ISDA: 1AF1

Deposition Date 1997-03-20

Release Date 1997-08-20

Last Version Date 2024-05-22

Entry Detail

PDB ID:

1AF1

Keywords:

DNA

Title:

THE SOLUTION NMR STRUCTURE OF AN R-STYRENE OXIDE ADDUCT AT THE N2 POSITION OF GUANINE OF AN 11 BASE-PAIR OLIGONUCLEOTIDE SEQUENCE CODING FOR AMINO ACIDS 11-13 OF THE PRODUCT OF THE N-RAS PROTOONCOGENE, MINIMIZED AVERAGE STRUCTURE

Biological Source:

Source Organism:

Method Details:

Experimental Method:

SOLUTION NMR

Conformers Calculated:

Conformers Submitted:

Selection Criteria:

THIS STRUCTURE PROVIDED THE BEST-FIT FOR THE NOE DATA BASED ON THE RELAXATION MATRIX ANALYSIS USING CORMA.

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Macromolecular Entities

Polymer Type:polydeoxyribonucleotide
Molecule:DNA (5'-D(*GP*GP*CP*AP*GP*GSRP*TP*GP*GP*TP*G)-3')
Chain IDs:A
Chain Length:11
Number of Molecules:1
Biological Source:

Polymer Type:polydeoxyribonucleotide
Molecule:DNA (5'-D(*CP*AP*CP*CP*AP*CP*CP*TP*GP*CP*C)-3')
Chain IDs:B
Chain Length:11
Number of Molecules:1
Biological Source:

Modified Residue

Compound ID	Chain ID	Parent Comp ID	Details	2D Image
GSR	A	DG	?

Ligand Molecules

Primary Citation

Styrene oxide adducts in an oligodeoxynucleotide containing the human N-ras codon 12 sequence: structural refinement of the minor groove R(12,2)- and S(12,2)-alpha-(N2-guanyl) stereoisomers from 1H NMR.

Zegar, I.S, Setayesh, F.R, DeCorte, B.L, Harris, C.M, Harris, T.M, Stone, M.P.Show

Biochemistry 35 4334 4348 (1996)

PMID: 8605182 DOI: 10.1021/bi952086s

Abstact

The structures of the (R)- and (S)-alpha-(N2-guanyl)styrene oxide adducts at X6 in d(GGCAGXTGGTG).d(CACCACCTGCC), encompassing codon 12 of the human n-ras protooncogene (underlined), were refined from 1H NMR data. These were the R(12,2) and S(12,2) adducts. For the R(12,2) adduct, upfield chemical shifts were observed for the T7 H6, H1', and N3H resonances. At 30 degrees C, R-SOG 6 N1H, T7 N3H, and T10 N3H disappeared due to exchange with solvent. For the S(12,2) adduct, S-SOG6 H1' shifted upfield 0.33 ppm, but all imino resonances were observed. The styrene methylene protons were nonequivalent for both adducts, suggesting hydrogen bonding between the hydroxyl and C18 O2 or O4' in the R(12,2) adduct and C17 O2 in the S(12,2) adduct. The styrene aromatic protons appeared as three signals in the R(12,2) adduct and as two signals in the S(12,2) adduct, suggesting rapid rotation of the styrene ring on the NMR time scale. NOE data revealed that the phenyl ring was oriented in the 3'-direction relative to R-SOG6 for the R(12,2) adduct and in the 5'-direction relative to S-SOG6 for the S(12,2) adduct. A total of 253 and 221 interproton distances were obtained from relaxation matrix analyses of the R(12,2) and S(12,2) adducts, respectively. NOE-restrained molecular dynamics calculations converged with root mean square deviations of 0.8-1.2 A for the R(12,2) adduct and 0.82-1.4 A for the S(12,2) adduct. Complete relaxation matrix analyses of the nine inner base pairs yielded sixth root residual indices between calculated and experimental NOE intensities of 8.8 x 10(-2) for the R(12,2) adduct and 7.9 x 10(-2) for the S(12,2) adduct. The refined structure for the R(12,2) adduct showed a 0.4 A increase in the stretch of R-SOG6.C17 and T7.A16, and a 1-2 A widening of the minor groove at and adjacent to the SO lesion, with the styrene ring oriented edgewise in the minor groove. Smaller minor groove disturbances were observed for the S(12,2) adduct, which had the styrene ring oriented flat in the minor groove. No DNA bending was predicted by the calculated structures.

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