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  • Title: Conformational studies of 13 trinucleoside bisphosphates by 360-MHz 1H-NMR spectroscopy. 1. Ribose protons.
    Author: Lee CH.
    Journal: Eur J Biochem; 1983 Dec 01; 137(1-2):347-56. PubMed ID: 6317391.
    Abstract:
    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.
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