脑脊液外泌体亚群的分离及其蛋白质组学分析

doi:10.3724/SP.J.1123.2024.10014

摘要/Abstract

摘要：

外泌体是一类尺寸为30~200 nm、携带有蛋白质等生物活性物质的细胞外小囊泡,能够分为具有不同功能的亚群,对外泌体异质性的了解有助于研究其在生理和病理中的作用机制。脑脊液来源的外泌体作为疾病的生物标志物具有巨大潜力,但是相关蛋白质组学的研究报道较少,且缺乏对脑脊液外泌体亚群的研究。本研究发展了串联体积排阻色谱法用于分离脑脊液外泌体亚群,并结合纳升级液相色谱-捕集离子淌度飞行时间质谱联用技术(nanoLC-TIMS-TOF-MS),对创伤性脑损伤患者的外泌体亚群进行了蛋白质组学分析。结果表明,利用串联体积排阻色谱法分离得到4个不同尺寸的脑脊液外泌体亚群,不同亚群共鉴定到739个蛋白质,进一步的蛋白质组学分析结果表明外泌体亚群与细胞信号转导、凝血过程和免疫反应等生物过程密切相关。此外,研究结果揭示了脑脊液外泌体亚群的蛋白表达存在异质性,特别是大尺寸的亚群在不同样本间存在较大的差异。综上,本研究利用开发的串联体积排阻色谱方法分离得到脑脊液外泌体亚群,并从蛋白质组学的角度丰富了对创伤性脑损伤患者脑脊液外泌体的认知。

关键词: 外泌体, 外泌体亚群, 蛋白质组学, 脑脊液, 创伤性脑损伤

Abstract:

Exosomes are small extracellular vesicles 30-200 nm in diameter that contain many bioactive macromolecules, including proteins, lipids, and nucleic acids; consequently, they play important roles in many physiological and pathological processes and are classified into various property-dependent subtypes. Research into exosome heterogeneity helps broaden our understanding of the physiological and pathological mechanisms associated with exosomes. Exosomes exist in many human biological fluids, with those derived from cerebrospinal fluid (CSF) regarded as potential disease biomarkers. Despite this, few studies have focused on their proteomics, and little research into CSF-derived exosome subtypes has been reported. Traumatic brain injury (TBI) is a major public health issue characterized by a large number of patients and complex pathological processes. While a comprehensive understanding of the pathophysiological processes that underpin TBI is essential for developing therapeutic interventions, proteomic studies into CSF-derived exosomes in patients with TBI are limited. Herein, we designed a tandem size-exclusion chromatography protocol for isolating and profiling the proteins of CSF-derived exosome subtypes from patients with TBI using nanoscale liquid chromatography and trapped-ion mobility spectrometry time-of-flight mass spectrometry (nanoLC-TIMS-TOF-MS). We first centrifuged the collected CSF to remove cells and cell debris, after which it was concentrated by ultrafiltration to increase the exosome concentration and remove small proteins and peptides. A mini-size exclusion chromatography (Mini-SEC) column was then used to separate the exosomes from large amounts of interfering proteins, after which high performance liquid-SEC (HPL-SEC) was used to further separate exosomes according to size. The entire extracellular-vesicle-subset separation and purification process takes approximately 1 h for a single CSF sample. Four differently sized exosome subtypes were successfully isolated and are referred to as S1, S2, S3, and S4 in order of descending size. The S1 subtype exhibited the highest exosome purity according to the particle-to-protein ratio. Multiple characterization methods, including transmission electron microscopy (TEM), Western blotting (WB), and nanoparticle tracking analysis (NTA), confirmed that the exosome subtypes had been successfully acquired. NanoLC-TIMS-TOF-MS, combined with database searching were then used to characterize the proteins. A total of 739 proteins were identified, of which 79% and 72% matched all proteins and the top 100 proteins in the Vesiclepedia database, respectively. Moreover, gene ontology analysis revealed that the identified proteins are mainly located in extracellular exosomes, and that the isolated exosome subtypes are closely related to multiple biological processes, including cell signaling, coagulation, and immune responses. Hierarchical cluster analysis revealed that samples from the same exosome subset are grouped first. Principal-component and Pearson’s correlation coefficient analyses revealed that the proteins expressed in the CSF-derived exosome subtypes are heterogeneous. Interestingly, the proteins identified in the S1 subtype varied greatly between samples, highlighting the potential applicability of this subtype to formulating precise therapeutic regimens for different patients. We also analyzed the highly expressed proteins in the exosome subtypes, which revealed that the enrichment pathway of the S1 subtype involves Vitamin B12 metabolism and the regulation of protein catabolic processes, while the specific enrichment pathway of the S2 subtype includes binding and ligand uptake by scavenger receptors, heme scavenging from plasma, and an inflammatory response. In contrast, the unique enrichment pathway of the S3 subtype contains complementary and coagulation cascades and acute-phase responses, while that of the S4 subtype includes post-translational protein phosphorylation. Furthermore, STRING-based protein-association analysis predicted multiple interactions among proteins in the various exosome subtypes. In conclusion, the developed tandem size-exclusion chromatography method was used to isolate cerebrospinal fluid exosome subtypes. This study enriches knowledge regarding cerebrospinal fluid exosomes in patients with TBI based on proteomics.

Key words: exosomes, exosome subtypes, proteomics, cerebrospinal fluid (CSF), traumatic brain injury (TBI)

中图分类号:

O658

陈晓菲, 刘威, 张文镓, 李言鹏, 王志华, 高明霞, 张祥民. 脑脊液外泌体亚群的分离及其蛋白质组学分析[J]. 色谱, 2025, 43(5): 518-528.

CHEN Xiaofei, LIU Wei, ZHANG Wenjia, LI Yanpeng, WANG Zhihua, GAO Mingxia, ZHANG Xiangmin. Isolation and proteomics analysis of cerebrospinal fluid exosome subtypes[J]. Chinese Journal of Chromatography, 2025, 43(5): 518-528.

图/表 8

表1 创伤性脑损伤患者的信息

Table 1 Information on patients with traumatic

Index	Age	Gender	Post-operative time for sampling/d
CSF1	79	male	1
CSF2	82	female	2

图1 脑脊液来源的不同尺寸的外泌体亚群的(a)分离和(b)蛋白质组学分析流程

Fig. 1 Workflows of (a) isolation and (b) proteomics analysis of distinct-size exosome subtypes from human cerebrospinal fluid (CSF) HPL-SEC: high performance liquid-size exclusion chromatography; NanoLC-TIMS-TOF-MS: nanoscale liquid chromatography and trapped-ion mobility spectrometry time-of-flight mass spectrometry.

图2 Mini-SEC柱馏分的(a)蛋白质含量和(b)免疫印迹检测图像;Mini-SEC柱(c)7~10号馏分和(d)11~14号馏分分别合并后的HPL-SEC色谱图

Fig. 2 (a) Contents of proteins and (b) Western blot images of fractions isolated from Mini-SEC column; chromatograms of HPL-SEC of the sample obtained by (c) combining fractions 7 to 10 and (d) combining fractions 11 to 14 from Mini-SEC column

表2 脑脊液经过超滤和2次体积排阻色谱处理后得到的样品的外泌体纯度

Table 2 Exosome purities of samples obtained from CSF processed by ultrafiltration and two SECs

Samples/process	Exosome content/ (10¹⁰ particles/mL)	Protein content/ (mg/mL)	Particle-to-protein ratio/(10¹⁰ particles/mg)
Concentrated CSF sample/ultrafiltration	130	139	0.935
Fractions 7-10 mixture/Mini-SEC	150	13.1	11.5
Fraction S1/Mini-SEC and HPL-SEC	37.4	0.621	60.2
Fraction S2/Mini-SEC and HPL-SEC	47.6	2.33	20.4
Fraction S3/Mini-SEC and HPL-SEC	39.1	2.00	19.6
Fraction S4/Mini-SEC and HPL-SEC	51.0	7.70	6.62

图3 脑脊液外泌体亚群的表征

Fig. 3 Characterization of exosome subtypes derived from CSF a. TEM images of S1-S4 (bar=100 nm); b. Western blot images; c. size distribution of HPL-SEC fractions.

图4 鉴定到的脑脊液外泌体蛋白质与Vesiclepedia外泌体数据库中(a)所有蛋白质和(b)按鉴定次数排序的前100个蛋白质的对比;(c)两个脑脊液样本外泌体亚群中鉴定到蛋白质的韦恩图;(d)脑脊液外泌体蛋白质的基因本体论分析

Fig. 4 Comparison between CSF exosomal proteins identified in this work and (a) all proteins and (b) top 100 proteins in order of number of times identified from Vesiclepedia exosome database; (c) Venn diagrams of proteins identified in exosome subtypes from two CSF samples; (d) gene oncology analysis of CSF exosomal proteins

图5 脑脊液外泌体亚群的蛋白质组学分析

Fig. 5 Analysis of proteomics of exosomes subtypes derived from CSF a. differentially expressed proteins of exosome subtypes and hierarchical clustering analysis; b. PCA analysis of exosome subtypes; c. Pearson’s correlation coefficient analysis of proteins label-free quantification (LFQ) intensity of exosome subtypes; d. differentially expressed proteins of highly expressed proteins among exosome subtypes; e. protein-protein interaction analysis for S1 exosome subtype.

表3 两个样品的外泌体亚群各自高表达蛋白质的通路和过程富集分析

Table 3 Pathway and process enrichment analysis for highly expressed proteins in the exosome subtypes of two samples

Pathway description	Number of genes
Pathway description	S1	S2	S3	S4
Vitamin B12 metabolism	5		3
Regulation of protein catabolic process	3
Binding and uptake of ligands by		5	3	3
scavenger receptors
Scavenging of heme from plasma		3
Inflammatory response		3
Complement and coagulation cascades			4	3
Acute-phase response			3
Post-translational protein phosphorylation				4

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