Impact of Sodium Cationization on Gas-Phase Conformations of DNA and RNA Cytidine Mononucleotides

Gas-phase conformations of the sodium-cationized forms of the 2'-deoxycytidine and cytidine mononucleotides, [pdCyd+Na]⁺ and [pCyd+Na]⁺, are examined by infrared multiple photon dissociation action spectroscopy. Complimentary electronic structure calculations at the B3LYP/6-311+G(2d,2p)//B3LYP/6-311+G(d,p) level of theory provide candidate conformations and their respective predicted IR spectra for comparison across the IR fingerprint and hydrogen-stretching regions. Comparisons of the predicted IR spectra and the measured infrared multiple photon dissociation action spectra provide insight into the impact of sodium cationization on intrinsic mononucleotide structure. Further, comparison of present results with those reported for the sodium-cationized cytidine nucleoside analogues elucidates the impact of the phosphate moiety on gas-phase structure. Across the neutral, protonated, and sodium-cationized cytidine mononucleotides, a preference for stabilization of the phosphate moiety and nucleobase orientation is observed, although the details of this stabilization differ with the state of cationization. Several low-energy conformations of [pdCyd+Na]⁺ and [pCyd+Na]⁺ involving several different orientations of the phosphate moiety and sugar puckering modes are observed experimentally.

Modulation of DNA Polymerase Noncovalent Kinetic Transitions by Divalent Cations

Replicative DNA polymerases (DNAPs) require divalent metal cations for phosphodiester bond formation in the polymerase site and for hydrolytic editing in the exonuclease site. Me(2+) ions are intimate architectural components of each active site, where they are coordinated by a conserved set of amino acids and functional groups of the reaction substrates. Therefore Me(2+) ions can influence the noncovalent transitions that occur during each nucleotide addition cycle. Using a nanopore, transitions in individual Φ29 DNAP complexes are resolved with single-nucleotide spatial precision and sub-millisecond temporal resolution. We studied Mg(2+) and Mn(2+), which support catalysis, and Ca(2+), which supports deoxynucleoside triphosphate (dNTP) binding but not catalysis. We examined their effects on translocation, dNTP binding, and primer strand transfer between the polymerase and exonuclease sites. All three metals cause a concentration-dependent shift in the translocation equilibrium, predominantly by decreasing the forward translocation rate. Me(2+) also promotes an increase in the backward translocation rate that is dependent upon the primer terminal 3'-OH group. Me(2+) modulates the translocation rates but not their response to force, suggesting that Me(2+) does not affect the distance to the transition state of translocation. Absent Me(2+), the primer strand transfer pathway between the polymerase and exonuclease sites displays additional kinetic states not observed at >1 mm Me(2+). Complementary dNTP binding is affected by Me(2+) identity, with Ca(2+) affording the highest affinity, followed by Mn(2+), and then Mg(2+). Both Ca(2+) and Mn(2+) substantially decrease the dNTP dissociation rate relative to Mg(2+), while Ca(2+) also increases the dNTP association rate.

[Quantitative parameters of the 3'-5'-exonuclease reaction of human apurinic/apyrimidinic endonuclease 1 and DNA with single-strand breaks containing dYMP or their modified analogues]

Human apurinic/apyrimidinic (AP) endonuclease 1 (APE1) is a multifunctional enzyme. In addition to its main AP endonuclease activity, the cleavage of DNA 5' to the AP site, it displays other weak enzymatic activities. One of them is 3'-5' exonuclease activity, which is most effectively pronounced for DNA duplexes containing modified or mismatched nucleotides at the 3' end of the primer chain. There is a presumption that APE1 can correct the DNA synthesis catalyzed by DNA polymerase beta during the base excision repair process. We determined the quantitative parameters of the 3'-5' exonuclease reaction in dependence on the reaction conditions to reveal the detailed mechanism of this process. The kinetic parameters of APE1 exonuclease excision of mismatched dCMP and dTMP from the 3' terminus of single-strand DNA and from photoreactive dCMP analogues applied for photoaffinity modification of proteins and DNA in recombinant systems and cell/nuclear extracts were determined. The English version of the paper: Russian Journal of Bioorganic Chemistry, 2008, vol. 34, no. 2; see also http://www.maik.ru.

Ultrafast IR spectroscopy of the short-lived transients formed by UV excitation of cytosine derivatives

A strong infrared band at 1574 cm(-1) is observed following 267 nm excitation of 2'-deoxycytidine (tau = 37 +/- 4 ps) or 2'-deoxycytidine 5'-monophosphate (tau = 33 +/- 4 ps); this band is provisionally attributed to an 1n(N)pi* state and is absent for cytosine.

Near 0 eV electrons attach to nucleotides

To elucidate the mechanism of the nascent stage of DNA strand breakage by low-energy electrons, theoretical investigations of electron attachment to nucleotides have been performed by the reliably calibrated B3LYP/DZP++ approach (Chem. Rev. 2002, 102, 231). The 2'-deoxycytidine-3'-monophosphate (3'-dCMPH) and its phosphate-deprotonated anion (3'-dCMP(-)) have been selected herein as models. This investigation reveals that 3'-dCMPH is able to capture near 0 eV electrons to form a radical anion which has a lower energy than the corresponding neutral species in both the gas phase and aqueous solution. The excess electron density is primarily located on the base of the nucleotide radical anion. The electron detachment energy of this pyrimidine-based radical anion is high enough that subsequent phosphate-sugar C-O sigma bond breaking or glycosidic bond cleavage is feasible. Although the phosphate-centered radical anion of 3'-dCMPH is not stable in the gas phase, it may be stable in aqueous solution. However, an incident electron with kinetic energy less than 4 eV might not be able to effectively produce the phosphate-centered radical anion either in solution or in the gas phase. This research also suggests that the electron affinity of the nucleotides is independent of the counterion in aqueous solution.

A structure-based proposal for the catalytic mechanism of the bacterial acid phosphatase AphA belonging to the DDDD superfamily of phosphohydrolases

The Escherichia coli gene aphA codes for a periplasmic acid phosphatase called AphA, belonging to class B bacterial phosphatases, which is part of the DDDD superfamily of phosphohydrolases. After our first report about its crystal structure, we have started a series of crystallographic studies aimed at understanding of the catalytic mechanism of the enzyme. Here, we report three crystal structures of the AphA enzyme in complex with the hydrolysis products of nucleoside monophosphate substrates and a fourth with a proposed intermediate analogue that appears to be covalently bound to the enzyme. Comparison with the native enzyme structure and with the available X-ray structures of different phosphatases provides clues about the enzyme chemistry and allows us to propose a catalytic mechanism for AphA, and to discuss it with respect to the mechanism of other bacterial and human phosphatases.

Impact of the translocational equilibrium of HIV-1 reverse transcriptase on the efficiency of mismatch extensions and the excision of mispaired nucleotides

The reverse transcriptase of the human immunodeficiency virus type 1 (HIV-1 RT) does not possess an exonucleolytic proofreading activity; however, previous studies have shown that this enzyme can excise incorporated chain-terminators in the presence of pyrophosphate or ATP. This type of reaction provides a plausible mechanism for HIV-1 resistance to several nucleoside analogue inhibitors. Here we studied the efficiency of pyrophosphorolysis in the context of mismatched nucleotides, and found that the removal of dCMP and dTMP opposite T is literally blocked. Thus, pyrophosphorolysis may not provide an alternative, universal proofreading mechanism, although excision of dGMP and the correct dAMP opposite T can occur with considerable efficiency. Site-specific footprinting experiments revealed that the 3' end of C:T- and T:T-mispaired primer strands is predominantly found in a post-translocational configuration, which prevents the removal of terminal nucleotides. In contrast, complexes containing G:T and A:T base pairs can exist in both post- and pre-translocational stages. Excision can only occur in the latter, which helps to explain the observed selectivity of the reaction. The efficiency of mismatch extensions does not appear to depend on pre-existing changes of the translocational equilibrium. However, footprints of complexes containing 3' penultimate mismatches suggest that the incorporation of the first nucleotide following the mispair can force the enzyme to slide backwards, which can inhibit ensuing polymerization events. The fact that misincorporated nucleotides can affect the precise positioning of RT provides a rational for the development of novel nucleoside analogue inhibitors that contain modifications in the base moiety.

Benzo[a]pyrene diol epoxide forms covalent adducts with deoxycytidylic acid by alkylation at both exocyclic amino N(4) and ring imino N-3 positions

The carcinogen 7r,8t-dihydroxy-9t,10t-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene (anti-BPDE) alkylates DNA at dGuo, dAdo, and dCyd. dCyd adducts, formed in small amounts, elute near the more abundant dGuo adducts. We isolated the dCyd adducts formed with dCMP. Each BPDE enantiomer forms three major adducts with dCMP, two cis and one trans. The trans adduct and one of the cis adducts form by alkylation at exocyclic N(4), while the second cis adduct is a dUrd adduct formed by alkylation at ring N-3 followed by deamination. Epoxide ring-opening geometries were assigned on the basis of halide and temperature effects on adduct yield, the sign of the major CD band, and benzo ring proton NMR coupling constants. One of each set of cis adducts is fluorescent (FL), and the other is nonfluorescent (NF). The trans and FL cis adducts have fluorescence quantum yields 40-50% of that of the BPDE hydrolysis product. The long wavelength UV maxima of the FL and NF cis adducts are red-shifted 1 and 3 nm relative to the trans adduct. (1)H NMR deuterium exchange experiments indicate that in the trans and FL cis adducts N(4)-H is coupled to C10-H. Adduct formation experiments with methyl-protected Cyd derivatives show that NF cis adducts result from alkylation at N-3. MS results, pK(a) measurements, and dUrd alkylation experiments indicate that the N-3 dCyd adducts spontaneously deaminate to dUrd adducts. NMR coupling constants show that in the NF cis adduct the C7 and C8 substituents are quasi equatorial and the C9 substituent is quasi axial, unlike in other cis BPDE adducts. (1)H NOESY spectra of the (-)-BPDE NF cis adduct reveal that it exists in two conformers. Molecular modeling shows that the conformers result from two low-energy conformations of very similar energies with the pyrimidine in opposite orientations, separated by significant barriers to rotation of the uracil moiety.

Isolation from Nocardioides sp. strain CT16, purification, and characterization of a deoxycytidine deaminase extremely thermostable in the presence of D,L-dithiothreitol

A deoxycytidine deaminase that was extremely thermostable in the presence of dithiothreitol was found in a mesophilic bacterium isolated from soil. The bacterium was classified as a Nocardioides sp. The enzyme was purified to a homogeneous protein by treatment at 100 degrees C, ammonium sulfate precipitation, and chromatography on DEAE-Toyopearl, hydroxyapatite, and then Sephacryl S-100. Twenty micrograms of the pure enzyme was obtained from 811 mg of the starting crude protein. After treatment at 50 degrees C for 15 min in the absence of dithiothreitol, enzyme activity was 44% of the starting activity; after treatment at 100 degrees C for 2 h in the presence of 50 mm dithiothreitol, activity was 56% of the starting activity. Dithiothreitol greatly stabilized the enzyme. Activity was maximum at 99 degrees C. The Km values for deoxycytidine, cytidine, and methyl-deoxycytidine were 55.2, 140, and 130 microM, respectively. The molecular mass was estimated to be 52 kDa by gel permeation chromatography. The enzyme molecule was dissociated into two subunits each of 18 kDa subunit when reduced with mercaptoethanol.

5-Methyldeoxycytidine monophosphate deaminase and 5-methylcytidyl-DNA deaminase activities are present in human mature sperm cells

Human mature sperm cells have a high nuclease and 5-methyldeoxycytidine monophosphate (5-mdCMP) deaminase activity. The deaminase converts the nuclease degradation product 5-mdCMP into dTMP which is further cleaved into thymine and the abasic sugar-phosphate. Both 5-methylcytidine 5' and 3' monophosphates are good substrates for the deaminase. 5-methylcytidine is not a good deaminase substrate and 5-methylcytosine (5mC) is not a substrate. A purified fraction of the deaminase free of nucleases deaminates 5mC present in intact methylated double-stranded DNA. 5-mdCMP deaminase co-purifies on SDS-PAGE with dCMP deaminase and has an apparent molecular weight of 25 kDa. The enzyme requires no divalent cations and has a Km of 1.4 x 10(-7) M for 5-mdCMP and a Vmax of 7 x 10(-11) mol/h/microg protein. The possible biological implications of the deaminase's activities in the present system are discussed.

Sugar specificity of bacterial CMP kinases as revealed by crystal structures and mutagenesis of Escherichia coli enzyme

Bacterial cytidine monophosphate (CMP) kinases are characterised by an insert enlarging their CMP binding domain, and by their particular substrate specificity. Thus, both CMP and 2'-deoxy-CMP (dCMP) are good phosphate acceptors for the CMP kinase from Escherichia coli (E. coli CMPK), whereas eukaryotic UMP/CMP kinases phosphorylate the deoxynucleotides with very low efficiency. Four crystal structures of E. coli CMPK complexed with nucleoside monophosphates differing in their sugar moiety were solved. Both structures with CMP or dCMP show interactions with the pentose that were not described so far. These interactions are lost with the poorer substrates AraCMP and 2',3'-dideoxy-CMP. Comparison of all four structures shows that the pentose hydroxyls are involved in ligand-induced movements of enzyme domains. It also gives a structural basis of the mechanism by which either ribose or deoxyribose can be accommodated. In parallel, for the four nucleotides the kinetic results of the wild-type enzyme and of three structure-based variants are presented. The phosphorylation rate is significantly decreased when either of the two pentose interacting residues is mutated. One of these is an arginine that is highly conserved in all known nucleoside monophosphate kinases. In contrast, the other residue, Asp185, is typical of bacterial CMP kinases. It interacts with Ser101, the only residue conserved in all CMP binding domain inserts. Mutating Ser101 reduces CMP phosphorylation only moderately, but dramatically reduces dCMP phosphorylation. This is the first experimental evidence of a catalytic role involving the characteristic insert of bacterial CMP kinases. Furthermore, this role concerns only dCMP phosphorylation, a feature of this family of enzymes.

High-performance liquid chromatographic determination of deoxycytidine monophosphate and methyldeoxycytidine monophosphate for DNA demethylation monitoring: experimental design and artificial neural networks optimisation

The optimal conditions for the separation of 2'-deoxycytidine-5'-monophosphate and 5-methyl-2'-deoxycytidine-5'-moncphosphate in the matrix of other natural occurring nucleotides after digest of DNA were investigated. Using experimental design combined with artificial neural networks, efficient optimisation of the HPLC separation conditions was performed. The mobile phase composition was optimised on the basis of its three components (concentration of phosphate, content of methanol and pH). The best separation was obtained with a mobile phase containing 50 mM phosphate, pH 5.5 and 6% methanol. The final resolution achieved between 2'-deoxycytidine-5'-monophosphate and 5-methyl-2'-deoxycytidine-5'-monophosphate was equal to 2.78. Finally, the optimised system was successfully tested on the nucleotide mixture solution to determine the methylation state of 2'-deoxycytidine-5'-monophosphate in DNA in the search for FMR1 gene changes.

5-Substituted N(4)-hydroxy-2'-deoxycytidines and their 5'-monophosphates: synthesis, conformation, interaction with tumor thymidylate synthase, and in vitro antitumor activity

Convenient procedures are described for the synthesis of 5-substituted N(4)-hydroxy-2'-deoxycytidines 5a,b,d-h via transformation of the respective 5-substituted 3', 5'-di-O-acetyl-2'-deoxyuridines 1a-c,e-h. These procedures involved site-specific triazolation or N-methylimidazolation at position C(4), followed by hydroxylamination and deblocking with MeOH-NH(3). Nucleosides 5a,b,d-h were selectively converted to the corresponding 5'-monophosphates 6a,b,d-h with the aid of the wheat shoot phosphotransferase system. Conformation of each nucleoside in D(2)O solution, deduced from (1)H NMR spectra and confirmed by molecular mechanics calculations, showed the pentose ring to exist predominantly in the conformation S (C-2'-endo) and the N(4)-OH group as the cis rotamer. Cell growth inhibition was studied with two L5178Y murine leukemia cell lines, parental and 5-fluoro-2'-deoxyuridine (FdUrd)-resistant, the latter 70-fold less sensitive toward FdUrd than the former. With FdUrd-resistant L5178Y cells, 5-fluoro-N(4)-hydroxy-2'-deoxycytidine (5e) caused almost 3-fold stronger growth inhibition than FdUrd; 5e was only some 3-fold weaker growth inhibitor of the resistant cells than of the parental cells. Thymidylate synthase inhibition was studied with two forms of the enzyme differing in sensitivities toward 5-fluoro-2'-deoxyuridine 5'-monophosphate (FdUMP), isolated from parental and FdUrd-resistant L1210 cell lines. All N(4)-hydroxy-dCMP (6a,b,d-h) and dUMP analogues studied were competitive vs dUMP inhibitors of the enzyme. Analogues 6b,d-h and 5-hydroxymethyl-dUMP, similar to N(4)-hydroxy-dCMP (6a) and FdUMP, were also N(5), N(10)-methylenetetrahydrofolate-dependent, hence mechanism-based, slow-binding inhibitors. 5-Chloro-dUMP, 5-bromo-dUMP, and 5-iodo-dUMP, similar to dTMP, did not cause a time-dependent inactivation of the enzyme. Instead, they behaved as classic inhibitors of tritium release from [5-(3)H]dUMP. 5-Bromo-dUMP and 5-iodo-dUMP showed substrate activity independent of N(5), N(10)-methylenetetrahydrofolate in the thymidylate synthase-catalyzed dehalogenation reaction. The =N-OH substituent of the pyrimidine C(4) prevented the enzyme-catalyzed release from the C(5) of Br(-) and I(-) (the same shown previously for H(+)). While FdUMP and 6a showed a higher affinity and greater inactivation power with the parental cell than FdUrd-resistant cell enzyme, an opposite relationship could be seen with 5-hydroxymethyl-dUMP.

Redox pathways in DNA oxidation: kinetic studies of guanine and sugar oxidation by para-substituted derivatives of oxoruthenium(IV)

The oxidation of nucleotides and DNA by a series of complexes based on Ru(tpy)(bpy)O2+ (1) was investigated (tpy = 2,2':6',2"-terpyridine; bpy = 2,2'-bipyridine). These complexes were substituted with electron-donating or-withdrawing substituents in the para positions of the polypyridyl ligands so that the oxidation potentials of the complexes were affected but the reaction trajectory of the oxo ligand with DNA was the same throughout the series. The prepared complexes were (with E1/2(III/II) and E1/2(IV/III) values in volts versus Ag/AgCl) Ru(4'-EtO-tpy)(bpy)O2+ (2; 0.47, 0.60), Ru(4'-Cl-tpy)(bpy)O2+ (3; 0.55, 0.63), Ru(tpy)(4,4'-Me2-bpy)O2+ (4; 0.48, 0.62), and Ru(tpy)(4,4'-Cl2-bpy)O2+ (5; 0.58, 0.63). The complexes oxidized deoxycytosine 5'-monophosphate at the sugar moiety (k = 0.24-0.47 M-1 s-1) and guanosine 5'-monophosphate at the base moiety (k = 6.1-15 M-1 s-1). The rate constants increase across these ranges in the order 3 > 1 > 4 > 2, which is the same order as the redox potentials of the complexes. The effect of the base on these reactions was also studied, and xanthine was found to react with 1 much faster than guanine while hypoxanthine was less reactive than the sugar moiety. The complexes all oxidized oligonucleotides to generate base-labile lesions at guanine and a combination of spontaneous and base-labile scission at the sugar functionalities. The selectivity of cleavage in duplex and single-stranded DNA was not a strong function of the substituents on the metal complex.

Crystal structure of deoxycytidylate hydroxymethylase from bacteriophage T4, a component of the deoxyribonucleoside triphosphate-synthesizing complex

Bacteriophage T4 deoxycytidylate hydroxymethylase (EC 2.1.2.8), a homodimer of 246-residue subunits, catalyzes hydroxymethylation of the cytosine base in deoxycytidylate (dCMP) to produce 5-hydroxymethyl-dCMP. It forms part of a phage DNA protection system and appears to function in vivo as a component of a multienzyme complex called deoxyribonucleoside triphosphate (dNTP) synthetase. We have determined its crystal structure in the presence of the substrate dCMP at 1.6 A resolution. The structure reveals a subunit fold and a dimerization pattern in common with thymidylate synthases, despite low (approximately 20%) sequence identity. Among the residues that form the dCMP binding site, those interacting with the sugar and phosphate are arranged in a configuration similar to the deoxyuridylate binding site of thymidylate synthases. However, the residues interacting directly or indirectly with the cytosine base show a more divergent structure and the presumed folate cofactor binding site is more open. Our structure reveals a water molecule properly positioned near C-6 of cytosine to add to the C-7 methylene intermediate during the last step of hydroxymethylation. On the basis of sequence comparison and crystal packing analysis, a hypothetical model for the interaction between T4 deoxycytidylate hydroxymethylase and T4 thymidylate synthase in the dNTP-synthesizing complex has been built.

Mechanistic studies comparing the incorporation of (+) and (-) isomers of 3TCTP by HIV-1 reverse transcriptase

Among the nucleoside inhibitors used clinically as anti-HIV drugs which target HIV-1 reverse transcriptase (RT), (-)-2', 3'-dideoxy-3'-thiacytidine [(-)SddC or 3TC] is the only analogue with the unnatural L(-) nucleoside configuration. 3TC has been shown to be more potent and less toxic than the D(+) isomer, (+)SddC, which has the natural nucleoside configuration. The mechanistic basis for the stereochemical selectivity and differential toxicity of the isomeric SddC compounds is not completely understood although a number of factors may clearly come into play including differences in uptake, metabolic activation, degradation, and transport. We used a pre-steady-state kinetic analysis to determine the maximum rate of incorporation, kpol, nucleotide-binding affinity, Kd, and efficiency of incorporation, kpol/Kd, for the (-) and (+) isomeric SddCTP compounds as well as the corresponding dideoxy and natural nucleoside triphosphates into a primer-template complex using HIV-1 reverse transcriptase. The affinity (Kd) of the dNTP was much tighter and the efficiency (kpol/Kd) of incorporation by enzyme into the primer-template complex was much higher for the DNA/RNA primer-template compared to DNA/DNA. The maximum rate of incorporation, kpol, followed the trend of dCTP > ddCTP > (+)SddCTP > (-)SddCTP while the Kd values determined for the DNA/RNA primer-template followed the order (-)SddCTP congruent with (+)SddCTP congruent with ddCTP > dCTP. The corresponding efficiency of incorporation followed the trend dCTP > ddCTP > (+)SddCTP > (-)SddCTP. These data suggest that perturbations on the ribose ring of cytidine analogues (C --> S) decrease the rate and efficiency of incorporation but enhance the binding affinity. These results are discussed in the context of a computer modeled structure of the ternary complexes of RT, DNA/RNA primer-template, and SddCTP analogues as well as implications for structure-activity relationships and further drug design. This information provides a mechanistic basis for understanding the inhibition of HIV-1 reverse transcriptase by 3TC.

D4T-5'-[p-bromophenyl methoxyalaninyl phosphate] as a potent and non-toxic anti-human immunodeficiency virus agent

Three aryl phosphate derivatives of 2',3'-didehydro-2',3'-dideoxythymidine (d4T) were tested for their anti-human immunodeficiency virus (HIV) activity in peripheral blood mononuclear cells (PBMC) and thymidine kinase (TK)-deficient CEM T cells. Compared to the parent compound d4T, the lead compound d4T-5'-[p-bromophenyl methoxyalaninylphosphate] with a para-bromo substituent in the aryl moiety was 12.6-fold more potent in inhibiting p24 production (IC50 values: 44 nM versus 556 nM) and 41.3-fold more potent in inhibiting the reverse transcriptase (RT) activity (IC50 values: 57 nM versus 2355 nM) in HIV-infected TK-deficient CEM cells. None of the compounds exhibited any detectable cytotoxicity to PBMC or CEM cells at concentrations as high as 10,000 nM. To our knowledge, this is the first demonstration that the potency as well as selectivity index of the d4T aryl phosphate derivatives in TK-deficient cells can be substantially enhanced by introducing a single para-bromo substituent in the phenyl moiety.

Conduction-band-edge ionization thresholds of DNA components in aqueous solution

Numerous investigations have focused on DNA damage induced by ionizing radiation; however, photoionization threshold energies of nucleic acid components in aqueous solution are not known. Herein, data from gas-phase photoelectron experiments have been combined with results from self-consistent field and post-self-consistent field molecular orbital calculations and with theoretical Gibbs free energies of hydration to describe aqueous ionization energies of 2'-deoxythymidine 5'-phosphate (5'-dTMP-) and 2'-deoxycytidine 5'-phosphate (5'-dCMP-). For the test molecules, indole and tryptophan, this approach yields aqueous ionization energies (4.46 and 4.58 eV, respectively) in agreement with experimental values (4. 35 and 4.45 eV). When uridine and 2'-deoxythymidine ionization energies are evaluated, the results agree with recent data from 193-nm laser measurements indicating that uridine ionization occurs via a one-photon event. For 5'-dCMP- and 5'-dTMP-, a comparison of aqueous ionization energies with gas-phase ionization potentials (IPs) indicates that hydration alters the relative energies of ionization events. In the gas phase, phosphate vertical IPs are approximately 1.3 eV smaller than base IPs. In aqueous solution, the base and phosphate ionization energies are more similar, and only differ by approximately 0.5 eV. For 5'-dCMP- and 5'-dTMP-, the increased favorableness of base ionization, which accompanies hydration, is consistent with experimental data indicating that, at 77 K in aqueous perchlorate glasses, the primary photoionization pathway involves base ionization followed by deprotonation.

In vitro anti-human immunodeficiency virus and anti-hepatitis B virus activities and pharmacokinetic properties of heterodinucleoside phosphates containing AZT or ddC

In vitro activities, against human immunodeficiency virus (HIV)- and hepatitis B virus (HBV)-infected cells, of four amphiphilic heterodinucleoside phosphates containing 3'-azido-2',3'-dideoxythymidine (AZT) or 2',3'-dideoxycytidine (ddC) as antiviral monomers were evaluated. The four compounds were N4-hexadecyl-2'-deoxyribocytidylyl-(3'-->5')-3'-azido-2',3'-deoxyt hymidine (N4-hxddC-AZT), N4-palmitoyl-2'-deoxyribocytidylyl-(3'-->5')-3'-azido-2',3'-deoxyt hymidine (N4-pamdC-AZT), N4-hexadecyl-2'-deoxycytidylyl-(3'-->5')-2',3'-dideoxycytidine (N4-hxddC-ddC) and 2'-deoxythymidylyl-(3'-->5')-N4-palmitoyl-2',3'-dideoxycytidine (dT-N4-pamddC). All four dimers were active against HIV, dT-N4-pamddC being the most active and least toxic. dT-N4-pamddC also exhibited strong antiviral effects against a panel of eight AZT-resistant HIV strains. The ddC-containing heterodimers incorporated in liposomes additionally inhibited HBV replication by 50-80% in HepG2 2.2.15 cells. AZT and the AZT-containing dimers were ineffective. Differences in pharmacokinetic properties between the antiviral monomers and the heterodimers were evaluated using liposomal formulations of 3H-labelled AZT heterodimers as model compounds. The cellular distribution of AZT in H9 cells was predominantly cytoplasmic, whereas the amphiphilic dimers were distributed more evenly throughout the cytoplasm, nuclear membranes and microsomes. Blood levels of the heterodimers decreased at a rate two- to threefold slower than AZT and the areas-under-the-curves were five- to sevenfold higher for N4-pamdC-AZT and N4-hxddC-AZT, respectively. Compared to AZT, the peak levels of the dimers were three to four times higher in blood and five to six times higher in the liver. Analysis of blood samples showed that 34% of N4-pamdC-AZT was metabolized to AZT, whereas only 9% of N4-hxddC-AZT released AZT. Considering the antiviral potency and the favourable pharmacokinetic properties of the heterodimers, these compounds merit further exploration as antiviral drugs.

Modeling of reaction steps relevant to deoxyuridylate (dUMP) enzymatic methylation and thymidylate synthase mechanism-based inhibition

Theoretical quantum mechanical ab initio Hartree-Fock calculations on molecular systems, modeling processes related to the specificity of thymidylate synthase inactivation are reported. We considered several steps of the methylation of the substrate dUMP and 4- or 5-mono- and 4,5-bisubstituted dUMP analogs, as well. The following reactions were modeled: the cysteine residue (Cys198 in the L.casei enzyme) nucleophilic attack on the substrate and the substrate C(5)-H proton abstraction. The substrate was modeled by the 1-methyluracil molecule and its structural analogs. The cysteine Cys198 residue was modeled by the methylmercaptane molecule. The substrate-enzyme binary complex was modeled by the 1-methyl-5,6-dihydro-6-thiomethyl-uracil (P1) molecule. The present theoretical calculations suggest that the cysteine nucleophilic attack on the substrate may result in the SH-group addition to the pyrimidine C(5)=C(6) bond in the course of a weakly exothermic reaction. The formerly presumed enolate carbanion appeared to be weakly stable or unstable and it can readily split into the thiol and pyrimidine residues. The s2-thio- (P2) and s2,4-dithio- (P3) substrate analogs should form stable thiolate anions after cysteine residue attachment to the C(6) position of the pyrimidine ring. Studies of the deformed P1 molecule interacting with a water molecule bound to the pyrimidine C(4)=O carbonyl residue allow a suggestion that this water molecule may be directly involved in the C(5)-H proton abstraction and may serve as a proton transmitter between the substrate and the proton acceptor residue, possibly located on the cofactor N10-nitrogen. Interaction of the pyrimidine C(4)=O group, or its modification, with the N5,10-methylenetetrahydrofolate N(10) nitrogen atom is suggested as an additional factor influencing the inhibition process.

A novel dCMP methylase by engineering thymidylate synthase

X-ray crystal structures of binary complexes of dUMP or dCMP with the Lactobacillus caseiTS mutant N229D, a dCMP methylase, revealed that there is a steric clash between the 4-NH2 of dCMP and His 199, a residue which normally H-bonds to the 4-O of dUMP but is not essential for activity. As a result, the cytosine moiety of dCMP is displaced from the active site and the catalytic thiol is moved from the C6 of the substrate about 0.5 A further than in the wild-type TS-dUMP complex. We reasoned that combining the N229D mutation with mutations at residue 199 which did not impinge on the 4-NH2 of dCMP should correct the displacements and further favor methylation of dCMP. We therefore prepared several TS N229D mutants and characterized their steady state kinetic parameters. TS H199A/N229D showed a 10(11) change in specificity for methylation of dCMP versus dUMP. The structures of TS H199A/N229D in complex with dCMP and dUMP confirmed that the position and orientation of bound dCMP closely approaches that of dUMP in wild-type TS, whereas dUMP was displaced from the optimal catalytic binding site.

Evidence for a common active site for cleavage of an AP site and the benzene-derived exocyclic adduct, 3,N4-benzetheno-dC, in the major human AP endonuclease

We have previously reported that the 3,N4-benzetheno-dC (p-BQ-dC) endonuclease activity found in HeLa cells is a novel function of the major human AP endonuclease (HAP1) [Hang et al. (1996) Proc. Natl. Acad. Sci. U.S.A. 93, 13737-13741]. In this study, we compare the enzymatic and biochemical properties of the enzyme toward p-BQ-dC and an AP site in a defined oligonucleotide. A comparative analysis of the specificity constants (Kcat./Km) for p-BQ-dC and an AP site indicates that the AP site is the preferred substrate. The enzyme does not cleave other structurally related exocyclic adducts and modified nucleosides such as 1,N6-etheno-dA, 3,N4-etheno-dC, 1, N2-etheno-dG, 1,N2-propano-dG, 8-oxo-dG, and thymine glycol. The p-BQ-dC activity requires a double-stranded DNA substrate and is affected by the base in the opposite strand, with maximal activity for a p-BQ-dC.G pair and minimal activity for a p-BQ-dC.C pair. The p-BQ-dC activity also requires Mg2+, Mn2+, or Zn2+ with optimal concentration spectra similar to those for the AP function. The optimal pH ranges for these two functions are also similar to each other (5.5-6.5). Six mutant HAP1 proteins containing single amino acid substitutions were assayed in parallel for comparison of their activities toward p-BQ-dC and the AP site. These mutants either concomitantly lost (N212A, D210N) or had reduced (D219A, E96A, and N212Q) or unchanged (H116N) p-BQ-dC and AP activities. This parallelism strongly supports the hypothesis that cleavage of p-BQ-dC requires the same catalytic active site as that proposed for the AP function. This dual activity toward two structurally unrelated substrates, an AP site and a bulky exocyclic adduct, has implications for substrate recognition. The AP site and p-BQ-dC cause different changes in the local conformation around the lesion as it is visualized by molecular modeling.

Thermodynamic characterization of the binding of dCMP to the Asn229Asp mutant of thymidylate synthase

Isothermal titration microcalorimetry and equilibrium dialysis have been used to characterize the binding of 2'-deoxycytidine 5'-monophosphate (dCMP) to the Asn229Asp mutant of Lactobacillus casei recombinant thymidylate synthase at pH 7.4 over a temperature range of 15 degrees C to 35 degrees C. Equilibrium dialysis analysis shows that dCMP binds to two sites in the dimer of both wild-type and mutant thymidylate synthase. A concomitant net uptake of protons with binding of dCMP to both enzymes, was detected carrying out calorimetric experiments in various buffer systems with different heats of ionization. The change in protonation for binding of dCMP to wild-type enzyme is lower than that obtained for binding of this nucleotide to TS N229D, which suggests that the pK value of Asp-229 is increased upon dCMP binding to the mutant enzyme. At 25 degrees C, although the binding of dCMP to wild-type and N229D TS is favoured by both enthalpy and entropy changes, the enthalpy change is more negative for the mutant protein. Thus, the substitution of Asn 229 for Asp results in a higher affinity of TS for dCMP due to a more favourable enthalpic contribution. The Gibbs energy change of binding of dCMP to the mutant enzyme is weakly temperature-dependent, because of the enthalpy-entropy compensation arising from a negative heat capacity change of binding equal to -0.83 +/- 0.02 kJ K(-1) per mol of dCMP bound.

An unusual mechanism for the major human apurinic/apyrimidinic (AP) endonuclease involving 5' cleavage of DNA containing a benzene-derived exocyclic adduct in the absence of an AP site

The major human apurinic/apyrimidinic (AP) endonuclease (class II) is known to cleave DNA 5' adjacent to an AP site, which is probably the most common DNA damage produced hydrolytically or by glycosylase-mediated removal of modified bases. p-Benzoquinone (pBQ), one of the major benzene metabolites, reacts with DNA to form bulky exocyclic adducts. Herein we report that the human AP endonuclease directly catalyzes incision in a defined oligonucleotide containing 3,N4-benzetheno-2'-deoxycytidine (pBQ-dC) without prior generation of an AP site. The enzyme incises the oligonucleotide 5' to the adduct and generates 3'-hydroxyl and 5'-phosphoryl termini but leaves the pBQ-dC on the 5' terminus of the cleavage fragment. The AP function of the enzyme is not involved in this action, as no preexisting AP site is present nor is a DNA glycosylase activity involved. Nicking of the pBQ-dC adduct also leads to the same "dangling base" cleavage when two Escherichia coli enzymes, exonuclease III and endonuclease IV, are used. Our finding of this unusual mode of action used by both human and bacterial AP endonucleases raises important questions regarding the requirements for substrate recognition and catalytic active site(s) for this essential cellular repair enzyme. We believe this to be the first instance of the presence of a bulky carcinogen adduct leading to this unusual mode of action.

Analysis of DNA adducts in DNA hydrolysates by capillary zone electrophoresis and capillary zone electrophoresis-electrospray mass spectrometry

The in vitro adduct formation with phenyl glycidyl ethers (PGEs) was studied on 2'-deoxynucleotides and DNA. The modified DNA was hydrolyzed enzymatically, and the mixtures consisting of unmodified 2'-deoxynucleotide adducts were analyzed by capillary zone electrophoresis (CZE), CZE-electrospray mass spectrometry (CZE/ES-MS) and CZE-electrospray tandem mass spectrometry (CZE/ES-MS/MS) using sample stacking. For the CZE analyses, a homemade system was developed in order to enhance the reproducibility of the retention times. This modification enabled the total comparison of the electropherograms obtained for the analysis of 2'deoxynucleotides mixtures with the electropherograms obtained for the DNA hydrolysates both treated with PGEs. The assignment of adducted and nonadducted 2'-deoxynucleotide peaks was unambiguous. Analysis of the CZE/ES-MS data gave the necessary structural information and revealed the presence of mono- and dialkylated 2'-deoxynucleotides. Interpretation of the CZE/ES-MS/MS data of the monoalkylated products allowed differentiation between purine or pyrimidine alkylation and alkylation of the 5-phosphate moiety. Recording of full-scan mass spectra during CZE/ES-MS/MS analysis of 2'-deoxynucleotide reaction mixtures and DNA hydrolysates was possible, using the described CZE sample stacking technique.

Interaction of bivalent copper, nickel, manganese ions with native DNA and its monomers

UV differential spectroscopy is applied to study the interaction of Cu2+, Ni2+, Mn2+ ions with deoxyribonucleotides of canonic bases (dGMP, dAMP, dCMP, dTMP) and native DNA. Heteroatoms of the bases, coordinating ions, and binding constants which characterize the formation of metal complexes are found. The affinity of the ions is lower for the deoxyribonucleotide bases than for the ribonucleotide ones. This indicates that 02' of ribose participates in the stabilization of the metal complex even under conditions close to the neutral one (pH 6). Unlike the Cu2+ ions, Ni2+ and Mn2+ ions do not interact with N3C both in monomers and polymers. This seems to be the main factor explaining why copper makes DNA transform into a structure with a quasi-Hoogsteen pairing of GC pairs. No transformations of this kind of helix-coil transitions are caused by manganese and nickel up to concentrations 4 X 10(-2) M.

Raman signature of the four-stranded intercalated cytosine motif in crystal and solution structures of DNA deoxycytidylates d(CCCT) and d(C8)

The Raman spectral signature of the four-stranded cytosine structure formed by intercalation of two hemiprotonated and parallel-stranded oligodeoxycytidylate duplexes (so-called i motif) has been obtained from the crystal structure of d(CCCT) [Kang, C.H., Berger, I., Lockshin, C., Ratliff, R., Moyzis, R., & Rich, A. (1994) Proc. Natl. Acad. Sci. U.S.A. 91, 11636-11640]. Identification of Raman markers diagnostic of the cytosine quadruplex is complemented by results obtained in a pH titration of 2'-deoxycytosine-5'-monophosphate (5'-dCMP) to show that the spectral fingerprint associated with N3 protonation of cytosine is distinct from that of quadruplex formation. The Raman spectrum thus provides a definitive basis for evaluating quantitatively both the extent of cytosine quadruplex formation and the degree of cytosine N3 protonation in DNA. Application to aqueous d(CCCT) and d(C8) demonstrates that the four-stranded intercalated structure is formed by both of these oligodeoxycytidylates in aqueous solution. Whereas both 5'-dCMP and the d(CCCT) quadruplex exhibit a midpoint of titration (apparent pKc) of 4.5 +/- 0.2 at 10 degrees C, cytosine protonation in d(C8) is shifted significantly toward the physiological range, with pKc = 5.8 +/- 0.2. The difference in pKc between the two quadruplexes is equivalent to a free energy difference of 1.7 kcal/mol at 10 degrees C. The present findings extend the library of Raman conformation markers to deoxycytidylate residues in the novel i quadruplex. The significance of these results for probing solution conformations of telomeric DNA sequences is also considered.

Partitioning roles of side chains in affinity, orientation, and catalysis with structures for mutant complexes: asparagine-229 in thymidylate synthase

Thymidylate synthase (TS) methylates only dUMP, not dCMP. The crystal structure of TS.dCMP shows sCMP 4-NH2 excluded from the space between Asn-229 and His-199 by the hydrogen bonding and steric properties and Asn-229. Consequently, 6-C of dCMP is over 4 A from the active site sulfhydryl. The Asn-229 side chain is prevented from flipping 180 degrees to and orientation the could hydrogen bond to dCMP by a hydrogen bond network between conserved residues. Thus, the specific binding of dUMP by TS results from occlusion of competing substrates by steric and electronic effects of residues in the active site cavity. When Asn-229 is replaced by a cysteine, the Cys-229 S gamma rotates out of the active site, and the mutant enzyme binds both dCMP and dUMP tightly but does not methylate dCMP. Thus simply admitting dCMP into the dUMP binding site of TS is not sufficient for methylation of dCMP. Structures of nucleotide complexes of TS N229D provide a reasonable explanation for the preferential methylation of dCMP instead of dUMP by this mutant. In TS N229D.dCMP, Asp-229 forms hydrogen bonds to 3-N and 40NH2 of dCMP. Neither the Asp-229 carboxyl moiety nor ordered water appears to hydrogen bond to 4-O of dUMP. Hydrogen bonds to 4-O (or 4-NH2) have been proposed to stabilize reaction intermediates. If their absence in TS N229D.dUMP persists in the ternary complex, it could explain the 10(4)-fold decrease in kcat/Km for dUMP.

Structure and function of the multifunctional DNA-repair enzyme exonuclease III

The repair of DNA requires the removal of abasic sites, which are constantly generated in vivo both spontaneously and by enzymatic removal of uracil, and of bases damaged by active oxygen species, alkylating agents and ionizing radiation. The major apurinic/apyrimidinic (AP) DNA-repair endonuclease in Escherichia coli is the multifunctional enzyme exonuclease III, which also exhibits 3'-repair diesterase, 3'-->5' exonuclease, 3'-phosphomonoesterase and ribonuclease activities. We report here the 1.7 A resolution crystal structure of exonuclease III which reveals a 2-fold symmetric, four-layered alpha beta fold with similarities to both deoxyribonuclease I and RNase H. In the ternary complex determined at 2.6 A resolution, Mn2+ and dCMP bind to exonuclease III at one end of the alpha beta-sandwich, in a region dominated by positive electrostatic potential. Residues conserved among AP endonucleases from bacteria to man cluster within this active site and appear to participate in phosphate-bond cleavage at AP sites through a nucleophilic attack facilitated by a single bound metal ion.

Evidence from 18O exchange studies for an exocyclic methylene intermediate in the reaction catalyzed by T4 deoxycytidylate hydroxymethylase

18O exchange experiments were designed to identify the final intermediate in the catalytic mechanism of bacteriophage T4 deoxycytidylate (dCMP) hydroxymethylase (CH). CH catalyzes the formation of 5-(hydroxymethyl)-dCMP (HmdCMP) from dCMP and methylenetetrahydrofolate (CH2-THF). CH resembles thymidylate synthase (TS), an enzyme of known three-dimensional structure, in both amino acid sequence and the reaction catalyzed. The final intermediate in the reaction catalyzed by TS or CH has been proposed to be the nucleotide with an exocyclic 5-methylene group covalently linked to the enzyme. This intermediate is then hydrated to HmdCMP (by CH) or reduced to deoxythymidylate (by TS). We report here that CH catalyzes the incorporation of 18O from solvent water into the product, HmdCMP, in the presence of tetrahydrofolate (THF). The cause of this exchange is a reverse reaction followed by a resynthesis. CH also catalyzes the exchange of 18O from solvent water into HmdCMP in the absence of exogenous THF and in the presence of THF analogues that lack N-5. N-5 is the nitrogen that is likely to be bound to the methylene as it is transferred to dCMP. A CH variant that lacks the nucleophilic Cys 148 is incapable of promoting these 18O exchange reactions. The THF analogues lacking N-5 do not promote a CH-catalyzed reverse reaction. Rather, we propose that the CH-catalyzed 18O exchange reaction promoted by these THF analogues occurs via 5-methylene-dCMP linked to the enzyme through Cys 148. We conclude here that enzyme-bound 5-methylene-dCMP is the final intermediate during catalysis by CH, as has also been proposed for TS and dUMP.

Exclusion of 2'-deoxycytidine 5'-monophosphate by asparagine 229 of thymidylate synthase

In thymidylate synthase (TS, EC 2.1.1.45), the only side chain in direct hydrogen bonding with the pyrimidine ring of the substrate dUMP is asparagine 229 (N229). In binary and ternary complexes, the carboxamide moiety of the side chain of N229 forms a cyclic hydrogen bond network bridging N-3 and O-4 of the uracil heterocycle. Most of the N229 mutants of TS bind dUMP and catalyze dTMP formation as well as the wild-type enzyme; thus, N229 does not contribute to binding of dUMP. Wild-type TS binds dCMP weakly and does not accept dCMP as a substrate. Mutations at N229 of TS modify the interaction of TS with dCMP. TS N229D and TS N229E catalyze the methylation of dCMP [Liu, L., & Santi, D. V. (1992) Biochemistry 31, 5010-5014]. With the exception of the TS N229Q, most of the N229 mutants bind dCMP as well as or tighter than dUMP and bind dCMP 300-3000-fold tighter than wild-type TS. We conclude that TS discriminates binding of dUMP versus dCMP by a 3-4 kcal mol-1 difference in binding energy by exclusion of dCMP from the active site. We propose that this exclusion is a consequence of untoward interactions between dCMP and the side-chain carboxamide group of the Asn or Gln at position 229 of TS. We speculate that exclusion of cytosine versus uracil by Asn or Gln may account for specificity observed in other protein-pyrimidine interactions.

Lanthanide ion luminescence as a probe of DNA structure. 2. Non- guanine-containing oligomers and nucleotides

Oligo(dC)8, oligo(dA)8, and oligo(dT)8 as well as d-CMP, d-AMP, and d-TMP, when complexed to Eu(3+), possess two classes of Eu(3+) binding environment. The binding environments consist of two classes, tight sites which coordinate two H2O molecules, and weaker sites which coordinate six or seven, analogous to the previously studied guanine-containing molecules. It is inferred that the tight class of Eu(3+) ion site observed with these oligomers and nucleotides corresponds to dimeric or polymeric structures. Comparison of the results for the guanine and non-guanine containing oligomers suggests that Eu(3+) possibly coordinates base nitrogen atoms in the former and in an outer sphere mode (hydrogen bonding via the H2O molecules coordinated to Eu(3+)) in the species examined here.

Theoretical analysis of deoxycytidine-5'-phosphate protonation

The electron density distribution in deoxycytidine-5'-monophosphate (5'-dCMP) molecule and dianion has been studied by the method of CNDO/2. The comparison between the results of calculation for the neutral molecule and the data obtained by Pearlman and Kim shows that there is a linear correlation between the atomic charges calculated using quantum chemistry and those derived from X-ray results. However, partial charges for the deoxyribose fragment are correlated in a nonlinear manner. The influence of the protons added to the cytosine and phosphate residues on the atomic charges and bond orders of deoxy-cytidine-5'-monophosphate has been analyzed here. The conclusion has been drawn that the semiempirical quantum-chemical CNDO/2 technique is applicable to the mononucleotide studies.

Identification of 3,N4-propanodeoxycytidine 5'-monophosphate formed by the reaction of acrolein with deoxycytidine 5'-monophosphate

Acrolein reacts with deoxycytidine 5'-monophosphate at physiological pH to form one major adduct. A second minor adduct can be detected when a 3-fold excess of acrolein is present in the reaction mixture. The products were separated by ion-pair HPLC on two reverse-phase columns connected in series using triethylammonium formate as ion-pair reagent. The major adduct was characterized as 3-(5'-monophospho-2'-deoxyribosyl)-7,8, 9-trihydro-7-hydroxy-pyrimido [3,4-c]pyrimidin-2-one (3,N4-propanodeoxcytidine 5'-monophosphate). This mixture of diastereomers was formed by addition of C1 of acrolein to the exocyclic amino group at the 4-position of cytidine, followed by ring closure between C3 of acrolein and N3 of the heterocyclic ring. In order to address the utility of 32P postlabeling for the detection of this exocyclic adduct in acrolein-modified nucleic acids, an acrolein-deoxycytidine 3'-monophosphate reaction mixture was subjected to 32P postlabeling. 3-Dephosphorylation with nuclease P1 and the 3'-phosphatase activity of T4 polynucleotide kinase yields a nucleotide 5'-[32P] monophosphate which cochromatographs with 3,N4-propanodeoxycytidine 5'-monophosphate. These data indicate that 32P postlabeling and 3'-dephosphorylation can be used in conjunction with ion-pair HPLC for the detection and quantitation of acrolein-modified nucleotides.