尿液细胞外囊泡的高效亲和纯化捕获与蛋白质组学分析

doi:10.3724/SP.J.1123.2024.11013

摘要/Abstract

摘要： 目前,液体活检因其创伤小、易获取且操作简便的优点,已成为癌症诊断中传统组织活检的替代方法。尿液来源的细胞外囊泡(extracellular vesicles, EVs)已被确定为癌症生物标志物的重要来源。EVs是由细胞分泌的磷脂双分子层囊泡,内含蛋白质、DNA及RNA等成分,且由于双层磷脂膜的保护,EVs内的蛋白质可免受体液中酶的降解。然而,在蛋白质组学分析中,低产率使得从生物体液中分离EVs仍是一个挑战。在本研究中,我们采用亲和磁珠EVlent对尿液中的EVs进行富集,EVlent通过识别EVs表面的特异性蛋白质实现高选择性富集。首先使用蛋白免疫印迹、纳米粒子追踪分析和透射电子显微镜对尿液中的EVs进行综合表征,结果表明,EVlent亲和磁珠成功的从尿液中分离出了EVs,且富集效果优于传统的超速离心方法。接下来,将此方法应用于15例健康志愿者和15例前列腺癌患者的尿液EVs蛋白质组学分析,并筛选潜在的肿瘤标志物。结果显示,健康对照组平均鉴定出2039种蛋白质和14490条肽段,前列腺癌患者中分别鉴定出1982种蛋白质和13100条肽段。进一步分析发现,91种蛋白质属于Vesiclepedia数据库中最常见的100种EV蛋白质。与健康对照组相比,前列腺癌患者尿液EVs中88种蛋白质表达上调,90种蛋白质下调。KEGG分析揭示4种蛋白质(尿激酶型纤溶酶原激活剂(PLAU)、血小板衍生生长因子A(PDGFA)、基质金属蛋白酶3 (MMP3)和神经母细胞瘤RAS病毒癌基因同源物(NRAS))在前列腺癌通路中富集,这些蛋白质未来有希望作为前列腺癌的潜在生物标志物,可以为前列腺癌的早期诊断及预后提供重要依据。

关键词: 细胞外囊泡, 尿液, 蛋白质组学, 前列腺癌, 亲和纯化

Abstract:

Liquid biopsy is a promising alternative to traditional tissue biopsies for diagnosing cancer because it offers advantages such as minimal invasiveness, accessibility, and ease of operation. Extracellular vesicles (EVs) are lipid bilayer vesicles that contain proteins, DNA, and RNA and are secreted by cells. Indeed, urinary EVs are important sources of cancer biomarkers. The lipid bilayer protects EV proteins from degradation by enzymes present in bodily fluids. Prostate cancer (PCa) is among the most prevalent malignancies in developed countries and is the second-leading cause of cancer-related mortality in men. Current screening methods commonly used to initially evaluate patients with suspected PCa include serum prostate-specific antigen (PSA) testing and digital rectal examination (DRE), with magnetic resonance imaging (MRI) and transrectal ultrasound often recommended for further assessment. However, both PSA testing and DRE have limited specificities, which results in a substantial number of unnecessary prostate biopsies. Consequently, additional reliable biomarkers need to be urgently discovered for rapidly diagnosing PCa more accurately. Prostate-derived secretions, including those associated with malignancies, are detectable in urine owing to the anatomical proximity of the prostate to the urethra; hence urine is a promising liquid-biopsy medium for discovering PCa biomarkers, which is a topic that has been the focus of extensive research efforts in recent years. However, isolating EVs from biofluids in sufficient yields for proteomics analysis remains challenging.

In this study, functional magnetic beads EVlent (extracellular vesicles isoLated efficiently, naturally, and totally) with high-affinity capabilities were developed for selectively enriching EVs from biological fluids.The surfaces of the beads were modified with three antibodies that target CD9, CD63, and CD81, which enables the specific recognition of EV surface proteins. The isolation performance of EVlent was validated by comprehensively characterizing urinary EVs using Western blotting (WB), nanoparticle tracking analysis (NTA), and transmission electron microscopy (TEM). WB revealed prominent bands for EV markers (CD9, TSG101, and HSP70) in EVlent-enriched samples, whereas weaker bands were observed following ultracentrifugation (UC). NTA revealed that the EVs isolated by EVlent are predominantly in the 50-400 nm size range, with a content of 4.1×10⁹ particles/mL, which is significantly higher than the value of 1.8×10⁹ particles/mL obtained by UC. TEM confirmed that the isolated EVs have characteristic elliptical or cup-shaped vesicular structures. These findings demonstrate that EVlent outperforms UC in terms of enrichment efficiency and purity, delivering a separation efficiency of 87.2% compared to the value of 30.3% obtained by UC. We used proteomics to analyze urinary EVs isolated from 15 healthy volunteers and 15 patients with prostate cancer using EVlent affinity magnetic beads with the aim of identifying potential biomarkers for prostate cancer. On average, 2039 proteins and 14490 peptides were identified in the control group, while 1982 proteins and 13100 peptides were identified in the patient group. Further analysis revealed 91 proteins commonly found in the Vesiclepedia database (Top 100). Compared with the healthy volunteers, 88 proteins were upregulated and 90 proteins were downregulated in patients with prostate cancer. Gene ontology (GO) analysis showed that these upregulated proteins are enriched in extracellular exosomes, extracellular space, extracellular region, collagen-containing extracellular matrix, proteolysis and protein-binding. Pathway analysis using the Kyoto Encyclopedia of Genes and Genomes (KEGG) highlighted associations between ribosomes, protein digestion and absorption, complement and coagulation cascades, prostate cancer, transcriptional misregulation in cancer, aldosterone-regulated sodium reabsorption, endocrine and other factor-regulated calcium reabsorption, and pancreatic secretion. Notably, four proteins including plasminogen activator urokinase (PLAU), platelet-derived growth factor subunit A (PDGFA), matrix metalloproteinase 3 (MMP3), and neuroblastoma RAS viral oncogene homolog (NRAS) were identified within the prostate cancer pathway, highlighting their potential as biomarkers for the early diagnosis and prognosis of prostate cancer. In conclusion, this study introduced EVlent as a robust platform for the efficient isolation and proteomics analysis of EVs, providing valuable insight into urinary EV biomarkers and their clinical prostate-cancer applications.

Key words: extracellular vesicles, urine, proteomics, prostate cancer, affinity purification

中图分类号:

O658

张贵元, 詹震, 陶纬国, 张昊. 尿液细胞外囊泡的高效亲和纯化捕获与蛋白质组学分析[J]. 色谱, 2025, 43(5): 508-517.

ZHANG Guiyuan, ZHAN Zhen, TAO Weiguo, ZHANG Hao. Efficient capture and proteomics analysis of urinary extracellular vesicles by affinity purification[J]. Chinese Journal of Chromatography, 2025, 43(5): 508-517.

图/表 6

图1 EVlent富集尿液中的EVs用于蛋白质组学研究

Fig. 1 EVlent enrichment of extracellular vesicle (EVs) in urine for proteomics analysis

图2 EVlent所富集EVs的相关表征

Fig. 2 Characterization of EVlent enriched EVs a. EVs in urine were analyzed by Western blotting (WB) for the biomarker proteins TSG101, CD9 and HSP70; b. nanoparticle tracking analysis (NTA) of EVs isolated from urine by EVlent; c, d. transmission electron microscopy (TEM) of EVs isolated from urine by EVlent.

图3 不同方法富集EVs的回收率(n=3)

Fig. 3 Recovery rate of EVs enriched by different methods (n=3) a. WB experiment of enriching EVs by different methods; b. recovery rate analysis of different enrichment methods.

图4 健康志愿者(Control 1~Control 3)与前列腺癌患者(PC1~PC3)的尿液细胞外囊泡蛋白质组学分析

Fig. 4 Proteomic analysis of urine extracellular vesicle in healthy volunteers (Control 1-Control 3) and prostate cancer patients (PC 1-PC 3) a. number of identified proteins and peptides; b. comparison between EVlent and Vesiclepedia databases; c. comparison of Top 100 in EVlent and Vesiclepedia databases.

图5 前列腺癌患者与健康志愿者尿液EVs差异表达蛋白质分析

Fig. 5 Analysis of differentially expressed proteins in urine EVs of prostate cancer patients and healthy volunteers a. Volcano plot of differentially expressed proteins (|log2 (Fold change)|>1, p < 0.05); b. heat map; c. Gene ontology (GO) analysis of upregulated proteins.

图6 尿液EVs中上调蛋白质的KEGG分析

Fig. 6 Kyoto encyclopedia of genes and genomes (KEGG) analysis of upregulated proteins in urine EVs

参考文献

[1]	Greening D W, Simpson R J. Proteomics, 2021, 21(13/14): e2100126
[2]	Kalluri R. J Clin Invest, 2016, 126(4): 1208
[3]	Kalluri R, LeBleu V S. Science, 2020, 367(6478): eaau6977
[4]	Witwer K W, Goberdhan D C, O'Driscoll L, et al. J Extracell Vesicles, 2021, 10(14): e12182
[5]	Alberro A, Iparraguirre L, Fernandes A, et al. Int J Mol Sci, 2021, 22(15): 8163
[6]	Marar C, Starich B, Wirtz D. Nat Immunol, 2021, 22(5): 560
[7]	Schubert A, Boutros M. Mol Oncol, 2021, 15(1): 3
[8]	Braun F, Rinschen M, Buchner D, et al. J Extracell Vesicles, 2020, 10(1): e12026
[9]	Fujita K, Kume H, Matsuzaki K, et al. Sci Rep, 2017, 7: 42961
[10]	Crocetto F, Russo G, Di Zazzo E, et al. Cancers (Basel), 2022, 14(13): 3272
[11]	Joncas F H, Lucien F, Rouleau M, et al. Prostate, 2019, 79(15): 1767
[12]	Ramirez-Garrastacho M, Bajo-Santos C, Line A, et al. Br J Cancer, 2022, 126(3): 331
[13]	Bernardino R M M, Leao R, Henrique R, et al. Int J Mol Sci, 2021, 22(24): 13605
[14]	Sequeiros T, Rigau M, Chiva C, et al. Oncotarget, 2016, 8(3): 4960
[15]	Pang B, Zhu Y, Ni J, et al. Theranostics, 2020, 10(5): 2309
[16]	Welsh J A, Goberdhan D C I, O'Driscoll L, et al. J Extracell Vesicles, 2024, 13(2): e12404
[17]	Zhu J, Zhang J, Ji X, et al. J Proteome Res, 2021, 20(10): 4901
[18]	Zhang G, Ma C, Ma L, et al. Anal Chem, 2025, 97(9):4889
[19]	Ni J, Cozzi PJ, Duan W, et al. Cancer Metastasis Rev, 2012, 31(3/4): 779
[20]	Manouchehri L, Zinati Z, Nazari L. World J Surg Oncol, 2024, 22(1): 177
[21]	Hosen S M Z, Uddin M N, Xu Z, et al. Front Immunol, 2022, 13: 1060957
[22]	Ding Y, Niu W, Zheng X, et al. J Gastrointest Oncol, 2022, 13(6): 3100
[23]	Nassir A M, Kamel H F M. Saudi J Biol Sci, 2020, 27(8): 1975
[24]	Li L, Ameri A H, Wang S, et al. Oncogene, 2019, 38(35): 6241
[25]	Hagberg Thulin M, Jennbacken K, Damber J E, et al. Clin Exp Metastasis, 2014, 31(3): 269
[26]	Gabriel K N, Jones A C, Nguyen J P, et al. Int J Oncol, 2016, 49(4): 1541
[27]	Gong Y, Chippada-Venkata U D, Oh W K. Cancers (Basel), 2014, 6(3): 1298
[28]	Ganguly S S, Hostetter G, Tang L, et al. Oncogene, 2020, 39(1): 204
[29]	Frieling J S, Li T, Tauro M, et al. Neoplasia, 2020, 22(10): 511
[30]	Li S, Zhuo Z, Chang X, et al. Gene, 2020, 727: 144262
[31]	Meng D, Yang S, Wan X, et al. Int J Biochem Cell Biol, 2016, 73: 30
[32]	Traynor P, McGlynn L M, Mukhergee R, et al. Dis Markers, 2008, 24(3): 157

编辑推荐

Metrics

阅读次数

全文

HTML			PDF

最新录用	在线预览	正式出版	最新录用	在线预览	正式出版
0	0	9	15	0	31

来源	本网站	其他网站

次数	55	0
比例	100%	0%

摘要

136

最新录用	在线预览	正式出版

84	0	52

	来源	本网站

	次数	136
	比例	100%