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喹啉类化合物能够抑制多种作用于DNA的酶。

Quinoline-based compounds can inhibit diverse enzymes that act on DNA.

作者信息

Zhou Jujun, Chen Qin, Ren Ren, Yang Jie, Liu Bigang, Horton John R, Chang Caleb, Li Chuxuan, Maksoud Leora, Yang Yifei, Rotili Dante, Jain Abhinav K, Zhang Xing, Blumenthal Robert M, Chen Taiping, Gao Yang, Valente Sergio, Mai Antonello, Cheng Xiaodong

机构信息

Department of Epigenetics and Molecular Carcinogenesis, University of Texas MD Anderson Cancer Center, Houston, TX 77030, USA.

Department of Biosciences, Rice University, Houston, TX 77005, USA.

出版信息

Cell Chem Biol. 2024 Dec 19;31(12):2112-2127.e6. doi: 10.1016/j.chembiol.2024.09.007. Epub 2024 Oct 21.

DOI:10.1016/j.chembiol.2024.09.007
PMID:39437789
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11663113/
Abstract

DNA methylation, as exemplified by cytosine-C5 methylation in mammals and adenine-N6 methylation in bacteria, is a key epigenetic process. Developing non-nucleoside inhibitors to cause DNA hypomethylation is crucial for treating various conditions without the toxicities associated with existing cytidine-based hypomethylating agents. This study characterized fifteen quinoline-based analogs, particularly compounds with additions like a methylamine (9) or methylpiperazine (11), which demonstrate similar low micromolar inhibitory potency against human DNMT1 and Clostridioides difficile CamA. These compounds (9 and 11) intercalate into CamA-bound DNA via the minor groove, causing a conformational shift that moves the catalytic domain away from the DNA. This study adds to the limited examples of DNA methyltransferases being inhibited by non-nucleotide compounds through DNA intercalation. Additionally, some quinoline-based analogs inhibit other DNA-interacting enzymes, such as polymerases and base excision repair glycosylases. Finally, compound 11 elicits DNA damage response via p53 activation in cancer cells.

摘要

DNA甲基化,如哺乳动物中的胞嘧啶C5甲基化和细菌中的腺嘌呤N6甲基化,是一个关键的表观遗传过程。开发非核苷抑制剂以引起DNA低甲基化对于治疗各种病症至关重要,且不会产生与现有基于胞苷的低甲基化剂相关的毒性。本研究对十五种基于喹啉的类似物进行了表征,特别是含有甲胺(9)或甲基哌嗪(11)等基团的化合物,它们对人DNMT1和艰难梭菌CamA表现出类似的低微摩尔抑制效力。这些化合物(9和11)通过小沟插入与CamA结合的DNA中,引起构象变化,使催化结构域远离DNA。本研究增加了通过DNA插入被非核苷酸化合物抑制的DNA甲基转移酶的有限实例。此外,一些基于喹啉的类似物还抑制其他与DNA相互作用的酶,如聚合酶和碱基切除修复糖基化酶。最后,化合物11在癌细胞中通过p53激活引发DNA损伤反应。

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