在小沟中定义鸟嘌呤-胞嘧啶特异性：双咪唑左旋肌动蛋白与C-A-T-G-G-C-C-A-T-G的并排结合

Defining GC-specificity in the minor groove: side-by-side binding of the di-imidazole lexitropsin to C-A-T-G-G-C-C-A-T-G.

作者信息

Kopka M L, Goodsell D S, Han G W, Chiu T K, Lown J W, Dickerson R E

机构信息

Molecular Biology Institute, University of California at Los Angeles 90095, USA.

出版信息

Structure. 1997 Aug 15;5(8):1033-46. doi: 10.1016/s0969-2126(97)00255-4.

DOI:10.1016/s0969-2126(97)00255-4

PMID:9309219

Abstract

BACKGROUND

Polyamide drugs, such as netropsin, distamycin and their lexitropsin derivatives, can be inserted into a narrow B-DNA minor groove to form 1:1 complexes that can distinguish AT base pairs from GC, but cannot detect end-for-end base-pair reversals such as TA for AT. In contrast, 2:1 side-by-side polyamide drug complexes potentially are capable of such discrimination. Imidazole (Im) and pyrrole (Py) rings side-by-side read a GC base pair with the Im ring recognizing the guanine side. But the reason for this specific G-Im association is unclear because the guanine NH2 group sits in the center of the groove. A 2:1 drug:DNA complex that presents Im at both ends of a GC base pair should help unscramble the issue of imidazole reading specificity.

RESULTS

We have determined the crystal structure of a 2:1 complex of a di-imidazole lexitropsin (DIM), an analogue of distamycin, and a DNA decamer with the sequence C-A-T-G-G-C-C-A-T-G. The two DIM molecules sit antiparallel to one another in a broad minor groove, with their cationic tails widely separated. Im rings of one drug molecule stack against amide groups of the other. DIM1 rests against nucleotides C7A8T9G10 of strand 1 of the helix, whereas DIM2 rests against G14G15C16C17 on strand 2. All DIM amide nitrogens donate hydrogen bonds to N and O atoms on the floor of the DNA groove and, in addition, the two Im rings on DIM2 accept hydrogen bonds from guanine N2 amines, thereby providing specific reading. The guanine N2 amine can bond to Im on its own side of the groove, but not on the cytosine side, because of limits on close approach of the two Im rings and the geometry of sp2 hybridization about the amide nitrogen.

CONCLUSIONS

Im and Py rings distinguish AT from GC base pairs because of steric factors involving the bulk of the guanine amine, and the ability of Im to form a hydrogen bond with the amine. Side-by-side Im and Py rings differentiate GC from CG base pairs because of tight steric contacts and sp2 hybridization at the amine nitrogen atom, with the favored conformations being G/Im,Py/C and C/Py,Im/G. Discrimination between AT and TA base pairs may be possible using bulkier rings, such as thiazole to select the A end of the base pair.

摘要

背景

聚酰胺药物，如纺锤菌素、偏端霉素及其左旋异构体衍生物，可插入狭窄的B - DNA小沟中形成1:1复合物，该复合物能区分AT碱基对和GC碱基对，但无法检测端对端碱基对的反转，如TA替代AT。相比之下，2:1的并排聚酰胺药物复合物可能具备这种区分能力。咪唑（Im）和吡咯（Py）环并排读取GC碱基对，其中Im环识别鸟嘌呤一侧。但这种特定的G - Im关联的原因尚不清楚，因为鸟嘌呤的NH₂基团位于小沟中央。一个在GC碱基对两端都呈现Im的2:1药物:DNA复合物应有助于解开咪唑读取特异性的问题。

结果

我们确定了双咪唑左旋异构体（DIM，偏端霉素的一种类似物）与序列为C - A - T - G - G - C - C - A - T - G的DNA十聚体形成的2:1复合物的晶体结构。两个DIM分子在宽阔的小沟中反平行排列，它们的阳离子尾部相距甚远。一个药物分子的Im环与另一个的酰胺基团堆叠。DIM1靠在螺旋链1的核苷酸C7A8T9G10上，而DIM2靠在链2上的G14G15C16C17上。所有DIM酰胺氮原子都与DNA小沟底部的N和O原子形成氢键，此外，DIM2上的两个Im环接受来自鸟嘌呤N2胺的氢键，从而实现特异性读取。由于两个Im环靠近的限制以及酰胺氮周围sp²杂化的几何结构，鸟嘌呤N2胺只能与小沟中其自身一侧的Im形成氢键，而不能与胞嘧啶一侧的Im形成氢键。

结论

由于涉及鸟嘌呤胺体积的空间因素以及Im与胺形成氢键的能力，Im和Py环能够区分AT和GC碱基对。并排的Im和Py环由于紧密的空间接触以及胺氮原子处的sp²杂化，能够区分GC和CG碱基对，偏好的构象为G/Im,Py/C和C/Py,Im/G。使用更大的环，如噻唑来选择碱基对的A端，可能实现对AT和TA碱基对的区分。