Mao B, Gorin A, Gu Z, Hingerty B E, Broyde S, Patel D J
Cellular Biochemistry and Biophysics Program, Memorial Sloan-Kettering Cancer Center, New York, New York 10021, USA.
Biochemistry. 1997 Nov 25;36(47):14479-90. doi: 10.1021/bi972205z.
This paper addresses structural issues related to the capacity of aminofluorene [AF] for frameshift mutations of the -2 type on C8 covalent adduct formation at the G3 site in the d(C-G1-G2-C-G3-C-C) NarI hot spot sequence. This problem has been approached from a combined NMR and relaxation matrix analysis computational structural study of the [AF]dG adduct in the d(C-G-G-C-[AF]G-C-C).d(G-G-C-C-G) sequence context at the 12/10-mer adduct level (designated [AF]dG.del(-2) 12/10-mer). The proton spectra of this system are of exceptional quality and are consistent with the formation of an AF-intercalated conformer with the modified guanine in a syn alignment displaced along with the 5'-flanking cytosine residue into the major groove. The solution structure has been determined by initially incorporating intramolecular and intermolecular proton-proton distances defined by lower and upper bound deduced from NOESY spectra as restraints in molecular mechanics computations in torsion angle space and subsequently refined through restrainted molecular dynamics calculations based on a NOE distance and intensity refinement protocol. Strikingly, the [AF]dG.del(-2) 12/10-mer duplex adopts only one of two potential AF-intercalation alignments for the [AF]dG adduct opposite the -2 deletion site in the NarI sequence context with the extrusion of the dC-[AF]dG step favored completely over extrusion of the [AF]dG-dC step at the lesion site. This polarity establishes that the structural perturbation extends 5' rather than 3' to the [AF]dG lesion site in the adduct duplex. This structure of the [AF]dG adduct opposite a -2 deletion site shows distinct differences with conclusions reported on the alignment of the related acetylaminofluorene [AAF]dG adduct opposite a -2 deletion site in the identical NarI sequence context [Milhe, C., Fuchs, R. P. P., and Lefevre, J. F. (1996) Eur. J. Biochem. 235, 120-127]. In that study, qualitative NMR data without computational analysis were employed to conclude that the extrusion at the lesion site occurs at the [AAF]dG-dC step for the AAF-intercalated conformer of the adduct duplex. The structure of the [AF]dG adduct opposite a -2 deletion site determined in our group provides molecular insights into the architecture of extended slipped mutagenic intermediates involving aromatic amine intercalation and base-displaced syn modified guanines in AF and, by analogy, AAF-induced mutagenesis in the NarI hot spot sequence context.
本文探讨了氨基芴[AF]在d(C-G1-G2-C-G3-C-C)NarI热点序列的G3位点形成C8共价加合物时产生-2型移码突变的能力相关的结构问题。该问题是通过对d(C-G-G-C-[AF]G-C-C).d(G-G-C-C-G)序列背景下12/10-mer加合物水平(命名为[AF]dG.del(-2) 12/10-mer)的[AF]dG加合物进行核磁共振(NMR)和弛豫矩阵分析计算结构研究来解决的。该系统的质子谱质量极佳,与形成一种AF插入构象一致,其中修饰的鸟嘌呤处于顺式排列,与5'-侧翼胞嘧啶残基一起位移到了大沟中。溶液结构的确定过程如下:首先在扭转角空间的分子力学计算中,将由NOESY谱推导的上下限定义的分子内和分子间质子-质子距离作为约束条件纳入,随后基于NOE距离和强度优化协议通过约束分子动力学计算进行优化。引人注目的是,在NarI序列背景下,[AF]dG.del(-2) 12/10-mer双链体在-2缺失位点对面的[AF]dG加合物仅采用两种潜在的AF插入排列中的一种,dC-[AF]dG步的挤出在损伤位点完全优先于[AF]dG-dC步的挤出。这种极性表明结构扰动在加合物双链体中延伸至[AF]dG损伤位点的5'端而非3'端。在相同NarI序列背景下,与-2缺失位点相对的[AF]dG加合物的这种结构与关于相关乙酰氨基芴[AAF]dG加合物在-2缺失位点对面排列的报道结论[Milhe, C., Fuchs, R. P. P., and Lefevre, J. F. (1996) Eur. J. Biochem. 235, 120 - 127]存在明显差异。在该研究中,采用了未经计算分析的定性NMR数据来得出结论,即对于加合物双链体的AAF插入构象,损伤位点的挤出发生在[AAF]dG-dC步。我们小组确定的与-2缺失位点相对的[AF]dG加合物的结构,为涉及AF中芳香胺插入和碱基位移顺式修饰鸟嘌呤的延伸滑动诱变中间体的结构,以及类推的NarI热点序列背景下AAF诱导的诱变,提供了分子层面的见解。
