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Resolution of Identity in Gas-Phase Dissociations of Mono- and Diprotonated DNA Trinucleotide Codons by 15N-Labeling and Computational Structure Analysis

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    0561449 - ÚOCHB 2023 RIV US eng J - Journal Article
    Wan, J. - Brož, Břetislav - Liu, Y. - Huang, S. R. - Marek, Aleš - Tureček, F.
    Resolution of Identity in Gas-Phase Dissociations of Mono- and Diprotonated DNA Trinucleotide Codons by 15N-Labeling and Computational Structure Analysis.
    Journal of the American Society for Mass Spectrometry. Roč. 33, č. 10 (2022), s. 1936-1950. ISSN 1044-0305. E-ISSN 1879-1123
    R&D Projects: GA MŠMT(CZ) LTAUSA19094
    Institutional support: RVO:61388963
    Keywords : tandem mass spectrometry * glycosidic bond cleavage * action spectroscopy
    OECD category: Analytical chemistry
    Impact factor: 3.2, year: 2022
    Method of publishing: Limited access
    https://doi.org/10.1021/jasms.2c00194

    Dissociations of DNA trinucleotide codons as gas-phase singly and doubly protonated ions were studied by tandem mass spectrometry using 15N-labeling to resolve identity in the nucleobase loss and backbone cleavages. The monocations showed different distributions of nucleobase loss from the 5′-, middle, and 3′-positions depending on the nucleobase, favoring cytosine over guanine, adenine, and thymine in an ensemble-averaged 62:27:11:<1 ratio. The distribution for the loss of the 5′-, middle, and 3′-nucleobase was 49:18:33, favoring the 5′-nucleobase, but also depending on its nature. The formation of sequence w2+ ions was unambiguously established for all codon mono- and dications. Structures of low-Gibbs-energy protomers and conformers of dAAA+, dGGG+, dCCC+, dTTT+, dACA+, and dATC+ were established by Born–Oppenheimer molecular dynamics and density functional theory calculations. Monocations containing guanine favored classical structures protonated at guanine N7. Structures containing adenine and cytosine produced classical nucleobase-protonated isomers as well as zwitterions in which two protonated bases were combined with a phosphate anion. Protonation at thymine was disfavored. Low threshold energies for nucleobase loss allowed extensive proton migration to occur prior to dissociation. Loss of the nucleobase from monocations was assisted by neighboring group participation in nucleophilic addition or proton abstraction, as well as allosteric proton migrations remote from the reaction center. The optimized structures of diprotonated isomers for dAAA2+ and dACA2+ revealed combinations of classical and zwitterionic structures. The threshold and transition-state energies for nucleobase-ion loss from dications were low, resulting in facile dissociations involving cytosine, guanine, and adenine.
    Permanent Link: https://hdl.handle.net/11104/0334066

     
     
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