Determination of the complete correlation between the sugar ring puckers and 5'-exocyclic group rotamers in conformationally-flexible nucleic acid components from NMR study

β-Cyanuryl Ribose, β-Barbituryl Ribose, and 6-Azauridine as Uridine Mimetics

Uridine (U) mimetics are sought after as tools for biochemical and pharmacological studies. Previously, we have identified recognition patterns of U by proteins. Here, we targeted the characterization of uridine mimetics-cyanuryl-ribose (CR), barbituryl-ribose (BR), and 6-azauridine (AU)-with a view to identify analogs with potentially more binding interactions than U with target biomolecules. We found that CR, BR, and AU retain selective U's natural H-bonds with adenosine vs guanosine. CR/AU and BR were 100- and 10,000-fold more acidic, respectively, than U. Under physiological pH, 54, 51, and 77% of CR, AU, and BR molecules, respectively, are ionized vs 13% for U. The electron-rich nature of CR and BR vs U was reflected by their ¹³C NMR chemical shifts and ε values. CR/AU and BR prefer N conformation (up to 73%) vs U (56%). Unlike U that prefers gg conformation around exocyclic methylol (48%), CR/AU and BR prefer both gt and gg rotamers. In conclusion, replacement of uridine's C6 by N or carbonyl, or C5-C6 by an amide, results in significant changes in U's ionization, electron density, conformation, base-stacking, etc., leading to potentially tighter binding than U with a target protein or nucleic acid and potential use for various biochemical and pharmacological applications.

Interactions of 2'-fluoro-substituted dUMP analogues with thymidylate synthase

A series of 2'-fluoro-substituted dUMP/FdUMP analogues were synthesized, their interaction with human recombinant thymidylate synthase investigated, and structural (1)H and (19)F NMR study of the corresponding nucleosides performed. While 2'-F-dUMP (fluorine in the "down" configuration), in striking contrast to 2'-F-ara-UMP (fluorine in the "up" configuration) and 2',2''-diF-dUMP, showed substrate activity, 2'-F-ara-UMP and 2',2''-diF-dUMP were classic inhibitors, and 2',5-diF-ara-UMP behaved as a strong slow-binding inhibitor, suggesting the 2'-F substituent in the "up" position to interfere with the active center cysteine thiol addition to the pyrimidine C(6) and the pyrimidine C(5)-F to prevent this interference. In support, the direct through space heteronuclear coupling J(HF) was observed for the fluorine "up" derivatives, 2'-F-ara-U and 2',5-diF-ara-U, causing the splitting of the H(6) resonance lines. The absence of such splitting in 2',2''-diF-dUrd, indicating an unusual orientation of the base in relation to the furanose, was associated with an exceptionally weak interaction with the enzyme.

1H NMR Conformational Study of a Variety of α-Anomers of C5-Substituted 2′-Deoxyuridines: Comparison to Their Antiherpetic β Counterparts

Although alpha-nucleosides are not found in nucleic acid, they do occur as constituents of smaller molecules in living cells, e.g., in vitamin B(12). There are now several examples of alpha-nucleosides exerting a biological activity in some instances equal to, or even exceeding, that of the corresponding beta-anomer. Examples include growth inhibitory properties against mouse leukemia cells and antitumor activity. From stereochemical point of view, alpha-anomers serve as references for studying of interaction of the base with the sugar moiety in beta-anomers and may help in better understanding of structure-activity relationships. One important problem preventing conformational analysis of alpha nucleosides is uncertainty in the determination of vicinal coupling constants from simulation of overlapping sugar proton resonances of strongly coupled spin systems. A successful resolution of near-isochronous H3' and H4' resonances made possible a full conformational analysis for a series of alpha-anomers C5-substituted 2'-deoxyuridines, including methyl, ethyl, isopropyl, fluor, vinyl, and bromovinyl, in comparison to their beta counterparts. Conformation of the sugar ring is determined from proton-proton coupling constants and described in terms of pseudorotation between two main puckering domains C2'endo (S) and C3'endo (N). A thorough analysis of chemical shifts as well as conformation of the sugar ring and C4'-C5' rotamers made possible determination of conformational preferences in equilibrium about the glycosidic bond between two regions, anti and syn. This work provides insights into the role of anomeric configuration of the base in conformational behavior of the sugar moiety, a link in the backbone of nucleic acids.

1H NMR conformational study of antiherpetic C5-substituted 2'-deoxyuridines: insight into the nature of structure-activity relationships

1H NMR study and conformational analysis of a broad series of biologically important C5-substituted 2'-deoxyuridines, including alkyl, halogen, vinyl, hydroxymethyl, and hydroxy derivatives as well as nitro, formyl, trifluoromethyl, and dimethylamino substituents, is presented. A thorough analysis of chemical shifts in correlation with C5-substituent electronegativity as well as calculations by SCF semi-empirical method of the formal charge localized on C6 carbon is discussed in terms of charge distribution for electron attracting and electron donating groups. Conformation of the sugar ring is determined from proton-proton coupling constants and described in terms of pseudorotation between two main puckering domains C2'endo (S) and C3'endo (N). Generally, electron donating groups destabilise the N conformation, simultaneously decreasing the mean pseudorotation amplitude. Absolute assignments of the H5' and H5'' methylene protons in 1H NMR spectra permitted the unequivocal determination of molar fractions of the three classical exocyclic C4'-C5' rotamers gauche+, trans, and gauche-, and correlation of them with the sugar ring puckering domains. Conformation about the glycosidic bond is described in terms of equilibrium between two conformational regions, anti and syn. Finally, the role of the C5-substituent in the creation of cytotoxic activity is considered on the basis of a simplified model assuming that compound activity is a function of substituent polar surface, its molecular volume, and its molecule polarity defined at the relative partition of the polar atoms.

Thermodynamic cycle between DNA and RNA constituents for conformation of the sugar ring from nuclear magnetic resonance study

The effect of a structural change of ribose to deoxyribose, by replacement of 2'-OH by 2'-H, on the conformational equilibrium of the sugar ring is described in terms of one thermodynamic cycle. The method is based on the observation that conformational correlations of the sugar ring--side chain ensemble in DNA and RNA components show one general pattern, reflecting an intrinsic physical property of this ensemble. The pattern determines a choice of model systems to study. The systems consist of pairs of DNA and RNA components, nucleosides and nucleotides in aqueous solution, where all conformational factors are fully controlled. This approach allowed us to describe the thermodynamic cycle and measure its fundamental parameters, equilibrium constants and free energy differences, delta delta G, from a nuclear magnetic resonance study. The delta delta G values as determined for pairs of ribo- and deoxyribo-nucleosides in classes of syn-constrained and anti-preferred models, are comparable and lie in a narrow range, delta delta G = 1.7 +/- 0.1 [kJ/mol]. For pairs of ribo- and deoxyribo-nucleotides, the delta delta G values also lie in narrow ranges, delta delta G = 1.7 +/- 0.1 [kJ/mol] for 5'-phosphate nucleotides and delta delta G = 1.9 +/- 0.1 [kJ/mol] for 3'-phosphate nucleotides, i.e. similar to those observed for nucleosides. The measured quantity, delta delta G, is generally observed in a relatively narrow range, delta delta G = 1.75 +/- 0.15 [kJ/mol], irrespective of the class of the model system. This quantity represents a "pure" constant contribution, pe one sugar moiety, as a "driving force" for the N-->S shift in the sugar ring conformational equilibrium, when one compares RNA and DNA. This important thermodynamic quantity, delta delta G, has not hitherto been determined for nucleic acids. Ultimately the delta delta G quantity is revealed in the tendency to adopt S(C2'endo) sugar puckering domain by the majority of DNA structures, whereas RNA generally adopt an N(C3'endo) puckering domain. A possible biological significance of the delta delta G quantity may include evolutionary aspects of nucleic acids.

6-Substituted and 5,6-disubstituted derivatives of uridine: stereoselective synthesis, interaction with uridine phosphorylase, and in vitro antitumor activity

Stereoselective procedures are described for the synthesis of 6-alkyluridines by Lewis acid-catalyzed condensation of (a) trimethylsilylated 6-alkyl-4-alkylthiouracils with 1-O-acetyl-2,3,5-tri-O-benzoyl-beta-D-ribofuranose (ABR) and (b) trimethylsilylated 6-alkyl-3-benzyluracils with ABR. The 4-methylthio group was subsequently removed with the use of 1 N trifluoroacetic acid and the 3-benzyl group by a new modified procedure with the use of the complex BBr3-THF. Furthermore, 6-(hydroxymethyl)uridine (39) and 5-fluoro-6-(hydroxymethyl)uridine (40) were obtained by sequential oxidation with SeO2 and reduction with tetrabutylammonium borohydride of the 6-methyl group of 6-methyluridine (5) and 5-fluoro-6-methyluridine (35), and their corresponding 6-fluoromethyl congeners 41 and 42 were obtained by DAST treatment of 39 and 40, respectively. For all the foregoing nucleosides in the fixed syn conformation about the glycosyl bond, 1H NMR spectroscopy further demonstrated that the pentose rings exist predominantly in the conformation N (3'-endo). Most of the nucleosides were weak substrates of Escherichia coli pyrimidine nucleoside phosphorylase. Enhanced susceptibility to phosphorolysis was exhibited by two of them, 39 and 41, with 6-CH2OH and 6-CH2F substituents capable of formation of an additional hydrogen bond with the enzyme. The 5-fluoro-6-substituted uridines were the poorest substrates. Cytotoxicities of the nucleosides were examined vs the human tumor cell lines MOLT-3, U-937, K-562, and IM-9, as well as PHA-stimulated human lymphocytes. Two of the analogues, 5-fluoro-6-(fluoromethyl)uridine (42) and 5-fluoro-6-(hydroxymethyl)uridine (40), exhibited cytotoxicities comparable to that of 5-fluorouracil.

Synthesis and interactions with thymidylate synthase of 2,4-dithio analogues of dUMP and 5-fluoro-dUMP

The 2,4-dithio analogues of 2'-deoxyuridine and 2'-deoxy-5-fluorouridine have been synthesized by thiation of the previously described 2-thio analogues, and then phosphorylated enzymatically or chemically to yield 2,4-dithio-dUMP and 2,4-dithio-5-fluoro-dUMP. In striking contrast to the 2-thio and 4-thio analogues of dUMP, which are good substrates of thymidylate synthase, 2,4-dithio-dUMP is not a substrate. But, surprisingly, it is a competitive inhibitor, relative to dUMP, of the purified enzymes from both parental and FdUrd-resistant L1210 cells, with K(i) values of 32 microM and 55 microM, respectively. Although 2,4-dithio-5-fluoro-dUMP behaved as a typical slow-binding inhibitor of the enzyme, its K(i) value was 10(3)-10(4)-fold higher than those for the corresponding 2-thio and 4-thio congeners. Similarly, 2,4-dithio-FdUrd was a much weaker inhibitor of tumour cell growth (IC50 approximately 10(-5)M) than FdUrd (IC50 approximately 10(-9)M), 2-thio-FdUrd(IC50 approximately 10(-7)M) or 4-thio-FdUrd (IC50 approximately 5x10(-8)M), while with 2,4-dithio-dUrd no influence on cell growth could be observed. Theoretical considerations, based on calculated aromaticities of the uracil and thiouracil rings, suggest that lack of substrate activity of 2,4-dithio-dUMP may result from increased pyrimidine ring aromaticity of the latter, leading to resistance of C(6) to nucleophilic attack by the enzyme active center cysteine.

The nature of conformational correlations in alpha- and beta-anomers of nucleic acid components in aqueous solution by nuclear magnetic resonance

The solution distribution of combinations of the sugar ring puckering domains, C2'endo(S), C3'endo(N), and C4'-C5' rotamers, +sc(g+), ap(t), -sc(g-), in alpha and beta-anomers in ribo- and deoxyribo- pyrimidine nucleic acid components can be determined from vicinal coupling constants (M. Remin, J. Biomol. Str. Dyn. 2, 211 (1984). A general correlation pattern with a conformational constant lambda reflecting an intrinsic physical property of the sugar-side chain ensemble, is developed and expressed in terms of four principles: I) The +sc rotamer contributes to the C3'endo population to a higher extent (1-Yt) than to C2'endo, (1-Yt-Yg-/Xs). II) The ap rotamer contributes to both C2'endo and C3'endo populations to the same extent (Yt). III) The -sc rotamer contributes only to the C2'endo population, (Yg-/Xs). IV) The molar fractions Xs, Yt and Yg- of conformations C2'endo, ap and -sc, respectively, are strongly correlated, lambda = (Yg-/Xs)/Yt approximately 0.5, and therefore Yt is a basic variable parameter which determines all others in the correlation pattern. In alpha-anomers, regardless of the type and conformation of the sugar ring and base, the molar fraction Yt = 0.37 +/- 0.02. This finding means that different alpha-anomers show one correlation pattern free of the influence of the base. In beta-anomers, structure and conformation of the base are important factors which modulate (through Yt) the correlation pattern, conserving its fundamental features. Yt is considerably increased by a syn-oriented pyrimidine base, but decreases when the base is anti. The transition from anti to syn orientation of the base is followed by destabilization of (C2'endo, +sc) in favor of (C3'endo, ap). The principles of conformational correlations rationalize a variety of correlations observed in the past.