On-DNA C–H functionalization of electron-rich arenes for DNA-encoded libraries

IF 19.2 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Nature chemistry Pub Date : 2025-06-16 DOI:10.1038/s41557-025-01844-6

Eduardo de Pedro Beato, Luca Torkowski, Philipp Hartmann, Lara Vogelsang, Karl-Josef Dietz, Tobias Ritter

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Abstract

DNA-encoded libraries (DELs) are useful for hit discovery in the pharmaceutical industry. Although a large number of individually coded molecules are accessible through DELs, their structural diversity is limited because few transformations are benign and chemoselective enough to be applied in the presence of DNA in aqueous environments. In particular, C–H functionalization chemistry that could be ideally suited to increase structural diversity through late-stage functionalization is currently absent from DEL synthesis. Here we present a general C–H functionalization of electron-rich arenes on DNA. The development of a selenoxide reagent is key to achieving the regio- and chemoselective formation of arylselenonium salts in aqueous media. The introduction of arylselenonium salts offers a versatile linchpin on DNA conjugates, which gives access to a multitude of analogues through diverse subsequent reactions, including transition-metal-mediated and photochemical transformations for the formation of C–C, C–I and C–S bonds.

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dna编码文库中富电子芳烃在dna上的碳氢功能化

dna编码文库（DELs）对制药行业的hit发现非常有用。尽管通过DELs可以获得大量单独编码的分子，但它们的结构多样性是有限的，因为很少有转化是良性的，并且具有化学选择性，足以在水环境中应用于DNA的存在。特别是，C-H功能化化学可以通过后期功能化来理想地增加结构多样性，目前在DEL合成中缺乏。在这里，我们提出了富电子芳烃在DNA上的一般碳氢功能化。硒氧化物试剂的研制是实现芳基硒鎓盐在水介质中区域选择性和化学选择性生成的关键。芳基硒鎓盐的引入为DNA偶联物提供了一个多功能的关键，它可以通过各种后续反应获得大量类似物，包括过渡金属介导的光化学转化，形成C-C， C-I和C-S键。

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来源期刊

Nature chemistry 化学-化学综合

CiteScore

29.60

自引率

1.40%

发文量

226

审稿时长

1.7 months

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