疑似蛇毒液样品的纳升级超高效液相色谱-高分辨质谱分析鉴定

doi:10.3724/SP.J.1123.2022.08009

摘要/Abstract

摘要：

针对5个疑似蛇毒毒液及其沾染样品,基于纳升级超高效液相色谱-四极杆-静电场轨道阱高分辨质谱(Nano LC-MS/HRMS)技术,结合尺寸排阻色谱分离,建立了一种蛋白质种类及物种归属的严格鉴定方法。5个样品经尺寸排阻色谱分离后均得到3个洗脱峰,分别冻干后以胰蛋白酶进行溶液内酶解处理并进行液相色谱-高分辨质谱分析鉴定。首先采用全扫描-数据依赖型MS/MS(Full MS/dd MS²)采集模式对样品中的肽段信息进行非靶向采集,依次与Swiss-Prot、蛇亚目(Serpentes)、游蛇科(Colubroidea)、眼镜蛇科(Elapidae)、眼镜蛇亚科(Elapinae)、眼镜蛇属(Naja)蛋白质数据库逐级收缩比对;再筛选符合肽谱匹配度、肽段错误发现率小于1%和特征肽段数目大于等于2的蛋白质,共鉴定到32种蛋白质均来自中华眼镜蛇(Naja atra),可归属于Naja atra的10个家族,主要为三指毒素、金属蛋白酶、磷脂酶A2等。最后,采用平行反应监测模式选取每种蛋白质的两条特征肽段进行靶向验证,当两条特征肽段均满足“至少75%的y⁺和b⁺离子的Δm/z小于5 ppm”时,方认为鉴定到了样品中的某一蛋白质。最终鉴定出5个样品均含有Naja atra蛇毒。此鉴定方法研究系统、严格,可为蛇毒中毒司法鉴定以及毒药物研究等提供有效的技术支持。

关键词: 纳升级超高效液相色谱, 高分辨质谱, 蛇毒, 蛋白质组学, 平行反应监测

Abstract:

Snake venom is a complex mixture secreted from the glands of poisonous snakes, which contains proteins, peptides, lipids, nucleosides, sugars, amino acids, amines, metal ions, and other components. According to the toxicological classification, snake venoms can be classified as neurotoxins, anticoagulants and procoagulant toxins, cardiac toxins, other toxin proteins, and enzymes. Proteins and peptides are the key components of snake venom. The establishment of rapid, accurate analysis and identification methods for proteins in snake venom is a prerequisite for snake venom-related forensic identification, intoxication events, and pharmaceutical development. Until now, the classical analysis and identification methods have mainly been biochemical or immunoassays for DNA or proteins, such as polymerase chain reaction, agglutination test, enzyme-linked immunosorbent assay, fluorescent immunoassay, and various biosensing approaches. These methods have some limitations such as a high false-positive ratio, low sensitivity, poor anti-interference ability, and limited species discrimination capability.

In recent years, with the rapid development of mass spectrometry (MS) techniques, the proteomics of snake venom has also attracted much attention and has contributed to the identification of snake species, in which non-targeted and targeted proteomics represent two main divisions. However, species identification via proteomics is in its infancy in forensic science. First, the tandem MS spectra of peptide sequences are highly complex, which poses a great challenge for the strict and accurate matching of peptides based on the rational speculation of MS fragmentation rules and theoretical calculations in non-targeted proteomics. Second, for the confirmation and identification of unknown substances, reference substances are commonly needed, but those for snake venom are lacking. Proteomics in snake venom identification is still in progress to improve the identification confidence and clarify the identification rules. In this work, a method based on nano-ultra-high performance liquid chromatography-quadrupole-orbitrap high-resolution mass spectrometry (Nano LC-MS/HRMS) and size exclusion chromatography (SEC) was developed for identifying proteins and their source species, with strict rules for five suspected snake venom samples and their contamination in one case. Three SEC elution peaks were obtained from each of the five samples, which were lyophilized and treated with trypsin in solution, and then separated and analyzed by Nano LC-MS/HRMS. First, the Full MS/dd MS² mode was used for the non-targeted acquisition of peptide information in the samples, and after submission to the Swiss-Prot database, the protein databases of Serpentes, Colubroidea, Elapidae, Elapinae, and Naja were contracted stepwise and compared. A total of 32 proteins from Naja atra were identified under the conditions of both peptide spectrum match and false discovery rate less than 1%, and number of characteristic peptides greater than or equal to two. All of these were derived from ten families of Naja atra, mainly three-finger toxins, metalloproteinases, and phospholipase A2. Proteins D3TTC2, D5LMJ3, Q7T1K6, Q9DEQ3, and Q9YGI4 were the most common among the five samples. Finally, the parallel reaction monitoring mode was adopted to select two unique peptides for each protein for targeted verification. It was considered that a protein in the samples was truly identified when it met the strict standard “the Δm/z of at least 75% y⁺ and b⁺ ions of each unique peptide was less than 5 ppm”. After these consequently procedures, we identified that all five samples contained the venom of the Naja atra. Our identification method is a systematic and strict example that can provide effective technical support for the forensic identification of snake venom poisoning, as well as for pharmaceutical development toward snake venoms.

Key words: nano-ultra-high performance liquid chromatography (Nano LC), high resolution mass spectrometry (HRMS), snake venom, proteomics, parallel reaction monitoring

中图分类号:

O658

李泽华, 王闯, 徐斌, 陈佳, 张瑛, 郭磊, 谢剑炜. 疑似蛇毒液样品的纳升级超高效液相色谱-高分辨质谱分析鉴定[J]. 色谱, 2023, 41(2): 122-130.

LI Zehua, WANG Chuang, XU Bin, CHEN Jia, ZHANG Ying, GUO Lei, XIE Jianwei. Analysis and identification of suspected snake venom samples using nano-ultra-high performance liquid chromatography-high resolution mass spectrometry[J]. Chinese Journal of Chromatography, 2023, 41(2): 122-130.

图/表 7

表1 疑似蛇毒样品的性状

Table 1 Characters of suspected snake venom samples

No.	Sample name	Character
A	powder inside newspaper	yellowish-brown
B	needles wrapped in paper	rufous
C	powder inside plastic bag	yellowish-brown
D	plastic bag	yellowish-brown
E	wine glass	contained thick yellowish liquid
		and several needles

图1 5个样品以10 mmol/L PBS洗脱的SEC色谱图

Fig. 1 Size exclusion chromatograms (SEC) of the five samples eluted by 10 mmol/L phosphate-buffered saline

图2 5个样品的蛋白质数据库匹配结果

Fig. 2 Results of protein database matching of the five samples The sections are named by the sample number-SEC eluted peak number; for example, A-p1 represents the first SEC eluted peak of sample A.

图3 3个SEC洗脱峰鉴定到的来自Naja atra的蛋白质

Fig. 3 Identified proteins of Naja atra from the three SEC elution peaks

图4 5个样品的SEC洗脱峰鉴定到的蛋白质

Fig. 4 Identified proteins from SEC elution peaks of the five samples The score is the scoring of the proteins identified in each component that matched the Naja database in the Sequest engine.

图5 PRM验证蛋白质的特征肽段提取离子色谱图

Fig. 5 Extracted ion chromatograms of unique peptides of proteins by parallel reaction monitoring (PRM) A total of 64 peptides for 32 proteins are shown, where -1 and -2 represent two separate unique peptides.

图6 来自于5个样品的32种鉴定蛋白质的进化树

Fig. 6 Evolution tree of 32 identified proteins in five samples Taking the first row as an example, sp, P01443, N2, 3SA4 NAJAT Cytotoxin 4, OS Naja atra, 81 AAs, 9.1 kDa, pI 9.01 represent the validated protein database, UniProt number of protein, nth protein from Naja atra, function of protein, species source, number of amino acids, relative molecular mass, and isoelectric point, respectively.

参考文献

[1]	World Health Organization. Snakebite Envenoming. (2021-05-17) [2022-08-03]. https://www.who.int/news-room/fact-sheets/detail/snakebite-envenoming
[2]	Seifert S A, Armitage J O, Sanchez E E. N Engl J Med, 2022, 386(1): 68
[3]	Fan Q S. Southwest National Defense Medicine, 2017, 27(8): 901
[3]	范泉水. 西南国防医药, 2017, 27(8): 901
[4]	Zhang J S, Xiang P, Shen M. Journal of Snake, 2019, 31(2): 175
[4]	张经硕, 向平, 沈敏. 蛇志, 2019, 31(2): 175
[5]	Munawar A, Ali S A, Akrem A, et al. Toxins (Basel), 2018, 10(11): 474
[6]	Harvey A L, Edrada-Ebel R, Quinn R J. Nat Rev Drug Discov, 2015, 14(2): 111
[7]	Freire M C L C, Noske G D, Bitencourt N V, et al. Molecules, 2021, 26(16): 4896
[8]	Zhang J S, Xiang P, Shen M. Chinese Journal of Forensic Sciences, 2014(4): 33
[8]	张经硕, 向平, 沈敏. 中国司法鉴定, 2014(4): 33
[9]	Xian R Q, Hang B J, Gong L P, et al. Chinese Journal of Chromatography, 2022, 40(9): 810
[9]	咸瑞卿, 杭宝建, 巩丽萍, 等. 色谱, 2022, 40(9): 810
[10]	Standing K G. Curr Opin Struct Biol, 2003, 13(5): 595
[11]	Fox J W, Serrano S M. Proteomics, 2008, 8(4): 909
[12]	Thevis M, Loo J A, Loo R R, et al. Rapid Commun Mass Spectrom, 2007, 21(3): 297
[13]	Worbs S, Skiba M, Söderström M, et al. Toxins (Basel), 2015, 7(12): 4906
[14]	Li Z, Li K, Xu B, et al. Electrophoresis, 2022, doi: 10.1002/elps.202200051
[15]	Fox J W, Ma L, Nelson K, et al. Toxicon, 2006, 47(6): 700
[16]	Mol E A, Goumans M J, Doevendans P A, et al. Nanomedicine, 2017, 13(6): 2061
[17]	Kulkeaw K, Chaicumpa W, Sakolvaree Y, et al. Toxicon, 2007, 49(7): 1026
[18]	Yang S D, Li N J, Ma Z, et al. Chinese Journal of Chromatography, 2021, 39(10): 1065
[18]	杨三东, 李乃杰, 马周, 等. 色谱, 2021, 39(10): 1065
[19]	Oulas A, Pavloudi C, Polymenakou P, et al. Bioinform Biol Insights, 2015, 9: 75
[20]	Timmins-Schiffman E, May D H, Mikan M, et al. ISME J, 2017, 11(2): 309
[21]	Deutsch E W, Overall C M, Van Eyk J E, et al. J Proteome Res, 2016, 15(11): 3961
[22]	Liang L H, Cheng X, Yu H L, et al. Anal Bioanal Chem, 2021, 413(2): 585
[23]	Merkley E D, Wunschel D S, Wahl K L, et al. Forensic Sci Int, 2019, 297: 350
[24]	Tan N H, Wong K Y, Tan C H. J Proteomics, 2017, 157: 18
[25]	Kini R M, Doley R. Toxicon, 2010, 56(6): 855
[26]	Li S, Wang J, Zhang X, et al. Biochem J, 2004, 384(Pt 1): 119