Density-based lipoprotein depletion improves extracellular vesicle isolation and functional analysis

Blood plasma is the main source of extracellular vesicles (EVs) in clinical studies aiming to identify biomarkers and to investigate pathophysiological processes, especially regarding EV roles in inflammation and thrombosis. However, EV isolation from plasma has faced the fundamental issue of lipopr...

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Published in:Journal of thrombosis and haemostasis Vol. 22; no. 5; pp. 1372 - 1388
Main Authors: Merij, Laura Botelho, da Silva, Luana Rocha, Palhinha, Lohanna, Gomes, Milena Tavares, Dib, Paula Ribeiro Braga, Martins-Gonçalves, Remy, Toledo-Quiroga, Kemily, Raposo-Nunes, Marcus Antônio, Andrade, Fernanda Brandi, de Toledo Martins, Sharon, Nascimento, Ana Lúcia Rosa, Rocha, Vinicius Novaes, Alves, Lysangela Ronalte, Bozza, Patrícia T., de Oliveira Trugilho, Monique Ramos, Hottz, Eugenio D.
Format: Journal Article
Language:English
Published: England Elsevier Inc 01-05-2024
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Summary:Blood plasma is the main source of extracellular vesicles (EVs) in clinical studies aiming to identify biomarkers and to investigate pathophysiological processes, especially regarding EV roles in inflammation and thrombosis. However, EV isolation from plasma has faced the fundamental issue of lipoprotein contamination, representing an important bias since lipoproteins are highly abundant and modulate cell signaling, metabolism, and thromboinflammation. Here, we aimed to isolate plasma EVs after depleting lipoproteins, thereby improving sample purity and EV thromboinflammatory analysis. Density-based gradient ultracentrifugation (G-UC) was used for lipoprotein depletion before EV isolation from plasma through size-exclusion chromatography (SEC) or serial centrifugation (SC). Recovered EVs were analyzed by size, concentration, cellular source, ultrastructure, and bottom-up proteomics. G-UC efficiently separated lipoproteins from the plasma, allowing subsequent EV isolation through SEC or SC. Combined analysis from EV proteomics, cholesterol quantification, and apoB-100 detection confirmed the significant reduction in lipoproteins from isolated EVs. Proteomic analysis identified similar gene ontology and cellular components in EVs, regardless of lipoprotein depletion, which was consistent with similar EV cellular sources, size, and ultrastructure by flow cytometry and transmission electron microscopy. Importantly, lipoprotein depletion increased the detection of less abundant proteins in EV proteome and enhanced thromboinflammatory responses of platelets and monocytes stimulated in vitro with EV isolates. Combination of G-UC+SEC significantly reduced EV lipoprotein contamination without interfering in EV cellular source, gene ontology, and ultrastructure, allowing the recovery of highly pure EVs with potential implications for functional assays and proteomic and lipidomic analyses.
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ISSN:1538-7836
1538-7836
DOI:10.1016/j.jtha.2024.01.010