基于配体垂钓技术筛选三七叶中环氧合酶-2抑制剂

doi:10.3724/SP.J.1123.2024.07003

摘要/Abstract

摘要：

市售环氧合酶-2(COX-2)抑制剂如美洛昔康、塞来昔布等与传统的非甾体抗炎药相比虽能够有效治疗炎症,但是也存在着引起肝毒性、心血管疾病的风险。中药三七、人参等被证实具有良好的抗炎作用且毒副作用小,因此从中药中筛选潜在的COX-2抑制剂对于开发安全有效的新型抗炎药具有重要意义。本研究以磁性纳米材料作为高效载体,采用配体垂钓法替代传统低效筛选手段,结合固定化金属亲和技术,解决了传统酶固定方法带来的酶活性降低或酶分子堆积等问题。首先合成了聚多巴胺(PDA)包覆的Fe₃O₄,在PDA表面螯合Ni²⁺,利用金属离子亲和作用固定COX-2,制备了一种绿色环保、特异性好的垂钓工具。采用扫描电子显微镜、透射电子显微镜、X射线光电子能谱仪、热重分析仪、振动样品磁强计等方法对其结构进行了表征,结果显示磁性纳米材料为核壳结构,粒径为250~300 nm,具有较大的比表面积,且磁性强、稳定性好。以COX-2抑制剂塞来昔布为垂钓目标物对COX-2的固定条件及垂钓条件进行了优化。该法成功应用于三七叶中潜在COX-2抑制剂的筛选,最终得到了13种能与COX-2相互作用的成分,经液相色谱-质谱联用技术鉴定均为20(S)-原人参二醇型皂苷。与传统的筛选方法相比,本方法简便快速,酶活性高,能够实现对特定目标物的捕获与富集。该研究对新型抗炎药的合成与开发具有指导意义,为高效地从中药复杂体系中发现抗炎药物或先导化合物提供了借鉴,同时也为三七叶的资源化合理应用提供了新的思路。

关键词: 配体垂钓, 环氧化酶-2抑制剂, 三七叶, 皂苷, 抗炎

Abstract:

Human health is increasingly affected by chronic inflammation, which can subsequently develop into chronic diseases such as cancer, arthritis, diabetes, and diseases of the cardiovascular and nervous systems. Traditional non-steroidal anti-inflammatory drugs (NSAIDs) that inhibit cyclooxygenase-1 (COX-1) produce side effects, such as irritation of the gastrointestinal tract and renal toxicity. While commercially available inhibitors of the cyclooxygenase-2 (COX-2) enzyme, such as meloxicam and celecoxib, treat inflammation more-effectively than traditional NSAIDs, they associate with liver-toxicity and cardiovascular-disease risks. Modern pharmacological studies have shown that Panax ginseng, Panax notoginseng, and other traditional Chinese medicines have anti-inflammatory properties; these medicines mainly contain flavonoids, alkaloids, saponins, polysaccharides, and other anti-inflammatory components, are highly efficient, and exhibit few side effects, which is advantageous. Therefore, screening potential COX-2 inhibitors from traditional Chinese medicine is greatly significant for the development of safe and effective novel anti-inflammatory drugs. However, screening these traditional medicines in an easy, quick, accurate, and efficient manner presents problem that require urgent solutions because traditional screening methods are cumbersome and inefficient.

In this study, we used the ligand fishing method instead of poorly efficient traditional screening methods, with magnetic nanoparticles used as the carrier owing to their advantageous fast separation speeds. In addition, we also maintained the spatial structure and activity of the fixed enzyme by combining immobilized metal affinity technology, and selected polydopamine (PDA) as a low-toxicity metal-chelating agent owing to its strongly adhesive nature and good chelating ability for various metal ions. The application of PDA solves the problems of metal-ion leakage and limited protein load associated with traditional chelating agents. Firstly, magnetic Fe₃O₄ nanoparticles were hydrothermally synthesized, after which their surfaces were coated with PDA using the magnetic-stirring method, with Ni²⁺ then chelated on the PDA surface and COX-2 fixed through metal-ion affinity, to afford a convenient, fast, green, and specific fishing tool. The structure and properties of the magnetic nanomaterial were characterized by scanning electron microscopy (SEM), transmission electron microscopy (TEM), X-ray photoelectron spectroscopy (XPS), thermogravimetric analysis, vibrating sample magnetometry (VSM), and other methods. The magnetic nanomaterials have core-shell structures with particles that are 250-300 nm in size; they also have a large specific surface area, are strongly magnetic, highly stable, and perform excellently. Celecoxib, a selective COX-2 inhibitor, was used as a fishing target during optimization of the fixed-COX-2 and fishing conditions, including the adsorption and elution conditions. The optimal settings were then successfully used to screen potential COX-2 inhibitors in Panax notoginseng leaves. Methodological experiments revealed that the instrument and method are highly precise, accurate, and repeatable, with a limit of detection (LOD) of 0.02 mg/mL and a limit of quantification (LOQ) of 0.07 mg/mL. Only celecoxib was detected in a fishing solution composed of glipizide, indomethacin, and celecoxib, which implies that immobilized COX-2 exhibits good fishing specificity, and that only components that strongly interact with COX-2 are caught. Thirteen components that interact with COX-2 were identified by liquid chromatography-mass spectrometry for a fishing solution of Panax notoginseng leaves, including notoginsenoside Fa and ginsenoside Rb₁, which are expected to be COX-2 inhibitors. Compared with traditional screening methods, the method developed in this study is simple, rapid, and highly specific and enzyme active, leading to the capture and enrichment of the specific target. This study provides guidance for the synthesis and development of new safe and effective anti-inflammatory drugs, and provides a reference for the efficient discovery of such drugs or lead compounds from complex traditional Chinese medicines; it also provides a new concept for the rational utilization of Panax notoginseng leaves.

Key words: ligand fishing, cyclooxygenase-2 inhibitor (COX-2 inhibitor), Panax notoginseng leaves, saponins, anti-inflammatory

中图分类号:

O658

张帆, 王薇, 曹颖, 张祎, 吴丽杰. 基于配体垂钓技术筛选三七叶中环氧合酶-2抑制剂[J]. 色谱, 2024, 42(12): 1126-1135.

ZHANG Fan, WANG Wei, CAO Ying, ZHANG Yi, WU Lijie. Screening of cyclooxygenase-2 inhibitors in Panax notoginseng leaves based on ligand fishing technique[J]. Chinese Journal of Chromatography, 2024, 42(12): 1126-1135.

图/表 11

图 1 Fe3O4@PDA-Ni2+的(a)SEM及(b)TEM表征图

Fig. 1 (a) SEM and (b) TEM characterization of Fe3O4@PDA-Ni2+

图 2 (a)Fe3O4@PDA-Ni2+的X射线光电子能谱宽谱及(b-f)C 1s、N 1s、O 1s、Fe 2p、Ni 2p窄谱扫描图

Fig. 2 (a) Wide spectrum and (b-f) narrow spectrum scanning of C 1s, N 1s, O 1s, Fe 2p, Ni 2p of X-ray photoelectron spectroscopy of Fe3O4@PDA-Ni2+

表 1 C 1s、O 1s、N 1s、Fe 2p、Ni 2p的峰位及原子比

Table 1 Peak positions and atomic ratios of C 1s, O 1s, N 1s, Fe 2p and Ni 2p

Name	Binding energy/eV	Atomic/%
C 1s	284.94	43.46
O 1s	532.36	11.17
N 1s	399.81	0.92
Fe 2p	710.96	0.46
Ni 2p	852.95	0.41

图 3 Fe3O4@PDA-Ni2+的(a)热重分析、(b)比表面及孔隙度分析及(c)磁性能表征结果

Fig. 3 Results of (a) thermogravimetric analysis of Fe3O4@PDA-Ni2+, (b) specific surface and porosity analyses, and (c)magnetic property characterization

图 4 固定化COX-2在不同(a)Ni2+质量浓度及(b)料液比条件下的垂钓效率(n=3)

Fig. 4 Fishing efficiencies of immobilized COX-2 under different (a) Ni2+ mass concentrations and (b) solid-liquid ratios (n=3)

图 5 固定化COX-2吸附塞来昔布使用不同(a)吸附时间、(b)吸附温度及(c)样品体积时的垂钓效率(n=3)

Fig. 5 Fishing efficiencies of celecoxib adsorbed by immobilized COX-2 at different (a) adsorption times, (b) adsorption temperatures and (c) sample volumes (n=3)

图 6 采用不同(a)洗脱溶剂、(b)洗脱溶剂体积及(c)洗脱时间时目标物的垂钓效率(n=3)

Fig. 6 Fishing efficiencies for the target with different (a) elution solvents, (b) elution solvent volumes and (c) elution times (n=3)

图 7 (a)混合标准溶液、(b)固定化COX-2垂钓液及(c)垂钓后剩余液的色谱图

Fig. 7 Chromatograms of (a) a mixed standard solution, (b) immobilized COX-2 fishing solution and (c) residual solution after fishing Peak identifications: 1. glipizide; 2. indometacin; 3. celecoxib.

图 8 13种皂苷的苷元结构图

Fig. 8 Glycogenin structure of 13 saponins

表 2 垂钓液中13种皂苷成分的名称及结构信息

Table 2 Names and structural information of 13 saponins in fishing fluid

No.	t/min	Experimental m/z ([M-H]^-)	Theoretical m/z ([M-H]^-)
1	17.03	1239.6421	1239.6374	3.8	C₅₉H₁₀₀O₂₇	notoginsenoside Fa	-Glc(2-1)Glc(2-1)Xyl	-Glc(6-1)Glc
2	18.13	1209.6316	1209.6268	4.0	C₅₈H₉₈O₂₆	notoginsenoside FP₂	-Glc(2-1)Glc(2-1)Xyl	-Glc(6-1)Ara(f)
3	18.37	1107.6001	1107.5951	4.5	C₅₄H₉₂O₂₃	ginsenoside Rb₁	-Glc(2-1)Glc	-Glc(6-1)Glc
4	19.49	1077.5889	1077.5845	4.1	C₅₃H₉₀O₂₂	ginsenoside Rc	-Glc(2-1)Glc	-Glc(6-1)Ara(f)
5	19.83	1209.6323	1209.6268	4.5	C₅₈H₉₈O₂₆	notoginsenoside Fc	-Glc(2-1)Glc(2-1)Xyl	-Glc(6-1)Xyl
6	20.76	1077.5886	1077.5845	3.8	C₅₃H₉₀O₂₂	ginsenoside Rb₂	-Glc(2-1)Glc	-Glc(6-1)Ara(p)
7	21.24	1077.5886	1077.5845	3.8	C₅₃H₉₀O₂₂	ginsenoside Rb₃	-Glc(2-1)Glc	-Glc(6-1)Xyl
8	23.22	945.5454	945.5423	3.3	C₄₈H₈₂O₁₈	ginsenoside Rd	-Glc(2-1)Glc	-Glc
9	25.51	945.5447	945.5423	2.5	C₄₈H₈₂O₁₈	gypenoside ⅩⅦ	-Glc	-Glc(6-1)Glc
10	27.09	915.5333	915.5317	1.7	C₄₇H₈₀O₁₇	notoginsenoside Fe	-Glc	-Glc(6-1)Ara(f)
11	28.43	915.5352	915.5317	3.8	C₄₇H₈₀O₁₇	vina-ginsenoside R₁₈	-Glc(2-1)Glc	-Xyl
12	28.94	915.5338	915.5317	2.3	C₄₇H₈₀O₁₇	gypenoside Ⅸ	-Glc	-Glc(6-1)Xyl
13	35.20	783.4907	783.4894	1.7	C₄₂H₇₂O₁₃	ginsenoside F₂	-Glc	-Glc

图 9 (a)三七叶提取液及(b)垂钓液的总离子流色谱图

Fig. 9 Total ion current chromatograms of (a) Panax Notoginseng leaf extract and (b) fishing liquid For peak identifications, see Table 2.

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