抗癌抗生素 Trioxacarcin A 和 LL-D49194α1 的不同 DNA 结合和损伤模式

IF 8.5 Q1 CHEMISTRY, MULTIDISCIPLINARY
Ruo-Qin Gao, Xiao-Dong Hu, Qiang Zhou, Xian-Feng Hou, Chunyang Cao* and Gong-Li Tang*, 
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引用次数: 0

摘要

Trioxacarcin A(TXN)是一种强效细胞毒性抗生素,其结构非常复杂。TXN 与双链 DNA(dsDNA)结合的晶体结构表明,TXN 的相互作用可能取决于两个糖亚基在 dsDNA 小沟和大沟上的位置。LL-D49194α1(LLD)是一种TXN类似物,具有相同的多环多酮支架和独特的糖基化模式。虽然 LLD 已进入 I 期临床试验阶段,但 LLD 与 dsDNA 的结合方式仍不清楚。在这里,我们以高分辨率解决了2″-氟标记的含鸟嘌呤双链体d(A1A2C3C4GFGFT7T8)2及其稳定的LLD和TXN共价结合复合物的溶液结构。结合生化试验,我们发现 TXN 烷基化的 dsDNA 会倾向于保持 DNA 的螺旋构象,而 LLD 烷基化的 dsDNA 比 TXN 烷基化的 dsDNA 更容易失去稳定性,导致 dsDNA 变性。因此,尽管 LLD 在体外的细胞毒性较低,但其糖取代的差异比 TXN 造成了更大的 DNA 损伤,从而带来了全新的生物效应。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Different DNA Binding and Damage Mode between Anticancer Antibiotics Trioxacarcin A and LL-D49194α1

Different DNA Binding and Damage Mode between Anticancer Antibiotics Trioxacarcin A and LL-D49194α1

Trioxacarcin A (TXN) is a highly potent cytotoxic antibiotic with remarkable structural complexity. The crystal structure of TXN bound to double-stranded DNA (dsDNA) suggested that the TXN interaction might depend on positions of two sugar subunits on the minor and major grooves of dsDNA. LL-D49194α1 (LLD) is a TXN analogue bearing the same polycyclic polyketide scaffold with a distinct glycosylation pattern. Although LLD was in a phase I clinical trial, how LLD binds to dsDNA remains unclear. Here, we solved the solution structures at high resolutions of palindromic 2″-fluorine-labeled guanine-containing duplex d(A1A2C3C4GFGFT7T8)2 and of its stable LLD and TXN covalently bound complexes. Combined with biochemical assays, we found that TXN-alkylated dsDNA would tend to keep DNA helix conformation, while LLD-alkylated dsDNA lost its stability more than TXN-alkylated dsDNA, leading to dsDNA denaturation. Thus, despite lower cytotoxicity in vitro, the differences of sugar substitutions in LLD caused greater DNA damage than TXN, thereby bringing about a completely new biological effect.

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CiteScore
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