The interaction of [13C]-enriched colchicine with tubulin as determined by NMR spectroscopy.

[13C]Colchicine, labeled at the tropolone ring methoxy carbon, was used to study interactions with tubulin containing either Mg2+ or Mn2+ at the high affinity divalent cation binding site. Similar experiments were carried out in the presence of excess free divalent cation. The results show that: (1) when Mn2+ occupies the N-site, the 13C signal of the colchicine methoxy carbon of protein-bound colchicine is not broadened, indicating that in protein-bound colchicine the tropolone methoxy group is not close to the N-site cation; (2) when excess Mn2+ is present in solution this 13C signal is severely broadened, indicating that a low affinity divalent cation site or the exchangeable site (E-site) divalent cation is situated near the colchicine binding site; and (3) in the absence of paramagnetic ions a downfield chemical shift is observed for the tropolone methoxy carbon of colchicine upon binding to tubulin, suggesting that colchicine binds near an aromatic group(s) on tubulin.

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.

GTP hydrolysis by tubulin occurs with water oxygen incorporation into inorganic phosphate.

Tubulin assembly was conducted in [18O]H2O and the resulting mixture of GTP, GDP and Pi was examined by 31P-NMR. Two Pi signals, separated by about 0.02 ppm, were observed. By combining this mixture with a solution of Pi containing all five possible 16O and 18O isotopomers of Pi, it was shown that the two signals were due to [16O4]- and [16O3, 18O]Pi. The amount of 18O incorporated into the Pi was that expected if the hydrolysis of GTP during tubulin assembly occurs with cleavage of the gamma-phosphorus-bridge oxygen bond.

Nuclear magnetic resonance relaxation studies of the interaction of ligands with the monomer and tetramer forms of formyltetrahydrofolate synthetase.

Previous work using n.m.r. spectroscopy to investigate the binding between formyltetrahydrofolate synthetase and its ligands was done using the catalytically active tetrameric form of the enzyme. By removal of specific monovalent cations the tetramer dissociates to four identical, catalytically inactive monomers, which are capable of binding nucleotides with affinities similar to those obtained with the tetramer. In the studies reported here, we examined the interaction of metal-nucleotide, formate and monovalent cations with the monomer using n.m.r. relaxation measurements. We were able to demonstrate that formate binds to the monomer. The spin-lattice relaxation rate (1/T1) of the formate carbon in the monomer.M2+.ADP.formate complex is enhanced when Mg2+ is replaced by Mn2+. By assuming that the exchange of formate is not rate-limiting and that tau c of the monomer is the same as that of the tetramer, the distance between the Mn2+ and the formate carbon was calculated and found to be similar in the monomer and tetramer complexes. The spin-lattice relaxation rates of [13C]trimethylammonium ion (an inactive monovalent cation), [13C]methylammonium and [15N]ammonium ions (both active monovalent cations), were measured in the presence of tetramer, MnADP and formate. The relaxation rates of methylammonium and ammonium ions were enhanced under these conditions whereas the relaxation rate of trimethylammonium ion was not. The results indicate that the active monovalent cations bind near the MnADP binding site. A distance from the Mn2+ to the ammonium nitrogen of between 0.5 and 0.6 nm was calculated.

C nuclear magnetic resonance study of acetate incorporation into malate during ca-uptake by isolated leaf tissues.

(13)C Nuclear magnetic resonance spectroscopy of leaflets of Gleditsia triacanthos and Albizia julibrisin was used to determine the fate of acetate taken up during the absorption of calcium from (13)C-labeled Ca-acetate solution. Small amounts of acetate accumulated temporarily in the leaf tissues, but the bulk of acetate was incorporated into malate. The initial rate of malate synthesis was very low, but increased rapidly during acetate treatment and reached its maximum after 8 hours; the enzymes involved in malate synthesis thus appear to be substrate induced. Use of acetate-2-(13)C yielded malate labeled in C-3, indicating that vacuolar malate accumulating during Ca-uptake might be synthesized via malate synthase from acetate and glyoxalate. However, a source of glyoxalate condensing with acetate during malate synthesis could not be identified. Glycolate produced in photorespiration is an unlikely source, because glycolate-2-(13)C was absorbed and metabolized by the leaf tissues into products of the glycolate pathway, but was not a major precursor in malate synthesis. Malate synthesis via the glyoxalate cycle is also unlikely, because no evidence for the recycling of a (13)C-labeled 4-carbon organic acid was found. Malate synthesis in the leaflets of Gleditsia and Albizia thus appears to involve the inducible condensation of acetate with a 2-carbon compound of unidentified nature and origin.

Substrate and inhibitor activities of the screw sense isomers of metal-nucleotide complexes in the formyltetrahydrofolate synthetase reaction.

Phosphorothioate analogues of ATP and isomers of CrATP and CrADP were used to examine the nucleotide stereoselectivity of formyltetrahydrofolate synthetase from procaryotic and eucaryotic sources. Substrate activity of the thio-ATP analogues increased as the site of sulfur substitution was changed from the gamma to the alpha position. Thus, adenine nucleotide analogues substituted with sulfur at an alpha nonbridging position (ATP alpha S isomers) were the most active, and ATP gamma S was inactive. When Mg2+ was used as the divalent cation, both enzymes showed a clear preference (higher V/Km value) for the Sp isomer of ATP beta S although the magnitude of the preference was greater with the bacterial enzyme. With Cd2+ as the divalent cation the Rp isomer was preferred, but the difference was greater with the yeast enzyme. Both (Sp)-MgATP beta S and (Rp)-CdATP beta S have the delta or right-hand screw sense configuration of the metal chelate ring. The reversal of stereoselectivity when the cation was changed indicates that the metal ion is coordinated to the beta-phosphate group. No stereoselectivity was observed when ATP alpha S isomers were used in the presence of Mg2+ or Cd2+, suggesting that the metals are not coordinated to the alpha-phosphate. ATP beta S was also found to be a competitive inhibitor of MgATP and CdATP, and the lowest Ki values were obtained with the lambda screw sense isomers. The screw sense isomers of bidentate CrATP exhibited no detectable substrate activity but were competitive inhibitors of MgATP.(ABSTRACT TRUNCATED AT 250 WORDS)

Nuclear magnetic resonance studies of formyltetrahydrofolate synthetase interactions with formate and methylammonium ion.

Using nuclear magnetic resonance techniques, we have measured the internuclear distances separating the nucleotide-bound metal from the carbon and hydrogen nuclei of formate as well as the carbon of methylammonium cation when bound to formyltetrahydrofolate synthetase. Measurements were made of the paramagnetic effect on the spin-lattice relaxation rates (1/T1) of 13C and 1H nuclei arising from the replacement of Mg2+ with Mn2+, which binds to the enzyme in the form of a metal-nucleotide complex. Distances from Mn2+ to the formate carbon and proton were found to be 6.3 and 7.4 A, respectively, in the E . ATP . Mn2+ . formate complex and 6.0 and 7.1 A, respectively, in the E . ADP . Mn2+ . formate complex. When tetrahydrofolate was added to the latter complex, the exchange of formate was greatly reduced and became rate limiting for relaxation. These results are consistent with substantial conformational effects produced by the binding of the cofactor. The distance from Mn2+ to the methylammonium carbon in the E . ADP . Mn2+ . CH3NH+3, E . ADP . Mn2+ . formate . CH3NH3+, and E . ADP . Mn2+ . tetrahydrofolate . CH3NH3+ complexes was estimated to be in the range of 7.4-12 A. However, in the E . ADP . Mn2+ formate . tetrahydrofolate . CH3NH3+ complex, the data suggest that exchange of cation contributes significantly to relaxation. These results, combined with other known features of the enzyme, suggest that there may be a monovalent cation site within the active site of the enzyme.