Design and synthesis of novel 2',3'-dideoxy-4'-selenonucleosides as potential antiviral agents

On the basis of potent anti-HIV activity of 2',3'-dideoxynucleosides (ddNs), their bioisosteric analogues, 2',3'-dideoxy-4'-selenonucleosides (4'-seleno-ddNs) were first synthesized from a chiral template, d-glutamic acid using stereoselective ring-closure reaction of the dimesylate with Se(2-) and Pummerer type condensation of the selenoxide with nucleobases as key steps. X-ray crystallographic analysis indicated that 4'-seleno-ddNs adopted the same C2'-endo/C3'-exo (South) conformation as anti-HIV active ddNs, but did not show anti-HIV activity, indicating that RT seems to prefer the C2'-exo/C3'-endo (North) conformation on binding with their triphosphates.     

Stereochemical studies on nucleic acid analogues. I. Conformations of alpha-nucleosides and alpha-nucleotides: interconversion of sugar puckers via O4'-exo.

The preferred conformations of ribo and deoxyribo alpha-nucleosides and alpha-nucleotides, the stereoisomers of the naturally occurring beta-isomers, are worked out by minimizing the conformational energy as a function of all the major parameters including the sugar ring conformations along the pseudorotation path. The results of the studies bring out certain distinct conformational features that are at variance with their beta counterparts. The range of glycosyl conformations are found to be not only quite restricted here but favor predominantly the anti conformation. The syn glycosyl conformation for the entire region of P values are found to be energetically less favorable, with the barrier to anti in equilibrium with syn interconversion being higher especially in alpha-ribonucleosides. The energetically preferred range of pseudorotation phase angles (P) is also considerably restricted and P values corresponding to the C1'-exo range of sugars are highly unfavorable for alpha-nucleosides, in sharp contrast to the broad range of sugar ring conformations favored by beta-isomers. While both trans congruent to 180 degrees and skew congruent to 270 degrees conformations around the C3'-O3' (phi') bond are favored for alpha-3'-nucleotides with deoxyribose sugars, ribose sugars seem to favor only the skew values of phi'. Most interestingly and in sharp contrast to beta-stereoisomers, an energy barrier is encountered at P values corresponding to O4'-endo sugars. This suggests that the possible sugar pucker interconversion between C2'-endo/C3'-exo and C3'-endo/C2'-exo in alpha-anomers could take place only through the O4'-exo region. Likewise the possible path of anti in equilibrium with syn interconversion in alpha-nucleosides is not via high anti, in sharp contrast to beta-nucleosides. These observations should be borne in mind while assigning the sugar ring conformers in alpha-nucleosides and those containing them from nmr investigations. Comparison of the results with beta-anomers seem to suggest on the whole a lack of conformational variability or the restricted nature of alpha-stereoisomers. This could be one of the reasons for its nonselection in the naturally occurring nucleic acids.     

A comparison of the conformations adopted by some 5-bromovinyl-2''-deoxyuridines and a correlation with their antiviral properties: an X-ray study.

Crystal structures of (Z)-5-(2-bromovinyl)-2'-deoxyuridine, 3',5'-di-O-acetyl-(E)-5-(2-bromovinyl)-2'-deoxyuridine and 3',5'-di-O-p-chlorobenzoyl-5-(2-dibromovinyl)-2'-deoxyuridine are compared with each other and with that of the most potent antiviral agent (E)-5-(2-bromovinyl)-2'-deoxyuridine (E-BVDU) reported earlier. A comparison of the conformation of 3',5'-di-O-acetyl-pyrimidine nucleoside structures in which intermolecular hydrogen bond network formation is minimized, with those of their parent compounds has shown that the greatest change in rotation about the glycosyl bond and in the sugar ring pucker is exhibited by E-BVDU. Upon acylation this molecule changes from C2'-endo/C3'-exo conformation to C3'-endo/C4'-exo conformation. The relevance of these structures upon the biological activity of the nucleosides and in particular to their ability to be a substrate for thymidine kinase is discussed.     

Conformation of 3'CMP bound to RNase A using TrNOESY

The conditions for accurately determining distance constraints from TrNOESY data on a small ligand (3'CMP) bound to a small protein (RNase A, <14 kDa) are described. For small proteins, normal TrNOESY conditions of 10:1 ligand:protein or greater can lead to inaccurate structures for the ligand-bound conformation due to the contribution of the free ligand to the TrNOESY signals. By using two ligand:protein ratios (2:1 and 5:1), which give the same distance constraints, a conformation of 3'CMP bound to RNase A was determined (glycosidic torsion angle, chi=-166 degrees ; pseudorotational phase angle, 0 degrees < or = P < or =36 degrees ). Ligand-protein NOESY cross peaks were also observed and used to dock 3'CMP into the binding pocket of the apo-protein (7rsa). After energy minimization, the conformation of the 3'CMP:RNase A complex was similar to the X-ray structure (1 rpf) except that a C3'-endo conformation for the ribose ring (rather than C2'-exo conformation) was found in the TrNOESY structure.     

Unusual conformational flexibility in N1-substituted uncommon purine nucleosides. Crystal structure of 1-allyl-isoguanosine and 1-allyl-xanthosine.

Several new N1-substituted uncommon purine nucleosides, including doridosine (1-methyl-isoguanosine; m-iG), 1-allyl-isoguanosine (a-iG) and 1-allyl-xanthosine (a-X), have been synthesized and tested as agonists for the adenosine receptors. Some have smooth muscle relaxant or negative chronotropic activities. The X-ray crystal structure of these compounds has been determined at atomic resolution in order to understand the structure-activity relationship. The structures were solved by direct methods and refined by full-matrix least-squares refinement procedure. The crystallographic parameters are: a-iG, space group P2(1), a = 10.573 (1) A, b = 21.955 (2) A, c = 14.360 (1) A, beta = 110.65 (1) degree, no. of 3 sigma Fo's = 4585, R = 0.047; a-X, space group P2(1)2(1)2(1), a = 16.015 (2) A, b = 16.239 (1) A, (1) A, c = 5.3723 (5) A, no. of 3 sigma Fo's = 1169, R = 0.031. In the a-iG crystal, there are 4 independent molecules (with different conformation) per asymmetric unit. While all 4 molecules adopt anti chi CN glycosyl torsion angle, their riboses have 3 distinct puckers (C2'-exo, C2'-endo and C1'-exo). In contrast, the a-X structure adopts a syn chi CN glycosyl torsion angle, which is stabilized by an intramolecular hydrogen bond between the N3 of purine base and the O5' of the ribose (in C2'-endo pucker). Both purine bases (a-iG and a-X) are mainly in the keto tautomer form. For the isoguanine base, the averaged N1-C2 bond distance (1.42 A) is significantly longer than that (1.375 A) of the guanine base. For the xanthine base, N3 nitrogen has an imino proton attached which is unambiguously located in the electron density map. The surprising flexibility in the ribose ring of these N1-substituted uncommon purine nucleosides suggests that the ribose moiety may not participate in the binding of nucleoside to the adenosine receptors.     

Nuclear overhauser effect studies on the conformation of magnesium adenosine 5'-triphosphate bound to rabbit muscle creatine kinase

Nuclear Overhauser effects were used to determine interproton distances on MgATP bound to rabbit muscle creatine kinase. The internuclear distances were used in a distance geometry program that objectively determines both the conformation of the bound MgATP and its uniqueness. Two classes of structures were found that satisfied the measured interproton distances. Both classes had the same anti glycosidic torsional angle (chi = 78 +/- 10 degrees) but differed in their ribose ring puckers (O1'-endo or C4'-exo). The uniqueness of the glycosidic torsional angle is consistent with the preference of creatine kinase for adenine nucleotides. One of these conformations of MgATP bound to creatine kinase is indistinguishable from the conformation found for Co(NH3)4ATP bound to the catalytic subunit of protein kinase, which also has a high specificity for adenine nucleotides [chi = 78 +/- 10 degrees, O1'-endo; Rosevear, P.R., Bramson, H.N., O'Brian, C., Kaiser, E.T., & Mildvan, A.S. (1983) Biochemistry 22, 3439]. Distance geometry calculations also suggest that upper limit distances, when low enough (less than or equal to 3.4 A), can be used instead of measured distances to define, within experimental error, the glycosidic torsional angle of bound nucleotides. However, this approach does not permit an evaluation of the ribose ring pucker.     

Allosteric effect of fructose 1,6-bisphosphate on the conformation of NAD+ as bound to L-lactate dehydrogenase from Thermus caldophilus GK24

The allosteric effect of fructose 1,6-bisphosphate (Fru-1,6-P2) on L-lactate dehydrogenase (L-lactate:NAD+ oxidoreductase, EC 1.1.1.27) from Thermus caldophilus GK24 was studied by means of 1H NMR analyses. The conformation of NAD+ as bound to the T. caldophilus enzyme was elucidated by analyses of the transferred nuclear Overhauser effects (TRNOE), in the presence and the absence of the allosteric effector, Fru-1,6-P2. Upon binding of Fru-1,6-P2 to the enzyme, the ribose ring of the adenosine moiety of NAD+ is converted from the C2'-endo form to the C3'-endo form. This C3'-endo form of the adenosine moiety is similar to that of NAD+ as bound to nonallosteric vertebrate enzymes. However, the anti conformation of the adenine-ribose bond of NAD+ as bound to the T. caldophilus enzyme is not affected by the binding of Fru-1,6-P2. In contrast, the syn conformation of the nicotinamide-ribose bond is converted to the anti form on the binding of Fru-1,6-P2, while the ribose ring remains in the C3'-endo form as found in the case of a nonallosteric enzyme. Such a conformational change of enzyme-bound NAD+ as found on TRNOE analysis is essentially involved in the allosteric regulation of the T. caldophilus enzyme by Fru-1,6-P2.     

Determination of the DNA sugar pucker using 13C NMR spectroscopy

Solid-state 13C NMR spectroscopy of a series of crystalline nucleosides and nucleotides allows direct measurement of the effect of the deoxyribose ring conformation on the carbon chemical shift. It is found that 3'-endo conformers have 3' and 5' chemical shifts significantly (5-10 ppm) upfield of comparable 3'-exo and 2'-endo conformers. The latter two conformers may be distinguished by smaller but still significant differences in the carbon chemical shifts at the C-2' and C-4' positions. High-resolution solid-state NMR of three modifications of fibrous calf thymus DNA shows that these trends are maintained in high-molecular-weight DNA and confirms that the major ring pucker in A-DNA is 3'-endo, while both B-DNA and C-DNA are largely 2'-endo. The data show that 13C NMR spectroscopy is a straightforward and useful probe of DNA ring pucker in both solution and the solid state.     

Computer modeling studies of ribonuclease T1-guanosine monophosphate complexes

The three-dimensional structures of ribonuclease (RNase) T1 complexes with the inhibitors 2'-guanylic acid (2'-GMP), 3'-guanylic acid (3'-GMP), and 5'-guanylic acid (5'-GMP) were predicted by energy minimization studies. It is shown that these inhibitors can bind to RNase T1 in either of the ribose puckered conformations (C2'-endo and C3'-endo) in solid state and exist in significant amounts in both forms in solution. These studies are in agreement with the x-ray crystallographic studies of the 2'-GMP-Lys25-RNase T1 complex, where the inhibitor binds in C2'-endo puckered conformation. These results are also in good agreement with the available 1H-nmr results of Inagaki et al. [(1985) Biochemistry 24, 1013-1020], but differ from their conclusions where the authors favor only the C3'-endo ribose conformation for all the three inhibitors. The calculations explain the apparent discrepancies in the conclusions drawn by x-ray crystallographic and spectroscopic studies. An extensive hydrogen-bonding scheme was predicted in all the three complexes. The hydrogen-bonding scheme predicted for the 2'-GMP (C2'-endo)-RNase T1 complex agrees well with those reported from x-ray crystallographic studies. In all three complexes the base and the phosphate bind in nearly identical sites independent of the position of the phosphate or the ribose pucker. The glycosyl torsion angle favors a value in the +syn range in the 2'-GMP (C2'-endo)-RNase T1, 3'-GMP (C2'-endo)-RNase T1, and 3'-GMP (C3'-endo)-RNase T1 complexes; in the high-syn range in the 2'-GMP (C3'-endo)-RNase T1 complex; and in the -syn range in the 5'-GMP (C2'-endo)-RNase T1 and 5'-GMP (C3'-endo)-RNase T1 complexes. These results are in agreement with experimental studies showing that the inhibitory power decreases in the order 2'-GMP greater than 3'-GMP greater than 5'-GMP, and they also explain the high pKa value observed for Glu58 in the 2'-GMP-RNase T1 complex.     

Environmentally induced conformational changes in B-type DNA: comparison of the conformation of the oligonucleotide d(TCGCGAATTCGCG) in solution and in its crystalline complex with the restriction nuclease EcoRI

Raman spectroscopic analysis of the secondary structure of the crystalline restriction endonuclease EcoRI, the oligonucleotide d(TCGCGAATTCGCG) in solution, and the corresponding crystalline EcoRI-oligonucleotide complex reveals structural differences between the complexed and uncomplexed protein and oligonucleotide components that appear to be linked to complex formation. Structural differences that are spectroscopically identified include (1) an increase in the population of furanose rings adopting the C3'-endo conformation and (2) spectroscopically observed changes in base stacking which are probably associated with the crystallographically observed distortion of the phosphate backbone about positions C(3)-G(4) and C(9)-G(10) and unwinding between the symmetry-related segments GAA-TTC which make up the central recognition core (McClarin et al., 1986). Changes in base stacking due to distortions and unwinding along the oligonucleotide result in differences in the base vibrational region between the spectra of the complex and the oligonucleotide in solution. The spectroscopic analysis indicates that the C2'-endo population is similar for the oligonucleotide in solution and in the complex. The additional C3'-endo population in the complex appears to arise from the conversion of rings adopting alternative conformations such as C1'-exo and O1'-endo. Analysis of the vibrational bands derived from guanine indicates that the population of guanine residues associated with furanose rings in a C2'-endo conformation is similar for the oligonucleotide in solution and in the crystalline complex. This implies that the increase in C3'-endo population is not associated with guanine residues. Large conformational distortions such as those observed in the crystal distortions are not observed in either the crystal or the solution of the oligomer d(CGCGAATTCGCG).(ABSTRACT TRUNCATED AT 250 WORDS)     

The effects of monovalent cations Li+, Na+, K+, NH4+, Rb+ and Cs+ on the solid and solution structures of the nucleic acid components. Metal ion binding and sugar conformation.

The interactions of the monovalent ions Li+, Na+, K+, NH4+, Rb+ and Cs+ with adenosine-5'-monophosphoric acid (H2-AMP), guanosine-5'-monophosphoric acid (H2-GMP) and deoxyguanosine-5'-monophosphoric acid (H2-dGMP) were investigated in aqueous solution at physiological pH. The crystalline salts M2-nucleotide.nH2O, where M = Li+, Na+, K+ NH4+, Rb+ and Cs+, nucleotide = AMP, GMP and dGMP anions and n = 2-4 were isolated and characterized by Fourier Transform infrared (FTIR) and 1H-NMR spectroscopy. Spectroscopic evidence showed that these ions are in the form of M(H2O)n+ with no direct metal-nucleotide interaction, in aqueous solution. In the solid state, Li+ ions bind to the base N-7 site and the phosphate group (inner-sphere), while the NH4+ cations are in the vicinity of the N-7 position and the phosphate group, through hydrogen bonding systems. The Na-nucleotides and K-nucleotides are structurally similar. The Na+ ions bind to the phosphate group of the AMP through metal hydration shell (outer-sphere), whereas in the Na2-GMP, the hydrated metal ions bind to the base N-7 or the ribose hydroxyl groups (inner-sphere). The Na2-dGMP contains hydrated metal-carbonyl and metal-phosphate bindings (inner-sphere). The Rb+ and Cs+ ions are directly bonded to the phosphate groups and indirectly to the base moieties (via H2O). The ribose moiety shows C2'-endo/anti conformation for the free AMP acid and its alkali metal ion salts. In the free GMP acid, the ribose ring exhibits C3'-endo/anti conformer, while a C2'-endo/anti sugar pucker was found in the Na2-GMP and K2-GMP salts and a C3'-endo/anti conformation for the Li+, NH4+, Rb+ and Cs+ salts. The deoxyribose has C3'-endo/anti conformation in the free dGMP acid and O4'-endo/anti in the Na2-dGMP, K2-dGMP and a C3'-endo/anti for the Li+, NH4+, Rb+ and Cs+ salts. An equilibrium mixture of the C2'-endo/anti and C3'-endo/anti sugar puckers was found for these metal-nucleotide salts in aqueous solution.     

Structure and conformation of 1-beta-D-ribo furanosyl pyridin-2-one-5-carboxamide: an anti-inflammatory agent

The pyrimidine nucleoside, 1-beta-D-ribofuranosyl pyridine-2-one-5-carboxamide, is an anti inflammatory agent used in the treatment of adjuvant-induced arthritis. It is the 2-one isomer of 1-beta-D-ribofuranosyl pyridine-4-one 5-carboxamide, an unusual nucleoside isolated from the urine of patients with chronic myelogenic leukemia and an important cancer marker. Crystals of 1-beta-D-ribofuranosyl pyridine-2-one-5-carboxamide are monoclinic, space group C2, with the cell dimensions a = 31.7920(13), b = 4.6872 (3), c = 16.1838(11), beta = 93.071(3) degrees , V = 2408.2(2) A(3), D(calc) = 1.496 mg/m(3) and Z = 8 (two molecules in the asymmetric unit). The structure was obtained by the application of direct methods to diffractometric data and refined to a final R value of 0.050 for 1669 reflections with I >or= 3sigma. The nucleoside exhibits an anti conformation across the glycosidic bond (chi(CN) = -15.5 degrees , -18.9 degrees ), a C3 '-endo C2 '-exo [(3)(2)T] ribose pucker and g(+) across the C(4 ')-C(5 ') exocyclic bond. The amino group of the carboxamide group is distal from the 2-one and lacks the intramolecular hydrogen bonding found in the related 2-one molecule. Nuclear magnetic resonance studies shows also an anti conformation across the glycosidic bond but the solution conformation of the furanose ring is not the same as that found in the solid state.     

X-ray crystal structure of a dimethylene sulfone-bridged ribonucleotide dimer in a single-stranded state.

A crystal structure has been solved for an analog of the r(ApU) ribodinucleotide, r(Aso2U), where a bridging non-ionic dimethylene sulfone linker replaces the phosphodiester linking group found in natural RNA. Crystals of the single-stranded state of r(Aso2U) were obtained from water at 50 degrees C. In these crystals, one hydrogen bond is formed between bases from different strands and base stacking occurs in intermolecular 'homo-A' and 'homo-U' stacks. Similar to typical oligoribonucleotides, the ribose rings adopt N-type conformations and dihedral angles chi are in the anti range. The all-trans rotamer of the CH2-SO2-CH2-CH2 bridge was found, which leads to a large adenine-uracil distance. Qualitative analysis of a NOESY spectrum of the Aso2U part in r(Uso2Cso2Aso2U) dissolved in a dimethylsulfoxide-D2O mixture indicates that the conformation observed in the crystal is also populated in solution. Comparison with the structure of r(Gso2C), which has been crystallized in the Watson-Crick paired state, shows that a rotation around zeta by +112 degrees leads from the observed, single-stranded state to a conformation that is compatible with formation of a duplex. A concerted trans/gauche flip of alpha and gamma then yields the standard conformer of A-type RNA helices. From the observed structure of r(Gso2C) and other oligonucleotides it is anticipated that this flip will also revert the ribose pucker from C2'-exo to C3'-endo.     

Nuclear Overhauser effect studies of the conformation of Co(NH3)4ATP bound to kidney Na,K-ATPase

Transferred nuclear Overhauser effect measurements (in the two-dimensional mode) 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., et al. (1982) Biochemistry 21, 4083]. Nine unique proton-proton distances on ATPase-bound Co(NH3)4ATP were determined from the initial build-up rates of the cross-peaks of the 2D-TRNOE data sets. These distances, taken together with previous 31P and 1H relaxation measurements with paramagnetic probes, are consistent with a single nucleotide conformation at the active site. The bound Co(NH3)4ATP) adopts an anti conformation, with a glycosidic torsion angle of 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 nucleotide adopts a bent configuration, in which the triphosphate chain lies nearly parallel to the adenine moiety. Mn2+ bound to a single, high-affinity site on the ATPase lies above and in the plane of the adenine ring. The distances from enzyme-bound 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. The NMR data also indicate that the structure of the bound ATP analogue is independent of the conformational state of the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Conformational studies of two isomeric ring-expanded purine nucleosides and their 5'-mono- and -diphosphate derivatives

The nucleosides Ia and IIa exist in syn and anti conformations, respectively, both in solid state and solution. Compound Ia undergoes significant conformational change, accompanied by increased population of the anti conformer, upon conversion to the corresponding 5'-mono- and- diphosphate derivatives, whereas conformation of IIa remains reasonably constant between nucleoside and nucleotides. While Ia possessed the C2'-endo-C3'-exo geometry, IIa had the opposite C2'-exo-C3'-endo conformation. The C5' of the two nucleosides bore axial and equatorial conformations, respectively.     

Conformational analysis of d(C3G3), a B-family duplex in solution

NMR and circular dichroism studies of the duplex formed by the self-complementary DNA hexanucleotide d(C3G3) indicate that it is a B-type structure but differs from standard B-form. An analysis of NMR coupling constants within the deoxyribose moieties yields a 70% or greater contribution from pseudorotation phase angles corresponding to the C3'-exo conformation, a conformation similar to the C2'-endo conformation associated with B-form DNA. Intranucleotide interproton distances are consistent with a B-form structure, but some internucleotide distances are intermediate between A- and B-form structures. Circular dichroism spectra have B-form characteristics but also include an unusual negative band at 282 nm. The solution spectroscopic results are in contrast with X-ray crystallographic studies which find A-form structures for similar sequences.     

Crystal structure and conformation of 5-fluorouridine: conformational preferences for 5-fluorinated pyranosides

Crystals of 5-fluorouridine (5FUrd) have unit cell dimensions a = 7.716(1), b = 5.861(2), c = 13.041(1)A, alpha = gamma = 90 degrees, beta = 96.70 degrees (1), space group P2(1), Z = 2, rho obs = 1.56 gm/c.c and rho calc = 1574 gm/c.c The crystal structure was determined with diffractometric data and refined to a final reliability index of 0.042 for the observed 2205 reflections (I > or = 3sigma). The nucleoside has the anti conformation [chi = 53.1(4) degrees] with the furanose ring in the favorite C2'-endo conformation. The conformation across the sugar exocyclic bond is g+, with values of 49.1(4) and -69.3(4) degrees for phi(theta c) and phi (infinity) respectively. The pseudorotational amplitude tau(m) is 34.5 (2) with a phase angle of 171.6(4) degrees. The crystal structure is stabilized by a network of N-H...O and O-H...O involving the N3 of the uracil base and the sugar 03' and 02' as donors and the 02 and 04 of the uracil base and 03' oxygen as acceptors respectively. Fluorine is neither involved in the hydrogen bonding nor in the stacking interactions. Our studies of several 5-fluorinated nucleosides show the following preferred conformational features: 1) the most favored anti conformation for the nucleoside [chi varies from -20 to + 60 degrees] 2) an inverse correlation between the glycosyl bond distance and the chi angle 3) a wide variation of conformations of the sugar ranging froni C2'-endo through C3'-endo to C4'-exo 4) the preferred g+ across the exocyclic C4'-C5' bond and 5) no role for the fluorine atom in the hydrogen bonding or base stacking interactions.     

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.     

Specific interaction of netropsin, distamycin-3 and analogs with LC duplexes: reversion towards the B form of the 2''-deoxy-.2''-deoxy-2''-fluoro-hybrid duplexes upon specific interaction with netropsin, distamycin-3 and analogs.

Binding of the B-form specific ligands netropsin and distamycin-3, -4 and -5 has been used to monitor the presence and/or the inducibility of a B-type structure in various poly-inosinic.poly-cytidilic double stranded polymers with deoxyribose, ribose or 2'-deoxy-2'-fluororibose as sugar on either strand. The efficiency of binding was followed by circular dichroism and further evaluated by the increase in melting temperature of the complexes. The efficient binding of netropsin and distamycins to the hybrid polymer (dIfl)n. (dC)n demonstrated that the fluorine carrying strand may undergo a A to B-type transition reflecting a change of the 2'-deoxy-2'-fluororibose from the 3'-endo to the 1'-exo or 2'-endo pucker. The less efficient binding of the same ligands to the reverse hybrid (dI)n.(dCfl)n showed that the geometry of the pyrimidine strand is the most critical for the specific interaction. Taking into account the recent findings about the regular hydration in the minor groove of the B-type dodecamer dCGCGAATTCGCG in solid-state, the different binding modes observed between the different polymers and antibiotics are explained by differences in their possibilities of hydration. Binding of netropsin to a double stranded deoxypolymer is interpreted as a local replacement of water molecules by netropsin in the minor groove hydration network which is typical of the B-form.     

The structure of 3'-O-anthraniloyladenosine, an analogue of the 3'-end of aminoacyl-tRNA.

3'-O-Anthraniloyladenosine, an analogue of the 3'- terminal aminoacyladenosine residue in aminoacyl-tRNAs, was prepared by chemical synthesis, and its crystal structure was determined. The sugar pucker of 3'-O-anthraniloyladenosine is 2'-endo resulting in a 3'-axial position of the anthraniloyl residue. The nucleoside is insynconformation, which is stabilized by alternating stacking of adenine and benzoyl residues of the neighboring molecules in the crystal lattice. The conformation of the 5'-hydroxymethylene in 3'-O- anthraniloyladenosine is gauche-gauche. There are two intramolecular and two intermolecular hydrogen bonds and several H-bridges with surrounding water molecules. The predominant structure of 3'-O-anthraniloyladenosine in solution, as determined by NMR spectroscopy, is 2'-endo,gauche-gauche and anti for the sugar ring pucker, the torsion angle around the C4'-C5'bond and the torsion angle around the C1'-N9 bond, respectively. The 2'-endo conformation of the ribose in 2'(3')-O-aminoacyladenosine, which places the adenine and aminoacyl residues in equatorial and axial positions, respectively, could serve as a structural element that is recognized by enzymes that interact with aminoacyl-tRNA or by ribosomes to differentiate between aminoacylated and non-aminoacylated tRNA.