基于镜像酶正交酶切的蛋白质复合物规模化精准分析新方法

doi:10.3724/SP.J.1123.2021.06010

色谱 ›› 2022, Vol. 40 ›› Issue (3): 224-233.DOI: 10.3724/SP.J.1123.2021.06010

基于镜像酶正交酶切的蛋白质复合物规模化精准分析新方法

韩若楠¹^,²^,^#, 赵丽丽²^,³^,^#, 安雨馨²^,³, 梁振², 赵群²^,^*(), 张丽华², 张玉奎¹^,²

1.大连理工大学, 张大煜学院, 辽宁大连 116024
2.中国科学院大连化学物理研究所, 中国科学院分离分析化学重点实验室, 辽宁大连 116023
3.中国科学院大学, 北京 100049

收稿日期:2021-06-07 出版日期:2022-03-08 发布日期:2022-03-04
通讯作者: 赵群
作者简介:第一联系人：
# 共同第一作者.
基金资助:
国家重点研发计划(2016YFA0501401);国家自然科学基金(21775150)

Mirror cutting-assisted orthogonal digestion enabling large-scale and accurate protein complex characterization

HAN Ruonan¹^,²^,^#, ZHAO Lili²^,³^,^#, AN Yuxin²^,³, LIANG Zhen², ZHAO Qun²^,^*(), ZHANG Lihua², ZHANG Yukui¹^,²

1. Zhang Dayu School of Chemistry, Dalian University of Technology, Dalian 116024, China
2. CAS Key Laboratory of Separation Sciences for Analytical Chemistry, Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian 116023, China
3. University of Chinese Academy of Sciences, Beijing 100049, China

Received:2021-06-07 Online:2022-03-08 Published:2022-03-04
Contact: ZHAO Qun
Supported by:
National Key Research and Development Program of China(2016YFA0501401);National Natural Science Foundation of China(21775150)

摘要/Abstract

摘要：

蛋白质主要以复合物的形式参与各项生命活动。化学交联质谱(CXMS)技术作为近年来新兴的蛋白质复合物解析技术,不仅可实现蛋白质复合物规模化解析,而且普遍适用于任意相对分子质量和纯度的蛋白质复合物样品,因此已成为X-射线晶体衍射技术、冷冻电镜技术等蛋白质复合物解析经典技术的重要补充。目前,CXMS主要采用胰蛋白酶将交联后的蛋白质复合物进行酶切,并进行质谱鉴定。然而鉴定到的交联肽段谱图中b/y特征碎片离子的鉴定数目不足,且因肽段序列匹配连续性较差导致谱图可信度相对较低,影响了蛋白质复合物交联位点的鉴定精准度。该文基于镜像酶正交切割的互补特性,采用胰蛋白酶镜像酶与胰蛋白酶联合酶切的方法,对交联后的蛋白质复合物分别进行酶切,再利用液相色谱-质谱联用技术对酶解产生的交联肽段进行鉴定,进而实现蛋白质复合物的组成、相互作用和结构位点距离约束的解析。对牛血清白蛋白和大肠杆菌全蛋白的交联肽段的分析结果表明,该方法通过增加交联肽段谱图中特征碎裂离子的数目和连续性,鉴定到的大肠杆菌全蛋白的交联位点,较单一胰蛋白酶酶切,提高了16%。因此,镜像酶正交酶切策略能有效提高交联肽段的鉴定准确度和覆盖度,有望为实现规模化的蛋白质复合物精准解析提供新思路。

关键词: 化学交联质谱, 多酶酶切, 蛋白质复合物, 镜像酶

Abstract:

Protein complexes are involved in a variety of biological activities. Accurate and comprehensive characterization of the structures and interactions of protein complexes is crucial in determining their biological functions. Chemical cross-linking coupled with mass spectrometry (CXMS) is an emerging investigative technique for protein complexes. CXMS enables the sensitive high-throughput analysis of protein complexes without the requirements of molecular weight and purification. These attributes have spurred the increased use of CXMS for the structure and interaction characterization of purified protein complexes and complicated cell lysate samples. CXMS utilizes chemical cross-linking reagents to covalently connect two reactive amino acids in or between proteins that are spatially close to each other. Subsequently, the cross-linked proteins are digested into cross-linked peptides, followed by LC-MS/MS analysis, as well as database searching to provide cross-linking information for the composition, interaction, and structural site distance restrictions of protein complex identification. Therefore, identification of cross-linked sites has a decisive influence on the characterization of protein complexes. This identification is limited by the unsatisfactory quality of the cross-linked peptide spectrum. Insufficient b/y fragment ions and poor continuity of amino acid sequence matching lead to low coverage and accuracy of cross-linked site identification. Based on the complementary feature of mirror-cutting digestion, an orthogonal digestion strategy based on LysargiNase combined with trypsin was developed in this study. Trypsin is the most commonly utilized digestion enzyme in proteomics, with extremely high enzyme activity and specificity. Trypsin generates C-terminally charged peptides after lysine (K) and arginine (R). LysargiNase is a mirror protease complementary to trypsin that cleaves before the K and R residues. This generates peptides with an N-terminal positively-charged residue. Owing to the different physical and chemical micro-environments of the cross-linked peptides digested by LysargiNase and trypsin, the behavior of their detection ability in MS analysis is diverse. Using the orthogonal digestion strategy, both simple and complicated cross-linked samples were analyzed in this study. For the analysis of bovine serum albumin (BSA), 291 pairs of non-redundant cross-linked sites were obtained, of which 216 pairs of cross-linked sites were provided by trypsin digestion, whereas 75 pairs of cross-linked sites were exclusively supplied by LysargiNase digestion. Except for the 35% increase in the number of identified cross-linked sites, 32% of the spectra of the commonly identified cross-linked peptides have better quality with more b-type fragment ions and consecutive sequence matching. Furthermore, for the Escherichia coli sample, 726 pairs of cross-linked sites were obtained in total, among which, 624 and 274 pairs were identified from trypsin and LysargiNase digestion, respectively. LysargiNase digestion yielded 120 individual cross-linked sites, which resulted in a 16% increase in single trypsin digestion. Consistent with the BSA sample, the quality was improved in 35% of the spectra of commonly identified cross-linked peptides. Corresponding to the identified cross-linked peptides, 242 structural constraints with 607 pairs of intra-cross-linked sites and 29 sets of protein-protein interactions with 119 pairs of inter-cross-linked sites were obtained. The collective results demonstrated that, mirror cutting-assisted orthogonal digestion strategy could significantly increase the number of identified fragment ions and amino acid sequences matching the continuity of the spectra by contributing b-and y-type ions, respectively. This improved the accuracy and coverage of cross-linked peptide identification. The findings additionally demonstrate the superiority of our method in the accurate identification of the cross-linked peptide spectra and the increased number of identified cross-linked sites. In a word, this method is expected to provide new insights for the large-scale and highly accurate characterization of protein complexes.

Key words: chemical cross-linking mass spectrometry technology (CXMS), multi-protease digestion, protein complex, mirror protease

中图分类号:

O658

韩若楠, 赵丽丽, 安雨馨, 梁振, 赵群, 张丽华, 张玉奎. 基于镜像酶正交酶切的蛋白质复合物规模化精准分析新方法[J]. 色谱, 2022, 40(3): 224-233.

HAN Ruonan, ZHAO Lili, AN Yuxin, LIANG Zhen, ZHAO Qun, ZHANG Lihua, ZHANG Yukui. Mirror cutting-assisted orthogonal digestion enabling large-scale and accurate protein complex characterization[J]. Chinese Journal of Chromatography, 2022, 40(3): 224-233.

图/表 6

图1 胰蛋白酶与LysargiNase酶解样品的交联位点在牛血清白蛋白晶体结构(PDB: 3V03)的映射

Fig. 1 Mapping of cross-linked sites obtained from trypsin and LysargiNase digestion on the bovine serum albumin crystal structure (PDB: 3V03)

图2 LysargiNase与胰蛋白酶酶解样品的交联位点对及单一交联位点的互补性

Fig. 2 Complementarity of LysargiNase and trypsin digested cross-linked site pairs and single cross-linked sites a. venn diagram of single cross-linked sites; b. venn diagram of the cross-linked site pairs; c. number of cross-linked site pairs of each single cross-linked site, digested with LysargiNase and trypsin.

图3 LysargiNase与胰蛋白酶酶解样品共同得到的交联位点鉴定打分比较

Fig. 3 Comparison of cross-linking site identification scores obtained by both LysargiNase and trypsin digestions

图4 b+/++与y+/++离子碎片分别在α/β-肽段的碎片覆盖度

Fig. 4 Fragment coverages of b+/++ and y+/++ ions of α/β-peptides

图5 LysargiNase与胰蛋白酶酶解的交联肽段质谱图

Fig. 5 Mass spectra of cross-linked peptides digested by LysargiNase and trypsin

图6 大肠杆菌样品中LysargiNase与胰蛋白酶酶切鉴定蛋白质复合物信息互补性

Fig. 6 Complementation of protein complex information identified by LysargiNase and trypsin digestion in Escherichia coli samples a. complementary of protein-protein interactions; b. example of complementary of intra-cross-linked protein structure information.

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基于镜像酶正交酶切的蛋白质复合物规模化精准分析新方法

Mirror cutting-assisted orthogonal digestion enabling large-scale and accurate protein complex characterization

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