N-glycosidic Bond Stability Research Articles

Influence of 5-fluorination on the structure and glycosidic bond stability of the protonated canonical DNA and RNA cytidine nucleosides: Oh, what a difference the 2′-hydroxy substituent makes?

Fluorinated nucleosides are well-established as anticancer and antiviral medications. As with many pharmaceuticals, the effects of fluorine modifications are often only partially understood. In this work, the effects of 5-fluorination of the cytosine nucleobase on the structures and glycosidic bond stabilities of the protonated canonical DNA and RNA cytidine nucleosides (dCyd and Cyd) are examined. Infrared multiple photon dissociation action spectroscopy experiments and electronic structure calculations are employed to probe the structural influences of 5-fluorination. Spectral signatures in the IR fingerprint and hydrogen-stretching regions indicate that 5-fluorination heavily directs for and solely produces O2 protonation para to the 5-fluoro substituent. This differs from the canonical cytidine nucleosides where roughly equal populations of O2 and N3 protonated structures were observed. Energy-resolved collision-induced dissociation experiments combined with survival yield analyses are performed to probe the influence of 5-fluorination on glycosidic bond stability. Trends in the energy-dependence of the survival yield curves indicate that 5-fluorination weakens the glycosidic bond, and that the influence of 5-fluorination on glycosidic bond stability is much greater for dCyd than Cyd. Theory also finds that 5-fluorination weakens the glycosidic bond but predicts that the influence of 5-fluorination on N-glycosidic bond stability is roughly the same for dCyd and Cyd. Oh, what a difference the 2′-hydroxy substituent makes?

Structures and Relative Glycosidic Bond Stabilities of Protonated 2'-Fluoro-Substituted Purine Nucleosides.

The 2'-substituent is the primary distinguishing feature between DNA and RNA nucleosides. Modifications to this critical position, both naturally occurring and synthetic, can produce biologically valuable nucleoside analogues. The unique properties of fluorine make it particularly interesting and medically useful as a synthetic nucleoside modification. In this work, the effects of 2'-fluoro modification on the protonated gas-phase purine nucleosides are examined using complementary tandem mass spectrometry and computational methods. Direct comparisons are made with previous studies on related nucleosides. Infrared multiple photon dissociation action spectroscopy performed in both the fingerprint and hydrogen-stretching regions allows for the determination of the experimentally populated conformations. The populated conformers of protonated 2'-fluoro-2'-deoxyadenosine, [Adofl+H]+, and 2'-fluoro-2'-deoxyguanosine, [Guofl+H]+, are highly parallel to their respective canonical DNA and RNA counterparts. Both N3 and N1 protonation sites are accessed by [Adofl+H]+, stabilizing syn and anti nucleobase orientations, respectively. N7 protonation and anti nucleobase orientation dominates in [Guofl+H]+. Spectroscopically observable intramolecular hydrogen-bonding interactions with fluorine allow more definitive sugar puckering determinations than possible for the canonical systems. [Adofl+H]+ adopts C2'-endo sugar puckering, whereas [Guofl+H]+ adopts both C2'-endo and C3'-endo sugar puckering. Energy-resolved collision-induced dissociation experiments with survival yield analyses provide relative glycosidic bond stabilities. The N-glycosidic bond stabilities of the protonated 2'-fluoro-substituted purine nucleosides are found to exceed those of their canonical analogues. Further, the N-glycosidic bond stability is found to increase with increasing electronegativity of the 2'-substituent, i.e., H < OH < F. The N-glycosidic bond stability is also greater for the adenine nucleoside analogues than the guanine nucleoside analogues.

Influence of 2′-fluoro modification on glycosidic bond stabilities and gas-phase ion structures of protonated pyrimidine nucleosides

The effects of 2′-fluoro substitution on the protonated gas-phase ions of the pyrimidine nucleosides are examined and compared with their previously reported canonical RNA and DNA forms. N-Glycosidic bond cleavage is the only collision-induced dissociation (CID) fragmentation pathway of protonated 2′-fluoro-2′-deoxycytidine, [Cydfl+H]+, and the major pathway of protonated 2′-fluoro-2′-deoxyuridine, [Urdfl+H]+. Based on energy-resolved CID and survival yield analysis, the N-glycosidic bond of [Cydfl+H]+ is more stable than that of [Urdfl+H]+. Further, the N-glycosidic bond stability of protonated pyrimidine nucleosides increases with increasing 2′-substituent electronegativity and follows the order F > OH > H. Gas-phase conformations of [Cydfl+H]+ and [Urdfl+H]+ are studied via infrared multiple photon dissociation (IRMPD) action spectroscopy coupled with theoretical calculations. IRMPD action spectra are measured over the IR fingerprint and hydrogen-stretching regions. Comparisons of theoretical and experimental spectra indicate that the experimentally accessed [Cydfl+H]+ and [Urdfl+H]+ conformers are highly parallel to those populated for their canonical counterparts. Evidence for gas-phase intramolecular O3′H⋯F2′ hydrogen-bonding in the IRMPD spectra of [Cydfl+H]+ and [Urdfl+H]+ allows for more definitive sugar puckering determinations than possible in the analogous canonical nucleosides.

Relative glycosidic bond stabilities of naturally occurring methylguanosines: 7-methylation is intrinsically activating.

The frequency and diversity of posttranscriptional modifications add an additional layer of chemical complexity beyond canonical nucleic acid sequence. Methylations are particularly frequently occurring and often highly conserved throughout the kingdoms of life. However, the intricate functions of these modified nucleic acid constituents are often not fully understood. Systematic foundational research that reduces systems to their minimum constituents may aid in unraveling the complexities of nucleic acid biochemistry. Here, we examine the relative intrinsic N-glycosidic bond stabilities of guanosine and five naturally occurring methylguanosines (O2'-, 1-, 7-, N2,N2-di-, and N2,N2,O2'-trimethylguanosine) probed by energy-resolved collision-induced dissociation tandem mass spectrometry and complemented with quantum chemical calculations. Apparent glycosidic bond stability is generally found to increase with increasing methyl substitution (canonical < mono- < di- < trimethylated). Many biochemical transformations, including base excision repair mechanisms, involve protonation and/or noncovalent interactions to increase nucleobase leaving-group ability. The protonated gas-phase methylguanosines require less activation energy for glycosidic bond cleavage than their sodium cationized forms. However, methylation at the N7 position intrinsically weakens the glycosidic bond of 7-methylguanosine more significantly than subsequent cationization, and thus 7-methylguanosine is suggested to be under perpetually activated conditions. N7 methylation also alters the nucleoside geometric preferences relative to the other systems, including the nucleobase orientation in the neutral form, sugar puckering in the protonated form, and the preferred protonation and sodium cation binding sites. All of the methylated guanosines examined here are predicted to have proton affinities and gas-phase basicities that exceed that of canonical guanosine. Additionally, the proton affinity and gas-phase basicity trends exhibit a roughly inverse correlation with the apparent glycosidic bond stabilities.

Conformations and N-glycosidic bond stabilities of sodium cationized 2′-deoxycytidine and cytidine: Solution conformation of [Cyd + Na]+ is preserved upon ESI

The local structures of DNA and RNA are influenced by protonation, deprotonation and noncovalent interactions with metal cations. In order to determine the effects of sodium cationization on the structures of 2′-deoxycytidine and cytidine, infrared multiple photon dissociation (IRMPD) action spectra of these sodium cationized nucleosides, [dCyd+Na]+ and [Cyd+Na]+, are measured using the FELIX free electron laser and an OPO/OPA laser system. Energy-resolved collision-induced dissociation (ER-CID) experiments for the protonated and sodium cationized forms of the cytosine nucleosides are performed using a Bruker amaZon ETD quadrupole ion trap mass spectrometer (QIT MS) to evaluate the relative propensities of protons and sodium cations for activating the glycosidic bonds of the cytosine nucleosides. Complementary electronic structure calculations are performed to determine the stable low-energy conformations of [dCyd+Na]+ and [Cyd+Na]+. For both cytosine nucleosides, theory suggests that tridentate binding of Na+ to the O2, O4′ and O5′ atoms of the cytosine nucleobase and sugar moiety is the most stable binding mode. However, comparison of the measured IRMPD action spectrum and computed linear IR spectra suggests that anti oriented bidentate conformers of [Cyd+Na]+ are predominantly populated in the experiments. The 2′-hydroxyl substituent of Cyd stabilizes the anti oriented bidentate conformers of [Cyd+Na]+, and enables formation of a 2′OH⋯3′OH hydrogen-bonding interaction. The 2′-hydroxyl substituent is found to stabilize the glycosidic bond of Cyd vs. that of dCyd for both the protonated and sodium cationized cytosine nucleosides. Compared to protonation, sodium cationization activates the N-glycosidic bond less effectively.

Gas-Phase Conformations and N-Glycosidic Bond Stabilities of Sodium Cationized 2'-Deoxyguanosine and Guanosine: Sodium Cations Preferentially Bind to the Guanine Residue.

2'-Deoxyguanosine (dGuo) and guanosine (Guo) are fundamental building blocks of DNA and RNA nucleic acids. In order to understand the effects of sodium cationization on the gas-phase conformations and stabilities of dGuo and Guo, infrared multiple photon dissociation (IRMPD) action spectroscopy experiments and complementary electronic structure calculations are performed. The measured IRMPD spectra of [dGuo+Na]+ and [Guo+Na]+ are compared to calculated IR spectra predicted for the stable low-energy structures computed for these species to determine the most favorable sodium cation binding sites, identify the structures populated in the experiments, and elucidate the influence of the 2'-hydroxyl substituent on the structures and IRMPD spectral features. These results are compared with those from a previous IRMPD study of the protonated guanine nucleosides to elucidate the differences between sodium cationization and protonation on structure. Energy-resolved collision-induced dissociation (ER-CID) experiments and survival yield analyses of protonated and sodium cationized dGuo and Guo are performed to compare the effects of these cations toward activating the N-glycosidic bonds of these nucleosides. For both [dGuo+Na]+ and [Guo+Na]+, the gas-phase structures populated in the experiments are found to involve bidentate binding of the sodium cation to the O6 and N7 atoms of guanine, forming a 5-membered chelation ring, with guanine found in both anti and syn orientations and C2'-endo (2T3 or 3T2) puckering of the sugar. The ER-CID results, IRMPD yields and the computed C1'-N9 bond lengths indicate that sodium cationization activates the N-glycosidic bond less effectively than protonation for both dGuo and Guo. The 2'-hydroxyl substituent of Guo is found to impact the preferred structures very little except that it enables a 2'OH···3'OH hydrogen bond to be formed, and stabilizes the N-glycosidic bond relative to that of dGuo in both the sodium cationized and protonated complexes.

Effects of sodium cationization versus protonation on the conformations and N-glycosidic bond stabilities of sodium cationized Urd and dUrd: solution conformation of [Urd+Na]+ is preserved upon ESI.

Uridine (Urd) is one of the naturally occurring pyrimidine nucleosides of RNA. 2'-Deoxyuridine (dUrd) is a naturally occurring modified form of Urd, but is not one of the canonical DNA nucleosides. In order to understand the effects of sodium cationization on the conformations and energetics of Urd and dUrd, infrared multiple photon dissociation (IRMPD) action spectroscopy experiments and density functional theory (DFT) calculations are performed. By comparing the calculated IR spectra of [Urd+Na]+ and [dUrd+Na]+ with the measured IRMPD spectra, the stable low-energy conformers populated in the experiments are determined. Anti oriented bidentate O2 and O2' binding conformers of [Urd+Na]+ are the dominant conformers populated in the experiments, whereas syn oriented tridentate O2, O4', and O5' binding conformers of [dUrd+Na]+ are dominantly populated in the experiments. The 2'-hydroxyl substituent of Urd stabilizes the anti oriented O2 binding conformers of [Urd+Na]+. Significant differences between the measured IRMPD and calculated IR spectra for complexes of [Urd+Na]+ and [dUrd+Na]+ involving minor tautomeric forms of the nucleobase make it obvious that none are populated in the experiments. Survival yield analyses based on energy-resolved collision-induced dissociation (ER-CID) experiments suggest that the relative stabilities of protonated and sodium cationized Urd and dUrd follow the order: [dUrd+H]+ < [Urd+H]+ < [dUrd+Na]+ < [Urd+Na]+. The 2'-deoxy modification is found to weaken the glycosidic bond of dUrd versus that of Urd for the sodium cationized uridine nucleosides.

Influence of Sodium Cationization versus Protonation on the Gas-Phase Conformations and Glycosidic Bond Stabilities of 2'-Deoxyadenosine and Adenosine.

The influence of noncovalent interactions with a sodium cation on the gas-phase structures and N-glycosidic bond stabilities of 2'-deoxyadenosine (dAdo) and adenosine (Ado), [dAdo+Na](+) and [Ado+Na](+), are probed via infrared multiple photon dissociation (IRMPD) action spectroscopy and energy-resolved collision-induced dissociation (ER-CID) experiments. ER-CID experiments are also performed on the protonated forms of these nucleosides, [dAdo+H](+) and [Ado+H](+), for comparison purposes. Complementary electronic structure calculations are performed to determine the structures and relative stabilities of the stable low-energy conformations of the sodium cationized nucleoside complexes and to predict their IR spectra. Comparison between the measured IRMPD action spectra and calculated IR spectra enables the conformations of the sodium cationized nucleosides present in the experiments to be elucidated. The influence of sodium cationization versus protonation on the structures and IR spectra is elucidated by comparison to IRMPD and theoretical results previously reported for the protonated forms of these nucleosides. The influence of sodium cationization versus protonation on the glycosidic bond stability of the adenine nucleosides is determined by comparison of the ER-CID behavior of these systems. All structures present in the experiments are found to involve tridentate binding of Na(+) to the N3, O4', and O5' atoms forming favorable 5- and 6-membered chelation rings, which requires that adenine rotate to a syn configuration. This mode of sodium cation binding results in moderate flexibility of the sugar moiety such that the sugar puckering of the conformations present varies between C2'-endo and O4'-endo. Sodium cationization is found to be less effective toward activating the N-glycosidic bond than protonation for both dAdo and Ado. Both the IRMPD yields and ER-CID behavior indicate that the 2'-hydroxyl substituent of Ado stabilizes the N-glycosidic bond relative to that of dAdo.

Mechanisms and energetics for N-glycosidic bond cleavage of protonated adenine nucleosides: N3 protonation induces base rotation and enhances N-glycosidic bond stability.

Our previous gas-phase infrared multiple photon dissociation action spectroscopy study of protonated 2'-deoxyadenosine and adenosine, [dAdo+H](+) and [Ado+H](+), found that both N3 and N1 protonated conformers are populated with the N3 protonated ground-state conformers predominant in the experiments. Therefore, N-glycosidic bond dissociation mechanisms of N3 and N1 protonated [dAdo+H](+) and [Ado+H](+) and the associated quantitative thermochemical values are investigated here using both experimental and theoretical approaches. Threshold collision-induced dissociation (TCID) of [dAdo+H](+) and [Ado+H](+) with Xe is studied using guided ion beam tandem mass spectrometry techniques. For both systems, N-glycosidic bond cleavage reactions are observed as the major dissociation pathways resulting in production of protonated adenine or elimination of neutral adenine. Electronic structure calculations are performed at the B3LYP/6-311+G(d,p) level of theory to probe the potential energy surfaces (PESs) for N-glycosidic bond cleavage of [dAdo+H](+) and [Ado+H](+). Relative energetics of the reactants, transition states, intermediates and products along the PESs for N-glycosidic bond cleavage are determined at the B3LYP/6-311+G(2d,2p), B3LYP-GD3BJ/6-311+G(2d,2p), and MP2(full)/6-311+G(2d,2p) levels of theory. The predicted N-glycosidic bond dissociation mechanisms for the N3 and N1 protonated species differ. Base rotation of the adenine residue enables formation of a strong N3H(+)O5' hydrogen-bonding interaction that stabilizes the N3 protonated species and its glycosidic bond. Comparison between experiment and theory indicates that the N3 protonated species determine the threshold energies, as excellent agreement between the measured and B3LYP computed activation energies (AEs) and reaction enthalpies (ΔHrxns) for N-glycosidic bond cleavage of the N3 protonated species is found.

2-Methylwyosine, a Nucleoside With Restricted Anti Conformation in the East Region Enforced by Nucleobase Moiety Modification: Synthesis and Conformational Analysis by NMR and Molecular Dynamics

GRAPHICAL ABSTRACT We synthesized a new 2-methyl derivative of wyosine using a multistep procedure starting from guanosine. We examined different synthetic paths and optimized the conditions for each step. Based on MD calculations and analysis of the 3 J HH and J C1′H1′ of the ribose moiety, we discovered that the sugar part adopted conformation specific for the East region rarely occurring in solution. This unusual conformational preference is probably due to steric repulsions between the methyl group at position 2 and the 5′-CH2OH group. We observed that N-glycosidic bond stability weakened 14-fold upon the introduction of the methyl group in position 2 compared with wyosine.

Gas-Phase Studies of Purine 3-Methyladenine DNA Glycosylase II (AlkA) Substrates

3-Methyladenine DNA glycosylase II (AlkA) is an enzyme that cleaves a wide range of damaged bases from DNA. The gas-phase thermochemical properties (tautomerism, acidity, and proton affinity) have been measured and calculated for a series of AlkA purine substrates (7-methyladenine, 7-methylguanine, 3-methyladenine, 3-methylguanine, purine, 6-chloropurine, xanthine) that have not been heretofore examined. The damaged nucleobases are found to be more acidic than the normal nucleobases adenine and guanine. Because of this increased acidity, the damaged bases would be expected to be more easily cleaved from DNA by AlkA (their conjugate bases should be better leaving groups). We find that the gas-phase acidity correlates to the AlkA excision rates, which lends support to an AlkA mechanism wherein the enzyme provides a nonspecific active site, and nucleobase cleavage is dependent on the intrinsic N-glycosidic bond stability.

Molecular Perspective Review of Biochemical Role of Nucleobases Modified by Oxidative Stress

Numerous damages to cellular DNA are imposed by oxidative stress. Formation of stable products resulting from oxidation of nucleobases is one of many observed consequences. The oxidized species constitute a class of heterocyclic compounds with great diversities of physicochemical properties. Modified nucleosides significantly differ from their canonical protoplasts by tautomeric equilibriums, protolytic properties in the gas phase and water solution, they have altered oxidative susceptibility and N-glycosidic bond stabilities. However, what is most important, they have overwhelmingly altered pairing properties, which are directly responsible for observed cytotoxic properties of these lesions. Besides, since many analogues are structurally different with respect to canonical bases their presence in DNA must impose many energetic, structural and dynamic modifications. These aspect are reviewed as fruits of project no 39 supported by computational grant in Poznan Supercomputing and Networking Center (PSNC, Poland).

THE INFLUENCES OF OXIDATION AND CATIONIZATION ON THE N-GLYCOSIDIC BOND STABILITY OF 8-OXO-2′-DEOXYADENOSINE — A THEORETICAL STUDY

This work is an attempt to evaluate theoretically the influences of oxidation and cationization on the N-glycosidic bond stability and the proton and sodium affinities on 8-oxo-2′-deoxyadenosine (8-oxodA) by using the density functional theory (DFT) B3LYP with basis set 6-31++G(d,p). This work shows that the cation attachment to 8-oxodA may modify the equilibrium geometry and bond dissociation. In all modified forms, the length of the N9–C1′ bond in which there is no intramolecular interaction, i.e. O8–H(Na)⋯O4′, increases relative to the neutral system 8-oxodA but that of others decreases. The analysis for the proton and sodium affinity energies indicates that the N1 and N3 atoms are the favorable sites for proton while the N1 atom is the favorable site for Na+. From the dissociation energies of the N-glycosidic bond, it has been found that the homolytic dissociation becomes more difficult upon introducing positive charge in the base ring. In contrast, these systems favor the heterolytic dissociation significantly. The influence is most prominent with the monocation obtained by O8 cationization.

Interaction of Mg 2+, Ca 2+, Zn 2+ and Cu + with cytosine nucleosides: Influence of metal on sugar puckering and stability of N-Glycosidic bond, a DFT study

The coordination geometries, electronic features, absolute metal ion affinities, geometrical multiplicity and binding strength for the complexes formed by Mg 2+, Ca 2+, Zn 2+ and Cu + with cytidine and deoxycytidine have been determined theoretically employing the hybrid B3LYP exchange-correlation functional and using 6-311++G(d,p) orbital basis sets. Our study shows that the most stable coordination modes of cytosine nucleosides with these cations are rather similar. In the isolated state, the most stable form corresponds to a tridentate complex in which the cation interacts with three oxygen atoms: one from the carbonyl oxygen of cytosine moiety and two from the sugar unit (i.e., O5′ and O4′). The influences of metal cationization on the strength of the N-glycosidic bond, the values of the phase angle of pseudorotation P in the sugar unit and sugar ring conformation have been studied. In all cases, the N1 C1′ bond distance changes upon introducing positive charge in the nucleosides.

The effects of oxidation and protonation on the N-glycosidic bond stability of 8-oxo-2′-deoxyguanosine: DFT study

This work is an attempt to evaluate the ability of protonation of 8-oxo-2′-deoxyguanosine (8-oxodG) and the effects of oxidation and protonation on its N-glycosidic bond stability by using the density functional theory B3LYP/6-31++G(d, p) method. In all modified forms, the length of the N9–C1′ bond increases as compared to the neutral system 8-oxodG. Especially, the changes are much more obvious for the di-cationic systems. The analysis for the ability of protonation indicates that for the mono-protonated systems, the O8 atom becomes the preferred protonation site in the gas phase. From the dissociation energies of the N-glycosidic bond, it has been found that the homolytic cleavage becomes more difficult upon introducing positive charge in the base ring. In contrast, these systems favor significantly the heterolytic cleavage, especially for the di-cationic systems in which the dissociation energy values are negative. The influence is most prominent with the mono-cation obtained by O8 protonation.

Specificity of human thymine DNA glycosylase depends on N-glycosidic bond stability.

Initiating the DNA base excision repair pathway, DNA glycosylases find and hydrolytically excise damaged bases from DNA. While some DNA glycosylases exhibit narrow specificity, others remove multiple forms of damage. Human thymine DNA glycosylase (hTDG) cleaves thymine from mutagenic G.T mispairs, recognizes many additional lesions, and has a strong preference for nucleobases paired with guanine rather than adenine. Yet, hTDG avoids cytosine, despite the million-fold excess of normal G.C pairs over G.T mispairs. The mechanism of this remarkable and essential specificity has remained obscure. Here, we examine the possibility that hTDG specificity depends on the stability of the scissile base-sugar bond by determining the maximal activity (k(max)) against a series of nucleobases with varying leaving-group ability. We find that hTDG removes 5-fluorouracil 78-fold faster than uracil, and 5-chlorouracil, 572-fold faster than thymine, differences that can be attributed predominantly to leaving-group ability. Moreover, hTDG readily excises cytosine analogues with improved leaving ability, including 5-fluorocytosine, 5-bromocytosine, and 5-hydroxycytosine, indicating that cytosine has access to the active site. A plot of log(k(max)) versus leaving-group pK(a) reveals a Brønsted-type linear free energy relationship with a large negative slope of beta(lg) = -1.6 +/- 0.2, consistent with a highly dissociative reaction mechanism. Further, we find that the hydrophobic active site of hTDG contributes to its specificity by enhancing the inherent differences in substrate reactivity. Thus, hTDG specificity depends on N-glycosidic bond stability, and the discrimination against cytosine is due largely to its very poor leaving ability rather than its exclusion from the active site.

Amino Acid Ester Prodrugs of 2-Bromo-5,6-dichloro-1-(β-d-ribofuranosyl)benzimidazole Enhance Metabolic Stability in Vitro and in Vivo

2-Bromo-5,6-dichloro-1-(beta-d-ribofuranosyl)benzimidazole (BDCRB) is a potent and selective inhibitor of human cytomegalovirus (HCMV), but it lacks clinical utility due to rapid in vivo metabolism. We hypothesized that amino acid ester prodrugs of BDCRB may enhance both in vitro potency and systemic exposure of BDCRB through evasion of BDCRB-metabolizing enzymes. To this end, eight different amino acid prodrugs of BDCRB were tested for N-glycosidic bond stability, ester bond stability, Caco-2 cell uptake, antiviral activity, and cytotoxicity. The prodrugs were resistant to metabolism by BDCRB-metabolizing enzymes, and ester bond cleavage was rate-limiting in metabolite formation from prodrug. Thus, BDCRB metabolism could be controlled by the selection of promoiety. In HCMV plaque-formation assays, l-Asp-BDCRB exhibited 3-fold greater selectivity than BDCRB for inhibition of HCMV replication. This potent and selective antiviral activity in addition to favorable stability profile made l-Asp-BDCRB an excellent candidate for in vivo assessment and pharmacokinetic comparison with BDCRB. In addition to rapid absorption and sufficient prodrug activation after oral administration to mice, l-Asp-BDCRB exhibited a 5-fold greater half-life than BDCRB. Furthermore, the sum of area under the concentration-time profile (AUC)(BDCRB) and AUC(prodrug) after l-Asp-BDCRB administration was roughly 3-fold greater than AUC(BDCRB) after BDCRB administration, suggesting that a reservoir of prodrug was delivered in addition to parent drug. Overall, these findings demonstrate that amino acid prodrugs of BDCRB exhibit evasion of metabolizing enzymes (i.e., bioevasion) in vitro and provide a modular approach for translating this in vitro stability into enhanced in vivo delivery of BDCRB.

A Regioselective Synthesis of Alkyl 2-(Guanin-9-yl)acetates as PNA Building Blocks from 7-(4-Nitrobenzyl)guanine Derivatives

Guanine derivatives substituted at N7 with 4-R-benzyl groups (R = H, MeO, NO2) have been evaluated in the regioselective N9-alkylation of guanine. Given the capricious removal of (substituted) benzyl groups from guanine derivatives and pent-4-enoylation of guaninium hydrochloride, an improved alternative approach has been elaborated consisting in the pent-4-enoylation and per-O-acetylation of guanosine (8), 4-nitrobenzylation at N7 followed by N-glycoside hydrolysis (10), N9-alkylation (13) and deprotection with sodium dithionite to afford the peptide nucleic acid building block tert-butyl [N2-(pent-4-enoyl)guanin-9-yl]- acetate (15) in 36% overall yield. This avoids N7 regioisomer formation, solubility problems and any chromatographic purification. A remarkable influence of the O- and/or N2-acyl groups on the stability of N-glycosidic bond and reactivity of 2-amino group was observed. The structure of a pyrimidine by-product 12 arising from the imidazole ring-opening of guaninium salt 4d in alkaline medium has been elucidated by 2D NMR.

An ab initio quantum chemistry study on N-glycosidic bond stabilities of hydroxyl radical modified guanosine analogs

Stabilities of N-glycosidic bond of N9-methoxymethyl guanosine, 8-oxo-guanosine, xanthine and fapy-guanosine in its most abundant tautomeric forms were studied by means of ab inito quantum chemistry methods. Gibbs free energies were estimated for all possible mono- and double-protonated compounds based on B3LYP/6–31G** geometries with inclusion of water solvent effects. Estimated values of protonation probabilities as well as proton affinities allow for comparison of basicidies, N-glycosidic bond stabilities and hydrolysis mechanism for studied compounds. Significant changes of the protonation affinities of hydroxyl radical modified guanosine has been noticed. This in turn has impact on the N-glycosidic bond properties. The first protonation takes place mostly at N3, N7 and O6 atoms, which seems to be most basic centers for guanosine analogs. However, depurination process for most probable protonated species is not thermodynamically favored. On the contrary, there was found strong thermodynamical stimulus in case of hydrolysis of directly protonated N9 center. However, this center has very low basicidity, what practically prohibits spontaneous occurrence in acidic conditions. Thus, mechanism of N-glycosidic bond hydrolysis is not as straightforward as expected till now.

An ab initio quantum chemistry study on N-glycosidic bond stabilities of hydroxyl radical modified guanosine analogs

Stabilities of N-glycosidic bond of N 9-methoxymethyl guanosine, 8-oxo-guanosine, xanthine and fapy-guanosine in its most abundant tautomeric forms were studied by means of ab inito quantum chemistry methods. Gibbs free energies were estimated for all possible mono- and double-protonated compounds based on B3LYP/6–31G** geometries with inclusion of water solvent effects. Estimated values of protonation probabilities as well as proton affinities allow for comparison of basicidies, N-glycosidic bond stabilities and hydrolysis mechanism for studied compounds. Significant changes of the protonation affinities of hydroxyl radical modified guanosine has been noticed. This in turn has impact on the N-glycosidic bond properties. The first protonation takes place mostly at N 3, N 7 and O 6 atoms, which seems to be most basic centers for guanosine analogs. However, depurination process for most probable protonated species is not thermodynamically favored. On the contrary, there was found strong thermodynamical stimulus in case of hydrolysis of directly protonated N 9 center. However, this center has very low basicidity, what practically prohibits spontaneous occurrence in acidic conditions. Thus, mechanism of N-glycosidic bond hydrolysis is not as straightforward as expected till now.