Recognition modes of hypoxanthine,xanthine and their derivatives by amino acid carboxylic group: UV spectroscopic and quantum chemical data

UV absorption spectra of Hyp, Xan, their nucleosides and methyl derivatives were studied in anhydrous dimethylsuloxide and the changes in these spectra on the interactions with neutral and deprotonated carboxylic groups of amino acids were traced. By the semiempirical quantum-chemical method MNDO/H it was shown, that interaction with carboxylate-ion fixes Hyp as the rare N7H enolic tautomer and converts Xan into its N9H diketo tautomeric form with a probable admixture of the N7H O6-enolic form. Significant changes in the UV spectra of Xan, m3Xan, m9Xan and X under interaction with carboxylate-ion are determined by essential contribution to complex formation of proton transfer from bases to ligands, m9Xan and X proving to be slightly protonated even by the solvent. The methylation of the N7 position in m7I and m7X was established to result in the practical absence of their interactions with carboxylate-ion and initiation of a new ability of forming complex with the neutral carboxylic group. Substitution of the C8H group by N in 8-azaXan does not change the interaction specificity of the base with two forms of carboxylic group.     

UV spectra of guanine methyl and glycosyl derivatives and their transformations induced by interactions with amino acids via carboxylic group in dimethylsulfoxide

UV absorption spectra of guanine derivatives m9Gua, m(2)2,9Gua, m1Gua, m(2)1,7Gua, m3Gua, G, dG, m1G, m2G, m7G, as well as guanine analogue isoGua were studied in anhydrous dimethylsulfoxide (DMSO). Changes in UV absorption spectra of guanine derivatives in the presence of amino acid derivatives with neutral carboxylic group (ac-Asp, ac-Glu, ac-Gly, ac-Asp-OMe) or deprotonated carboxylic group (NaAc, f-Gly-ONa) were investigated and interpreted. The m1Gua and m7Gua derivatives were shown to exist as the N9H tautomers in anhydrous DMSO. The majority of examined guanine derivatives were determined to interact with deprotonated carboxylic group only, except of m7G, isoGua and m3Gua, which are able to form complexes with neutral carboxylic group as well.     

Specific interactions of isoguanine with the neutral and deprotonated carboxylic group of amino acids: results of model quantum chemical calculations

The MNDO/H quantum chemical calculations performed in order to estimate energetic features of the isoguanine (isoGua) prototropic tautomers complexes with acetic acid and its carboxylate-ion (models of neutral and deprotonated forms of amino acid carboxylic group) demonstrate ability of the latter to induce the N9H-->N7H tautomeric transition in the base, being characteristic to other purine bases as well. By contrast, the neutral carboxylic group forms the most stable complex with the ground-state isoGua tautomer N3HN9H.     

Deprotonated carboxylic group of amino acids transforms adenine into its rare prototropic tautomers

By UV spectroscopic data for anhydrous DMSO solutions and ab initio HF/6-31G** calculations in vacuum it was shown for the first time that deprotonated amino acid carboxylic group is able to change tautomeric state of a nucleotide base, exactly to convert the N9H ground-state prototropic tautomer of adenine into the N7H and N1H rare ones.     

Conformational preferences of modified nucleic acid bases N6-methyl-N6-(N-threonylcarbonyl) adenine and 2-methylthio-N6-(N-threonylcarbonyl) adenine by the quantum chemical PCILO calculations

Conformational preferences of the hypermodified nucleic acid bases N6-methyl-N6-(N-threonylcarbonyl) Adenine, m6tc6 Ade, and 2-methylthio-N6-(N-threonylcarbonyl) Adenine, mS2 tc6 Ade, have been studied theoretically using the quantum chemical PCILO (Perturbative Configuration Interaction using Localized Orbitals) method. The multidimensional conformational space has been searched using selected grid points formed by combining the various torsion angles which take the favoured values obtained from energy variation with respect to each torsion angle individually. In m6 tc6 Ade and mS 2tc6 Ade alike the threonylcarbonyl substituent preferably orients away (distal) from the imidazole moiety of the adenine ring. And as in the simpler N6-(N-threonylcarbonyl) Adenine, tc6 Ade, the atoms in the ureido group as well as the amino acid carbon atoms C(12) and C(13) remain coplanar with the purine base. As in tc6 Ade, this conformation is stabilized by the intramolecular hydrogen bond between N(11)H of the amino acid and N(1) of the adenine base. The N6-methyl protons, in m6 tc6 Ade, take trans-staggered orientation with respect to the C(6)-N(6) bond. The preferred orientation of the 2-methylthio group is cis to the C(2)-N(3) bond in mS 2tc6 Ade. This is in marked contrast to the modified nucleic acid base 2-methylthio-N6-(delta 2-isopentenyl) Adenine, mS 2i6 Ade, where the 2-methylthio group orients trans to the C(2)-N(3) bond, causing a change in the preferred orientation of the isopentenyl component on methylthiolation. The present results thus indicate that unlike in the isopentenyl adenine the role of further chemical substitutions in threonylcarbonyl adenine may be indirect and less pronounced.     

Specific interaction of isocytosine and amino acid carboxylic group shifts the base tautomeric equilibrium

By 1H NMR, UV and IR spectroscopies in anhydrous DMSO and quantum-chemical calculations by MNDO/H in vacuum specific interactions of isocytosine with neutral and deprotonated carboxylic groups of amino acids were investigated. In vacuum interaction with carboxylate ion provokes in isoCyt transition from the ground-state enolic form to the high energy N3H-keto tautomer. In DMSO keto tautomer N3H of isoCyt is stabilized but interactions with carboxylate ion essentially shifts equilibrium to enolic form. Neutral carboxylic group forms the most stable complex with the ground-state enolic tautomer in vacuum but in DMSO it proves to shift the keto(N3H)-enolic equilibrium to the right.     

Thermochemistry of aqueous solutions of alkylated nucleic acid bases. VI. Enthalpies of hydration of 2-alkyl-9-methyladenines

Enthalpies of solution in water, delta H0sol, and vant'Hoff enthalpies of sublimation, delta H0subl, were determined experimentally for a number of crystalline 2-alkyl derivatives of 9-methyladenine: m2(2,9)Ade, e2m9Ade, pr2m9Ade and but2m9Ade. Standard enthalpies of hydration, delta H0hydr derived from these data were corrected for the calculated cavity terms, delta H0cav, to yield enthalpies of interaction, delta H0int, of the solutes with their hydration shells. The apparent residual contribution of alkyl groups, R, to the enthalpy of interaction delta delta H0int (R) was found to increase linearly with the number of CH2 groups added upon alkyl substitution, whereas this contribution calculated per unit area of the water-accessible molecular surface, SB, of alkyl residues delta delta H0int (R): delta SB(R) appeared constant over the whole series of the compounds investigated. This indicates that alkyl groups substituted at the C(2) carbon atom of the adenine contribute additively to the van der Waals' part of the enthalpy of interaction and do not affect the electrostatic part of the energy of interaction of the solutes with their hydration shells.     

Stacking interactions between protonated nucleic acid bases and aromatic amino acids: spectroscopic and structural analyses of m3CMP-tryptophan derivative complex

As a stacking model between nucleic acid bases and aromatic amino acids, the interaction on m3 CMP-tryptophan derivative has been studied by 1H-NMR and X-ray crystal analyses. From the comparative 1H-NMR experiments using CMP and m3CMP, it is suggested that the N(3)-protonation by methylation greatly strengthens the stacking interaction with tryptophan. Parallel alignment with a separation distance of 3.38A is shown by the X-ray analysis of m CMP-tryptamine complex. The stacking mode is very similar to those observed in the complexes of indole ring with m1A and m7G.     

Analysis of free-radical products of near-UV irradiation at 77 K of frozen adenine and adenosine diphosphate solutions containing inorganic phosphate

Irradiation by near-UV light at 77 K of aqueous solutions of inorganic phosphate in weakly acidic conditions in the presence of the photosensitizers adenine and adenosine diphosphate results in the formation of free radicals of these compounds, photosensitized free radicals of phosphate itself, and H* and OH* radicals. The relative concentrations of free radical products were estimated by the analysis of total ESR signals registered in the region of g = 2.00 in the photosystems Ade + Pi and Adphi + Pi using the original computer program of ESR spectra simulation.     

Structure of pvu II DNA-(cytosine N4) methyltransferase, an example of domain permutation and protein fold assignment.

We have determined the structure of Pvu II methyltransferase (M. Pvu II) complexed with S -adenosyl-L-methionine (AdoMet) by multiwavelength anomalous diffraction, using a crystal of the selenomethionine-substituted protein. M. Pvu II catalyzes transfer of the methyl group from AdoMet to the exocyclic amino (N4) nitrogen of the central cytosine in its recognition sequence 5'-CAGCTG-3'. The protein is dominated by an open alpha/beta-sheet structure with a prominent V-shaped cleft: AdoMet and catalytic amino acids are located at the bottom of this cleft. The size and the basic nature of the cleft are consistent with duplex DNA binding. The target (methylatable) cytosine, if flipped out of the double helical DNA as seen for DNA methyltransferases that generate 5-methylcytosine, would fit into the concave active site next to the AdoMet. This M. Pvu IIalpha/beta-sheet structure is very similar to those of M. Hha I (a cytosine C5 methyltransferase) and M. Taq I (an adenine N6 methyltransferase), consistent with a model predicting that DNA methyltransferases share a common structural fold while having the major functional regions permuted into three distinct linear orders. The main feature of the common fold is a seven-stranded beta-sheet (6 7 5 4 1 2 3) formed by five parallel beta-strands and an antiparallel beta-hairpin. The beta-sheet is flanked by six parallel alpha-helices, three on each side. The AdoMet binding site is located at the C-terminal ends of strands beta1 and beta2 and the active site is at the C-terminal ends of strands beta4 and beta5 and the N-terminal end of strand beta7. The AdoMet-protein interactions are almost identical among M. Pvu II, M. Hha I and M. Taq I, as well as in an RNA methyltransferase and at least one small molecule methyltransferase. The structural similarity among the active sites of M. Pvu II, M. Taq I and M. Hha I reveals that catalytic amino acids essential for cytosine N4 and adenine N6 methylation coincide spatially with those for cytosine C5 methylation, suggesting a mechanism for amino methylation.     

Structure of oxidatively damaged nucleic acid adducts. 3. Tautomerism, ionization and protonation of 8-hydroxyadenosine studied by 15N NMR spectroscopy.

Natural abundance 15N NMR spectroscopy and ancillary spectroscopic techniques have been employed to study the solution structure of 8-hydroxyadenosine. 8-Hydroxyadenosine is a naturally occurring oxidized nucleic acid adduct that is generally implied to have an 8-hydroxy tautomeric structure. 15N NMR chemical shifts and coupling constants, however, indicate that the modified base exists as an 8-keto tautomer. The pH dependence of 15N NMR and UV spectra showed the presence of two pKa's, at 2.9 and 8.7, corresponding to protonation at N1 and ionization at N7, respectively. The latter results in the formation of an 8-enolate structure. Unusual upfield shifts of the 1H and 15N resonances of the NH2 group, and a reduction in the one-bond coupling constant 1JN6-H6, is indicative of an unfavorable steric or electronic interaction between the NH2 group and the adjacent N7-H proton. This interaction results in a subtle change in the structure of the NH2 group. In addition to being a possible mechanism for alteration of hydrogen bonding in oxidized DNA, this type of interaction gives a better understanding into N7-N9 tautomerism of adenine. Furthermore, the structure of 8-hydroxyadenosine has been related to possible mechanisms for mutations.     

Reactions of 4‐[Bis(2‐chloroethyl)amino]benzenebutanoic Acid (Chlorambucil) with DNA

4‐[Bis(2‐chloroethyl)amino]benzenebutanoic acid (=chlorambucil, 1 ; 2.5 mM ) was allowed to react with single‐ and double‐stranded calf thymus DNA at physiological pH (cacodylic acid, 50% base) at 37°. The DNA–chlorambucil adducts were identified by analyzing the DNA hydrolysates by NMR, UV, HPLC, LC/ESI‐MS/MS techniques as well as by spiking with authentic materials. ssDNA was more reactive than dsDNA, and the order of reactivity in ssDNA was Ade‐N1>Gua‐N7>Cyt‐N3>Ade‐N3. The most reactive site in dsDNA was Ade‐N3. The Gua‐N7 and Ade‐N3 adducts were hydrolytically labile. Ade‐N7 adduct could not be identified in the hydrolysates of ssDNA or dsDNA. The adduct Gua‐N7,N7, which consists of two units of Gua bound together with a unit derived from chlorambucil, is a cross‐linking adduct, and it was detected in the hydrolysates of ssDNA and dsDNA. Also several other adducts were detected which could be characterized by spiking with previously isolated authentic adducts or tentatively by MS. The role of chlorambucil–DNA adducts on the cytotoxicity and mutagenity of 1 is also discussed.     

A selective recognition mode of a nucleic acid base by an aromatic amino acid: L-phenylalanine-7-methylguanosine 5''-monophosphate stacking interaction.

The conformation of 7-methylguanosine 5'-monophosphate (m7GMP) and its interaction with L-phenylalanine (Phe) have been investigated by X-ray crystallographic, 1H-nuclear magnetic resonance, and energy calculation methods. The N(7) methylation of the guanine base shifts m7GMP toward an anti--gauche, gauche conformation about the glycosyl and exocyclic C(4')-C(5') bonds, respectively. The prominent stacking observed between the benzene ring of Phe and guanine base of m7GMP is primarily due to the N(7) guarternization of the guanine base. The formation of a hydrogen bonding pair between the anionic carboxyl group and the guanine base further stabilizes this stacking interaction. The present results imply the importance of aromatic amino acids as a hallmark for the selective recognition of a nucleic acid base.     

The influence of Li+, Na+, Mg2+, Ca2+, and Zn2+ ions on the hydrogen bonds of the Watson-Crick base pairs

The interaction of mono- and divalent metal ions with the nucleic acid base pairs A:T and G:C has been studied using ab initio self-consistent field Hartree-Fock computations with minimal basis sets. Energy-optimized structures of the two base pairs with a final base-base distance of L = 10.35 A have been determined and were further used in calculations on ternary complexes Mn+ - A:B together with previously computed coordination geometries of the cations at adenine (Ade), thymine (Thy), and guanine (Gua). Besides the binding energy of the various metal ions to the base pairs, changes in the stability of the H bonds between Ade and Thy or Gua and Cyt have been determined. Polarization effects of the metal ion on the ligand turned out to increase the binding between complementary bases. Regardless of the metal species, cation binding to Gua N(3) and Thy O(2) leads to a special increase in H-bond stability, whereas binding to Ade N(3) changes the H-bond stability least. Situated in between are the stabilizing effects caused by Gua and Ade N(7) coordination. A remarkable relation between the stability of the H bond and the distance from metal binding site to H bonds was found. This relationship has been rationalized in terms of partial charges of the atoms participating in H bonding, which can reveal the trend in the electrostatic part of total H bond energy. It can be shown that a short distance between coordination site and acceptor hydrogen increases the H-bond strength substantially, while a long distance shows minor effects as supposed. On the other hand, the opposite effect is observed for the influence of the distance between binding site and donor atom. A comparison of our findings with a new model of transition metal ion facilitated rewinding of denatured DNA proposed by S. Miller, D. VanDerveer, and L. Marzilli is given [(1985) J. Am. Chem. Soc. 107, 1048-1055].     

West Nile virus methyltransferase catalyzes two methylations of the viral RNA cap through a substrate-repositioning mechanism

Flaviviruses encode a single methyltransferase domain that sequentially catalyzes two methylations of the viral RNA cap, GpppA-RNA-->m(7)GpppA-RNA-->m(7)GpppAm-RNA, by using S-adenosyl-l-methionine (SAM) as a methyl donor. Crystal structures of flavivirus methyltransferases exhibit distinct binding sites for SAM, GTP, and RNA molecules. Biochemical analysis of West Nile virus methyltransferase shows that the single SAM-binding site donates methyl groups to both N7 and 2'-O positions of the viral RNA cap, the GTP-binding pocket functions only during the 2'-O methylation, and two distinct sets of amino acids in the RNA-binding site are required for the N7 and 2'-O methylations. These results demonstrate that flavivirus methyltransferase catalyzes two cap methylations through a substrate-repositioning mechanism. In this mechanism, guanine N7 of substrate GpppA-RNA is first positioned to SAM to generate m(7)GpppA-RNA, after which the m(7)G moiety is repositioned to the GTP-binding pocket to register the 2'-OH of the adenosine with SAM, generating m(7)GpppAm-RNA. Because N7 cap methylation is essential for viral replication, inhibitors designed to block the pocket identified for the N7 cap methylation could be developed for flavivirus therapy.     

Conformational Preferences of Modified Nucleic Acid Bases N6-Methyl-N6-(N-Threonylcarbonyl) Adenine and 2-Methylthio-N6-(N-Threonylcarbonyl) Adenine by the Quantum Chemical PCILO Calculations

Abstract

Conformational preferences of the hypermodified nucleic acid bases N⁶-methyl-N⁶-(N- threonylcarbonyl) Adenine, m⁶ tc⁶ Ade, and 2-methylthio-N⁶-(N-threonylcarbonyl) Adenine, mS² tc⁶ Ade, have been studied theoretically using the quantum chemical PCILO (Perturbative Configuration Interaction using Localized Orbitals) method. The multidimensional conformational space has been searched using selected grid points formed by combining the various torsion angles which take the favoured values obtained from energy variation with respect to each torsion angle individually. In m⁶ tc⁶ Ade and mS² tc⁶ Ade alike the threonylcar- bonyl substituent preferably orients away (distal) from the imidazole moiety of the adenine ring. And as in the simpler N⁶-(N-threonylcarbonyl) Adenine, tc⁶ Ade, the atoms in the ureido group as well as the amino acid carbon atoms C(12) and C(13) remain coplanar with the purine base. As in tc⁶ Ade, this conformation is stabilized by the intramolecular hydrogen bond between N(11)H of the amino acid and N(l) of the adenine base.

The N⁶-methyl protons, in m⁶ tc⁶ Ade, take trans-staggered orientation with respect to the C(6)-N(6) bond. The preferred orientation of the 2-methylthio group is cis to the C(2)-N(3) bond in mS² tc⁶ Ade. This is in marked contrast to the modified nucleic acid base 2-methylthio-N⁶-(Δ²-isopentenyl) Adenine, mS² i⁶ Ade, where the 2-methylthio group orients trans to the C(2)- N(3) bond, causing a change in the preferred orientation of the isopentenyl component on methylthiolation. The present results thus indicate that unlike in the isopentenyl adenine the role of further chemical substitutions in threonylcarbonyl adenine may be indirect and less pronounced.     

Conformational preferences of anticodon 3'-adjacent hypermodified nucleic acid base cis-or trans-zeatin and its 2-methylthio derivative, cis-or trans- ms(2)zeatin

Conformational preferences of the hypermodified nucleic acid bases N6-(Delta(2)-cis-hydroxyisopentenyl)adenine, cis-io(6)Ade also known as cis-zeatin, and N(6)-(Delta(2)-trans-hydroxyisopentenyl)adenine, trans-io(6)ade or trans-zeatin, and 2-methylthio derivatives of these cis-ms(2)io(6)Ade or cis-ms(2)zeatin, and trans-ms(2)io6Ade or trans-ms(2)zeatin have been investigated theoretically by the quantum chemical Perturbative Configuration Interaction with Localized Orbitals (PCILO) method. Automated geometry optimization using quantum chemical MNDO, AM1 and PM3 methods has also been made to compare the salient features. The predicted most stable conformation of cis-io(6)Ade, trans-io(6)Ade, cis-ms(2)io(6)Ade and trans-ms(2)io(6)Ade are such that in each of these molecules the isopentenyl substituent spreads away (has "dista" conformation) from the five membered ring imidazole moiety of the adenine. The atoms N(6), C(10) and C(11) remain coplanar with the adenine ring in the predicted preferred conformation for each of these molecules. In cis-io(6)Ade as well as cis-ms(2)io(6)Ade the hydroxyl oxygen may participate in intramolecular hydrogen bonding with the H-C(10)-H group. In trans-io(6)Ade the hydroxyl group is oriented towards the H-C(2) instead. This orientation is retained in trans-ms(2)io(6)Ade, possible O-H...S hydrogen bonding may be a stabilizing factor. In all these four modified adenines C(11)-H is favourably placed to participate in intramolecular hydrogen bonding with N(1). In cis-ms(2)io(6)Ade as well as trans-ms(2)io(6)Ade the 2-methylthio group preferentially orients on the same side as C(2)-N(3) bond, due to this non-obstrusive placing, orientation of the hydroxyisopentenyl substituent remains unaffected by 2-methylthiolation. Thus the N(1) site remains shielded irrespective of the 2-methylthiolation status in these various cis-and trans-zeatin analogs alike. Firmly held orientation of hydroxyisopentenyl substituent in zeatin isomers and derivatives, in contrast to adaptable orientation of isopentenyl substituent in i(6)Ade and ms(2)i(6)Ade, may account for the increased efficiency of suppressor tRNA and reduced codon context sensitivity accompanied with the occurrence of ms(2)-zeatin (ms(2)io(6)Ade) modification.     

Methylated bases in mycoplasmal DNA.

The DNAs of four Mycoplasma and one Acholeplasma species were found to contain methylated bases. All of the five species contained 6-methyladenine (m6Ade), the methylated base characteristic of prokaryotic DNA. The extent of methylation of adenine residues in the mycoplasmal DNA ranged from 0.2% in Mycoplasma capricolum to about 2% in Mycoplasma arginini and Mycoplasma hyorhinis with intermediate methylation values for Mycoplasma orale and Acholeplasma laidlawii DNAs. About 5.8% of the cytosine residues in M. hyorhinis DNA were methylated also. Analysis of cell culture DNA for the presence of m6Ade as a means for detection of contamination by mycoplasmas, and the phylogenetic implications of the finding of methylated bases in mycoplasmal DNAs are discussed.     

Study of ATP binding in the active site of Na,K-ATPase as probed by ultraviolet resonance Raman spectroscopy

The ultraviolet resonance Raman (UV RR) spectra of functional ATP/membrane-bound Na⁺K⁺-ATPase complexes have been obtained. The substrate binding in the enzyme active site has been shown to be accompanied with significant changes in the electronic vibrational structure of the adenine ring. From the spectral analysis of ATP, 8-Br-ATP and 6-NHMe-adenine at various pH values the conclusion was made that N1 and the NH₂, group and, probably, N7 of the substrate adenine part, interact with the protein surroundings via hydrogen bonds.     

ATR-FTIR redox difference spectroscopy of Yarrowia lipolytica and bovine complex I

ATR-FTIR spectroscopy in combination with electrochemistry has been applied to the redox centers of Yarrowia lipolytica complex I. The redox spectra show broad similarities with previously published data on Escherichia coli complex I and with new data here on bovine complex I. The spectra are dominated by amide I/II protein backbone changes. Comparisons with redox IR spectra of small model ferredoxins demonstrate that these amide I/II changes arise primarily from characteristic structural changes local to the iron-sulfur centers, rather than from global structural alterations as has been suggested previously. Bands arising from the substrate ubiquinone were evident, as was a characteristic 1405 cm(-)(1) band of the reduced form of the FMN cofactor. Other signals are likely to arise from perturbations or protonation changes of a carboxylic amino acid, histidine, and possibly several other specific amino acids. Redox difference spectra of center N2, together with substrate ubiquinone, were isolated from those of the other iron-sulfur centers by selective redox potentiometry. Its redox-linked amide I/II changes were typical of those in other 4Fe-4S iron sulfur proteins. Contrary to published data on bacterial complex I, no center N2 redox-linked protonation changes of carboxylic amino acids or tyrosine were evident, and other residues that could provide its redox-linked protonation site are discussed. Features of the substrate ubiquinone associated with the center N2 spectrum were particularly clear, with firm assignments possible for bands from both oxidized and reduced forms. This is the first report of IR properties of ubiquinone in complex I, and the data could be used to estimate a stoichiometry of 0.2-0.4 per complex I.