Chemistry and Biology of Non-canonical Nucleic Acids. Naoki Sugimoto. Читать онлайн. Newlib. NEWLIB.NET

Автор: Naoki Sugimoto
Издательство: John Wiley & Sons Limited
Серия:
Жанр произведения: Химия
Год издания: 0
isbn: 9783527817863
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U/A −2.6 −0.3 0.7 1.1 [1.9]C 2.2 2.8 2.8 A/U −1.9 0.2 0.3 0.6 2.3 2.5 2.8 Schematic illustration of the mismatched G-A and G-G base pairs observed in nucleic acid structures. (a) G-A mismatched base pairs with various compositions in their glycosidic bond angles. (b) Symmetric (left) and asymmetric (right) G-G mismatched base pairs.

      2.2.4 Pyrimidine–Pyrimidine Mismatches

Schematic illustration of the mismatched T-T, C-T, and C-C base pairs observed in nucleic acid structures. (a) Interconvertible T-T mismatched base pairs with wobble-like orientation. (b) C-T mismatched base pairs at neutral form (upper) and a form, in which cytosine nucleobase is protonated (lower). (c) C-C+ mismatched base pairs at wobble-like orientation (upper) and symmetric orientation (lower).

Schematic illustration of the structures of A-type (a) and Z-type (b) DNA duplexes formed in GC-rich sequence. Top views of consecutive G-C base pairs are shown above the entire structure.

      DNA also form Z-type duplex (Z-DNA) (Figure 2.5). Z-DNA with the two strands forming left-handed helix shows a radically different structure from A- and B-DNAs. Phosphate backbone of Z-DNA forms a distinct zigzag pattern, which is an origin of its name, whereas that of B-DNA and A-DNA is uniformly wound to form the helix. Formation of Z-DNA depends on the oligonucleotide sequence that needs alternating purine–pyrimidine sequence such as d(GCGCGC). Guanine nucleotides in Z-DNA show C3′-end conformation in its sugar puckering and syn orientation in its glyosidic bond angle. These features place the guanine nucleobase back over the sugar ring and make the zigzag pattern in the alternating sequence. Z-DNA has a structure feature that the distance between phosphate groups at interstrand is shorter than B-DNA and A-DNA that results in stronger electrostatic repulsion. Therefore, Z-DNA needs a solution having a high salt concentration or low dielectric constant to be stabilized. It is also known that the Z-DNA is stabilized under the condition with a negative twist when the sequence is incorporated in plasmid DNA and applied in a supercoil state. The biological aspects of Z-DNA have gained more attention after the Z-DNA recognition domain has been discovered in proteins involved in gene