Conformation of the common purine (β) ribosides in solution: further evidence for a correlation between N-S state of the ribose moiety and syn-anti equilibrium

The solution conformations of adenosine, guanosine and inosine in liquid ND₃ have been determined by NMR. Comparison of the Karplus analysis of the proton HR spectra of the ribose moiety obtained in this solvent with the data from aqueous solutions of A and I proves that the conformations of the nucleosides are very similar in both liquids. From the analysis of the vicinal coupling constants of the ring protons it has been deduced that the S state C(2′)-endo is slightly preferred. The mole fraction in S approximates 0.6 for all three nucleosides. C-13 relaxation measurements have been applied in the determination of the correlation times for rotational diffusion. Only at temperatures below −40‡ C is the pseudorotation of the furanoside ring slowed down sufficiently for it not to contribute to the measured relaxation rates. From NOE studies and T¹ measurements on the individual protons it is derived that the N, C(3′)-endo, form of the ribose is correlated with an anti conformation of the base (Y≈210‡ to 220‡) and the S, C(2′)-endo, form of the ribose with a syn conformation of the base (Y≈30‡ to 50‡). The glycosyl torsion angles derived for the two conformations of A, G, and I are equal within the limits of accuracy.     

Molecular orbital studies on nucleoside analogs. II. Conformation of 6-azapyrimidine nucleosides.

PCILO (Perturbative Configuration Interaction using Localised Orbitals) computations have been carried out for three 6-azapyrimidine nucleosides, 6-azauridine, 6-azacytidine and 6-azathymidine, for both C(2')-endo and C(3')-endo pucker of the sugar ring. The results indicate a syn (chiCN=180 degrees) conformation followed by chiCN=90 degrees and gg conformation for C(3')-endo 6-aza analogs as compareed to the anti (chiCN=0 degrees) and gg conformation preferred by the corresponding pyrimidine nucleosides. For C(2')-endo sugar geometry, 6-azauridine and 6-azacytidine prefer, respectively, chiCN=0 degrees (anti) and phi C(4')-C(5')=60 degrees C (gg) and chiCN-240 degrees (syn) and phi C(4')-C(5')=120 degrees. The corresponding nucleosides, uridine and cytidine, show a preference for syn (chiCN=240 degrees) and gg and anti(chiCN=0 degrees) and gg , respectively. The X-ray crystallographic conformations of 6-azauridine and 6-azacytidine have been attributed to intermolecular hydrogen bonding and crystal packing forces. The results of PMR, CD and ORD studies on 6-azauridine and 6-azacytidine in aqueous solutions are in agreement with the PCILO predictions.     

The crystal and molecular structure of 2'-deoxy-2'-fluoroinosine monohydrate.

The structure of the hydrate of 2'-deoxy-2'-fluoroinosine has been determined by single-crystal x-ray diffraction. The nucleoside crystallizes in space group P2(1)2(1)2(1) with unit cell dimensions, a = 33.291, b = 10. 871, c = 6.897A. There are two nucleosides and two water molecules in the asymmetric unit. The structure was solved by direct methods and refined to a residual R = 0.095. The two independent nucleosides in the asymmetric unit show different conformations about the glycosidic bond, while other structural details are similar. The base orientation to the sugar is syn in molecule A, whereas anti in molecule B. The exocyclic C(4')-C(5') bond conformation defined with respect to C(3')-C(4')-C(5')-O(5') is gauche+ in both molecules A and B. The sugar ring pucker defined by the pseudorotation phase angle P is a twisted conformation in both, C(3')-endo-C(4')-exo with P = 29 degrees in molecule A and C(4')-exo-C(3')-endo with P = 41 degrees in molecule B. It is shown by comparison with x-ray results of other 2'-fluoronucleosides and unmodified nucleosides including inosines that, in addition to a strong preference of the C(3')-endo type pucker, twisted conformations involving C(4')-exo puckering may be one of characteristic features of 2'-fluoronucleosides.     

1H-, 13C-, 31P-NMR studies and conformational analysis of NADP+, NADPH coenzymes and of dimers from electrochemical reduction of NADP+.

All H,H, H,P and several C,P coupling constants, including those between C-4' and the vicinal phosphorus atom, have been determined for NADP+, NADPH coenzymes and for a 4,4-dimer obtained from one-electron electrochemical reduction of NADP+. From these data the preferred conformation of the ribose, that of the 1,4-dihydronicotinamide rings, and the conformation about bonds C(4')-C(5') and C(5')-O(5') were deduced. The preferred form of the 1,4- and 1,6-dihydropyridine rings and the conformation about the ring-ring junction were also obtained for all the other 4,4- and 4,6-dimers formed in the same reduction. All the dimers show a puckered structure, i.e., a boat form for the 1,4- and a twist-boat for the 1,6-dihydronicotinamide ring; both protons at the ring-ring junctions are equatorial and have preferred gauche orientation. On the contrary, the reduced coenzyme NADPH displays a planar or highly flexible conformation, rapidly flipping between two limiting boat structures. The conformation of the ribose rings, already suggested for the NADP coenzymes to be an equilibrium mixture of C(2')-endo (S-type) and C(3')-endo (N-type) puckering modes, has been reexamined by using the Altona procedure and the relative proportion of the two modes has been obtained. The S and N families of conformers have almost equal population for the adenine-ribose, whereas for the nicotinamide-ribose rings the S-type reaches the 90%. The rotation about the ester bond C(5')-O(5') and about C(4')-C(5'), defined by torsion angles beta and gamma respectively, displays a constant high preference for the trans conformer beta t (75-80%), whereas the rotamers gamma are spread out in a range of different populations. The values are distributed between the gauche gamma + (48-69%) and the trans gamma t forms (28-73%). The gamma + conformer reaches a 90% value in the case of NADP+ and NMN+. The conformations of the mononucleotides 5'-AMP, NMN+ and NMNH were also calculated from the experimental coupling constant values of the literature.     

Conformational analysis of arabinonucleosides and nucleotides. A comparison with the ribonucleosides and nucleotides.

Conformations of arabino nucleosides and nucleotides have been analyzed by semiempirical energy calculations. It is found that the change in the configuration of the O(2')-hydroxyl group in arabinoses compared to riboses exerts significant influence on the conformational priorities of the glycosyl and the exocyclic C(4')-C(5') bond torsions. While the anti conformations for the bases are preferred, the anti in equilibrium or formed from syn interconversion is considerably hampered compared to ribosides due to large energy barrier. Further the preferred anti glycosyl torsions are shifted to higher values for C(3')-endo puckers and in ribosides. While the gauche+ conformation around the C(4')-C(5') bond is favored for C(3')-endo arabinosides, it is strongly stabilized for C(2')-endo arabinosides only in the presence of the intrasugar hydrogen bond O(2')-H ... O(5'). The net attractive electrostatic interactions between the phosphate and the base stabilizes the preferred conformations of 5'-arabinonucleotides also.     

Molecular orbital studies on the structure of nucleoside analogs. I. Conformation of 8-azapurine nucleosides

PCILO (perturbative configuration interaction using localized orbitals) computations have been carried out for the conformational properties of 8-azapurine nucleosides. The results indicate an anti conformation for Xcn and a gg conformation for phiC(4')-C(5') for C(2')-endo 8-aza analogs compared to the syn and gg conformation for the corresponding purine nucleosides. For C(3')-endo sugar puckering, both molecules prefer the syn conformation due to intramolecular hydrogen bonding between O(5')-H of the sugar and N(3) of the base, the preference being more profound in 8-aza analogs. The crystallographic conformation 8-azaadenosine has been attributed to crystal forces. The available NMR data on 8-azapurine nucleosides are in agreement with the PCILO predictions.     

Determination of the solution conformation of adenosein 2':3'-monophosphate by nuclear magnetic resonance with lanthanide probes.

The aqueous solution conformation of adenosine 2':3'-monophosphate at pH 2.5 has been determined by a nuclear magnetic resonance method utilizing lanthanide ions as shift and relaxation probes. The ribose conformation is best described as a rapid equilibrium of 2'-endo(3'-exo) and 3'-endo(2'-exo) conformations in a ratio of approximately 2 to 1. The orientation of the base relative to ribose is restricted to a narrow range about chiCN=-70 degrees.     

1H nuclear magnetic resonance studies of the conformation of an ATP analogue at the active site of Na,K-ATPase from kidney medulla

1H nuclear magnetic relaxation measurements have been used to determine the three-dimensional conformation of an ATP analogue, Co(NH3)4ATP, at the active site of sheep kidney Na,K-ATPase. Previous studies have shown that Co(NH3)4ATP is a competitive inhibitor with respect to MnATP for the Na,K-ATPase [Klevickis, C., & Grisham, C. M. (1982) Biochemistry 21, 6979; Gantzer, M. L., Klevickis, C., & Grisham, C. M. (1982) Biochemistry 21, 4083] and that Mn2+ bound to a single, high-affinity site on the ATPase can be an effective paramagnetic probe for nuclear relaxation studies of the Na,K-ATPase [O'Connor, S. E., & Grisham, C. M. (1979) Biochemistry 18, 2315]. From the paramagnetic effect of Mn2+ bound to the ATPase on the longitudinal relaxation rates of the protons of Co(NH3)4ATP at the substrate site (at 300 and 361 MHz), Mn-H distances to seven protons on the bound nucleotide were determined. Taken together with previous 31P nuclear relaxation data, these measurements are consistent with a single nucleotide conformation at the active site. The nucleotide adopts a bent configuration, in which the triphosphate chain lies nearly parallel to the adenine moiety. The glycosidic torsion angle is 35 degrees, and the conformation of the ribose ring is slightly N-type (C2'-exo, C3'-endo). The delta and gamma torsional angles in this conformation are 100 degrees and 178 degrees, respectively. The bound Mn2+ lies above and in the plane of the adenine ring. The distances from Mn2+ to N6 and N7 are too large for first coordination sphere complexes but are appropriate for second-sphere complexes involving, for example, intervening hydrogen-bonded water molecules.(ABSTRACT TRUNCATED AT 250 WORDS)     

The crystal and molecular structure of 8-methyladenosine 3'-monophosphate dihydrate.

8-Methyladenosine 3'-monophosphate dihydrate was synthesized and crystallized in the monoclinic space group P21 with the unit cell dimensions: a = 9.095(2) A, b = 16.750(3) A, c = 5.405(2) A and beta = 97.61(3) degrees. The structure was determined by the application of the heavy atom method and refined to give a final R factor of 0.047. The pertinent conformations are as follows: the syn conformation about the glycosyl bond (chiCN = 216.8 degrees), the C(2')-endo sugar puckering with the displacement of 0.55 A; and the gauche-gauche conformation about the C(4')-C(5') bond capable of forming an intramolecular hydrogen bonding between N(3) of adenine base and O(5') of the hydroxymethylene group on the ribose. The molecule exists in the zwitterionic form with the N(1) of the adenine base protonated by a phosphate proton and is stabilized by three-dimensional networks of hydrogen bonding through the crystalline water molecules or directly between the adjacent nucleotide molecules; no base stacking was observed.     

Ab-inito quantum mechanical calculations of NMR chemical shifts in nucleic acids constituents. II. Conformational dependence of the 1H and 13C chemical shifts in the ribose

The magnetic shielding constant of the different 13C and 1H nuclei of a deoxyribose are calculated for the C2' endo and C3' endo puckerings of the furanose ring as a function of the conformation about the C4'C5' bond. For the carbons the calculated variations are of several ppm, the C3' endo puckering corresponding in most cases to a larger shielding than the C2' endo one. For the protons the calculated variations of chemical shifts are all smaller than 1.3 ppm, that is of the order of magnitude of the variation of the geometrical shielding produced on these protons by the other units of a DNA double helix, with a change of the overall structure of the helix. The computations carried out on the deoxyribose-3' and 5' phosphates for several conformations of the phosphate group tend to show that the changes of conformation of the charged group of atoms produce chemical shift variations smaller than the two conformational parameters of the deoxyribose itself. The calculations carried out for a ribose do give the general features of the differences between the carbon and proton spectra of deoxynucleosides and nucleosides. The comparison of the measured and calculated phosphorylation shifts tend to show that the counterion contributes significantly, for some nuclei of the deoxyribose, to the shifts measured. The calculated magnitude of this polarization effect on carbon shifts suggests a tentative qualitative interpretation of carbon spectra of the ribose part of DNA double helices.     

Structural studies of O6-methyldeoxyguanosine and related compounds: a promutagenic DNA lesion by methylating carcinogens.

O6-Methylation of guanine residues in DNA can induce mutations by formation of base mispairing due to the deprotonation of N(1). The electronic, geometric and conformational properties of three N(9)-Substituted O6-methylguanine derivatives, O6-methyldeoxyguanosine (O6mdGuo), O6-methylguanosine (O6mGuo) and O6, 9-dimethylguanine (O6mdGua), were investigated by X-ray and/or NMR studies. O6mdGuo crystallizes in the monoclinic space group P2(1) with cell parameters a = 5.267(1), b = 19.109(2), c = 12.330(2) A, beta = 92.45(1) degrees, V = 1239.8(3) A3, z = 4 (two nucleosides per asymmetric unit), and O6mGua in the monoclinic space group P2(1)/n with cell parameters a = 10.729(2), b = 7.640(1) c = 10.216(1) A, beta = 92.17(2) degrees, V = 836.7(2) A3, z = 4. The geometry and conformation of O6-methylguanine moieties observed in both crystals and are very similar. Furthermore, the molecular dimensions of the O6methylguanine residue resemble more closely those of adenine than those of guanine. The methoxy group is coplanar with the purine ring, the methyl group being cis to N(1). The conformation of O6-methylguanine nucleosides is variable. The glycosidic conformation of O6mdGuo is anti for molecule (a) and high-anti for molecule (b) in the crystal, while that of O6mGuo is syn [Parthasarathy, R & Fridey, S. M. (1986) Carcinogenesis 7, 221-227]. The sugar ring pucker of O6mdGuo is C(2')-endo for molecule (a) and C(1')-exo for molecule (b). The C(4')-C(5') exocyclic bond conformation in O6mdGuo is gauche- for molecule (a) but trans for molecule (b), in contrast with gauche+ for O6mGuo. The hydrogen bonds exhibited by O6-methylguanine derivatives differ from those in guanine derivatives; the amino N(2) and ring N(3) and N(7) atoms of O6-methylguanine residues are involved in hydrogen bonding. 1H-NMR data for O6mdGuo and O6mdGuo reveal the predominance of a C(2')-endo type sugar puckering. In O6mdGuo, however, a contribution of a C(1')-exo sugar puckering is significant. The NOE data also indicate that O6mdGuo molecules exist with nearly equal population for anti (including high anti) and syn glycosidic conformations. These observations and their biological implications are discussed.     

Crystal structure and conformation of 8-(2-hydroxyethylamino) and 8-(pyrrolidin-1-yl) adenosines

In the course of investigation of 8-alkylamino substituted adenosines, the title compounds were synthesized as potential partial agonists for adenosine receptors. The structure determination of these compounds was carried out with the X-ray crystallography study. Crystals of 8-(2-hydroxyethylamino)adenosine are monoclinic, space group P 2(1); a = 7.0422(2), b = 11.2635(3), c = 8.9215(2) A, beta = 92.261(1) degrees, V = 707.10(3) A3, Z = 2; R-factor is 0.0339. The nucleoside is characterized by the anti conformation; the ribose ring has the C(2')-endo conformation and gauche-gauche form across C(4')-C(5') bond. The molecular structure is stabilized by intramolecular hydrogen bond of N-HO type. Crystals of 8-(pyrrolidin-1-yl)adenosine are monoclinic, space group C 2; a = 19.271(1), b = 7.3572(4), c = 11.0465(7) A, beta = 103.254(2), V = 1524.4(2) degrees A3, Z = 4; R-factor is 0.0498. In this compound, there is syn conformation of the nucleoside; the ribose has the C(2')-endo conformation and gauche -gauche form across C(4')- C(5') bond. The molecular structure is stabilized by intramolecular hydrogen bond of O-HN type. For both compounds, the branching net of intermolecular hydrogen bonds occur in the crystal structures.     

DNA fragment conformations. A 1H-NMR conformational analysis of the d(G-G)-chelated platinum-oligonucleotide d(A-T-G-G)cisPt

The conformation of d(A-T-G-G) and d(A-T-G-G)cisPt has been investigated by 1H-NMR at 500 MHz and 90 MHz under various experimental conditions of temperature and concentration. Analysis of the coupling constants between the deoxyribose protons shows that all the sugar rings of d(A-T-G-G) adopt the S(C2'-endo) conformation most of the time. By contrast, in the platinated tetramer, d(A-T-G-G)cisPt, the N(C3'-endo) conformation is highly predominant for the internal dG residue while the S(C2'-endo) conformation is largely favoured for the other residues as in the case of the unplatinated compound. The relaxation time and nuclear Overhauser effect measurements indicate that the orientation of the two guanines of d(A-T-G-G)cisPt is anti in agreement with the previous results obtained for the dimers: r(G-G)cisPt, d(G-G)cisPt. On lowering the temperature from 80 degrees C to 20 degrees C, several proton resonances of d(A-T-G-G)cisPt exhibit large chemical shift and linewidth variations. The most spectacular temperature effect was observed for the internal dG(H1') and dT(H4') protons. All the delta = f(t) curves display a sigmoid form with the same mid-point temperature of 44 +/- 2 degrees C. This mid-point temperature together with the observed chemical shift and linewidth variations were found to be independent of the d(A-T-G-G)cisPt concentration. These results suggest that d(A-T-G-G)cisPt can adopt two different conformations depending on the temperature. The enthalpy for the transition between the high and low temperature conformations is about 84 kJ/mol.     

Modified bases in tRNA: the structures of 5-carbamoylmethyl- and 5-carboxymethyl uridine.

The crystal structures of two nucleosides, 5-carbamoylmethyluridine (1) and 5-carboxymethyluridine (2), were determined from three-dimensional x-ray diffraction data, and refined to R = 0.036 and R = 0.047, respectively. Compound 1 is in the C3'-endo conformation with chi +5.2 degrees (anti), psiinfinity = +63.4 degrees and psialpha = +180.0 degrees (tt); 2 is in the C2'endo conformation with chi +49.4 degrees (anti), psiinfinity -60.5 degrees and psialpha +60.0 degrees (gg). For each derivative, the plane of the side chain substituent is skewed with respect to the plane of the nucleobase; for 1, the carboxamide group is on the same side of the uracil plane vis a vis the ribose ring; for 2, the carboxyl group is on the opposite side of this plane. No base pairing is observed for either structure. Incorporation of structure 1 into a 3'-stacked tRNA anticodon appears to place 08 within hydrogen bonding distance of the 02' hydroxyl of ribose 33, which may limit the ability of such a molecule of tRNA to "wobble".     

Tautomerism and conformation of the promutagenic analogue N6-methoxy-2'',3'',5''-tri-O-methyladenosine

N6-Methoxy-2',3',5'-tri-O-methyladenosine crystallizes in space group P2(1)2(1)2(1) with cell dimensions a = 4.693, b = 11.412, c = 31.741 A. Least-squares refinement of diffractometer data converged at R = 0.038. The location of a hydrogen atom at N1 and the observed bond lengths and bond angles indicate unequivocally the imino tautomer of the adenine moiety. The N6-methoxy group is oriented syn to N1 and the glycosidic torsion angle XCN is -3.6 degrees, i.e. in the anti range. The furanose ring has a C2'-exo/C3'- endo pucker (P = 0.9 degrees) and is unusually flattened (tau m = 30.0 degrees). The conformations of the O-methyl groups of the ribose ring are compared with those of monomethylated nucleosides, including the biologically important 2'-O-methyl nucleosides. Evidence is presented for the existence of C-H ... N intermolecular hydrogen bonds between adenine moieties. Bearing in mind that N6-methoxyadenosine is a promutagenic analogue, the results are compared with those for the corresponding promutagenic N4-methoxycytidine. They are also discussed in relation to the tautomerism, the conformation of the N6-methoxy group, and the associated base-pairing abilities in the absence and presence of polymerases.     

Determination of the activation energy for pseudorotation of the furanose ring in nucleosides by 13-C nuclear-magnetic-resonance relaxation.

The activation energies for the pseudorotation of the furanose ring in adenosine, guanosine, inosine and xanthosine dissolved in liquid deuteroammonia have been determined by analysis of the longitudinal relaxation rates of the single tertiary carbons between +40 degrees C and minus 60 degrees C. For the purine ribosides the average activation energy was found to be 4.7 plus or minus 0.5 kcal x mol-1 (20 plus or minus 2 kJ x mol-1). For the pyrimidine nucleosides cytidine and uridine the respective activation energy should be higher since it could not be determined by 13-C relaxation measurements. This result can be explained by the formation of a hydrogen bond between the 5'-hydroxymethyl group and the base. In adenosine, guanosine, inosine and xanthosine the relaxation rates of C(5') are smaller than all others thus excluding the formation of a hydrogen bond between the purine base and the 5'-hydroxymethyl group of a strength comparable to the one suggested for cytidine and uridine.     

NMR conformational analysis of p-tolyl furanopyrimidine 2'-deoxyribonucleoside and crystal structure of its 3',5'-di-O-acetyl derivative

The conformation of a representative molecule of a new, potent class of antiviral-active modified nucleosides is determined. A bicyclic nucleoside, 3-(2'-deoxy-beta-D-ribofuranosyl)-6-(4-methylphenyl)-2,3-dihydrofuro[2,3-d]pyrimidin-2-one, shows C2'-endo and C3'-endo ribose conformations in solution (63:37, 37 degrees C; DMSO-d6), as determined by 1H NMR studies. The crystal structure of a 3',5'-di-O-acetyl-protected derivative (monoclinic, P21, a/b/c= 6.666(1)/12.225(1)/24.676(2) A, beta=90.24(1) degrees , Z=4) shows exclusively C2'-endo deoxyribose puckering. The base is found in the anti position both in solution and in crystalline form.     

Oligonucleotide conformations. (5) NMR and relaxation studies on GpU and UpG at neutral pH.

The average conformation of GpU and UpG in neutral aqueous solutions has been investigated by proton chemical shifts and coupling measurements as well as T1 relaxation time experiments. The proportion of the N and S pseudorotational conformers of the ribose ring has been derived from the vicinal coupling constants. The relaxation data provide information about the syn--anti equilibrium of the orientation of the base about the glycosidic bond. This orientation is predominantly syn for the Guo base in both dinucleoside phosphates, that of Urd is anti in the case of GpU and shows an almost equivalent syn and anti character for UpG.     

Assignment of non-exchangeable base proton and H1' resonances of a deoxyoctanucleoside heptaphosphate d(G-G-C*-C*-G-G-C-C) by using the nuclear Overhauser effect.

The resonances of the non-exchangeable base protons and 1' protons of the octamer d(G-G-C*-C*-G-G-C-C), C* = m5dC, have been assigned by means of NOE difference NMR spectroscopy at 500 MHz. From the measured J1'2' and J1'2" it follows that the octamer at low temperature prefers to adopt a B-DNA double-helical conformation in solution, however, some residual conformational freedom is detected at the 3' terminus. From the chemical shift versus temperature profiles it is concluded that no major conformational change occurs below 60-65 degrees C where the duplex formation for residues (2) to (6) is essentially completed under the conditions used.     

Solution conformational analysis of 2'-amino-2'deoxyadenosine, 3'-amino-3'-deoxyadenosine and puromycin by pulsed nuclear-magnetic-resonance methods.

The solution conformation of 2'-amino-2'-deoxyadenosine, 3'-amino-3'-deoxyadenosine, and 3'-amino-3'-deoxy-6-N,N-dimethyladenosine have been determined by nuclear magnetic resonance in aqueous and ammonia solutions. The analysis of the ribose moiety is based on the two-state S in equilibrium N model of Altona and Sundaralingam. Longitudinal proton relaxation time and nuclear Overhauser enchancement measurements have been carried out in order to characterize the orientation of the base relative to the ribose. Those studies indicate that 3'-amino-3'-deoxyadenosine and 3'-amino-3'-deoxy-6-N,N-dimethyladenosine exist in solution preferentially in the N-anti-g + conformations. On the other hand, 2'-amino-2'-deoxyadenosine adopts the S-syn-g +/t conformation families. It appears that the base is restricted to the anti conformation in the first two compounds, while in 2'-amino-2'-deoxyadenosine, one third of the molecules in the S state are in the anti range. These studies corroborate the previously proposed correlations between the N state of the ribose and the anti orientation of the base and between the S state of the ribose and the syn orientation of the base.