An in vivo model for extracellular vesicle–induced emphysema
Camilla Margaroli, Matthew C. Madison, Liliana Viera, Derek W. Russell, Amit Gaggar, Kristopher R. Genschmer, J. Edwin Blalock
Camilla Margaroli, Matthew C. Madison, Liliana Viera, Derek W. Russell, Amit Gaggar, Kristopher R. Genschmer, J. Edwin Blalock
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Research Article Pulmonology

An in vivo model for extracellular vesicle–induced emphysema

Abstract

Chronic obstructive pulmonary disease (COPD) is a debilitating chronic disease and the third-leading cause of mortality worldwide. It is characterized by airway neutrophilia, promoting tissue injury through release of toxic mediators and proteases. Recently, it has been shown that neutrophil-derived extracellular vesicles (EVs) from lungs of patients with COPD can cause a neutrophil elastase–dependent (NE-dependent) COPD-like disease upon transfer to mouse airways. However, in vivo preclinical models elucidating the impact of EVs on disease are lacking, delaying opportunities for therapeutic testing. Here, we developed an in vivo preclinical mouse model of lung EV–induced COPD. EVs from in vivo LPS-activated mouse neutrophils induced COPD-like disease in naive recipients through an α-1 antitrypsin–resistant, NE-dependent mechanism. Together, these results show a key pathogenic and mechanistic role for neutrophil-derived EVs in a mouse model of COPD. Broadly, the in vivo model described herein could be leveraged to develop targeted therapies for severe lung disease.

Authors

Camilla Margaroli, Matthew C. Madison, Liliana Viera, Derek W. Russell, Amit Gaggar, Kristopher R. Genschmer, J. Edwin Blalock

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Figure 1

Characterization of airway EVs following i.t. treatment with LPS.

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Characterization of airway EVs following i.t. treatment with LPS. (A) EV...
(A) EVs were harvested from BALF 24 hours following saline or LPS (35 μg) treatment of 11-week-old A/J mice (n = 10 per group). (B) Flow cytometric analysis of the cellular composition of BALF following LPS or saline treatment. (C) Size distribution of airway EVs (LPS and saline treated) determined using NanoSight measurements following purification via differential ultracentrifugation. (D) Quantification of surface NE on airway EVs of LPS- and saline-treated mice by bead-based flow cytometric analysis. (E) Analysis of NE activity of airway EVs (LPS and saline) using an NE-specific FRET assay. (F) NE activity for EVs from LPS-treated Elane–/– mice or WT mice treated with α-1AT (1 μg) or depleted of Ly6G+ EVs. (G) NE activity for LPS EVs from E pretreated with NE Inhibitor II (NE INH. II; 20 μM) prior to the assay. Data are shown as median and IQR (n = 3 replicates per experiment). Statistical analyses were performed using Wilcoxon’s signed-rank test; ****P < 0.0001.