剧毒性Ⅱ型核糖体失活蛋白蓖麻毒素和相思子毒素的检测鉴定方法研究进展

doi:10.3724/SP.J.1123.2020.10001

摘要/Abstract

摘要：

Ⅱ型核糖体失活蛋白(RIPs)是一类重要的蛋白毒素,该类毒素大都具有一对二硫键连接的A-B链结构特征,B链具有半乳糖结合特性,能够与真核细胞膜表面受体特异性结合,将具有N-糖苷酶活性的A链导入细胞,与核糖体特定位点发生脱嘌呤作用使核糖体失活,最终通过抑制蛋白质合成而展现出细胞毒性。Ⅱ型RIPs毒素毒性极强,来源于植物的蓖麻毒素(ricin)和相思子毒素(abrin)的毒性分别是神经性毒剂维埃克斯(Vx)的385倍和2885倍。同时,该类毒素来源广泛、易于制备、稳定性好,成为一类潜在化生恐怖战剂,受到国内外广泛关注,其中蓖麻毒素作为唯一的蛋白毒素被收录于禁止化学武器公约禁控清单。近年来发生的多次蓖麻毒素邮件恐怖事件,进一步促进了有关Ⅱ型RIPs毒素的准确、灵敏、快速的检测鉴定技术的发展。剧毒性Ⅱ型RIPs毒素的检测鉴定方法主要涉及免疫分析法为代表的特异性识别和生物质谱分析为主的定性定量检测方法,以及基于脱嘌呤反应活性和细胞毒性的毒素活性检测方法。基于抗原-抗体作用的免疫检测法及基于寡核苷酸适配体的特异性识别检测法具有速度快、灵敏度高的优势,但对于复杂样品中高度同源蛋白的检测,易产生假阳性结果。随着生物质谱技术的快速发展,电喷雾离化(ESI)或基质辅助激光解吸离化(MALDI)等技术广泛应用于蛋白质的准确鉴定,不仅能够提供蛋白毒素的准确分子量和结构序列信息,而且能够实现准确定量。酶解质谱法是应用最为广泛的检测鉴定方法,通过酶解肽指纹谱分析,实现蛋白毒素的准确鉴定;对于复杂样品中蛋白毒素的分析,通过多种蛋白酶酶解策略获得丰富的特异性肽段标志物,然后进行肽段标志物的靶向质谱分析从而获得准确的定性及定量信息,方法有效提升了Ⅱ型RIPs毒素鉴定的准确度和灵敏度。免疫分析法和生物质谱法能够准确鉴定Ⅱ型RIPs毒素,但无法识别毒素是否还保持毒性。对于Ⅱ型RIPs毒素的活性分析,主要包括基于N-糖苷酶活性的脱嘌呤反应测定法和细胞毒性测定法,两种方法均可实现毒素毒性的简便、快速、灵敏的分析检测,是Ⅱ型RIPs毒素检测方法的有效补充。由于该类毒素的高度敏感性,国际禁止化学武器组织(OPCW)对相关样品中Ⅱ型RIPs毒素的分析提出了唯一性鉴定的技术要求。该文引用了Ⅱ型RIPs毒素及其检测方法相关的70篇文献,综述了以上Ⅱ型RIPs毒素的结构性质、中毒机理及典型剧毒性Ⅱ型RIPs毒素检测方法的研究进展,对不同检测方法的特点和应用潜力进行了总结,并结合OPCW对Ⅱ型RIPs毒素唯一性鉴定的技术需求,展望了未来Ⅱ型RIPs毒素检测技术研究的发展趋势。

关键词: Ⅱ型核糖体失活蛋白, N-糖苷酶活性, 毒素, 分析检测方法, 综述

Abstract:

Type Ⅱ ribosome-inactivating proteins (RIPs) are an important class of protein toxins that consist of A and B chains linked by an interchain disulfide bond. The B-chain with lectin-like activity is responsible for binding to the galactose-containing receptors on eukaryotic cell surfaces, which is essential for A-chain internalization by endocytosis. The A-chain has N-glycosidase activity that irreversibly depurinates a specific adenine from 28S ribosomal RNA (28S rRNA) and terminates protein synthesis. The synergistic effect of the A-B chain inactivates the ribosome, inhibits protein synthesis, and exhibits high cytotoxicity. Ricin and abrin that are expressed by the plants Ricinus communis and Abrus precatorius, respectively, are typical type Ⅱ RIPs. The toxicity of ricin and abrin are 385 times and 2885 times, respectively, more that of the nerve agent VX. Owing to their ease of preparation, wide availability, and potential use as a bioterrorism agent, type Ⅱ RIPs have garnered increasing attention in recent years. Ricin is listed as a prohibited substance under schedule 1A of the Chemical Weapons Convention (CWC). The occurrence of ricin-related bioterrorism incidents in recent years has promoted the development of accurate, sensitive, and rapid detection and identification technology for type Ⅱ RIPs. Significant progress has been made in the study of toxicity mechanisms and detection methods of type Ⅱ RIPs, which primarily involve qualitative and quantitative analysis methods including immunological assays, mass spectrometry analysis methods, and toxin activity detection methods based on depurination and cytotoxicity. Immunoassays generally involve the specific recognition of antigens and antibodies, which is based on oligonucleotide molecular recognition elements called aptamers. These methods are fast and highly sensitive, but for highly homologous proteins in complex samples, they provide false positive results. With the rapid development of biological mass spectrometry detection technology, techniques such as electrospray ionization (ESI) and matrix-assisted laser desorption ionization (MALDI) are widely used in the identification of proteins. These methods not only provide accurate information on molecular weight and structure of proteins, but also demonstrate accurate quantification. Enzyme digestion combined with mass spectrometry is the predominantly used detection method. Accurate identification of protein toxins can be achieved by fingerprint analysis of enzymatically digested peptides. For analysis of protein toxins in complex samples, abundant peptide markers are obtained using a multi-enzyme digestion strategy. Targeted mass spectrometry analysis of peptide markers is used to obtain accurate qualitative and quantitative information, which effectively improves the accuracy and sensitivity of the identification of type Ⅱ RIP toxins. Although immunoassay and mass spectrometry detection methods can provide accurate identification of type Ⅱ RIPs, they cannot determine whether the toxins will retain potency. The widely used detection methods for activity analysis of type Ⅱ RIPs include depurination assay based on N-glycosidase activity and cytotoxicity assay. Both the methods provide simple, rapid, and sensitive analysis of type Ⅱ RIP toxicity, and complement other detection methods. Owing to the importance of type Ⅱ RIP toxins, the Organization for the Prohibition of Chemical Weapons (OPCW) has proposed clear technical requirements for the identification and analysis of relevant samples. We herein reviewed the structural characteristics, mechanism of action, and the development and application of type Ⅱ RIP detection methods; nearly 70 studies on type Ⅱ RIP toxins and their detection methods have been cited. In addition to the technical requirements of OPCW for the unambiguous identification of biotoxins, the trend of future development of type Ⅱ RIP-based detection technology has been explored.

Key words: type Ⅱ ribosome-inactivating proteins (RIPs), N-glycosidase activity, toxin, detection methods, review

中图分类号:

O658

梁龙辉, 夏俊美, 刘昌财, 刘石磊. 剧毒性Ⅱ型核糖体失活蛋白蓖麻毒素和相思子毒素的检测鉴定方法研究进展[J]. 色谱, 2021, 39(3): 260-270.

LIANG Longhui, XIA Junmei, LIU Changcai, LIU Shilei. Highly toxic type Ⅱ ribosome-inactivating proteins ricin and abrin and their detection methods: a review[J]. Chinese Journal of Chromatography, 2021, 39(3): 260-270.

图/表 4

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Toxin	Source	Toxicity
Toxin	Source	Hela cell IC₅₀/(mol/L)^a)	Mice injection LD₅₀/(μg/kg)^b)
Abrin (相思子毒素)	Abrus precatorius seeds	3.9×10^-12	0.04
Ricin (蓖麻毒素)	Ricinus communis seeds	6.0×10^-13	3
Mistletoe lectin I (槲寄生凝集素I)	Viscum album leaves	1.7×10^-9	2.4
Modeccin (药莲毒素)	Adenia digitata root	2.8×10^-12	5.3
Volkensin (蒴莲毒素)	Adenia volkensii root	3.0×10^-13	1.7
RIP (RIP毒素)	Adenia goetzii caudex	1.0×10^-12	-
Lanceolin (柳杉毒素)	Adenia lanceolata caudex	5.0×10^-13	6.8
Stenodactylin (西番莲毒素)	Adenia stenodactyla caudex	3.0×10^-13	1.2
Aralin (阿拉林毒素)	Aralia elata shoots	1.3×10^-12	-
Riproximin (利普西敏毒素)	Ximenia americana powder	1.1×10^-12	-

Toxin	Source	Toxicity
Toxin	Source	Hela cell IC₅₀/(mol/L)^a)	Mice injection LD₅₀/(μg/kg)^b)
Abrin (相思子毒素)	Abrus precatorius seeds	3.9×10^-12	0.04
Ricin (蓖麻毒素)	Ricinus communis seeds	6.0×10^-13	3
Mistletoe lectin I (槲寄生凝集素I)	Viscum album leaves	1.7×10^-9	2.4
Modeccin (药莲毒素)	Adenia digitata root	2.8×10^-12	5.3
Volkensin (蒴莲毒素)	Adenia volkensii root	3.0×10^-13	1.7
RIP (RIP毒素)	Adenia goetzii caudex	1.0×10^-12	-
Lanceolin (柳杉毒素)	Adenia lanceolata caudex	5.0×10^-13	6.8
Stenodactylin (西番莲毒素)	Adenia stenodactyla caudex	3.0×10^-13	1.2
Aralin (阿拉林毒素)	Aralia elata shoots	1.3×10^-12	-
Riproximin (利普西敏毒素)	Ximenia americana powder	1.1×10^-12	-