智能聚合物基材料富集磷酸化肽和糖肽的研究进展

doi:10.3724/SP.J.1123.2020.05036

色谱 ›› 2021, Vol. 39 ›› Issue (1): 15-25.DOI: 10.3724/SP.J.1123.2020.05036

智能聚合物基材料富集磷酸化肽和糖肽的研究进展

郑鑫彤¹^,², 王雪², 张福生², 张旭阳², 赵艳艳¹, 卿光焱²^,^*()

1.大连医科大学药学院, 辽宁大连 116044
2.中国科学院分离分析化学重点实验室, 中国科学院大连化学物理研究所, 辽宁大连 116023

收稿日期:2020-06-05 出版日期:2021-01-08 发布日期:2020-12-20
通讯作者: 卿光焱
作者简介:

卿光焱: 主要从事智能生物分离材料方面的研究工作,开发了一系列生物分子响应性聚合物材料、手性功能表面和面向翻译后修饰蛋白质组学的聚合物基富集材料。以第一或通讯作者在Nat Comm(1篇), Adv Mater(3篇), J Am Chem Soc(5篇), Angew Chem Int Ed (2篇), Chem Sci(2篇), NPG Asia Materials(3篇), TrAC-Trends Anal Chem(2篇)等国际知名权威期刊上发表SCI论文60篇,其中影响因子10以上的论文13篇,参与发表论文37篇,他引1300余次;申报国家发明专利10项,授权15项。主持国家自然科学基金面上项目3项、青年科学基金项目1项、科技部973重大研究计划三级子课题1项,作为骨干成员参与3项国家自然科学基金面上项目、德国Sofja Kovalevskaja Award、基金委创新团队、长江学者创新团队项目的研究工作,并以第二完成人获得了2011年湖北省自然科学一等奖。2012年12月被评选为湖北省楚天学者特聘教授,2014年7月获得湖北省杰出青年基金资助。2017年4月入选武汉理工大学青年拔尖人才支持项目。2018年1月在中科院大连化物所生物技术部成立生物分离与界面分子机制创新特区组,担任研究组组长、特聘研究员、博士生导师。2018年12月入选辽宁省“兴辽英才计划”海内外高层次人才引进集聚计划创新领军人才。2019年8月获得国家基金委优秀青年基金资助,入选大连化物所张大煜青年学者,2019年11月入选辽宁省百千万人才工程“千”层次。*Tel:(0411)84379050,E-mail:qinggy@dicp.ac.cn.
基金资助:
国家自然科学基金(21775116);国家自然科学基金(21922411);大连化学物理研究所创新基金(DICP-RC201801);兴辽英才项目(XLYC1802109)

Advances in enrichment of phosphorylated peptides and glycopeptides by smart polymer-based materials

ZHENG Xintong¹^,², WANG Xue², ZHANG Fusheng², ZHANG Xuyang², ZHAO Yanyan¹, QING Guangyan²^,^*()

1. Pharmacy College, Dalian Medical University, Dalian 116044, China
2. Key Laboratory of Separation Science for Analytical Chemistry, Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian 116023, China

Received:2020-06-05 Online:2021-01-08 Published:2020-12-20
Contact: QING Guangyan
Supported by:
National Natural Science Foundation of China(21775116);National Natural Science Foundation of China(21922411);Dalian Institute of Chemical Physics Innovation Funding(DICP-RC201801);Liaoning Revitalization Talents Program(XLYC1802109)

摘要/Abstract

摘要：

翻译后修饰是蛋白质组学研究的前沿和重点,它不仅调节着蛋白质的折叠、状态、活性、定位以及蛋白质间的相互作用,也能帮助科学家更全面地了解生物体的生命过程,为疾病的预测、诊断和治疗提供更加强大的支撑和依据。翻译后修饰产物(例如磷酸化肽和糖肽)丰度很低,且存在着强烈的背景干扰,很难直接用质谱进行分析,因此迫切需要开发高效的富集材料和技术来选择性富集翻译后修饰产物。近年来,智能聚合物基材料通过外部物理、化学或生物刺激可逆地改变其结构和功能,实现对磷酸化肽和糖肽高度可控的吸附和脱附,进而衍生开发出一系列新颖的富集方法,极大地吸引研究者们的兴趣。一方面,智能聚合物基材料的响应变化包括材料疏水性的增加或减少、形状和形貌的改变、表面电荷的重新分布以及亲和配体的暴露或隐藏等特性。这些特性使得目标物和智能聚合物基材料之间的亲和力可以通过简单改变外部条件(如温度、pH值、溶剂极性和生物分子等)实现更可控和更智能的精细调节。另一方面,智能聚合物基材料为集成功能模块提供了便捷的可扩展平台,例如特定的识别组件,显著提高了目标物质的分离选择性。智能聚合物基材料在分离方面展现出巨大的潜力,这为蛋白质翻译后修饰产物的分析和研究带来了希望。围绕上述主题,该文依据Web of Science近20年来近50篇代表性文献,概述了智能聚合物基材料在磷酸化肽和糖肽分离及富集中的发展方向。

关键词: 蛋白质组学, 富集, 翻译后修饰, 智能聚合物, 磷酸化肽, 糖肽, 综述

Abstract:

Protein post-translational modification (PTM) is at the forefront of focus of proteomics research. It not only regulates protein folding, state, activity, localization, and protein interactions, but also helps scientists understand the biological processes of organisms more comprehensively, providing stronger support and basis for the prediction, diagnosis, and treatment of diseases. In living organisms, there are more than 300 types of PTMs of proteins and their modification processes are dynamic. At the same time, protein modifications do not exist in isolation. The occurrence of the same physiological or pathological process requires the joint action of various modified proteins, which affect and coordinate with each other. Owing to the low abundance of PTM products (e. g., phosphorylated peptides or glycopeptides) and the presence of strong background interference, it is difficult to analyze them directly through mass spectrometry. Therefore, the development efficient materials and techniques for the selective enrichment of PTM peptides is urgently needed. Conventional separation methods have partially solved the challenges involved in the enrichment of glycopeptides and phosphorylated peptides; however, there are some inevitable issues, such as the excessive binding force of metal ions (e. g., Fe³⁺and Ti⁴⁺) toward multiple phosphorylated peptides, resulting in difficulty in elution and identification through mass spectrometry. In addition, owing to the insufficient binding affinity of materials toward glycopeptides, most glycopeptides that have been identified at present are of the sialic acid type, and a large number of neutral glycans, for instance, O-link glycopeptides and high mannose-type glycans are difficult to enrich and identify.
The emergence of smart polymers provides a new avenue for the development of PTM-enriched materials. Several studies have reported that smart polymers can reversibly change their structure and function through external physical, chemical, or biological stimulation, to achieve highly controllable adsorption and desorption of phosphorylated peptides and glycopeptides. Based on this strategy, a series of novel enrichment materials and methods have been developed, which have greatly attracted the interest of researchers. On the one hand, the response changes of smart polymers include the increase or decrease of hydrophobicity, the change of shape and morphology, the redistribution of surface charge, the exposure or hiding of affinity ligands, etc. Changes in these properties can be achieved by simply changing external conditions such as temperature, pH, solvent polarity, and biomolecules. These properties, in turn, enable the fine-tuning of the affinity between the target and the smart polymers. Furthermore, the affinity can provide an additional driving force, which can significantly improve biological separation.
On the other hand, smart polymers provide a series of convenient and expandable platforms for integrating various functional modules, such as specific recognition components, which will facilitate the development of novel enrichment materials for protein methylation, acetylation, and ubiquitination. Smart polymer materials show great potential in the field of separation, which is promising for the analysis and research of protein PTMs. This review summarizes the research progress of smart polymer materials for the separation and enrichment of phosphorylated peptides and glycopeptides according to nearly 50 representative articles from the Web of Science in the past two decades.

Key words: proteomics, enrichment, post-translational modification (PTM), smart polymer, phosphorylated peptides, glycopeptides, review

中图分类号:

O658

郑鑫彤, 王雪, 张福生, 张旭阳, 赵艳艳, 卿光焱. 智能聚合物基材料富集磷酸化肽和糖肽的研究进展[J]. 色谱, 2021, 39(1): 15-25.

ZHENG Xintong, WANG Xue, ZHANG Fusheng, ZHANG Xuyang, ZHAO Yanyan, QING Guangyan. Advances in enrichment of phosphorylated peptides and glycopeptides by smart polymer-based materials[J]. Chinese Journal of Chromatography, 2021, 39(1): 15-25.

图/表 7

表 1 用于富集翻译后修饰产物的代表性智能聚合物基材料

Table 1 Representative smart polymer-based materials used for post-translational modification (PTM) enrichment

Material type	Target	Real biological sample	Stimulus	Binding mode	Ref.
PNIPAM-co-	phosphorylated peptides	HeLa S3 cell lysate	pH/temperature/	hydrogen bonds	[18]
ATBA_0.2@SiO₂			solvent polarity
PNIPAM-co-	phosphorylated peptides and	HeLa cell lysate	pH	hydrogen bonds	[19]
ATBA_0.2@SiO₂	sialylated glycopeptides
Fe₃O₄/PDA/PAMA-Arg	phosphorylated peptides	rat brain lysate	solvent polarity	hydrogen bonds	[20]
Fe₃O₄@PGMA-guanidyl	phosphorylated peptides	tryptic digest of	solvent polarity	-	[21]
		nonfat milk
TMIPs	phosphorylated peptides	-	temperature	size of the imprinting	[22]
				cavities
Poly-(AA-co-hydrazide)	glycopeptides	mouse brain lysate	pH	covalent bonds	[23]
PNIPAM-TP polymer	glycoprotein	HeLa cell lysate	temperature	covalent bonds	[24]
b-PMMA spheres	glycoprotein	egg white	pH/temperature	covalent bonds	[25]
Poly(Pro-Glu)@SiO₂	glycopeptides	HeLa cell lysate	pH	hydrogen bonds	[26,27]
Fe₃O₄@PMAH	glycopeptides	colorectal cancer	-	covalent bonds	[28]
		patient serum

图 1 智能聚合物基材料对多磷酸化肽和唾液酸型糖肽的可控吸附和脱附行为[19]

Fig. 1 Controllable adsorption and desorption behaviors of smart polymer-based materials toward both multiple phosphorylated peptides and sialylated glycopeptides[19] Man: mannose; GlcNAc: N-acetyl-glucosamine; Gal: galactose; Neu5Ac: N-acetylneuraminic acid.

图 2 温敏型分子印迹聚合物的合成和工作模式图[22]

Fig. 2 Synthesis of thermo-sensitive molecular printing polymer and working principle of the material[22] Red, green, yellow, and blue balls represent tyrosine, serine, threonine phosphorylation sites, and unmodified amino acids, respectively. PPA: phenylphosphonic acid; NIPAm: N-isopropylacrylamide; MBA: N,N-methylenebisacrylamide; LCST: lower critical solution temperature; T: temperature.

图 3 聚丙烯酸-co-酰肼材料与常规非均相材料对糖肽以及糖蛋白富集模式的对比图[23]

Fig. 3 Comparison of enrichment patterns of glycopeptide and glycoprotein between poly (AA-co-hydrazide) and conventional heterogeneous materials[23] a. comparison of glycopeptides enrichment strategy between poly(AA-co-hydrazide) and conventional heterogeneous materials[23]; b. kinetics analysis of glycoprotein adsorption using soluble poly(AA-co-hydrazide) or solid/insoluble agarose beads[23]; c. comparison of matrix assisted laser desorption ionization-time of flight-mass spectrometer (MALDI-TOF-MS) signal intensities of the enriched N-glycopeptides of asialofetuin obtained by using different enrichment approaches[23].

图 4 基于可溶性和热敏性PNIPAM-三芳基膦均相富集O-GlcNAc蛋白的策略[24]

Fig. 4 Liquid phase homogenous enrichment strategy of O-GlcNAc protein using highly soluble and thermo-sensitive PNIPAM-triarylphosphine[24] a. working principle of the highly soluble and thermo-sensitive PNIPAM-triarylphosphine[24]; b. synthesis of the highly soluble and thermo-sensitive PNIPAM-triarylphosphine[24].

图 5 用于选择性分离卵清糖蛋白的温敏型聚合物修饰的分子印迹核壳纳米微球的制备示意图[25]

Fig. 5 Preparation of molecularly imprinted core-shell nanospheres modified by thermo-sensitive polymer for selective separation of ovalbumin (OB)[25] MMA: methyl methacrylate; p-VPBA: 4-vinylphenylbronic acid; KPS: potassium persulfate; SDS: sodium dodecyl sulfate; NIPAAm: N-isopropylacrylamide; AAm: acrylamide; MBA: N,N-methylenebisacrylamide; TEMED: N,N,N,N-tetramethylenediamine.

图 6 聚合物材料的筛选及其对糖肽的富集[26,27]

Fig. 6 Screening of polymer materials and enrichment of glycopeptide[26,27] a. highly efficient enrichment of glycopeptides and precise discrimination of glycosylic linkage isomers by Pro-Glu dipeptide based polymeric material, which was screened by orthogonal experiments[26]; b. possible binding model of polyacrylamide-g-allose0.10 with sialic acid through multiple hydrogen bonding interactions[27]; c. influence of grafting ratios of the allose in the polymer for binding with a sialylated glycopeptide[27].

参考文献

[1]	Pandey A, Mann M. Nature, 2000,405(6788):837
[2]	Robinson J T, Thorvaldsdótti H, Winckler W, et al. Nat Biotechnol, 2011,29(1):24
[3]	Hart G W, Copeland R J. Cell, 2010,143(5):672
[4]	Nicholson J K, Lindon J C. Nature, 2008,455(7216):1054
[5]	Mann M, Jensen O N. Nat Biotechnol, 2003,21(3):255
[6]	Pawson T, Scott J D. Trends Biochem Sci, 2005,30(6):286
[7]	Hakomori S. Cancer Res, 1996,56(23):5309
[8]	Hubbard M J, Cohen P. Trends Biochem Sci, 1993,18(5):172
[9]	Vosseller K, Trinidad J C, Chalkley R J, et al. Mol Cell Proteomics, 2006,5(5):923
[10]	Cao J, Shen C P, Wang H, et al. J Proteome Res, 2009,8:662
[11]	Singhal R P, Desilva S S M. Adv Chromatogr, 1992,31:293
[12]	Hemstrom P, Irgum K. J Sep Sci, 2006,29(12):1784
[13]	Serpa G, Augusto E F P, Tamashiro W, et al. J Chromatogr B, 2005,816(1/2):259
[14]	Leitner A. TrAC-Trends Anal Chem, 2010,29(2):177
[15]	Galaev I Y, Mattiasson B. Trends Biotechnol, 1999,17(8):335
[16]	Jochum F D, Theato P. Chem Soc Rev, 2013,42(17):7468
[17]	Chen H, Qi B, Moore T, et al. Small, 2014,10(1):160
[18]	Qing G Y, Lu Q, Li X L, et al. Nat Commun, 2017,8(1):461
[19]	Lu Q, Chen C, Xiong Y T, et al. Anal Chem, 2020,92(9):6269
[20]	Luo B, Zhou X, Jiang P, et al. J Mater Chem B, 2018,6(23):3969
[21]	Xiong Z C, Chen Y J, Zhang L Y, et al. ACS Appl Mater Inter, 2014,6(24), 22743
[22]	Xia Y, Yang X Q. J Sep Sci, 2016,39(2):419
[23]	Bai H H, Fan C, Zhang W J, et al. Chem Sci, 2015,6(7):4234
[24]	Zhang W J, Liu T, Dong H Y, et al. Anal Chem, 2017,89(11):5810
[25]	Gao F X, Ma X T, He X W, et al. Colloid Surface A, 2013,433(20):191
[26]	Qing G Y, Li X L, Xiong P, et al. ACS Appl Mater Inter, 2016,8(34):22084
[27]	Li X L, Xiong Y T, Qing G Y, et al. ACS Appl Mater Inters, 2016,8(21):13294
[28]	Liu L, Yu M, Zhang Y, et al. ACS Appl Mater Inter, 2014,6(10):7823
[29]	Hunter T. Cell, 2000,100(1):113
[30]	Grimsrud P A, Swaney D L, Wenger C D, et al. ACS Chem Biol, 2010,5(1):105
[31]	Olsen J V, Blagoev B, Gnad F, et al. Cell, 2006,127(3):635
[32]	Hunter T. CSH Perspect Biol, 2014,6(5):a020644
[33]	Selkoe D. J Physiol Rev, 2001,81(2):741
[34]	Hammarsten P, Karalija A, Josefsson A, et al. Cancer Res, 2010,16(4):1245
[35]	Heemskerk A A M, Busnel J M, Schoenmaker B, et al. Anal Chem, 2012,84(10):4552
[36]	Qin W J, Zhang W J, Song L N, et al. Anal Chem, 2010,82(22):9461
[37]	Emgenbroich M, Borrelli C, Shinde S, et al. Chem Eur, 2008,14(31):9516
[38]	Stefan H, Sudhirkumar S, Frederic B, et al. Anal Chem, 2011,83(5):1862
[39]	Yan K G, Li S W, Liu L K, et al. Adv Mater, 2019,31(50):1902048
[40]	Raman R, Raguram S, Venkataraman G, et al. Nat Methods, 2005,2(11):817
[41]	Li X L, Liu H L, Qing G Y, et al. J Mater Chem B, 2014,2(16):2276
[42]	Qing G Y, Sun T L. Adv Mater, 2011,23(14):1615
[43]	Lv Z Y, Li X L, Chen Z H, et al. ACS Appl Mater Inter, 2015,7(49):27223
[44]	Xiong Y T, Jiang G, Li M M, et al. Sci Rep, 2017,7(1):40913
[45]	Chen Z H, Lv Z Y, Wang X, et al. NPG Asia Mater, 2018,10(3):e472
[46]	Jin T, Xiong Z C, Zhu X, et al. ACS Macro Lett, 2015,4(5):570
[47]	Song Y Y, Fan J B, Li X L, et al. Adv Mater, 2018,30(39):1803299

智能聚合物基材料富集磷酸化肽和糖肽的研究进展

Advances in enrichment of phosphorylated peptides and glycopeptides by smart polymer-based materials

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

扫码分享

图/表 7

参考文献

相关文章 15

编辑推荐

Metrics

[1]	周然锋, 张惠贤, 尹小丽, 彭西甜. 新型纳米材料在农产品安全分析中的应用进展[J]. 色谱, 2023, 41(9): 731-741.
[2]	解伟亚, 朱晓晗, 梅宏成, 郭洪玲, 李亚军, 黄阳, 秦皓, 朱军, 胡灿. 基于功能材料的固相微萃取技术及其在法庭科学领域中的应用[J]. 色谱, 2023, 41(4): 302-311.
[3]	叶翰章, 刘婷婷, 丁永立, 顾婧婧, 李宇浩, 王琪, 张占恩, 王学东. 泡腾辅助微萃取技术的开发与应用研究进展[J]. 色谱, 2023, 41(4): 289-301.
[4]	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.
[5]	欧阳艺兰, 易琳, 邱露允, 张真庆. 色谱技术在肝素结构分析中的研究进展[J]. 色谱, 2023, 41(2): 107-121.
[6]	赵媛, 刘新, 张译丹, 张健, 刘向, 杨国锋. 基于串联质量标记的帕金森病血浆及血浆外泌体定量蛋白质组学分析[J]. 色谱, 2023, 41(12): 1073-1083.
[7]	翟洪稳, 马红玉, 曹梅荣, 张明星, 马俊美, 张岩, 李强. 在线样品制备技术耦合液相色谱-质谱系统在食品危害物检测中的应用进展[J]. 色谱, 2023, 41(12): 1062-1072.
[8]	余涛, 陈立, 张文敏, 张兰, 卢巧梅. 微孔有机网络材料的合成方法及其在样品前处理中的应用进展[J]. 色谱, 2023, 41(12): 1052-1061.
[9]	王国秀, 陈永雷, 吕文娟, 陈宏丽, 陈兴国. 共价有机框架材料在毛细管电色谱中的应用进展[J]. 色谱, 2023, 41(10): 835-842.
[10]	闫美婷, 龙文雯, 陶雪平, 王丹, 夏之宁, 付琦峰. 金属有机骨架材料在色谱固定相构建及应用中的研究进展[J]. 色谱, 2023, 41(10): 879-890.
[11]	宋春颖, 金高娃, 俞东萍, 夏东海, 丰静, 郭志谋, 梁鑫淼. 超临界流体色谱固定相的发展及在天然产物中的应用[J]. 色谱, 2023, 41(10): 866-878.
[12]	蒋文倩, 陈宇媚, 毕文韬. 基于低共熔溶剂的多孔有机框架材料合成及其在固相萃取中的应用[J]. 色谱, 2023, 41(10): 901-910.
[13]	刘威, 徐之薇, 王睿, 赵雨, 贾琼. 多孔有机框架材料在真菌毒素分离富集与检测中的研究进展[J]. 色谱, 2023, 41(10): 891-900.
[14]	杨涵, 汤雯淇, 曾楚, 孟莎莎, 徐铭. 高效金属有机骨架气相色谱固定相的理性设计[J]. 色谱, 2023, 41(10): 853-865.
[15]	玛依热·阿不力提甫, 钟子豪, 白希. 制备气相色谱在挥发性成分分离中的应用研究进展[J]. 色谱, 2023, 41(1): 37-46.