卤化多肽真空紫外激光解离及蛋白质组学分析

doi:10.3724/SP.J.1123.2024.08009

摘要/Abstract

摘要：

化学修饰在蛋白质组学定量和相互作用分析等研究领域应用广泛。本工作发展了一种针对复杂组织提取蛋白质酶解样品的多肽溴化、碘化光化学修饰新方法,实现了酪氨酸、组氨酸、色氨酸位点的高效溴化和酪氨酸、组氨酸位点的高效碘化修饰。进一步采用193 nm真空紫外激光解离(UVPD)串联质谱技术对光化学溴化和碘化标记后的鼠肝酶解肽样品进行了序列、修饰位点和光解离机制分析。由于Br和I原子对193 nm紫外光子的强吸收特性,193 nm UVPD可引起卤化位点的C-Br/C-I键断裂并产生多肽自由基离子,自由基迁移进一步引起多肽骨架碎裂。此外,193 nm UVPD与常规的高能碰撞诱导解离(HCD)模式结合可以提升蛋白质组学的卤化位点定位准确性。因此,整合光化学卤化修饰和193 nm UVPD可引发新型自由基解离途径,提升蛋白质组学的分析性能。

关键词: 蛋白质组学, 光化学卤化, 串联质谱, 193 nm紫外激光解离, 自由基解离

Abstract:

Chemical modifications are widely used in research fields such as quantitative proteomics and interaction analyses. Chemical-modification targets can be roughly divided into four categories, including those that integrate isotope labels for quantification purposes, probe the structures of proteins through covalent labeling or cross-linking, incorporate labels to improve the ionization or dissociation of characteristic peptides in complex mixtures, and affinity-enrich various poorly abundant protein translational modifications (PTMs). A chemical modification reaction needs to be simple and efficient for use in proteomics analysis, and should be performed without any complicated process for preparing the labeling reagent. High reaction specificity, which reduces product complexity, and mild biocompatible reaction conditions are also favored. In addition, modification labels should be compatible with mass spectrometry to prevent interference from ionization and dissociation processes. Pulsed ultraviolet (UV) lasers can produce large amounts of active radical species within a few nanoseconds for use in rapid photochemical-modification processes. Usually, UV lasers with wavelengths greater than 240 nm are used in current in-situ photochemical-modification methods; consequently, special conjugated photoreaction probes need to be designed and oxidants and catalysts added, which reduce the biocompatibility of the reaction. The high single-photon energy of the 193 nm laser is capable of efficiently exciting conventional photo-inert substances in aqueous solution, leading to efficient photochemical peptide modifications. In this study, we developed a new method for photochemically brominating and iodinating enzymatic protein samples extracted from complex tissue with a 193 nm ArF nanosecond pulsed laser, which efficiently brominated tyrosine, histidine, and tryptophan, and iodinated tyrosine and histidine.

Tandem mass spectrometry (MS/MS) can generate fragmentation patterns of ions which can afford diagnostic molecular fingerprints to decipher sequences of biopolymers such as peptides. Peptide fragmentation is commonly implemented using collision-based, electron-based, or photodissociation-based methods. Compared with the most commonly used collision-based methods, ultraviolet photodissociation (UVPD) uses high-energy ultraviolet photons with wavelengths shorter than 200 nm to excite and dissociate ions. Single-pulse excitation can provide the energy required to promote ions into their excited electronic states, with excitation speeds of up to several nanoseconds. Since dissociation may occur directly from the excited states, UVPD spectra can show a wide variety of fragmentation pathways, thereby providing more sequence and structural information. The most commonly used wavelengths are 157, 193, and 266 nm. UVPD has been integrated into high-resolution orbitrap mass spectrometer by adding optical windows and other optics to direct the photons to the analyte ions, and by implementing a triggering method that synchronizes the photoirradiation process with ion-analysis events. The large photoabsorption cross sections of peptides at 193 nm and the resulting high internal energy deposition can generate abundant fragment ions and achieve high sequence coverage. The excellent fragmentation performance offered by 193 nm UVPD of peptides with its high sequence coverage and lack of charge-state dependence, has motivated its use in high-throughput proteomics. Photochemically brominated and iodinated mouse-liver tryptic peptides were further characterized by 193 nm UVPD tandem mass spectrometry with the aim of analyzing their sequences, modification sites, and photodissociation mechanisms. Br and I atoms strongly absorb 193 nm photons; consequently, UVPD can cleave C-Br/C-I bonds at halogenated sites to generate peptide radical ions, with further peptide-backbone fragmentation caused by radical migration. In addition, the combination of 193 nm UVPD with conventional high-energy collision-induced dissociation (HCD) mode improves the identification-reliability of halogenation sites in proteomics. Therefore, integrating photochemical halogenation and 193 nm UVPD can trigger novel radical-dissociation pathways, thereby improving analytical proteomics performance.

Key words: proteomics, photochemical halogenation, tandem mass spectrometry (MS/MS), 193 nm ultraviolet photodissociation (193 nm UVPD), radical dissociation

中图分类号:

O658

罗盼, 薛洁滢, 刘哲益, 王方军. 卤化多肽真空紫外激光解离及蛋白质组学分析[J]. 色谱, 2025, 43(2): 131-138.

LUO Pan, XUE Jieying, LIU Zheyi, WANG Fangjun. Vacuum ultraviolet laser dissociation and proteomic analysis of halogenated peptides[J]. Chinese Journal of Chromatography, 2025, 43(2): 131-138.

图/表 5

图 1 (a)酪氨酸、组氨酸和色氨酸的主要卤化产物以及(b)卤化肽段的193 nm UVPD解离示意图

Fig. 1 (a) Main halogenation products of tyrosine, histidine, and tryptophan and (b) a schematic diagram of halogenated peptides by utilizing 193 nm UVPD fragmentation Y: tyrosine; H: histidine; W: tryptophan. UVPD: ultraviolet photodissociation.

图 2 HCD和193 nm UVPD解离鉴定到的溴化肽段二级质谱图

Fig. 2 MS/MS spectra of the brominated peptides identified by the high-energy collision induced dissociation (HCD) and 193 nm UVPD fragmentation modes

图 3 HCD和193 nm UVPD解离鉴定到的碘化肽段二级质谱图

Fig. 3 MS/MS spectra of the iodinated peptides identified by the HCD and 193 nm UVPD fragmentation modes

图 4 碘化DIVEAHYR肽段经(a)HCD和(b)193 nm UVPD 解离模式鉴定的二级质谱图

Fig. 4 MS/MS spectra of the iodinated DIVEAHYR identified by the (a) HCD and (b) 193 nm UVPD fragmentation modes

图 5 溴化SLGQWLQEEK肽段经(a)HCD和(b)193 nm UVPD解离模式鉴定的二级质谱图

Fig. 5 MS/MS spectra of the brominated SLGQWLQEEK identified by the (a) HCD and (b) 193 nm UVPD fragmentation modes

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