Conformational analysis of the deoxyribofuranose ring in DNA by means of sums of proton-proton coupling constants: a graphical method

A graphical method is presented for the conformational analysis of the sugar ring in DNA fragments by means of proton-proton couplings. The coupling data required for this analysis consist of sums of couplings, which are referred to as sigma 1' (= J1'2' + J1'2'), sigma 2' (= J1'2' + J2'3' + J2'2'), sigma 2' (= J1'2' + J2'3' + J2'2') and sigma 3' (= J2'3' + J2'3' + J3'4'). These sums of couplings correspond to the distance between the outer peaks of the H1', H2', H2' and H3' [31P] resonances, respectively, (except for sigma 2' and sigma 2' in the case of a small chemical shift difference between the H2' and H2' resonances) and can often be obtained from 1H-NMR spectra via first-order measurement, obviating the necessity of a computer-assisted simulation of the fine structure of these resonances. Two different types of graphs for the interpretation of the coupling data are discussed: the first type of graph serves to probe as to whether or not the sugar ring occurs as a single conformer, and if so to analyze the coupling data in terms of the geometry of this sugar ring. In cases where the sugar ring does not occur as a single conformer, but as a blend of N- and S-type sugar puckers, the second type of graph is used to analyze the coupling data in terms of the geometry and population of the most abundant form. It is shown that the latter type of analysis can be carried out on the basis of experimental values for merely sigma 1',sigma 2' and sigma 2', without any assumptions or restrictions concerning a relation between the geometry of the N- and S-type conformer. In addition, the question is discussed as to how insight can be gained into the conformational purity of the sugar ring from the observed fine structure of the H1' resonance. Finally, a comparison is made between experimental coupling data reported for single-stranded and duplex DNA fragments and covalent RNA-DNA hybrids on the one hand and the predicted couplings and sums of couplings presented in this paper on the other hand.     

Proton magnetic resonance study of nucleosides,nucleotides, and dideoxynucleoside monophosphates containing a syn pyrimidine base

Proton magnetic resonance data have been obtained for 6-methyl-2′-deoxyuridine (dT*), its 3′- and 5′-monophosphates, and its 3′,5′-diphosphate, as well as for the corresponding thymine derivatives. The synthesis of the dideoxynucleoside monophosphates—d(TpT), d(T*pT), d(TpT*), and d(T*pT*)—was accomplished, and spectral data were obtained for these four dimers. The data show that the 6-methyluracil base prefers the syn conformation about the N-glycosyl bond at the monomer and dimer levels. The presence of the syn base leads to increases in the cis couplings of the sugar ring, J_1′2″ and J_2′3′, which indicate a trend towards eclipsing of the substituents on the C1′-C2′ and C2′-C3′ fragments. This trend is discussed in terms of changes in the pseudorotational parameters which describe the pucker of the ring. The syn base destabilizes the g⁺ conformer about the C4′-C5′ bond, leading to a preference for the t conformer in all dT* residues at the monomer and dimer levels. Preliminary work on the formation of cyclobutane-type photodimers in d(T*pT) and d(T*pT*) is discussed and presented as evidence for the capability of the syn 6-methyluracil base to form base-stacked complexes.     

The octamer motif in immunoglobulin genes: extraction of structural constraints from two-dimensional NMR studies.

Phase-sensitive two-dimensional nuclear Overhauser enhancement (2D NOE) and double-quantum-filtered correlated (2QF-COSY) spectra were recorded at 500 MHz for the DNA duplex d(CATTTGCATC).d(GATGCAAATG), which contains the octamer element of immunoglobulin genes. Exchangeable and nonexchangeable proton resonances including those of the H5' and H5" protons were assigned. Overall, the decamer duplex adopts a B-type DNA conformation. Scalar coupling constants for the sugar protons were determined by quantitative simulations of 2QF-COSY cross-peaks. These couplings are consistent with a two-state dynamic equilibrium between a minor N- and a major S-type conformer for all residues. The pseudorotation phase angle P of the major conformer is in the range 117-135 degrees for nonterminal pyrimidine nucleotides and 153-162 degrees for nonterminal purine nucleotides. Except for the terminal residues, the minor conformer comprises less than 25% of the population. Distance constraints obtained by a complete relaxation matrix analysis of the 2D NOE intensities with the MARDIGRAS algorithm confirm the dependence of the sugar pucker on pyrimidine and purine bases. Averaging by fast local motions has at most small effects on the NOE-derived interproton distances.     

Deoxyribose ring conformation of [d(GGTATACC)]2: an analysis of vicinal proton-proton coupling constants from two-dimensional proton nuclear magnetic resonance

Exchangeable and nonexchangeable protons of [d(GGTATACC)]2 in aqueous cacodylate solution were assigned from two-dimensional nuclear Overhausser effect (2D NOE) spectra. With phase-sensitive COSY and double quantum filtered COSY (DQF-COSY) experiments, the cross-peaks resulting from deoxyribose ring conformation sensitive proton-proton vicinal couplings, i.e., all 1'-2', 1'-2", 2'-3', and 3'-4' couplings and six from 2"-3' couplings, were observed. From the cross-peak fine structure, the 2',2" proton assignments can be confirmed; coupling constants J1'2' and J1'2" and sums of coupling constants involving H2' and H2" for all residues and H3' for C8 were obtained. The DISCO procedure [Kessler, H., Muller, A., & Oschkinat, H. (1985) Magn. Reson. Chem. 23, 844-852] was used to extract individual 1'-2' and 1'-2" coupling constants. The sum of coupling constants involving H1' or H3' was measured from the one-dimensional spectrum where signal overlap is not a problem. Analysis of the resulting coupling constants and sums of coupling constants, in the manner of Rinkel and Altona [Rinkel, L. J., & Altona, C. (1987) J. Biomol. Struct. Dyn. 4, 621-649], led to the following conclusion: C2'-endo deoxyribose ring conformation is predominant for every residue, but a significant amount of C3'-endo conformation may exist, ranging from 14% to 30%.     

Evaluation of Biopolymer Conformations: Substituent Electronegativity in Nucleosides

Coupling constants J_ij for resonating vicinal protons i and j in NMR are studied theoretically and computationally. Electronegativity as a source of an additive correction for J_{1′, 2′} and J_{2′, 3′}, in two families of nucleosides is examined. Variations in J_{1′, 2′} + J_{3′, 4′} and J_{2′, 3′} are explained by conformational changes only. Variations in J_{1′, 2′} and J_{3′, 4′} are partially explained by a change of conformation, but mainly by variation in population caused by the 2′ substituents and by bee changes. Moreover, the changes of populations are quantifiable with respect to the substituent in 1′ or 2′. A computer program called SEARCH has been developed which optimizes the phase angle of pseudorotation P and the degree of pucker τ_m for a set of ring sugar coupling constants.     

The Conformation of the d(ACCCGGGT) Duplex in Aqueous Solution

Abstract

The nonexchangeable base and sugar protons of the octanucleotide d(ACCCGGGT)₂ have been assigned using two dimensional homonuclear Hartmann-Hahn relayed spectroscopy (HOHAHA), double quantum filtered homonuclear correlation spectroscopy (DQFCOSY) and nuclear Overhauser spectroscopy (NOESY) in D₂O at 12°C. The observed NOE's between the base protons and their own H2′ protons and between the base protons and the H2′ protons of the 5′adjacent nucleotide and the observed coupling constants between the deoxyribose 1′ and 2′,2″ protons indicate that this duplex assumes a right-handed B-type helix conformation in solution.     

Assignment of 13C Chemical Shifts of α-D-Ribonucleoside Sugar Carbons by 1J(CH) Coupling Constants

Abstract

The ¹J(CH) coupling constant of C-1 in nucleosides is increased compared to those of the other carbons of the sugar moiety. Applying this to several D-ribonucleosides the signals C-4′/C-1′of these a-anomers are reversed to those of the 8-counterparts (C-1′/C-4′). This phenomenon and the broadening of the C-3′ signal compared to that of C-2′ establishes the seauence C-4′,1′,2′,3′,5′ (increasing field) for a number of α-D-ribonucleosides.     

Carbon-13 NMR in conformational analysis of nucleic acid fragments. 4. The torsion angle distribution about the C3''-O3'' bond in DNA constituents.

Carbon-13 and proton NMR spectra of a series of oligodeoxynucleotides (d(CT), d(CC), d(TA), d(AT), d(CG), d(GC), d(AG), d(AAA), d(TATA) and d(GGTAAT] were measured at various temperatures. The three coupling constants that are related to the magnitude of backbone angle epsilon (J(C4'-P), J(C2'-P) and J(H3'-P] are analyzed in terms of a three-state equilibrium about this bond. Two epsilon (trans) angles occur, which differ in magnitude depending on the conformation (N or S) of the adjoining deoxyribose ring. The S-type deoxyribose ring is associated with a smaller epsilon (trans) angle: epsilon (t,S) = 192 degrees. The N-type deoxyribose ring is associated with a larger epsilon (trans) angle epsilon (t,N) = 212 degrees. The third rotamer participating in the conformational equilibrium, is a gauche(-) (epsilon (-] conformer and occurs exclusively in combination with the S-type sugar ring (epsilon (-,S) = 266 degrees). Within the limits of experimental error, the magnitude of these three angles appears to be independent of the particular base sequence, except in the case of d(CG) where a slightly larger epsilon (t,S) angle (197 degrees) is indicated. A simple equation is proposed which may be used to calculate the population of epsilon (t,S) conformer in cases where only J(H3'-P) is known.     

Conformational study of ribonucleotides, 2′-deoxyribonucleotides,and arabinonucleotides by carbon-13 nuclear magnetic resonance

The geminal and vicinal ¹³C-³¹P coupling constants have been monitored, as a function of pH, for a series of uracil and cytosine 3′- and 5′-nucleotides with a ribose, arabinose, or 2′-deoxyribose sugar. Data were also obtained for two 3′,5′-diphosphates in the ribose and arabinose series. The geminal J(C5′-P5′) and J(C3′-P3′) couplings show only a small dependence on the ionization state of the phosphate, decreasing by < 0.5 Hz in the pH 5–7 range. For the ribose and arabinose 3′-nucleotides, the vicinal J(C4′-P3′) increase (up to 1.5 Hz) on secondary phosphate ionization in the pH 5–7 range, whereas their J(C2′-P3′) couplings decrease (up to 1.5 Hz) over the same pH range. In contrast for the 2′-deoxyribose molecules, both couplings decrease (～0.5 Hz) on phosphate ionization. The titration curves provide information about the influence of the sugar on the conformation about the C3′? O3′ bond. Some conformational trends could be rationalized by consideration of the sugar-puckerdependent contact interactions between the 3′-phosphate and the substituents on the furanose ring.     

Conformationally Restricted 2-Substituted Wyosine Derivatives. 1H, 13C,and 15N NMR Study

Abstract

It was found by ¹H, ¹³C and ¹⁵N NMR study that substitution of 4,9-dihydro-4, 6-dimethyl-9-oxo-3-(2′,3′,5′-tri-O-acetyl-β-D-ribofuranosyl) imidazo [1,2-a]purine (wyosine triacetate, 1) at C2 position with electronegative groups CH₃O and C₆H₅CH₂O results in a noticeable electron distribution disturbance in the “left-hand” imidazole ring and a significant increase in the North conformer population of the sugar moiety.     

Sequence-dependent conformations of DNA duplexes: the TATA segment of the d(G-G-T-A-T-A-C-C) duplex in aqueous solution

The base and sugar protons of the d(G-G-T-A-T-A-C-C) duplex have been assigned from two-dimensional correlated (COSY) and nuclear Overhauser effect (NOESY) measurements in D₂O solution at 25°C. The nucleic acid protons have been assigned from NOEs between protons on adjacent bases on the same and partner strands, as well as from NOEs between the base protons and their own and 5′-flanking H1′, H2′, H2″, H3′, and H4′ sugar protons. These assignments are confirmed from coupling constant and NOE connectivities within the sugar protons of a given residue. Several of these NOEs exhibit directionality and demonstrate that the d(G-G-T-A-T-A-C-C) duplex is a right-handed helix. The relative magnitude of the NOEs between the base protons and the sugar H2′ protons of its own and 5′-flanking sugar demonstrate that the TATA segment of the d(G-G-T-A-T-A-C-C) duplex adopts a B-DNA type helix geometry in solution, in contrast to the previous observation of a A-type helix for the same octanucleotide duplex in the crystalline state.     

Diarylpropanoids from Iryanthera polyneura

The trunk wood of Iryanthera polyneura Ducke (Myristicaceae) contains pinocembrin, 1-(2′,4′-dihydroxyphenyl)-3-(3″,4″-methylenedioxyphenyl)-propane, 1-(2′,4′-dihydroxy-3′-methylphenyl)-3-(2″-methoxy-4″, 5″-methylenedioxyphenyl)-propane and 4,2′,4′-trihydroxy-3-methoxydihydrochalcone.     

1H NMR Assignments and Conformational Analysis of the Oligoribonucleotides CA,CAU, CAUG,ACAUG, and UCAUG: Observation of Pyrimidine H5-H1′ Long-Range Scalar Couplings

Abstract

Conformational analysis and ¹H NMR spectral assignments have been carried out using COSY and RELAY methods for a series of related oligoribonucleotides including two pen- tamers with 5′-dangling bases. Intraresidue long-range five bond scalar coupling was observed between pyrimidine H5 and H1′ protons in the COSY-45 spectra and this feature was useful for both assignment purposes and conformational analysis. The ribose ring conformations were predominantly C3′-endo with the C2′-endo population increasing at the 3′-terminus. The 5′-dangling bases were not stacked efficiently, exhibiting lower % C3′-endo values than their 3′-nearest neighbors. Backbone torsion angle populations, β′, γ⁺, ε′, were determined using ′H-′H, ′H-³¹P, and ¹³C-³¹P coupling constants. From β′ and γ⁺ populations the U3-G4 step in CAUG was found to be less efficiently stacked than the C1-A2 and A2-U3 steps. This observation in solution is consistent with the fiber diffraction A-RNA model (S. Arnott, D.W.L. Hukins, S.D. Dover, W. Fuller and A.R. Hodgson, J. Mol. Biol. 81, 107-122, 1973) which also predicts poor stacking in a U-G dinucleotide. The ε′ populations were >65% for all C3′- O3′ bonds and consistent with a right-handed A-RNA helix.     

Neolignans of Virola carinata bark

Four neolignans, dehydrodieugenol, its monomethylether, carinatone and carinatin have been isolated from the hexane fraction of the bark of Virola carinata. Three new neolignans were separated from the chloroform fraction and examined by spectroscopy and chemical reactions. Their structures were determined as (2S, 3S)-5-allyl- 7-methoxy-3-hydroxymethyl-2-(3′,4′-dimethoxyphenyl)-2,3-dihydrobenzofuran, (2S)- 1-(3′,4′-dimethoxyphenyl)-2-(3″-allyl-5″-methoxy-6″-hydroxyphenyl)propanone(1) ol(3), (1S,2S)-1-(3′,4′-dimethoxyphenyl)-2-(3″-allyl-5″-methoxy-6″-hydroxyphenyl) propanol(1) and called dihydrocarinatinol, carinatonol and carinatol, respectively.     

Quinoline alkaloids and cytotoxic lignans from Haplophyllum tuberculatum

Three quinoline alkaloids and two lignan lactones were isolated from Haplophyllum tuberculatum. Physicochemical and spectral evidence established the structures of two of the alkaloids as a new quinoldione, 3-(1′,1′-dimethylallyl)-3-(3″,3″-dimethylallyl)-1,2,3,4-tetrahydro-2,4-quinoldione and the known 4-(3′,3′-dimethylallyloxy)-3-(3″,3″-dimethylallyl)-2(1H)-quinolone. The former was shown to undergo facile [3,3]-sigmatotropic transformation into the latter. The remaining compounds were identified as the known Polygamain, kusunokinin and 1-methyl-2-n-nonyl-4(1H)-quinolone.     

Diarylpropanes from the wood of Iryanthera grandis

Trunk wood of Iryanthera grandis contains 1(2′-hydroxy-4′,6′-dimethoxyphenyl)-3-(3″,4″-methylenedioxyphenyl)-propane and 1(2′-hydroxy-4′,6′-dimethoxyphenyl)-3-(3″-methoxy-4″-hydroxyphenyl)-propane, as well as three additional known diarylpropanes, a new flavan (±)-5,7-dimethoxy-4′-hydroxyflavan and the known (±)-7,4′-dihydroxy-3′-methoxyflavan.     

Tetronic acid and diarylpropanes from Iryanthera elliptica

The trunk wood of Iryanthera elliptica Ducke (Myristicaceae) contains, besides 2-(ω-piperonyltridecyl) -4-methylidenetetronic acid (iryelliptin), three biogenetically related compounds: (±)-7,4′-dihydroxy-3′-methoxyflavan, 1-(4′-hydroxy-2′-methoxyphenyl)- 3-(4″-hydroxy-3″-methoxyphenyl)-propane and spiro-[3-methoxy-2,5-cyclohexadien-1.1′-6′,7′- dihydroxy-5′-methoxy-1′,2′,3′,4′-tetrahydronaphthalen]-4-one-(spiroelliptin). Spiroelliptin rearranges upon methylation to 2,2′-trimethylene-3,4,5,4′,5′-penta-methoxybiphenyl.     

Sequence-dependent recognition of DNA duplexes: netropsin complexation to the TATA site of the d(G-G-T-A-T-A-C-C) duplex in aqueous solution

We have recorded one-dimensional exchangeable proton and two-dimensional nonexchangeable proton nmr spectra on the complex of netropsin with the self-complementary d(G-G-T-A-T-A-C-C) duplex in aqueous solution between 25° and 35°C. The antibiotic amide, pyrrole, and methylene protons, and the nucleic acid base and sugar H1′, H2′, H2″, and H3′ protons, have been assigned from an analysis of the two-dimensional nuclear Overhauser effect (NOESY) spectra of the complex. We observe intermolecular NOEs between the antibiotic concave face amide, pyrrole, and CH₂ resonances, and the adenosine H2 and sugar H1′ protons of base-pairs T3·A6 and A4·T5 in the central TATA core of the d(G₁-G₂-T₃-A₄-T₅-A₆-C₇-C₈) duplex. We present a molecular model outlining these seven antibiotic-DNA contacts for the complex in solution. The observed line-broadening of several base and sugar protons at the TATA minor groove netropsin binding site in the complex at 35°C are interpreted in terms of intermediate exchange between two orientations of bound netropsin on the duplex.     

NMR study of dideoxynucleotides with anti-human immunodeficiency virus (HIV) activity

The molecular structures of 3′-azido-2′,3′-dideoxyribosylthymine 5′-triphosphate (AZTTP), 2′,3′-dideoxyribosylinosine 5′-triphosphate (ddITP), 3′-azido-2′,3′-dideoxyribosylthymine 5′-monophosphate (AZTMP) and 2′,3′-dideoxyribosyladenine 5′-monophosphate (ddAMP) have been studied by NMR to understand their anti-HIV activity. For ddAMP and ddITP, conformations are almost identical with their nucleoside analogues with sugar ring pucker equilibriating between C3′-endo (∼75%) and C2′-endo (∼25%). AZTMP and AZTTP on the other hand show significant variations in the conformational behaviour compared with 3′-azido-2′,3′-dideoxyribo-sylthymine (AZT). The sugar rings for these nucleotides have a much larger population of C2′-endo (∼75%) conformers, like those observed for natural 2′-deoxynucleosides and nucleotides. The major conformers around C5′-O5′, C4′-C5′ and the glycosidic bonds are the β^t, γ⁺ and anti, respectively.     

Untenability of the Heteronomous DNA Model for Poly(dA) · Poly(dT) in Solution. This DNA Adopts a Right-Handed B-DNA Duplex in Which the Two Strands are Conformationally Equivalent. A 500 MHz NMR Study Using One Dimensional NOE

Abstract

ID NOE ¹H NMR spectroscopy at 500 MHz was employed to examine the structure of poly(dA)·poly(dT) in solution. NOE experiments were conducted as a function of presaturation pulse length (50, 30, 20 and 10 msec) and.power (19 and 20 db) to distinguish the primary NOEs from spin diffusion. The 10 msec NOE experiments took 49 hrs and over 55,000 scans for each case and the difference spectra were almost free from diffusion.

The spin diffused NOE difference spectra as well as difference NOE spectra in 90% H₂O + 10% D₂O in which TNH3 was presaturated enabled to make a complete assignment of the base and sugar protons. It is shown that poly(dA) ·poly(dT) melts in a fashion in which single stranded bubbles are formed with increasing temperature.

Extremely strong primary NOEs were observed at H2′/H2″ when AH8 and TH6 were presaturated. The observed NOEs at AH2′ and that AH2″ were very similar as were the NOEs at TH2′ and TH2″. The observed NOEs at AH2′ and AH2″when AH8 was presaturated were very similar to those observed at TH2′ and TH2″ when TH6 was presaturated. In addition, presaturation of H1′ of A and T residues resulted in similar NOEs at AH2′/H2″ and TH2′/H2″ region and these NOEs at H2′ and H2″ were distinctly asymmetric as expected in a C2′-endo sugar pucker. There was not a trace of NOE at AH8 and TH6 when AH3′ and TH3′ were presaturated indicating that C3′-endo, × = 30–40° conformation is not valid for this DNA. From these NOE data, chemical shift shielding calculations and stereochemistry based computer modellings, we conclude that poly(dA)·poly(dT) in solution adopts a right- handed B-DNA duplex in which both dA and dT strands are conformationally equivalent with C2′-endo sugar pucker and a glycosyl torsion, ×, of ?73°, the remaining backbone torsion angles being φ′ = 221°, ω′ = 212°, ω = 310°, φ = 149°, ψ = 42°, ψ′ = 139°. The experimental data are in total disagreement with the heteronomous DNA model of Arnott et. al. proposed for the fibrous state. (Arnott, S., Chandrasekaran, R., Hall, I.H., and Puigjaner, L.C., Nucl. Acid Res. 11, 4141, 1983).