Selenium-Centered Cascade Exchangers and Conformational Control Unlock Unique Patterns of Thiol-Mediated Cellular Uptake

Filipe Coelho, Lukas Zeisel, Prof. Oliver Thorn-Seshold, Prof. Stefan Matile
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Abstract

Dynamic-covalent electrophiles called cascade exchangers (CAXs) can reversibly engage cell-surface thiols. Conjugates between CAXs and molecular or even protein-sized cargos can deliver these cargos into cells by thiol-mediated uptake (TMU); free CAXs can also hinder TMU presumably by competing for thiol exchange sites. So far, three orthogonal networks of cellular thiol exchange partners have been identified to participate in TMU, centering on the transferrin receptor, integrins, and protein disulfide isomerases. This study introduces cyclic selenenylsulfides as a new CAX type, with polarised reactivity that brings important differences from the known disulfide and diselenide CAXs. Additionally, this study introduces methods to modulate CAX activity by employing remote functional groups to tune ring re-closure rates, e. g. via thiolate de/stabilization by hydrogen bonding and ion pairing. Differently to all CAXs known, Se-centred CAXs participate in two different TMU networks (integrins preferred, PDIA3 tolerated). When free, the remotely tuned Se-centred CAXs were strong inhibitors of most TMU systems, but again brought a novel feature: they increased the uptake of tetrel-centred Michael acceptor CAXs, making them the first free CAX we know of that can accelerate TMU. We conclude that Se- and tetrel-centred CAXs share a cellular thiol exchange partner that hinders TMU, which may be a target for improving the delivery of Michael acceptor drugs. The unique thiol exchange partner patterns generated by Se-centered CAXs with remotely tuned ring closure motifs support that they will prove a valuable tool to help decode TMU and achieve chemical control over cellular entry on the molecular level.

Abstract Image

以硒为中心的级联交换器和构象控制揭开了硫醇介导的细胞摄取的独特模式
被称为级联交换体(CAXs)的动态共价亲电体可以可逆地与细胞表面的硫醇结合。CAXs 与分子甚至蛋白质大小的载体之间的共轭物可以通过硫醇介导的摄取(TMU)将这些载体送入细胞;游离的 CAXs 也可能通过竞争硫醇交换位点而阻碍 TMU。迄今为止,已发现有三个正交的细胞硫醇交换伙伴网络参与了 TMU,它们分别以转铁蛋白受体、整合素和蛋白二硫异构酶为中心。本研究将环硒硫化物作为一种新的 CAX 类型引入,它具有极化反应活性,与已知的二硫化物和二硒化物 CAX 有着重要区别。此外,本研究还介绍了利用远程官能团调节 CAX 活性的方法,例如通过氢键和离子配对的硫醇脱/稳定作用来调节环的再闭合速率。与已知的所有 CAX 不同,以硫酸盐为中心的 CAX 参与两种不同的 TMU 网络(整合素优先,PDIA3 可容忍)。当自由时,远程调谐的以 Se 为中心的 CAX 对大多数 TMU 系统有很强的抑制作用,但同样带来了一个新的特征:它们增加了以四面体为中心的迈克尔受体 CAX 的吸收,使它们成为我们所知的第一个能加速 TMU 的自由 CAX。我们得出结论:以硒和四羟基为中心的 CAX 有一个共同的细胞硫醇交换伙伴,会阻碍 TMU,这可能是改善迈克尔受体药物递送的一个目标。以 Se 为中心的 CAX 生成的独特硫醇交换伙伴模式具有远程调整的闭环图案,这支持它们将被证明是一种有价值的工具,有助于解码 TMU 并在分子水平上实现对细胞进入的化学控制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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