Nucleotides as nucleophiles: Reactions of nucleotides with phosphoimidazolide activated guanosine

An earlier study of the reaction of phosphoimidazolide activated nucleosides (ImpN) in aqueous phosphate buffers indicated two modes of reaction of the phosphate monoanion and dianion. The first mode is catalysis of the hydrolysis of the P-N bond in ImpN's which leads to imidazole and nucleoside 5-monophosphate. The second represents a nucleophilic substitution of the imidazole to yield the nucleoside 5-diphosphate. This earlier study thus served as a model for the reaction of ImpN with nucleoside monophosphates (pN) because the latter can be regarded as phosphate derivatives. In the present study we investigated the reaction of guanosine 5-phosphate-2-methylimidazolide, 2-MeImpG, in the presence of pN (N=guanosine, adenosine and uridine) in the range 6.9 pH 7.7. We observed that pN's do act as nucleophiles to form NppG, and as general base to enhance the hydrolysis of the P-N bond in 2-MeImpG, i.e. pN show the same behavior as inorganic phosphate. The kinetic analysis yields the following rate constants for the dianion pN^2–:k _n ^pN =0.17±0.02 M^–1 h^–1 for nucleophilic attack andk _h ^pN =0.11±0.07 M^–1 h^–1 for general base catalysis of the hydrolysis. These rate constants which are independent of the nucleobase compare withk _{p 2}=0.415 M^–1 h^–1 and =0.217 M^–1 h^–1 for the reactions of HPO ₄ ^2– . In addition, this study shows that under conditions where pN presumably form stacks, the reaction mechanism remains unchanged although in quantitative terms stacked pN are somewhat less reactive. Attack by the 2-OH and 3-OH groups of the ribose moiety in amounts 1% is not observed; this is attributed to the large difference in nucleophilicity in the neutral pH range between the phosphate group and the ribose hydroxyls. This nucleophilicity rank is not altered by stacking.     

Aquo-pentamine Co(III) complexes as models for carbonic anhydrase

The hydrolysis of 4-nitrophenyl acetate by metal complexes Co(en)2(imH)H2O3+, Co(en)2(bzmH)H2O3+, and Co(en)2(imCH3)H2O3+ (imH = imidazole, bzmH = benzimodazole, imCH3 = methyl imidazole) has been investigated in the pH range 5.4-8.9. The small difference in nucleophilic reactivity in the pH range 5.4-6.7 is assumed to be due to hydrogen bonding abilities of the imidazole and substituted imidazole ligands and small pKa differences (k2(imH) = 2.2 X 10(-2) M-1 sec-1, k2(bzmH) = 5.68 X 10(-2) M-1 sec-1, k2(imCH3) = 1.35 X 10(-2) M-1 sec-1, 40 degrees C, 1 = 0.3 NaClO4, pKa(imH) = 6.2, pKa(imCH3) = 6.2 and pKa(bzmH) = 5.9). In the pH range 7.8-8.9, the differences in nucleophilic reactivity (k3(imH) = 85.5 X 10(-2) M-1 sec-1, k3(bzmH) = 33.4 X 10(-2) M-1 sec-1, 40 degrees C, I = 0.3 NaClO4) are reconciled with a significant steric factor outweighing the acidity of the benzimidazole complex. In the pH region 6.7-7.7, the deviation from linearity is presumably due to both hydroxo and imido ligands functioning as nucleophiles, the latter being about 40 times stronger than the former.     

Reactivity of modified ribose moieties of guanosine: new cleavage reactions mediated by the IVS of Tetrahymena precursor rRNA.

An RNA molecule consisting of the 5' exon and intervening sequence (IVS) of Tetrahymena precursor rRNA was oxidized with sodium periodate to convert the ribose moiety of the 3' terminal guanosine into a dialdehyde form. The modified RNA undergoes a specific cleavage reaction at the 5' splice site, but has no apparent cyclization activity. This novel reaction mediated by the IVS RNA is pH dependent over the range 6.5-8.5 and leaves a 5' phosphate and a 3'-OH at the newly created termini. The dialdehyde form of monomer guanosine is also capable of causing a specific cleavage reaction at the 5' splice site although the nucleotide is not covalently attached to the IVS RNA in the final product. These and other findings described in this report suggest that the cis diol of the intact ribose moiety of guanosine is not an absolute requirement for the IVS-mediated reactions.     

Purine nucleoside phosphorylase. Inosine hydrolysis, tight binding of the hypoxanthine intermediate, and third-the-sites reactivity.

Purine nucleoside phosphorylase from calf spleen is a trimer which catalyzes the hydrolysis of inosine to hypoxanthine and ribose in the absence of inorganic phosphate. The reaction occurs with a turnover number of 1.3 x 10(-4) s-1 per catalytic site. Hydrolysis of enzyme-bound inosine occurs at a rate of 2.0 x 10(-3) s-1 to form a stable enzyme-hypoxanthine complex and free ribose. The enzyme hydrolyzes guanosine; however, a tightly-bound guanine complex could not be isolated. The complex with hypoxanthine is stable to gel filtration but can be dissociated by acid, base, or mild denaturing agents. Following gel filtration, the E.hypoxanthine complex dissociates at a rate of 1.9 x 10(-6) s-1 at 4 degrees C and 1.3 x 10(-4) s-1 at 30 degrees C. The dissociation constant for the tightly-bound complex of enzyme-hypoxanthine is estimated to be 1.3 x 10(-12) M at 30 degrees C on the basis of the dissociation rate. The stoichiometry of the reaction is 1 mol of hypoxanthine bound per trimer. The reaction is reversible since the same complex can be formed from enzyme and hypoxanthine. Addition of ribose 1-phosphate to the complex results in the formation of inosine without release of hypoxanthine. Thus, the complex is catalytically competent. Inorganic phosphate or arsenate prevents formation of the tightly-bound E.hypoxanthine complex from inosine or hypoxanthine. Direct binding studies with hypoxanthine in the presence of phosphate result in 3 mol of hypoxanthine bound per trimer with a dissociation constant of 1.6 microM. In the absence of phosphate, three hypoxanthines are bound, but higher hypoxanthine concentrations cause the release of two of the hypoxanthines with an apparent inhibition constant of 130 microM. The results establish that enzymatic contacts with the nucleoside alone are sufficient to destabilize the N-glycosidic bond. In the absence of phosphate, water attacks slowly, causing net hydrolysis. The hydrolytic reaction leaves hypoxanthine stranded at the catalytic site, tightly bound to the enzyme with a conformation related to the transition state. In the phosphorolysis reaction, ribose 1-phosphate causes relaxation of this conformation and rapid release of hypoxanthine.     

Limiting concentrations of activated mononucleotides necessary for poly(C)-directed elongation of oligoguanylates

Summary Selected imidazolide-activated nucleotides have been subjected to hydrolysis under conditions similar to those that favor their template-directed oligomerization. Rate constants of hydrolysis of the P–N bond in guanosine 5-monophosphate 2-methylimidazolide (2-MeImpG) and in guanosine 5-monophosphate imidazolide (ImpG), k_h, have been determined in the presence/absence of magnesium ion as a function of temperature and polycytidylate [poly(C)] concentration. Using the rate constant of hydrolysis of 2-MeImpG and the rate constant of elongation, i.e., the reaction of an oligoguanylate with 2-MeImpG in the presence of poly(C) acting as template, the limiting concentration of 2-MeImpG necessary for oligonucleotide elongation to compete with hydrolysis can be calculated. The limiting concentration is defined as the initial concentration of monomer that results in its equal consumption by hydrolysis and by elongation. These limiting concentrations of 2-MeImpG are found to be 1.7 mM at 37°C and 0.36 mM at 1°C. Boundary conditions in the form of limiting concentration of activated nucleotide may be used to evaluate a prebiotic model for chemical synthesis of biopolymers. For instance, the limiting concentration of monomer can be used as a basis of comparison among catalytic, but nonenzymatic, RNA-type systems.We also determined the rate constant of dimerization of 2-MeImpG, k₂=0.45±0.06 M^–1 h^–1 in the absence of poly(C), and 0.45±0.06k₂0.97±0.13 M^–1 h^–1 in its presence at 37°C and pH 7.95. This dimerization, as well as the trimerization of 2-MeImpG, which represent the first steps in the oligomerization reaction, are markedly slower than the elongation of longer oligoguanylates, (pG) _n n>6. This means that in the presence of low concentrations of 2-MeImpG (1.7 mM) the system directs the elongation of longer oligomers more efficiently than the formation of short oligomers such as dimers and trimers. These results will be discussed as a possible example of chemical selection in template-directed reactions of nucleotides.     

DIMERIZATION IN HIGHLY CONCENTRATED SOLUTIONS OF PHOSPHOIMIDAZOLIDE ACTIVATED MONONUCLEOTIDES

Phosphoimidazolide activated ribomononucleotides (*pN) are useful substrates for the non-enzymatic synthesis of polynucleotides. However, dilute neutral aqueous solutions of *pN typically yield small amounts of dimers and traces of polymers; most of *pN hydrolyzes to yield nucleoside 5-monophosphate. Here we report the self-condensation of nucleoside 5-phosphate 2-methylimidazolide (2-MeImpN with N = cytidine, uridine or guanosine) in the presence of Mg2+ in concentrated solutions, such as might have been found in an evaporating lagoon on prebiotic Earth. The product distribution indicates that oligomerization is favored at the expense of hydrolysis. At 1.0 M, 2-MeImpU and 2-MeImpC produce about 65% of oligomers including 4% of the 3,5-linked dimer. Examination of the product distribution of the three isomeric dimers in a self-condensation allows identification of reaction pathways that lead to dimer formation. Condensations in a concentrated mixture of all three nucleotides (U,C,G mixtures) is made possible by the enhanced solubility of 2-MeImpG in such mixtures. Although percent yield of internucleotide linked dimers is enhanced as a function of initial monomer concentration, pyrophosphate dimer yields remain practically unchanged at about 20% for 2-MeImpU, 16% for 2-MeImpC and 25% of the total pyrophosphate in the U,C,G mixtures. The efficiency by which oligomers are produced in these concentrated solutions makes the evaporating lagoon scenario a potentially interesting medium for the prebiotic synthesis of dimers and short RNAs.     

Pre-steady-state analysis of the nucleoside hydrolase of Trypanosoma vivax. Evidence for half-of-the-sites reactivity and rate-limiting product release

The nucleoside hydrolase (NH) of the Trypanosoma vivax parasite catalyzes the hydrolysis of the N-glycosidic bond in ribonucleosides according to the following reaction: beta-purine (or pyrimidine) nucleoside + H(2)O --> purine (pyrimidine) base + ribose. The reaction follows a highly dissociative nucleophilic displacement reaction mechanism with a ribosyl oxocarbenium-like transition state. This paper describes the first pre-steady-state analysis of the conversion of a number of purine nucleosides. The NH exhibits burst kinetics and behaves with half-of-the-sites reactivity. The analysis suggests that the NH of T. vivax follows a complex multistep mechanism in which a common slow step different from the chemical hydrolysis is rate limiting. Stopped-flow fluorescence binding experiments with ribose indicate that a tightly bound enzyme-ribose complex accumulates during the enzymatic hydrolysis of the common purine nucleosides. This is caused by a slow isomerization between a tight and a loose enzyme-ribose complex forming the rate-limiting step on the reaction coordinate.     

Three-dimensional structure of ribonuclease T1 complexed with an isosteric phosphonate substrate analogue of GpU: alternate substrate binding modes and catalysis

The X-ray crystal structure of a complex between ribonuclease T1 and guanylyl(3'-6')-6'-deoxyhomouridine (GpcU) has been determined at 2. 0 A resolution. This ligand is an isosteric analogue of the minimal RNA substrate, guanylyl(3'-5')uridine (GpU), where a methylene is substituted for the uridine 5'-oxygen atom. Two protein molecules are part of the asymmetric unit and both have a GpcU bound at the active site in the same manner. The protein-protein interface reveals an extended aromatic stack involving both guanines and three enzyme phenolic groups. A third GpcU has its guanine moiety stacked on His92 at the active site on enzyme molecule A and interacts with GpcU on molecule B in a neighboring unit via hydrogen bonding between uridine ribose 2'- and 3'-OH groups. None of the uridine moieties of the three GpcU molecules in the asymmetric unit interacts directly with the protein. GpcU-active-site interactions involve extensive hydrogen bonding of the guanine moiety at the primary recognition site and of the guanosine 2'-hydroxyl group with His40 and Glu58. On the other hand, the phosphonate group is weakly bound only by a single hydrogen bond with Tyr38, unlike ligand phosphate groups of other substrate analogues and 3'-GMP, which hydrogen-bonded with three additional active-site residues. Hydrogen bonding of the guanylyl 2'-OH group and the phosphonate moiety is essentially the same as that recently observed for a novel structure of a RNase T1-3'-GMP complex obtained immediately after in situ hydrolysis of exo-(Sp)-guanosine 2',3'-cyclophosphorothioate [Zegers et al. (1998) Nature Struct. Biol. 5, 280-283]. It is likely that GpcU at the active site represents a nonproductive binding mode for GpU [Steyaert, J., and Engleborghs (1995) Eur. J. Biochem. 233, 140-144]. The results suggest that the active site of ribonuclease T1 is adapted for optimal tight binding of both the guanylyl 2'-OH and phosphate groups (of GpU) only in the transition state for catalytic transesterification, which is stabilized by adjacent binding of the leaving nucleoside (U) group.     

Analysis of the adenosylcobinamide kinase/adenosylcobinamide-phosphate guanylyltransferase (CobU) enzyme of Salmonella typhimurium LT2. Identification of residue His-46 as the site of guanylylation

CobU is a bifunctional enzyme involved in adenosylcobalamin (coenzyme B(12)) biosynthesis in Salmonella typhimurium LT2. In this bacterium, CobU is the adenosylcobinamide kinase/adenosylcobinamide-phosphate guanylyltransferase needed to convert cobinamide to adenosylcobinamide-GDP during the late steps of adenosylcobalamin biosynthesis. The guanylyltransferase reaction has been proposed to proceed via a covalently modified CobU-GMP intermediate. Here we show that CobU requires a nucleoside upper ligand on cobinamide for substrate recognition, with the nucleoside base, but not the 2'-OH group of the ribose, being important for this recognition. During the kinase reaction, both the nucleotide base and the 2'-OH group of the ribose are important for gamma-phosphate donor recognition, and GTP is the only nucleotide competent for the complete nucleotidyltransferase reaction. Analysis of the ATP:adenosylcobinamide kinase reaction shows CobU becomes less active during this reaction due to the formation of a covalent CobU-AMP complex that holds CobU in an altered conformation. Characterization of the GTP:adenosylcobinamide-phosphate guanylyltransferase reaction shows the covalent CobU-GMP intermediate is on the reaction pathway for the generation of adenosylcobinamide-GDP. Identification of a modified histidine and analysis of cobU mutants indicate that histidine 46 is the site of guanylylation.     

Affinity of guanosine derivatives for polycytidylate revisited

Evidence is presented for complexation of guanosine 5-monophosphate 2-methylimidazolide (2-MeImpG) with polycytidylate (poly(C)) at pH 8.0 and 23°C in the presence of 1.0 M NaCl and 0.2 M MgCl₂ in water. The association of 2-McImpG with poly(C) was investigated using UV-vis spectroscopy as well as by monitoring the kinetics of the nucleophilic substitution reaction of the imidazole moiety by amines. The results of both methods are consistent with moderately strong poly(C) · 2-McImpG complexation and the spectrophotometric measurements allowed the construction of a binding isotherm with a concentration of 2-McImpG equal to 5.55 ± 0.15 mM at half occupancy. UV spectroscopy was employed to establish the binding of other guanosine derivatives on poly(C). These derivatives are guanosine 5-monophosphate (5GMP), guanosine 5monophosphate imidazolide (ImpG), and guanosine 5monophosphate morpholidate (morpG). Within experimental error these guanosine derivatives exhibit the same affinity for poly(C) as 2-McImpG.     

"Single Addition" substrates for the synthesis of specific oligoribonucleotides with polynucleotide phosphorylase. Synthesis of 2'-(alpha-methoxyethy) nucleoside 5'-diphosphates.

A number of synthetic methods for the preparation of the 2-O-(alpha-methoxyethyl) derivatives of the 5-diphosphates of adenosine, cytidine, guanosine, and uridine have been studied in order to provide nucleotide substrates that can be applied to the synthesis of specific oligoribonucleotides using polynucleotide phosphorylase. The reaction of nucleoside 5-diphosphates with methyl vinyl ether for a limited time produces low yields of the corresponding 2-O-(alpha-methoxyethyl) derivatives because the rate of methoxyethylation of the 3-hydroxyl groups. A study of the rates of acidic hydrolysis of alpha-methoxyethyl groups in the 2 and 3 positions of nucleosides and nucleotides has been made, and the results obtained form the basis of a more efficient method for the synthesis of the blocked nucleoside diphosphates. The method involves the reaction of nucleoside 5-diphosphates with methyl vinyl ether to give the corresponding 2,3-di-O-(alpha-methoxyethyl)nucleoside 5-diphosphates, and exploits the fact that, in the acidic hydrolysis of these derivatives, the rate of removal of the 3-methoxyethyl group is about twice that of the group in the 2 position. Alternative syntheses were based on the phosphorylation of methoxyethylated nucleosides and nucleotides. The derivatives, 2-O- and 2,3-di-O-(alpha-methoxyethyl)uridine, were prepared by the methoxyethylation of 3,5-di-O-acetyluridine and 5-O-acetyluridine followed by removal of the acetyl groups. The corresponding guanosine derivatives were made by the synthetic routes: (i) guanosine leads to O-2,O-3,O-5,N-2-tetrabenzoylguanosine leads to 2-N-benzoylguanosine leads to O3-acetyl-N-2,O5-dibenzoylguanosine leads to 2-O-(alpha-methoxyethyl)guanosine, and (ii) 2,3-O-isopropylideneguanosine leads to N-2,O5-diacetyl-2,3-O-isopropylideneguanosine leads to N-2,O-5-diacetylguanosine leads to 2,3-di-O-(alpha-methoxyethyl)guanosine. These methoxyethylated nucleosides were converted to the corresponding 5-phosphates by reaction with cyanoethyl phosphate and dicyclohexylcarbodiimide, and then to the corresponding 5-diphosphates by subsequent reaction with 1,1-carbonyldiimidazole and inorganic phosphate.     

DNA topoisomerase II from Drosophila melanogaster. Relaxation of supercoiled DNA

In order to study the double-strand DNA passage reaction of eukaryotic type II topoisomerases, a quantitative assay to monitor the enzymic conversion of supercoiled circular DNA to relaxed circular DNA was developed. Under conditions of maximal activity, relaxation catalyzed by the Drosophila melanogaster topoisomerase II was processive and the energy of activation was 14.3 kcal . mol-1. Removal of supercoils was accompanied by the hydrolysis of either ATP or dATP to inorganic phosphate and the corresponding nucleoside diphosphate. Apparent Km values were 200 microM for pBR322 plasmid DNA, 140 microM for SV40 viral DNA, 280 microM for ATP, and 630 microM for dATP. The turnover number for the Drosophila enzyme was at least 200 supercoils of DNA relaxed/min/molecule of topoisomerase II. The enzyme interacts preferentially with negatively supercoiled DNA over relaxed molecules, is capable of removing positive superhelical twists, and was found to be strongly inhibited by single-stranded DNA. Kinetic and inhibition studies indicated that the beta and gamma phosphate groups, the 2'-OH of the ribose sugar, and the C6-NH2 of the adenine ring are important for the interaction of ATP with the enzyme. While the binding of ATP to Drosophila topoisomerase II was sufficient to induce a DNA strand passage event, hydrolysis was required for enzyme turnover. The ATPase activity of the topoisomerase was stimulated 17-fold by the presence of negatively supercoiled DNA and approximately 4 molecules of ATP were hydrolyzed/supercoil removed. Finally, a kinetic model describing the switch from a processive to a distributive relaxation reaction is presented.     

Purine nucleoside phosphorylase. Kinetic mechanism of the enzyme from calf spleen.

Ribose 1-phosphate, phosphate, and acyclovir diphosphate quenched the fluorescence of purine nucleoside phosphorylase at pH 7.1 and 25 degrees C. The fluorescence of enzyme-bound guanine was similar to that of anionic guanine in ethanol. Guanine and ribose 1-phosphate bound to free enzyme, whereas inosine and guanosine were not bound to free enzyme in the absence of phosphate. Thus, synthesis proceeded by a random mechanism, and phosphorolysis proceeded by an ordered mechanism. Steady-state kinetic data for the phosphorolysis of 100 microM guanosine were fitted to a bifunctional kinetic model with catalytic rate constants of 22 and 1.3 s-1. The dissociation rate constants for guanine from the enzyme-guanine complex at high and low phosphate concentrations were similar to the catalytic rate constants. Fluorescence changes of the enzyme during phosphorolysis suggested that ribose 1-phosphate dissociated from the enzyme ribose 1-phosphate-guanine complex rapidly and that guanine dissociated from the enzyme-guanine complex slowly. The association and dissociation rate constants for acyclovir diphosphate, a potent inhibitor of the enzyme (Tuttle, J. V., and Krenitsky, T. A. (1984) J. Biol. Chem. 259, 4065-4069), were also dependent on phosphate concentration. The effects of phosphate are discussed in terms of a dual functional binding site for phosphate.     

Loop motion and base release in purine-specific nucleoside hydrolase: A molecular dynamics study

Although various Trypanosoma vivax purine-specific inosine–adenosine–guanosine nucleoside hydrolase (IAG-NH) crystal structures have been determined and the chemical reaction mechanism of substrate hydrolysis has been studied recently, the mechanistic details for the release of base and ribose are still unclear. Herein molecular dynamics (MD) simulations combined with umbrella sampling technique were utilized to explore the regulation mechanisms of key residues and loops 1 and 2 for the base release. Our results have indicated that the base release process is not the rate-limiting step in the entire hydrolysis process, and the very low barrier of ~ 5.6 kcal/mol can be washed out easily by the notable exothermicity from the substrate hydrolysis step. Moreover, the MD simulations have revealed that Glu82/Trp83 in loop 1 and His247/Arg252 in loop 2 are important to modulate the base release. The partial helix-to-coil change of loop 2 along with the base release process has been observed, showing good agreement with the IAG-NH crystal structures. The local binding site around the ribose after the base release is also discussed.     

Catalytic mechanism of α-phosphate attack in dUTPase is revealed by X-ray crystallographic snapshots of distinct intermediates, 31P-NMR spectroscopy and reaction path modelling

Enzymatic synthesis and hydrolysis of nucleoside phosphate compounds play a key role in various biological pathways, like signal transduction, DNA synthesis and metabolism. Although these processes have been studied extensively, numerous key issues regarding the chemical pathway and atomic movements remain open for many enzymatic reactions. Here, using the Mason–Pfizer monkey retrovirus dUTPase, we study the dUTPase-catalyzed hydrolysis of dUTP, an incorrect DNA building block, to elaborate the mechanistic details at high resolution. Combining mass spectrometry analysis of the dUTPase-catalyzed reaction carried out in and quantum mechanics/molecular mechanics (QM/MM) simulation, we show that the nucleophilic attack occurs at the α-phosphate site. Phosphorus-31 NMR spectroscopy (³¹P-NMR) analysis confirms the site of attack and shows the capability of dUTPase to cleave the dUTP analogue α,β-imido-dUTP, containing the imido linkage usually regarded to be non-hydrolyzable. We present numerous X-ray crystal structures of distinct dUTPase and nucleoside phosphate complexes, which report on the progress of the chemical reaction along the reaction coordinate. The presently used combination of diverse structural methods reveals details of the nucleophilic attack and identifies a novel enzyme–product complex structure.     

Computer simulation in template-directed oligonucleotide synthesis

Summary A computer simulation (KINSIM) modeling up to 33 competing reactions was used in order to investigate the product distribution in a template-directed oligonucleotide synthesis as a function of time and concentration of the reactants. The study is focused on the poly(C)-directed elongation reaction of an oligoguanylate (a 7-mer is chosen) with guanosine 5-monophosphate-2-methylimidazolide (2-MeImpG), the activated monomer. It is known that theelongation of oligoguanylates to form oligomeric products such as 8-mer, 9-mer, 10-mer, etc., is in competition with (1) thedimerization and further oligomerization reaction of 2-MeImpG that leads to the formation of dimers and short oligomers, and (2) thehydrolysis of 2-MeImpG that forms inactive guanosine 5-monophosphate, 5-GMP. Experimentally determined rate constants for the above three processes at 37°C and pH 7.95 were used in the simulation; the initial concentrations of 2-MeImpG, [M]_o, and of the oligoguanylate primer, [7-mer]_o, were varied, and KINSIM calculated the distribution of products as a function of time until equilibration was reached, i.e., when all the activated monomer has been consumed. In order to sort out how strongly the elongation reaction may be affected by the competing hydrolysis and dimerization, we also simulated the idealized situation in which these competing reactions do not occur. Simulation of the idealized system suggests that (1) the fraction of [7-mer]_o that has reacted as well as the product distribution after equilibration do not depend on the absolute concentrations of the reactants, but only on their ratio, [M]_o/[7-mer]_o; (2) the rate of elongation is proportional to [7-mer]_o and not to [M]_o; and (3) as the [M]_o/[7-mer]_o ratio increases longer oligomers are formed. The results of the computer simulation with the experimental system, i.e., elongation in the presence of both hydrolysis and dimerization, are similar to the ones obtained with the idealized system as long as dimerization and hydrolysis are not responsible for consuming a substantial fraction of 2-MeImpG.     

Mechanism of the Escherichia coli ADP-ribose pyrophosphatase,a Nudix hydrolase

Escherichia coli ADP-ribose (ADPR) pyrophosphatase (ADPRase), a Nudix enzyme, catalyzes the Mg(2+)-dependent hydrolysis of ADP-ribose to AMP and ribose 5-phosphate. ADPR hydrolysis experiments conducted in the presence of H(2)(18)O and analyzed by electrospray mass spectrometry showed that the ADPRase-catalyzed reaction takes place through nucleophilic attack at the adenosyl phosphate. The structure of ADPRase in complex with Mg(2+) and a nonhydrolyzable ADPR analogue, alpha,beta-methylene ADP-ribose, reveals an active site water molecule poised for nucleophilic attack on the adenosyl phosphate. This water molecule is activated by two magnesium ions, and its oxygen contacts the target phosphorus (P-O distance of 3.0 A) and forms an angle of 177 degrees with the scissile bond, suggesting an associative mechanism. A third Mg(2+) ion bridges the two phosphates and could stabilize the negative charge of the leaving group, ribose 5-phosphate. The structure of the ternary complex also shows that loop L9 moves fully 10 A from its position in the free enzyme, forming a tighter turn and bringing Glu 162 to its catalytic position. These observations indicate that as part of the catalytic mechanism, the ADPRase cycles between an open (free enzyme) and a closed (substrate-metal complex) conformation. This cycling may be important in preventing nonspecific hydrolysis of other nucleotides.     

The effective synthesis of uridylyl/3''-5''/5-methylcytidylyl/3''-5''/guanosine.

The triester method was adapted to the synthesis of uridylyl/3'-5'/5-methylcytidylyl/3'-5'/guanosine. As the protecting groups 4-methoxy-5,6-dihydro-2H-pyran for 2'-OH and 5'-OH groups of uridine and 2'-OH group of 5-methylcytidine, methoxymethylidene for I:3'-cis-diol system of guanosine, and benzoyl for the amino groups of 5-methylcytidine and guanosine were used. The obtained product was characterised by UV, electrophoresis, chromatography, an enzymatic digestion and alkaline hydrolysis.     

Binding of vanadate (V) to ribonuclease-T1 and inosine, investigated by 51V NMR spectroscopy

Ribonuclease T1 (RNase-T1) from Aspergillus Oryzae cleaves ribonucleic acid specifically at guanosine to yield oligonucleotides with terminal guanosine-3'-phosphate. It forms a complex with vanadate (association constant K approximately 145 +/- 30 M-1; delta (51V) = -514 ppm) with spectral features similar to the less stable complexes obtained with di- and tripeptides (Gly-His, Pros-His-Ala, Gly-His-Lys, Val-Glu) containing amino acids that are constituents at the active site of the enzyme. Guanosine also forms a (sparingly soluble) complex with vanadate. Its role is mimicked by inosine, which yields two soluble complexes with vanadate, characterized by delta values of -511 (K = 94 M-1) and -523 ppm (K = 305 M-1 in TRIS buffer and 685 m-1 in buffer-free solution). Comparison with literature values leads to an assignment of the delta = -523 signal to a complex where monovanadate, possibly in a trigonal bipyramidal geometry suggested for the transition state of the phosphate analogue, is coordinated to the 2'- and 3'-oxygens of the ribose ring. A drastic increase of complex stability is observed in the ternary vanadate (12-16 mM)/inosine(10.5 mM)/RNase-T1(5.4 mM) system. An approximate lower limit for the association constant is 1.5.10(5) M-2. The spectral characteristics of the main component of the binary vanadate/inosine complex are essentially maintained (delta = -525 ppm, half-width = 960 Hz), suggesting vanadate binding to the enzyme through hydrogen bonds.