and binds to a third site on tubulin itself or to another protein associated with it. Tubulin preparations also show a low ATPase or GTPase activity, which in part is accounted for by turnover of GTP on the N site, the remainder may be associated with the transphosphorylase, tubulin aggregation or contaminating enzyme activity. In addition, during microtubule formation the bound γ-³²P of GTP is lost from both the E and the N sites, leaving bound GDP on the former and probably on the latter site.     

Biophysical investigations on the active site of brain hexokinase

Replacement of Mg (II), the natural activator of brain hexokinase (EC 2.7.1.1) by paramagnetic Mn (II) without affecting the physiological properties of the enzyme, has rendered brain hexokinase accessible to investigations by magnetic resonance methods. Based on such studies, a site on the enzyme, where Mn (II) binds directly with high affinity has been identified and characterized in detail. Use ofβ,γ-bidentate Cr (III) ATP as an exchange-inert analogue for Mn (II) ATP has shown that Mn (II) binding directly to the enzyme has no catalytic role but another Mn (II) ion binding simultaneously and independently to the enzyme through the nucleotide bridge participates in enzyme function. However, using this direct binding Mn (II) ion and a covalently bound spin label as paramagnetic probes a beginning has been made in mapping the ligand binding sites of the enzyme. Ultra-violet difference spectroscopy has revealed the presence of at least two glucose 6-phosphate locations on the enzyme one of which presumably is the high affinity regulatory site modulated by substrate glucose. Elution behaviour of the enzyme on a phosphocellulose column suggests that glucose induces a specific phosphate site on the enzyme to which the phosphate bearing regulatory ligands of the enzyme may bind.     

Orotate phosphoribosyltransferase and hypoxanthine/guanine phosphoribosyltransferase from yeast: nuclear magnetic relaxation studies of the structures of enzyme-bound phosphoribosyl 1-pyrophosphate

Nuclear magnetic relaxation rate measurements have been performed on the protons and phosphorus atoms of phosphoribosyl 1-pyrophosphate (PRibPP) in the presence and absence of paramagnetic chromium(III), cobalt(II), and manganese(II) ions. The longitudinal relaxation rates were then used to calculate interatomic distances between the magnetic nuclei and these paramagnetic probes, from which was devised a conformation of the PRibPP-metal ion complex in solution. Thereafter, the experiments were accomplished in the presence of Mn(II) and a series of orotate phosphoribosyltransferase (OPRTase) and hypoxanthine/guanine phosphoribosyltransferase (HGPRTase) concentrations, and from these data were estimated the distances between Mn(II) and the PRibPP nuclei at the active sites of these two enzymes from yeast. Comparisons between the Mn(II)-PRibPP conformation in solution and this structure at the active sites of OPRTase and HGPRTase revealed that the metal ion remained coordinated with the pyrophosphate group of PRibPP in all instances, whereas the overall distances between the ribose ring and Mn(II) at the enzyme active sites were approximately 1 A further from the metal ion. Model building studies also revealed that the 5'-phosphate group of PRibPP is positioned directly over the ribose ring in solution and at the OPRTase and HGPRTase active sites and may protect the 1'-carbon of PRibPP against on-line displacements of pyrophosphate under these conditions, where the PRibPP-to-Mn(II) concentration ratio is greater than 2000.(ABSTRACT TRUNCATED AT 250 WORDS)     

Magnetic resonance studies of Mn(II)-, Mn(III)-, and Fe(III)-conalbumin complexes.

Apoconalbumin binds Mn(II) at two sites with association constants of K1 = 7 (+/- 1) X 10(4) and K2 = 0.4 (+/- 0.25) X 10(4) M-1. The binding is tighter in the presence of excess bicarbonate resulting in K1 = 1.8 (+/- 0.2) X 10(5) and K2 = 3 (+/- 2) X 10(4) M-1. The electron paramagnetic resonance spectrum (at both 9 and 35 GHz) of Mn(II) bound at the tight site reveals a rhombic distortion (lambda = E/D approximately equal to 0.25-0.31) in the protein ligand environment of the mental ion. An evaluation of the 1/pT1p, paramagnetic contribution to the longitudinal relaxation rate of solvent protons with Mn(II)-, Mn(III)-, and Fe(III)-derivatives of conalbumin revealed that the mental ion in each site of conalbumin is accessible to one water molecule. For Mn(II)-conalbumin and Mn(III)-conalbumin species, inner coordination sphere protons are rapidly exchanging with the bulk solvent, while slow exchange conditions prevail for Fe(III)-conalbumin.     

Nuclear magnetic relaxation studies of the conformation of adenosine 5'-triphosphate on pyruvate kinase from rabbit muscle.

The conformation of adenosine 5'-triphosphate in the manganese complex of pyruvate kinase from rabbit muscle was determined from six metal to nucleus distances derived by nuclear magnetic relaxation techniques. On the enzyme, no direct metal-ATP coordination exists. The phosphorous atoms of ATP are 4.9 to 5.1 A away from manganese, a distance which indicates either a predominantly (greater than or equal to 94%) second sphere complex or, less likely, a highly distorted inner sphere complex. Thus, water ligands or ligands from the protein might intervene between the ATP molecule and the divalent metal ion and facilitate their interaction. The metal-gammaP distance of 5 A for pyruvate kinase-bound ATP is equal to that found for the phosphorous atom of phosphoenolpyruvate and cobalt(II) on pyruvate kinase (Melamud, E., and Mildvan, A. S. (1975) J. Biol. Chem. 250, 8193-8201), which is consistent with the overlap in space of the P-enolpyruvate-phosphorus and the gammaP of ATP at the active site. This observation explains the competitive binding of these two substrates to the enzyme, as detected by NMR and by early kinetic studies. From the phosphorus data and from measurements of the relaxation rates of 3 protons of ATP in the pyruvate kinase-metal-ATP complex, the conformation of ATP was characterized as extended with distances of 6.0, 9.1, and 7.5 A from manganese to the H8, H2, and H'1 protons, respectively. The torsion angle about the glycosidic bond (chi) which defines the conformation of the enzyme-bound riboside and adenine rings was determined to be 30 degrees. In contrast, the conformation of the binary Mn(II)-ATP complex in solution is folded around the metal with direct manganese coordination of the alpha-, beta-, and gamma-phosphorus atoms, and with metal to proton distances of 4.5, 6.4, and 6.2 A for the H8, H2, and H'1 protons, suggesting a second sphere manganese-adenine interaction. The chi angle equals 90 degrees for the binary complex primarily because of the metal-base interaction. Thus, a profound change in the conformation and structure of Mn(II)-ATP from a folded chelate to an extended second sphere complex results when the nucleotide binds to pyruvate kinase.     

Evidence that the tightly bound magnesium in tubulin is associated with the N-site GTP

In an attempt to determine whether the tightly bound Mg2+ found in purified tubulin in associated with the N-site GTP or the E-site GDP or GTP, we removed the E-site nucleotide by several means: (i) alkaline phosphatase treatment; (ii) displacement using excess GMPPCP; and (iii) polymerizing tubulin in the presence of alkaline phosphatase and non-hydrolyzable analogues. The Mg2+ content remained equal to about 1 mol/mol tubulin under conditions where denaturation did not occur. Moreover, the Mg/GTP ratio always remained equal to 1. These results indicate that the Mg2+ is associated with the N-site GTP.     

Glutamine synthetase from Salmonella typhimurium: manganese(II), substrate, and inhibitor interaction with the unadenylylated enzyme.

Unadenylylated glutamine synthetase (EC 6.3.1.2) was isolated and purified to homogeneity from Salmonella typhimurium. The enzyme molecule is a symmetrical aggregate of 12 subunits arranged in two hexagonal layers, as is evident from electron micrographs. The subunit molecular weight of the enzyme was found to be approximately 50,000 by polyacrylamide gel electrophoresis in sodium dodecyl sulfate when compared to Escherichia coli glutamine synthetase and other protein standards. A long tube of glutamine synthetase was formed as a single-stranded coil resulting from incubation of the enzyme in a low ionic strength buffer. A study of Mn(II) binding to the unadenylylated enzyme at 25 °C was conducted as a function of pH. At pH 7.1 two classes of metal ion sites per subunit were found with K_D values of 3.7 × 10^?6 and 1.7 × 10^?4m, while at pH 6.8 these values were 1.1 × 10^?5 and 1.0 × 10^?4m, respectively. Only one set of binding sites was observed at pH 6.2 with a K_D value of 1.0 × 10^?4m. The metal ion binding sites were further investigated by monitoring proton relaxation rates (prr) and the epr spectrum of enzyme-bound Mn(II). The longitudinal prr of water protons at pH 7.1 indicate that protons interacting with enzyme-Mn(II) at the “tight” site (K_D = 3.7 × 10^?6) are de-enhanced (?_b1 = 0.42) and result from water protons beyond the inner coordination sphere. The second Mn(II) site has a value of ?_b2 = 35 for the binary enhancement, suggesting that this site probably has two to three rapidly exchanging water molecules in its coordination sphere. The epr spectrum of enzyme-bound Mn(II) at the “tight” site is isotropic and is dramatically sharpened by adding the substrate analog methionine sulfoximine. Subsequent addition of ATP or the ATP analog, AMP-PCP (adenylyl methylene diphosphate) produced anisotropic spectra that were similar, suggesting that both ATP and AMP-PCP bind similarly on the enzyme surface. However, a marked change in the Mn(II) environment from anisotropic to near cubic results from the addition of ADP to the quaternary enzyme-Mn(II)-sulfoximine- (AMP-PCP) complex, indicating that ADP displaces AMP-PCP. No change in the anisotropic spectrum due to the enzyme-Mn(II)-sulfoximine-ATP complex is seen by the addition of ADP. This experimental result supports the experimental findings of Ronzio and Meister [Proc. Nat. Acad. Sci. USA59, 164 (1968)], who established that ATP phosphorylates methionine sulfoximine, thereby producing an inactive enzyme. The allosteric effectors, AMP and Trp, have little effect on the epr spectrum of the complex formed from Mn(II), enzyme, sulfoximine, and ADP, suggesting the absence of direct coordination of AMP or Trp to the bound Mn(II). The prr and epr results reported herein with glutamine synthetase from S. typhimurium when compared to those seen for the enzyme from E. coli [Villafranca et al., Biochemistry15, 544 (1976)] demonstrate some similarities but also many substantial differences between the enzymes from these two bacterial sources.     

Quantitative evaluation of metal ion binding to PvuII restriction endonuclease

19 F NMR spectroscopy have been applied to evaluate metal ion binding by the representative PvuII endonuclease in the absence of substrate. In separate experiments, ITC data demonstrate that PvuII endonuclease binds 2.16 Mn(II) ions and 2.05 Ca(II) metal ions in each monomer active site with K _d values of  ≈ 1 mM. While neither calorimetry nor protein NMR spectroscopy is directly sensitive to Mg(II) binding to the enzyme, Mn(II) competes with Mg(II) for common sites(s) on PvuII endonuclease. Substitution of the conserved active site carboxylate Glu68 with Ala resulted in a loss of affinity for both equivalents of both Ca(II) and Mn(II). Interestingly, the active site mutant D58A retained an affinity for Mn(II) with K _d  ≈ 2 mM. Mn(II) paramagnetic broadening in ¹⁹F spectra of wild-type and mutant 3-fluorotyrosine PvuII endonucleases are consistent with ITC results. Chemical shift analysis of 3-fluorotyrosine mutant enzymes is consistent with a perturbed conformation for D58A. Therefore, free PvuII endonuclease binds metal ions, and metal ion binding can precede DNA binding. Further, while Glu68 is critical to metal ion binding, Asp58 does not appear to be critical to the binding of at least one metal ion and appears to also have a role in structure. These findings provide impetus for exploring the roles of multiple metal ions in the structure and function of this representative endonuclease. Received: 30 March 1999 / Accepted: 28 September 1999     

Assembly of pure tubulin in the absence of free GTP: effect of magnesium, glycerol, ATP, and the nonhydrolyzable GTP analogues

We describe in vitro microtubule assembly that exhibits, in bulk solution, behavior consistent with the GTP cap model of dynamic instability. Microtubules assembled from pure tubulin in the absence of free nucleotides could undergo one cycle of assembly, but could not sustain an assembly plateau. After the initial peak of assembly was reached and bound E-site GTP hydrolyzed to GDP, the microtubules gradually disassembled. We studied buffer conditions that maximized this disassembly while still allowing robust assembly to take place. While both glycerol and glutamate increased the rate of initial assembly and then slowed disassembly, magnesium promoted initial assembly and, surprisingly, enhanced disassembly. After cooling, a second cycle of assembly was unsuccessful unless GTP or the hydrolyzable GTP analogue GMPCPOP was readded. The nonhydrolyzable GTP analogues GMPPNP and GMPPCP could not support the second assembly cycle in the absence of E-site GTP. Analysis using HPLC found no evidence that GMPPNP, GMPPCP, or ATP could bind to free tubulin, and these nucleotides did not compete with GTP for the E-site. We have, however, demonstrated that the nonhydrolyzable GTP analogues and ATP do have an important effect on microtubule assembly. GMPPNP, GMPPCP, and ATP could each enhance the rate of assembly and stabilize the plateau of assembled microtubules against disassembly, while not binding appreciably to free tubulin. We conclude that these nucleotides, as well as GTP itself, enhance assembly by binding to a site on microtubules that is not present on free, unpolymerized tubulin. We estimate the affinity (KD) of the polymeric site for nucleotide triphosphates to be approximately 10(-4)M.     

Proton nuclear magnetic resonance and electron paramagnetic resonance studies on skeletal muscle actin indicate that the metal and nucleotide binding sites are separate

The distance separating the high-affinity binding sites of actin for a divalent metal ion and nucleotide was evaluated by using high-resolution proton NMR and EPR spectroscopy. Replacement of the Ca2+ or Mg2+ bound to the high-affinity divalent cation site of G-actin by trivalent lanthanide ions such as La3+, EU3+, or Gd3+ results in an increase in the mobility of the bound ATP as observed in the NMR spectra of G-actin monomers. Little difference was observed between the spectra obtained in the presence of the diamagnetic La3+ control and the paramagnetic ions Eu3+ and Gd3+ which respectively shift and broaden the proton resonances of amino acids in the vicinity of the binding site. Analysis of the NMR spectra indicates that the metal and nucleotide binding sites are separated by a distance of at least 16 A. In the past, the metal and ATP have been widely assumed to bind as a complex. Further verification that the two sites on actin are physically separated was obtained by using an ATP analogue with a nitroxide spin-label bound at the 6' position of the purine ring. An estimate of the distance was made between the site containing the ATP analogue and the paramagnetic ion, Mn2+, bound to the cation binding site. These EPR experiments were not affected by the state of polymerization of the actin. The data obtained by using this technique support the conclusion stated above, namely, that the cation and nucleotide sites on either G- or F-actin are well separated.     

Magnetic resonance studies on manganese-nucleotide complexes of phosphoglycerate kinase.

Measurements of the relaxation rate of water protons (PRR) have been used to study the interaction of yeast phosphoglycerate kinase with the manganous complexes of a number of nucleotides. The results indicate that phosphoglycerate kinase belongs to the same class of enzymes as creatine kinase, adenylate kinase, formyltetrahydrofolate synthetase, and arginine kinase, with maximal binding of metal ion to tne enzyme in the presence of the nucleotide substrate. However, an analysis of titration curves for a number of nucleoside diphosphates (ADP, IDP, GDP) showed that there is a substantial synergism in binding of the metal ion and nucleotide to the enzyme in the ternary complex. The metal-substrate binds to the enzyme approximately two orders of magnitude more tightly than the free nucleotide; Other evidence for an atypical binding scheme for Mn(II)-nucleoside diphosphates was obtained by electron paramagnetic resonance (EPR) studies; the EPR spectrum for the bound Mn(II) in the enzyme-MnADP complex differed substantially from those obtained for other kinases. An identical EPR spectrum is observed with the MnADP complex with the rabbit muscle enzyme as with the yeast enzyme. In contrast, the dissociation constant for the enzyme-MnATP complex is approximately fourfold lower than that for enzyme-ATP, and there are no substantial changes in the electron paramagnetic resonance spectrum of MnATP2- when the complex is bound to phosphoglycerate kinase. A small but significant change in the PRR of water is observed on addition of 3-phosphoglycerate (but not 2-phosphoglycerate) to the MnADP-enzyme complex. However, addition of 3-phosphoglycerate to enzyme-MnADP did not influence the EPR spectrum of the enzyme-bound Mn(II).     

Reexamination of the role of nonhydrolyzable guanosine 5'-triphosphate analogues in tubulin polymerization: reaction conditions are a critical factor for effective interactions at the exchangeable nucleotide site

Recently it was proposed [O'Brien, E. T., & Erickson, H. P. (1989) Biochemistry 28, 1413-1422] that tubulin polymerization supported by guanosine 5'-(beta,gamma-imidotriphosphate) [p(NH)ppG], guanosine 5'-(beta,gamma-methylenetriphosphate) [p(CH2)ppG], and ATP might be due to residual GTP in reaction mixtures and that these nucleotides would probably support only one cycle of assembly. Since we had observed polymerization with these three compounds, we decided to study these reactions in greater detail in two systems. The first contained purified tubulin and a high concentration of glycerol, the second tubulin and microtubule-associated proteins (MAPs). In both systems, reactions supported by nucleotides other than GTP were most vigorous at lower pH values. In the glycerol system, repeated cycles of polymerization were observed with ATP and p(CH2)ppG, but not with p(NH)ppG. With p(NH)ppG, a single cycle of polymerization was observed, and this was caused by contaminating GTP. In the MAPs system, repeated cycles of polymerization were observed with both nonhydrolyzable GTP analogues, even without contaminating GTP, but ATP was not active at all in this system. Binding to tubulin of p(NH)ppG, p(CH2)ppG, and, to a lesser extent, ATP was demonstrated indirectly, since high concentrations of the three nucleotides displaced radiolabeled GDP originally bound in the exchangeable site, with p(NH)ppG the most active of the three compounds in this displacement assay. The failure of GTP-free p(NH)ppG to support tubulin polymerization in our glycerol system even though it displaced GDP from the exchangeable site was further investigated by examining the effects of p(NH)ppG on polymerization and polymer-bound nucleotide with low concentrations of GTP. The two nucleotides appeared to act synergistically in supporting polymerization, so that a reaction occurred with a subthreshold GTP concentration if p(NH)ppG was also in the reaction mixture. Analysis of radiolabeled exchangeable-site nucleotide in polymers formed in reaction mixtures containing both GTP and p(NH)ppG demonstrated that p(NH)ppG which entered polymer did so primarily at the expense of GDP originally bound in the exchangeable site rather than at the expense of GTP. It appears that in the glycerol reaction condition, tubulin-p(NH)ppG cannot initiate tubulin polymerization but that it can participate in polymer elongation. ATP and p(CH2)ppG also entered the exchangeable site during polymerization without GTP in glycerol, as demonstrated by displacement of radiolabeled GDP from polymer when these alternate nucleotides were used.(ABSTRACT TRUNCATED AT 400 WORDS)     

Determination of metal-metal distances in E. coli glutamine synthetase by EPR.

This paper reports the first determination of the distance between the two metal ions (per subunit) of $\text{E. coli}$ glutamine synthetase. When Mn(II) is bound at the n₁ metal ion site its EPR spectrum is diminished in intensity but not broadened as Cr(III)-ATP or Cr(III)-ADP is bound to the enzyme. A paramagnetic spin-spin interaction is responsible for this phenomenon and a metal-metal distance of ～7 Å is calculated for enzyme - Mn(II) - Cr(III)-ATP and ～6Å for enzyme - Mn(II) - Cr(III)-ADP. The metal-metal distance changes slightly when substrates or inhibitors are also bound to the enzyme demonstrating induced conformational changes in the protein at the metal ion sites.