三唑啉二酮蛋白修饰：从被忽视的脱靶效应到基于色氨酸的生物共轭策略。

Triazolinedione protein modification: from an overlooked off-target effect to a tryptophan-based bioconjugation strategy.

作者信息

Decoene Klaas W, Unal Kamil, Staes An, Zwaenepoel Olivier, Gettemans Jan, Gevaert Kris, Winne Johan M, Madder Annemieke

机构信息

Department of Organic and Macromolecular Chemistry, Ghent University Krijgslaan 281 S4 9000 Ghent Belgium

Department of Biomolecular Medicine, Ghent University Ghent Belgium.

出版信息

Chem Sci. 2022 Mar 15;13(18):5390-5397. doi: 10.1039/d1sc06942j. eCollection 2022 May 11.

DOI:10.1039/d1sc06942j

PMID:35655564

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9093138/

Abstract

Labelling of tyrosine residues in peptides and proteins has been reported to selectively occur a 'tyrosine-click' reaction with triazolinedione reagents (TAD). However, we here demonstrate that TAD reagents are actually not selective for tyrosine and that tryptophan residues are in fact also labelled with these reagents. This off-target labelling remained under the radar as it is challenging to detect these physiologically stable but thermally labile modifications with the commonly used HCD and CID MS/MS techniques. We show that selectivity of tryptophan over tyrosine can be achieved by lowering the pH of the aqueous buffer to effect selective Trp-labelling. Given the low relative abundance of tryptophan compared to tyrosine in natural proteins, this results in a new site-selective bioconjugation method that does not rely on enzymes nor unnatural amino acids and is demonstrated for peptides and recombinant proteins.

摘要

据报道，肽和蛋白质中酪氨酸残基的标记是通过与三唑啉二酮试剂（TAD）发生“酪氨酸点击”反应而选择性发生的。然而，我们在此证明，TAD试剂实际上对酪氨酸没有选择性，色氨酸残基实际上也会被这些试剂标记。这种脱靶标记一直未被发现，因为用常用的HCD和CID MS/MS技术检测这些生理上稳定但热不稳定的修饰具有挑战性。我们表明，通过降低水性缓冲液的pH值以实现选择性色氨酸标记，可以实现色氨酸对酪氨酸的选择性。鉴于天然蛋白质中色氨酸相对于酪氨酸的相对丰度较低，这产生了一种新的位点选择性生物共轭方法，该方法不依赖于酶或非天然氨基酸，并已在肽和重组蛋白中得到验证。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7ed2/9093138/aa1ab0bafec5/d1sc06942j-s1.jpg

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三唑啉二酮蛋白修饰：从被忽视的脱靶效应到基于色氨酸的生物共轭策略。

Triazolinedione protein modification: from an overlooked off-target effect to a tryptophan-based bioconjugation strategy.

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