Direct mapping of tyrosine sulfation states in native peptides by nanopore

IF 12.9 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Nature chemical biology Pub Date : 2024-09-25 DOI:10.1038/s41589-024-01734-x

Hongyan Niu, Meng-Yin Li, Yan Gao, Jun-Ge Li, Jie Jiang, Yi-Lun Ying, Yi-Tao Long

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Abstract

Sulfation is considered the most prevalent post-translational modification (PTM) on tyrosine; however, its importance is frequently undervalued due to difficulties in direct and unambiguous determination from phosphorylation. Here we present a sequence-independent strategy to directly map and quantify the tyrosine sulfation states in universal native peptides using an engineered protein nanopore. Molecular dynamics simulations and nanopore mutations reveal specific interactions between tyrosine sulfation and the engineered nanopore, dominating identification across diverse peptide sequences. We show a nanopore framework to discover tyrosine sulfation in unknown peptide fragments digested from a native protein and determine the sequence of the sulfated fragment based on current blockade enhancement induced by sulfation. Moreover, our method allows direct observation of peptide sulfation in ultra-low abundance, down to 1%, and distinguishes it from isobaric phosphorylation. This sequence-independent strategy suggests the potential of nanopore to explore specific PTMs in real-life samples and at the omics level.

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利用纳米孔直接绘制原生肽中的酪氨酸硫酸化状态图

硫酸化被认为是酪氨酸上最常见的翻译后修饰（PTM）；然而，由于很难直接明确地测定磷酸化，其重要性常常被低估。在这里，我们提出了一种独立于序列的策略，利用工程蛋白纳米孔直接绘制和量化通用原生肽中的酪氨酸硫酸化状态。分子动力学模拟和纳米孔突变揭示了酪氨酸硫酸化与工程纳米孔之间的特异性相互作用，从而主导了对不同肽序列的识别。我们展示了一种纳米孔框架，它能发现从原生蛋白质中消化出的未知肽片段中的酪氨酸硫酸化，并根据硫酸化引起的电流阻断增强确定硫酸化片段的序列。此外，我们的方法还能直接观察肽硫酸化的超低丰度（低至 1%），并将其与等压磷酸化区分开来。这种与序列无关的策略表明，纳米孔有潜力探索真实样本中的特定 PTM，并在全局水平上进行研究。

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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来源期刊

Nature chemical biology 生物-生化与分子生物学

CiteScore

23.90

自引率

1.40%

发文量

238

审稿时长

12 months

期刊介绍： Nature Chemical Biology stands as an esteemed international monthly journal, offering a prominent platform for the chemical biology community to showcase top-tier original research and commentary. Operating at the crossroads of chemistry, biology, and related disciplines, chemical biology utilizes scientific ideas and approaches to comprehend and manipulate biological systems with molecular precision. The journal embraces contributions from the growing community of chemical biologists, encompassing insights from chemists applying principles and tools to biological inquiries and biologists striving to comprehend and control molecular-level biological processes. We prioritize studies unveiling significant conceptual or practical advancements in areas where chemistry and biology intersect, emphasizing basic research, especially those reporting novel chemical or biological tools and offering profound molecular-level insights into underlying biological mechanisms. Nature Chemical Biology also welcomes manuscripts describing applied molecular studies at the chemistry-biology interface due to the broad utility of chemical biology approaches in manipulating or engineering biological systems. Irrespective of scientific focus, we actively seek submissions that creatively blend chemistry and biology, particularly those providing substantial conceptual or methodological breakthroughs with the potential to open innovative research avenues. The journal maintains a robust and impartial review process, emphasizing thorough chemical and biological characterization.