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氧化还原控制的化学蛋白质合成:潜伏的种种变化。

Redox-Controlled Chemical Protein Synthesis: Sundry Shades of Latency.

机构信息

Univ. Lille, CNRS, Inserm, CHU Lille, Institut Pasteur de Lille, U1019-UMR 9017, Center for Infection and Immunity of Lille, F-59000 Lille, France.

Centrale Lille, F-59000 Lille, France.

出版信息

Acc Chem Res. 2022 Sep 20;55(18):2685-2697. doi: 10.1021/acs.accounts.2c00436. Epub 2022 Sep 9.

DOI:10.1021/acs.accounts.2c00436
PMID:36083810
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9494750/
Abstract

The last two decades have witnessed the rise in power of chemical protein synthesis to the point where it now constitutes an established corpus of synthetic methods efficiently complementing biological approaches. One factor explaining this spectacular evolution is the emergence of a new class of chemoselective reactions enabling the formation of native peptide bonds between two unprotected peptidic segments, also known as native ligation reactions. In recent years, their application has fueled the production of homogeneous batches of large and highly decorated protein targets with a control of their composition at the atomic level. In doing so, native ligation reactions have provided the means for successful applications in chemical biology, medicinal chemistry, materials science, and nanotechnology research.The native chemical ligation (NCL) reaction has had a major impact on the field by enabling the chemoselective formation of a native peptide bond between a C-terminal peptidyl thioester and an N-terminal cysteinyl peptide. Since its introduction in 1994, the NCL reaction has been made the object of significant improvements and its scope and limitations have been thoroughly investigated. Furthermore, the diversification of peptide segment assembly strategies has been essential to access proteins of increasing complexity and has had to overcome the challenge of controlling the reactivity of ligation partners.One hallmark of NCL is its dependency on thiol reactivity, including for its catalysis. While Nature constantly plays with the redox properties of biological thiols for the regulation of numerous biochemical pathways, such a control of reactivity is challenging to achieve in synthetic organic chemistry and, in particular, for those methods used for assembling peptide segments by chemical ligation. This Account covers the studies conducted by our group in this area. A leading theme of our research has been the conception of controllable acyl donors and cysteine surrogates that place the chemoselective formation of amide bonds by NCL-like reactions under the control of dichalcogenide-based redox systems. The dependency of the redox potential of dichalcogenide bonds on the nature of the chalcogenides involved (S, Se) has appeared as a powerful means for diversifying the systems, while allowing their sequential activation for protein synthesis. Such a control of reactivity mediated by the addition of harmless redox additives has greatly facilitated the modular and efficient preparation of multiple targets of biological relevance. Taken together, these endeavors provide a practical and robust set of methods to address synthetic challenges in chemical protein synthesis.

摘要

过去的二十年见证了化学蛋白质合成的崛起,它现在已经成为一种成熟的合成方法体系,有效地补充了生物学方法。这种显著的发展可以归因于一类新的选择性化学反应的出现,这些反应能够在两个未保护的肽段之间形成天然肽键,也称为天然连接反应。近年来,这些反应的应用推动了大量高复杂度、高度修饰的蛋白质靶标的均质批量生产,实现了在原子水平上对其组成的控制。通过这种方式,天然连接反应为化学生物学、药物化学、材料科学和纳米技术研究领域的成功应用提供了手段。

天然化学连接(NCL)反应通过在 C 端肽硫酯和 N 端半胱氨酸肽之间选择性地形成天然肽键,对该领域产生了重大影响。自 1994 年引入以来,NCL 反应已经得到了显著的改进,其范围和局限性也得到了彻底的研究。此外,肽段组装策略的多样化对于获得越来越复杂的蛋白质至关重要,并且必须克服控制连接伙伴反应性的挑战。

NCL 的一个特点是依赖于巯基反应性,包括其催化反应。虽然自然界经常利用生物巯基的氧化还原性质来调节许多生化途径,但在合成有机化学中,特别是在通过化学连接组装肽段的方法中,这种控制反应性具有挑战性。本综述涵盖了我们小组在这一领域的研究。我们研究的一个主要主题是设计可控的酰基供体和半胱氨酸类似物,使通过 NCL 样反应形成酰胺键的化学选择性置于基于二硫键的氧化还原体系的控制之下。二硫键的氧化还原电位取决于所涉及的硫族元素(S、Se)的性质,这已成为多样化体系的有力手段,同时允许它们用于蛋白质合成的顺序激活。通过添加无害的氧化还原添加剂来控制反应性,极大地促进了具有生物相关性的多个目标的模块化和高效制备。总之,这些努力为解决化学蛋白质合成中的合成挑战提供了实用而稳健的方法集。

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