| Literature DB >> 29997840 |
Richard A Manderville1, Stacey D Wetmore2.
Abstract
Aryl radical species derived from enzymatic transformations of aromatic mutagens preferentially react at the 8-site of the guanine (G)Entities:
Year: 2016 PMID: 29997840 PMCID: PMC6007177 DOI: 10.1039/c6sc00053c
Source DB: PubMed Journal: Chem Sci ISSN: 2041-6520 Impact factor: 9.825
Fig. 1(a) Structures of 8oxoG and 8arylG adducts with different linkages. (b) Structures of mutagens that produce the different 8arylG adducts.
Fig. 2Structures of B-form and Z-form DNA duplexes and an intramolecular antiparallel G-quadruplex (GQ).
Fig. 3(a) Syn (left) and anti (right) structures of PhG. The dihedral angle χ (∠(O4′–C1′–N9–C4)) defines the glycosidic bond orientation to be anti (χ = 180 ± 90°) or syn (χ = 0 ± 90°) and θ (∠(N9–C8–C10–C11)) defines the degree of twist between the nucleobase and the 8-phenyl substituent. (b) Structures of 8arylG probes.
Scheme 1Acid-catalyzed hydrolysis of 2′-deoxyguanosine.
Fig. 4(a) Methods for synthesis of oligonucleotides containing modified DNA bases at defined positions. (b) Postsynthetic Suzuki–Miyaura cross-coupling of 8BrG-modified oligonucleotides for synthesis of 8arylG-modified DNA substrates. (c) Utility of the DMPx group for solid-phase synthesis of oligonucleotides containing acid-sensitive 8arylG adducts.
Fig. 5Depictions of the three major conformations produced by 8arylG adducts, various 8aryl groups used to model C-linked 8arylG adducts and oligonucleotide sequences of NarI(12) and NarI(22).
Fig. 6(a) Proposed model for two-base slippage induced by N-linked 8arylG lesions in a CpG dinucleotide repeat sequence. (b) Thermal melting (Tm) values for 8arylG lesions in full-length relative to truncated NarI(12) duplexes. (c) Most stable MD structures of QG (quinolyl group in red, G nucleobase in green) in NarI(12) paired opposite C (anti-QG:C), within the truncated duplex (syn-QG:–2) and emission spectra (λex = 330 nm) of QG within the full-length (solid black trace) and truncated (dashed red trace) duplexes.
Fig. 7Representative MD structures and relative stability (ΔG, kJ mol–1) of the B (left), W (middle) and S (right) conformers of the monoanionic OTAG adduct incorporated into the (a) G1, (b) G2 or (c) G3 position in the NarI(12) duplex.
Fig. 8Structures of a G-tetrad and the basket, hybrid and propeller folds of GQs produced by HTelo22. The 8arylG probe FurG was inserted into positions 3, 4, 8 or 10 of the GQs, anti-Gs are shown in brown, syn-Gs are shown in green.
Fig. 9TBA sequence with G5, G6 and G8 highlighted in red, blue and green, respectively. Excitation and emission spectra for mTBA with duplexes as dashed traces, GQs solid traces and different colours for the various positions of the 8arylG probe within mTBA. Thermal melting parameters for duplex (d) and GQ in K+ solution for mTBA compared to the unmodified sequence.
Fig. 10(a) Schematic for FRET in TBA using FurG as the donor (D, λex = 315 nm) paired with an acceptor (A, λem = 470 nm) in the G-tetrad. (b) Structure of the A probe vBthG. (c) Emission spectra (λex = 315 nm) of mTBA in K+-solution with FurG (D, syn-G10) in the absence (blue trace) and presence (red trace) of vBthG (A, syn-G5) for a FRET efficiency of 88% in the antiparallel GQ. (d) Thrombin emission titration with mTBA (D/A, 10; 5) with λex = 315 nm.