多肽识别导向的外泌体分离富集方法研究进展

doi:10.3724/SP.J.1123.2024.10015

摘要/Abstract

摘要：

外泌体是由细胞分泌的双层膜囊泡,携带有丰富的生物分子,是细胞间信息交流的重要媒介,与多种疾病的发生发展密切相关。在复杂体系中开展外泌体分离富集研究,对于疾病诊断、预后检测和分子机制研究具有重要意义。但外泌体广泛存在于复杂生命体系中,尺寸小且分布范围宽,为其分离富集带来了困难与挑战。目前已经发展了基于物理性质的超速离心、体积排阻色谱、超滤和聚合物沉淀等方法。以亲和配体为识别单元,基于分子识别的亲和分离策略能够实现外泌体高选择性分离富集。在众多分子识别工具中,多肽凭借着可设计性强、构象自由灵活等优势,被应用于外泌体亲和分离之中。本文首先对目前外泌体分离富集方法进行了总结,之后重点介绍了以外泌体蛋白质和生物膜特性为靶标的亲和多肽设计与筛选原理及其在外泌体亲和分离富集中的应用。

关键词: 外泌体, 分子识别, 多肽, 分离富集

Abstract:

Exosomes are bilayered vesicles derived from living cells and bacteria that are loaded with abundant biomolecules, such as proteins and nucleic acids. As an important medium of remote cell communication, exosomes are closely related to the occurrence and development of a number of diseases, including those involving tumors and inflammation. The isolation and enrichment of exosomes in complex biosystems is greatly significant for the diagnosis, prognosis, and detection of diseases, as well as in molecular-mechanism research. However, exosomes are usually nanoscale size distribution and widely existed in complex biological samples, including blood, tissue fluids, and urine, which bring difficulties and challenges to the isolation and enrichment of exosomes. To address this issue, several methods based on the physical properties of exosomes have been developed. For example, exosomes can be obtained by ultracentrifugation at high centrifugal force based on density differences; they can also be isolated and enriched by size-exclusion chromatography and ultrafiltration based on size heterogeneity. Exosomes can also be separated in high yields but with low purities using commercial polymer-coprecipitation-based isolation kits. While the abovementioned methods can be used to isolate and enrich exosomes in a highly efficient manner, accurately distinguishing interfering particles, including protein aggregates and microvesicles, in biosystems is still difficult, resulting in the poor purity of exosome isolation and enrichment. Affinity ligands are widely used during the affinity isolation and enrichment of exosomes. Antibodies exhibit high selectivity and affinity; consequently exosomes can be captured highly selectively by exploiting specific antigen/antibody interactions. However, antibodies also have some limitations, including complex preparation procedures, high costs, and poor stability. Chemical affinity ligands, such as aptamers, peptides, and small molecules, are also widely used to isolate and enrich exosomes. As a kind of molecular recognition tool, peptides contain a variety of amino acids and exhibit many advantages, including good biocompatibility, low immunogenicity, and design flexibility. Solid-phase synthesis strategies have rapidly developed, thereby providing a basis for automated and large-scale peptide synthesis. Affinity peptides have been widely used to recognize and analyze target biomolecules in complex physiological environments in a highly selective manner. A series of protein-targeting peptides has been reported based on the biomolecular characteristics of exosomes. These affinity peptides can be specifically anchored onto highly enriched transmembrane proteins on exosome surfaces, thereby enabling the efficient and highly selective isolation and enrichment of exosomes in complex systems. Additionally, exosomes contain stable bilayer membranes consisting of abundant and diverse phospholipid molecules. The development of phospholipid-molecule-targeting peptides is expected to effectively eliminate interference from protein aggregates and other particles. In addition to differences in the compositions of phospholipids in biofilms, exosomes are smaller and more curved than apoptotic bodies and microvesicles. A series of affinity peptides capable of inducing and sensing high membrane curvatures are widely used to isolate and enrich exosomes. The tumor microenvironment can produce and release tumor-derived exosomes that are buried in a large number of normal cell-derived exosomes. Accordingly, pH-responsive peptides have been designed and modified based on the acidic environments of tumor-derived exosomes, which were accurately and tightly anchored via peptide insertion and folding. Focusing on the current status of exosome research, this paper introduces and summarizes current and widely used methods for isolating and enriching exosomes. Various exosome-targeting peptide-design and screening principles are introduced based on the characteristics and advantages of peptides. The applications of these peptides to the isolation and enrichment of exosomes are also summarized, thereby providing strong guidance for the efficient and highly selective isolation and enrichment of exosomes in complex life-related systems.

Key words: exosome, molecular recognition, peptide, isolation and enrichment

中图分类号:

O658

徐坤, 黄嫣嫣, 赵睿. 多肽识别导向的外泌体分离富集方法研究进展[J]. 色谱, 2025, 43(5): 446-454.

XU Kun, HUANG Yanyan, ZHAO Rui. Research progress of peptide recognition-guided strategies for exosome isolation and enrichment[J]. Chinese Journal of Chromatography, 2025, 43(5): 446-454.

图/表 7

表1 外泌体分离富集方法的比较

Table 1 Comparison of exosome isolation and enrichment methods

Method	Mechanism	Advantages	Disadvantages
Ultracentrifugation	density	standard protocol, large sample volume	low yield and purity, ultracentrifuge
Size-exclusion chromatography	size	high reproducibility, fast and easy preparation	relatively small volume, low specificity
Ultrafiltration	size	fast and easy preparation, serviced in series	possibility of clogging, low specificity
Polymer precipitation	solubility	simple equipment and operation, high yield	low purity, long processing time
Affinity capture	molecular recognition	high specificity, small volume for rare sample	high cost, extra steps for exosome elution, optimization for exosome markers

表2 基于靶向多肽的外泌体分离富集方法

Table 2 Exosome isolation and enrichment methods based on targeted peptides

Peptide	Sequence	Targets	Samples	References
CP05	CRHSQMTVTSRL	CD63	serum	[37]
P238	RSHRLRLH	CD9	cell culture	[38⇓-40]
			mediums (CCMs)
APQQ	RGLLVSQLQIQQ	CD81	unreported	[41]
Vn96	PSQGKGRLSLSRFSWGALTLGEFLKL	heat shock protein	CCMs, plasma,	[42⇓-44]
			cerebrospinal fluid
PS-specific	CLIKKPF	phosphatidylserine	serum	[45]
peptide
BK	RPPGFSPFR	membranes (curvature sensing)	CCMs	[46]
D-S v1	GGEQNPIYWARYADWLFTTPFGLLDLAHLVAADEGT	membranes (low pH-sensing)	serum	[47]

图1 基于正义肽-反义肽相互作用原理的CD81靶向多肽的设计与亲和筛选[41]

Fig. 1 Design and affinity screening of CD81-targeting peptides based on the interactions between sense-antisense peptides[41] a. structure of tetraspanin CD81; b. design of CD81-targeting peptides; c. affinity screening of peptide candidates based on ligand-binding-induced fluorescence.

图2 反向迁移等电聚焦用于重组HSP亲和多肽的筛选[42]

Fig. 2 Affinity peptide screening with recombinant heat shock protein (HSP) using counter migration isoelectric focusing gels[42]

图3 磷脂酰丝氨酸亲和多肽功能化SiO2微球用于外泌体分离和蛋白质组学分析[45]

Fig. 3 Peptide ligand-SiO2 microspheres with specific affinity for phosphatidylserine as a new strategy for exosome isolation and proteomics analysis[45]

图4 基于曲率靶向肽的外泌体分离与荧光检测示意图[46]

Fig. 4 Scheme of exosome isolation and fluorescence detection based on curvature-targeting peptides[46]

图5 低pH嵌入肽(pHLIP)的结构和折叠行为[47]

Fig. 5 Structures and folding behaviors of pH-low insertion peptides (pHLIP)[47] a. wild type pHLIP; b. D-S v1.

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