共价有机骨架功能材料及其在糖肽选择性富集中的应用

doi:10.3724/SP.J.1123.2021.02001

色谱 ›› 2021, Vol. 39 ›› Issue (6): 588-598.DOI: 10.3724/SP.J.1123.2021.02001

共价有机骨架功能材料及其在糖肽选择性富集中的应用

盛骞莹¹, 周扬², 赵治全¹, 王耀慧¹, 李伟诚¹, 柯燕雄², 蓝闽波¹^,^*(), 卿光焱³^,^*(), 梁鑫淼²^,³

1.华东理工大学化学与分子工程学院, 上海 200237
2.华东理工大学药学院, 上海 200237
3.中国科学院大连化学物理研究所, 辽宁大连 116023

收稿日期:2021-02-02 出版日期:2021-06-08 发布日期:2021-04-13
通讯作者: 蓝闽波,卿光焱
作者简介:Tel:(0411)84379050,E-mail: qinggy@dicp.ac.cn(卿光焱).
* Tel:(021)64253574,E-mail: minbolan@ecust.edu.cn(蓝闽波);
基金资助:
国家自然科学基金(21775116);国家自然科学基金(21804041);国家自然科学基金(21922411);国家自然科学基金(21934005)

Covalent organic framework functional materials and their applications in glycopeptide enrichment

SHENG Qianying¹, ZHOU Yang², ZHAO Zhiquan¹, WANG Yaohui¹, LI Weicheng¹, KE Yanxiong², LAN Minbo¹^,^*(), QING Guangyan³^,^*(), LIANG Xinmiao²^,³

1. School of Chemistry and Molecular Engineering, East China University of Science and Technology, Shanghai 200237, China
2. School of Pharmacy, East China University of Science and Technology, Shanghai, 200237, China
3. Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian 116023, China

Received:2021-02-02 Online:2021-06-08 Published:2021-04-13
Contact: LAN Minbo,QING Guangyan
Supported by:
National Natural Science Foundation of China(21775116);National Natural Science Foundation of China(21804041);National Natural Science Foundation of China(21922411);National Natural Science Foundation of China(21934005)

摘要/Abstract

摘要：

蛋白质糖基化是生物体中最重要的翻译后修饰手段之一,糖蛋白/糖肽的有效分离和富集成为目前糖蛋白组学研究的首要问题。对于复杂的生物样本,糖蛋白的数量较少,酶解后大量高丰度非糖基化修饰肽的存在,使得低丰度糖肽的检测更加困难。因此,需要一些手段来有效地富集糖肽以提高其检测丰度,发展高选择性的糖肽富集材料及方法就成为在分子水平上有效地监测糖蛋白或糖肽的重要途径。相对于传统的糖肽富集材料,共价有机骨架材料具有比表面积大和可修饰位点丰富的优点,在糖肽富集领域具有很大的应用潜力。该文制备了一种新型的共价有机骨架材料(O-T-D-COFs),利用1,3,5-三(4-氨苯基)苯和2,5-二甲氧基苯-1,4-二甲醛作为反应单体通过共聚缩合反应生成的席夫碱构成了材料的框架,对合成后的中间体材料进行氧化处理,从而提高材料的富集性能。利用扫描电镜、透射电镜、红外光谱和固体核磁等表征技术对材料的结构进行了表征,并将其应用于糖肽的选择性富集。分别对富集过程的上样条件、淋洗条件、洗脱条件进行了优化,结合质谱检测技术,从人血清免疫球蛋白G酶解液中观察到32个明显的糖肽信号峰。通过模拟复杂样本体系验证材料富集选择性,在人血清免疫球蛋白G和牛血清白蛋白的酶解液混合物摩尔比达到1∶50时,该材料仍然保持了良好的选择性。此外,还考察了材料的检测限、富集容量、回收率等富集性能,及在实际样品中的应用潜力。以人血清免疫球蛋白G为评价对象,O-T-D-COFs具有较低的检测限(2.5 fmol/μL)、较高的富集容量(120 mg/g),及较好的富集回收率(103.5%±6.6%、101.5%±10.4%)。在血清样品中富集到来自53个N-糖蛋白中的86个N-糖肽序列,并鉴定到了94个N-糖基化位点。这些结果都表明,该材料在糖肽富集领域有较好的应用前景。

关键词: 质谱, 共价有机骨架材料, 功能化修饰, 糖肽, 选择性富集

Abstract:

Protein glycosylation is among the most important post-translational modifications in living organisms and the research in the field of protein glycosylation continues to garner attention. Currently, the efficient separation and enrichment of glycoproteins and glycopeptides is the primary challenge of glycoproteomics research. The number of glycoproteins is small in complex biological samples. Moreover, the presence of highly-abundant, non-glycosylated, and modified peptides makes the detection of low-abundance glycopeptides more difficult. Therefore, efficient glycopeptide enrichment methods are required to improve the detection of these compounds. The development of highly selective glycopeptide enrichment tools is important to efficiently capture glycoproteins or glycopeptides at the molecular level. Compared with traditional glycopeptide-enriched materials, covalent organic framework materials have the advantages of large specific surface area and rich modification sites, thereby exhibiting great application potential in the field of glycopeptide enrichment. In this study, a novel covalent organic framework material (O-T-D-COFs) was prepared and applied for selective glycopeptide enrichment. We applied the solvothermal method, using 2,5-dimethoxy benzene-1,4-2 formaldehyde and 1,3,5-Tris(4-aminophenyl) benzene, to synthesize imino-based COFs. The Schiff base generated via copolymerization condensation reaction constitutes the framework of the material. Next, the synthesized intermediate material was oxidized to improve the enrichment performance of the material. The functional, specific glycopeptide-binding groups were modified on the COF channels and the structure of the material was characterized using scanning and transmission electron microscope, as well as infrared spectrum and solid-state nuclear magnetic resonance. The enrichment conditions comprised the loading and elution steps, including the optimization of the elution conditions. We could observe the clear profile of 32 glycopeptides derived from human serum immunoglobulin G (IgG) tryptic digests with a significantly improved signal-to-noise (S/N) ratio. We applied a complex sample system to verify the enrichment selectivity of the material when the molar ratios of the IgG and bovine serum albumin (BSA) tryptic digest mixtures reached 1∶50. In addition, we investigated the enrichment performance of the detection limit, enrichment capacity, recovery rate of the material, and the application potential in glycopeptides enrichment using real samples. The material showed a good detection limit (2.5 fmol/μL), an ideal enrichment capacity (120 mg/g), and enrichment recovery (103.5%±6.6% and 101.5%±10.4%). We identified a total of 86 glycopeptides derived from 53 glycoproteins with 94 N-glycosylation sites from only 1 μL human serum. The O-T-D-COFs exhibited a good glycopeptide separation and enrichment potential, indicating that the COF material has promising application potential in glycoproteomics.

Key words: mass spectrometry (MS), covalent organic framework (COF) material, functional modification, glycopeptides, selective enrichment

中图分类号:

O658

盛骞莹, 周扬, 赵治全, 王耀慧, 李伟诚, 柯燕雄, 蓝闽波, 卿光焱, 梁鑫淼. 共价有机骨架功能材料及其在糖肽选择性富集中的应用[J]. 色谱, 2021, 39(6): 588-598.

SHENG Qianying, ZHOU Yang, ZHAO Zhiquan, WANG Yaohui, LI Weicheng, KE Yanxiong, LAN Minbo, QING Guangyan, LIANG Xinmiao. Covalent organic framework functional materials and their applications in glycopeptide enrichment[J]. Chinese Journal of Chromatography, 2021, 39(6): 588-598.

图/表 10

图 1 O-T-D-COF的合成路线

Fig. 1 Synthetic route of O-T-D-COF

图 2 O-T-D-COF材料放大(a)5000倍和(b)18000倍的SEM图及(c)固体核磁13C谱和(d)红外光谱图

Fig. 2 SEM images of O-T-D-COF at (a) 5000 and (b) 18000 magnifications, and (c)13C NMR spectra and (d) IR spectra of O-T-D-COF

图 3 O-T-D-COF材料的TEM图

Fig. 3 TEM images of O-T-D-COF

图 4 (a)上样液的酸度、(b)上样液中的乙腈体积分数、(c)淋洗液的酸度、(d)洗脱液的酸度对富集效果的影响

Fig. 4 Effects of (a) loading buffer acidity, (b) ACN volume percentage in loading buffer, (c) washing buffer acidity, and (d) eluent buffer acidity on enrichment m/z 2601.2, 2633.2, 2764.1, 2795.5, 2925.6, and 2957.5: six highly abundant glycopeptides of IgG digests.

图 5 富集(a)前和(b)最优条件下富集的糖肽质谱图

Fig. 5 Mass spectra of the tryptic digest of IgG (a) before and (b) after enrichment under optimum conditions m/z of glycopeptide peak No. 1: 2398.5; 2: 2430.4; 3: 2455.5; 4: 2487.5; 5: 2560.5; 6: 2592.5; 7: 2601.2; 8: 2617.5; 9: 2633.2; 10: 2642.4; 11: 2649.5; 12: 2659.0; 13: 2691.0; 14: 2764.1; 15: 2779.6; 16: 2795.5; 17: 2804.5; 18: 2811.5; 19: 2821.3; 20: 2836.5; 21: 2853.3; 22: 2925.6; 23: 2957.5; 24: 2966.6; 25: 2983.2; 26: 2998.5; 27: 3015.1; 28: 3054.5; 29: 3129.2; 30: 3160.5; 31: 3216.6; 32: 3248.6.

图 6 复杂体系的糖肽富集质谱图

Fig. 6 Mass spectra of the complex system for glycopeptides enrichment Mixture of tryptic digests of human serum immunoglobulin G (IgG) and bovine serum albumin (BSA) at amount of material ratios of (a) 1∶10 and (b) 1∶50. Peak Nos.: see Fig. 5.

图 7 (a)5 fmol/μL和(b)2.5 fmol/μL的IgG酶解液的富集质谱图

Fig. 7 Mass spectra of the tryptic digests of (a) 5 fmol/μL and (b) 2.5 fmol/μL IgG Peak Nos.: see Fig. 5.

图 8 不同质量O-T-D-COF材料富集6 μg IgG酶解液的结果

Fig. 8 Results of enrichment of 6 μg IgG tryptic digest with different amount of O-T-D-COF materials m/z 2601.2, 2633.2, 2764.1, 2795.5, 2925.6, and 2957.5: glycopeptides.

图 9 从IgG酶解液回收轻/重二甲基标记的去糖基化肽的3组平行试验

Fig. 9 Three paralleled experiments of the recovery of the light- and heavy-dimethyl labeled deglycosylated peptides from human IgG tryptic digest

表 1 人IgG酶解液经O-T-D-COF材料富集后两个去糖基化肽的回收率(n=3)

Table 1 Recoveries of two deglycosylated peptides from human IgG tryptic digest enriched by O-T-D-COF (n=3)

No.	Recoveries/%
No.	EEQFN#STFR (m/z 1158.5)	EEQYN#STYR (m/z 1190.5)
1	110.1	93.8
2	99.0	111.9
3	101.4	98.8
Average	103.5±6.6	101.5±10.4

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共价有机骨架功能材料及其在糖肽选择性富集中的应用

Covalent organic framework functional materials and their applications in glycopeptide enrichment

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