Structure of guanylyl-3',5'-cytidine monophosphate. II. Description of the molecular and crystal structure of the calcium derivative in space group P2(1)

Structure-spectrum correlations in nucleic acids. I. Raman lines in the 600-700 cm-1 range of guanosine residue

Raman spectra of nine crystals of known structures which involve guanosine moieties with various conformations have been observed. It has been established that a guanosine residue with the C3'endo-anti conformation gives a strong Raman line at 666 +/- 2 cm-1. It has also been found that the residue with 04'endo-anti gives a strong Raman line at 682 cm-1, and C3'exo-syn at 616 cm-1. The usefulness of these structure-spectrum correlations in the conformation studies of polynucleotides are shown.

Conformational studies of 13 trinucleoside bisphosphates by 360-MHz 1H-NMR spectroscopy. 1. Ribose protons

The ribose protons of 13 trinucleoside bisphosphates (trimers) were studied, using 360-MHz proton nuclear magnetic resonance spectroscopy. Complete assignments and analyses of the NMR signals of these protons were carried out by the methods of homonuclear decoupling and computer line-shape simulations. It was shown that the trinucleotides preferred the anti, 3' endo, gamma +, beta t and epsilon t/epsilon- conformations for the glycosidic torsions, the ribose rings, the C4'-C5' bonds, the C5'-O5' bonds, and the C3'-O3' bonds, respectively. It was also found that the trimers, especially those which had noticeable population of 'bulged' structures, did not necessarily have a higher population of these preferred local conformations than their component dimers. The overall conformations of the trinucleotides are classified into two categories. The conformations in the first category involve the nearest-neighbor interactions. Each dinucleotide moiety can assume one of the four stable conformations (I, I', II and III) or the open forms of dinucleoside monophosphates. However, due to steric hindrance, there are only four cases in which both dinucleotide moieties can assume one of the four stable conformations at the same time. These four combinations of conformations are I-I, I'-I', I-II and III-I', where the first Roman numeral represents the conformation of the NpN'p-moiety and the second one, that of the -pN'pN'' moiety of the trimers. Among them, I-I and I'-I' are helical structures, capable of forming a double helix. The second category contains conformations with bulged structures which have the two dinucleotide moieties in open forms (i.e. no nearest-neighbor interactions) and the bases of the two terminal residues stacking on each other while the middle residue is bulged out. These bulged conformations may serve as structural models for frame-shift mutations.

A nuclear magnetic resonance study of the ribotrinucleoside diphophate UpUpC

500 MHz 1H, 67.89 MHz 13C and 80.97 MHz 31P-NMR studies are reported on the ribotrinucleoside diphosphate UpUpC, the triplet codon corresponding to the amino acid phenylalanine. Complete spectral assignments are given and conformational parameters for the backbone and the furanose rings are determined. All three nucleotide units show a near-balance for the N/S equilibrium with a slight preference for the N-type ribose (approximately 60%). The backbone conformation around the C3'-03' bonds show a preference for the trans domain, while the orientation around the C5'-05' bonds is predominantly trans.

Raman diagnosis of nucleic acid structure: sugar-puckering and glycosidic conformation in the guanosine moiety

Observations of Raman spectra of various nucleic acids indicate that the guanine ring breathing frequency is sensitive to the internal rotation angle around the glycosidic bond and to the conformation of the five-membered ring of the ribose residue that is directly connected with the guanine residue in question. It is found that 682 cm-1 for C2'-endo-anti, at 665 cm-1 for C3'-endo-anti, and at 625 cm-1 for C3'-endo-syn. A DNA octamer d(GpGpApApTpTpCpC) shows, in its aqueous solution, a broad Raman band at 680 cm-1 with a tail at 670 cm-1. This fact suggests that the guanosine residues in this oligomer take primarily C2'-endo-anti conformation but an appreciable amount of fluctuation of the ribose ring structure towards C3'-endo is involved.

Why do nucleic acids have 3'5' phosphodiester bonds?

Details of the stereochemistry of the 2'5' and 3'5' dinucleoside monophosphates of polynucleotides have been delineated in aqueous solution using nuclear magnetic resonance spectroscopy. Incorporation of these experimentally determined geometries into the structure of polynucleotides reveals that the intrinsic spatial configurations of the 2'5' bonds cannot support helical structures whereas the geometries of 3'5' bonds allow the formation of helical configurations for RNA.

Structure of a dinucleoside phosphate--drug complex as model for nucleic acid--drug interaction

The crystal structure of a 3:2 complex of the frameshift mutagen proflavine with the dinucleoside phosphate cytidylyl-3'5'-guanosine has been determined. The complex has one drug molecule intercalated between Watson--Crick base pairs of the nucleotide duplex. The other two proflavine molecules are bound to the exterior of the miniature double helix. The orientation of the base pairs in this miniature double helix has aspects similar to that found in RNA 11.

The effect of (2'-5') and (3'-5') phosphodiester linkages on conformational and stacking properties of cytidylyl-cytidine in aqueous solution

Conformational properties of (2'-5') and (3'-5') CpC have been determined by proton magnetic resonance spectroscopy at 220 MHz. The ribose ring structures are predominantly 3E with the exception of the ring from the 2'-phosphate fragment of C(2'-5')pC which exhibits an 2E pucker. Bases are oriented anti with respect to the ribose and the conformations about C4'-C5', C5'-O5', C3'-O3' (C2'-O2') are gg, g'g', and g+ in equilibrium g-, respectively. The dimers exist as mixtures of stacked (g+g+ and g-g- about the P-O(C) bonds) and unstacked species at 20 degrees C. Stacking is estimated to be 35% in both dimers.