Abstract
Lung epithelial lining fluid (ELF) harbors a variety of proteins that influence homeostatic and stress responses in the airspaces. Exosomes, nano-sized extracellular vesicles, contain many proteins that vary in abundance and composition based on the prevailing conditions. Ozone causes inflammatory responses in the airspaces of experimental animals and humans. However, the exosomal protein signatures contained within the ELF from ozone-exposed lung airspaces remain poorly characterized. To explore this, we hypothesized that ozone triggers the release of exosome-bound inflammatory proteins from various cells that reflect mucoobstructive lung disease. Accordingly, we repetitively exposed adult male and female C57BL/6 mice to HEPA-filtered air (air) or 0.8 ppm ozone (4 h per day) for 14 days (five consecutive days of exposure, 2 days of rest, five consecutive days of exposure, 2 days of rest, four consecutive days of exposure). Exosome-bound proteomic signatures, as well as the levels of soluble inflammatory mediators in the bronchoalveolar lavage fluid (BALF), were determined 12–16 h after the last exposure. Principal component analyses of the exosome-bound proteome revealed a clear distinction between air-exposed and ozone-exposed mice, as well as between ozone-exposed males and ozone-exposed females. In addition to 575 proteins that were enriched in both sexes upon ozone exposure, 243 and 326 proteins were enriched uniquely in ozone-exposed males and females, respectively. Ingenuity pathway analyses on enriched proteins between ozone- and air-exposed mice revealed enrichment of pro-inflammatory pathways. More specifically, macrophage activation-related proteins were enriched in exosomes from ozone-exposed mice. Cytokine analyses on the BALF revealed elevated levels of G-CSF, KC, IP-10, IL-6, and IL-5 in ozone-exposed mice. Finally, the histopathological assessment revealed significantly enhanced intracellular localization of mucoinflammatory proteins including MUC5B and FIZZ1 in ozone-exposed mice in a cell-specific manner indicating the cellular sources of the proteins that are ferried in the exosomes upon ozone-induced lung injury. Collectively, this study identified exosomal, secretory, and cell-specific proteins and biological pathways following repetitive exposure of mice to ozone.
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Introduction
Exosomes are nano-sized extracellular vesicles (EV) that originate from the endosomal compartment of the cells and are known to contain biomolecules including proteins, lipids, RNA, DNA, and metabolites1,2,3. The composition of these biomolecules in bodily fluids such as plasma4,5, epithelial lining fluid (ELF)6,7, saliva8, milk8, and urine8,9 may yield valuable information about their cellular origins, physiological roles, prevailing pathological stresses, and, clinically, may have diagnostic and prognostic values10,11,12. All eukaryotic cells release exosomes in healthy as well as stressed conditions and the relative composition of exosomes derived from a variety of cell types lining the body cavity contributes to the overall heterogeneity of the exosome population. Following release into the extracellular milieu, the biological activities of exosomes are mediated either through their direct interaction with the target cells or through their role as a messenger in cell–cell communication13. Accordingly, the exosomal cargo proteins can play important roles in the maintenance of tissue homeostasis as well as the manifestation of stress responses.
The epithelial lining fluid (ELF), a thin liquid layer covering the epithelial cells in the airway and alveolar spaces, contains exosomes that are released from the resident (during homeostasis) and/or recruited cells (in stressed conditions)14. Encounters between inhaled entities and the cellular and/or molecular constituents of the ELF of the respiratory tract result in the altered composition of the exosome population in the respiratory tract3,15. For example, hyperoxia exposure, as well as acid inhalation, results in elevated levels of exosomes in the BALF of mice16. However, a detailed proteomic analysis on bronchoalveolar lavage fluid (BALF) exosomes from ozone-exposed mice have never been conducted.
Ozone inhalation causes lung injury and inflammatory responses in experimental animals and humans. In our recent publication17, we performed transcriptomic analyses on three distinct lung compartments, i.e., extrapulmonary airways, parenchyma, and purified alveolar macrophages, from mice that were repetitively exposed to filtered air (air) or 0.8 ppm ozone. Here, using the BALF samples from the same set of animals, we investigated whether the enriched protein signatures in BALF reflect upregulation of their transcripts. Accordingly, we hypothesized that repetitive ozone exposure triggers the release of exosome-bound inflammatory proteins from various cells that reflect the mucoobstructive lung disease. Previous studies suggested that, as compared to ozone-exposed males, ozone-exposed females exhibit exaggerated inflammatory responses17. Accordingly, our second hypothesis was that exosomes from ozone-exposed females possess unique protein signatures that cause exaggerated inflammatory responses. To test these hypotheses, we asked a series of questions including, (1) Which proteins are enriched in the airspace-derived exosomes from healthy lungs (homeostasis)? (2) Whether the composition and the abundance of exosomal proteins is altered following ozone exposure (stressed environment)? (3) What biological pathways are influenced by the exosomal proteins during homeostasis and under stressed environment? (4) Does the composition of the exosomal proteins reflect the mucoinflammatory disturbances in the airspaces following ozone-induced stress? (5) What are the likely contributors to the key inflammatory proteins in the airspaces following ozone-induced stress? and (6) Whether it is possible to identify the cellular sources of proteins present within the heterogeneous population of airspace exosomes? We attempted to address these questions through comprehensive exosomic-proteomic analyses, immunohistochemical staining, secretory protein measurements, and comparative analyses between proteomic and transcriptomic signatures. This study revealed several interesting findings related to ozone- and sex-specific protein signatures within the pulmonary airspaces.
Materials and methods
Animal husbandry
Male and female mice on C57BL/6 background were procured from Jackson Laboratory (Bar Harbor, ME). We used mice on C57BL/6 background because they exhibit robust mucous cell metaplasia and eosinophilic inflammation upon repetitive exposure to ozone18. Upon arrival at Louisiana State University (LSU) vivarium, mice were allowed to acclimatize for 3 weeks. Mice were maintained in individually-ventilated, hot-washed cages on a 12 h dark/light cycle. Except during the exposures, mice were maintained on a regular diet and water ad libitum. All methods related to animal experimentation were approved by LSU Institutional Animal Care and Use Committee (IACUC) and performed in accordance with the ethical guidelines and regulations. The authors complied with the Animal Research: Reporting of In Vivo Experiments (ARRIVE) guidelines.
Experimental design and ozone exposure
Male and female mice, housed in separate cages, were exposed to HEPA-filtered air (air) or HEPA-filtered ozone (806.1 ± 2.68 ppb; 4 h per day) for 14 days (five consecutive days of exposure, two days of rest, five consecutive days of exposure, two days of rest, four consecutive days of exposure). Cages were randomly assigned to the air and ozone exposure groups. We included 14 mice in each of the four experimental groups, i.e., air-exposed males, air-exposed females, ozone-exposed males, and ozone-exposed females. Tissues were harvested from experimental mice 12–16 h after the end of the last exposure. Of note, BALF samples and lung tissues were harvested from the same cohort of mice that were exposed to air or ozone for our recently published study17.
Hatch et al. reported that ~ 4–5 times higher inhaled ozone (18O3) concentration was required for comparable 18O labeling of cells and extracellular BALF materials between resting rats and exercising humans19,20,21. The ozone concentration used in this study was ~ 11.5 fold higher than the 8 h National Ambient Air Quality Standards (NAAQS) for ozone, i.e., 0.07 ppm.
Previous reports have highlighted sex-associated differences in the susceptibility to ozone-induced lung injury and inflammation22,23,24,25; therefore, both sexes were exposed to air or ozone. To replicate real-life exposure conditions of humans during the active phase, mice were exposed in the nightly conditions, a state of higher physical activity in mice26. Briefly, the loading of animals onto the light-proof chambers was coordinated with the start of the night cycle at the vivarium. All the exposures took place between 6:00 PM and 11:00 PM.
Necropsy and tissue harvesting
Mice were anesthetized with an intraperitoneal injection of 2,2,2-tribromoethanol (250 mg/kg; Sigma-Aldrich, St Louis, MO) and thoracotomy was performed to expose lungs and extrapulmonary airways. A 20-gauge cannula was inserted into the trachea and secured in place with a suture. Lungs were lavaged with a calculated volume (Body weight in grams × 0.035 × 1000 = volume in µl) of ice-cold Dulbecco’s phosphate-buffered saline (DPBS) without calcium and magnesium. The first two lavages were pooled and stored on ice. To increase the exosome yield, further lavages were performed to collect additional 9 ml of BALF. Three hundred microliters from the first two lavages were centrifuged at 500g for 5 min at 4 °C in order to pellet the cells. Cell-free supernatant was saved at − 80 °C for cytokine analyses. The remaining portion of the first two lavages and 9 ml volume of serial lavages were pooled and centrifuged (as above) to collect cell-free BALF. To increase the exosome yield, cell-free BALF from three individual mice with similar treatment and sex were pooled.
Exosome isolation from bronchoalveolar lavage fluid (BALF)
Exosomes were isolated by a differential ultracentrifugation method as previously described with some modifications27. Briefly, the BALF from three sex- and treatment-matched mice were pooled and centrifuged at 500g for 5 min to sediment the BALF immune cells. The cell-free supernatant was further centrifuged at 3000g for 10 min to sediment the dead cells. Then, the supernatant was centrifuged at 10,000g for 70 min using SW28 rotor (Beckman Coulter Optima L-90 K Ultracentrifuge). The pellet comprising of cell debris and large microvesicles was discarded and the supernatant was filtered using a 0.2 µm filter (VWR, Radnor, PA). The filtered supernatant was further centrifuged at 100,000g for 100 min. The supernatant was carefully discarded without disturbing the exosome pellet. The pellet was resuspended in 200 µl of phosphate-buffered saline (PBS). Nanoparticle tracking analyses (NTA; Nanosight 300) on vesicular population harvested using differential ultracentrifugation method typically have a diameter of 131.2 ± 4.4 nm (mean ± SEM) and 102.4 ± 5.8 nm (mode ± SEM). Resuspended exosomes were snap-frozen and stored at − 80 °C. All the centrifugation steps were performed at 4 °C.
Sample preparation for proteomic analyses
Proteins were reduced, alkylated, and purified by chloroform/methanol extraction prior to digestion with sequencing grade modified porcine trypsin (Promega, Madison, WI). Tryptic peptides were then separated by reverse-phase XSelect CSH C18 2.5 µm resin (Waters) on an in-line 150 × 0.075 mm column using an UltiMate 3000 RSLCnano system (Thermo). Peptides were eluted using a 90 min gradient from 97:3 to 60:40 buffer A:B ratio (Buffer A = 0.1% formic acid, 0.5% acetonitrile; Buffer B = 0.1% formic acid, 99.9% acetonitrile). Eluted peptides were ionized by electrospray (2.15 kV) followed by mass spectrometric (MS) analysis on an Orbitrap Eclipse Tribrid mass spectrometer (Thermo Fisher Scientific, Waltham, MA). MS data were acquired using the FTMS analyzer in profile mode at a resolution of 120,000 over a range of 375 to 1200 m/z. Following HCD activation, MS/MS data were acquired using the ion trap analyzer in centroid mode and normal mass range with a normalized collision energy of 30%.
Data analysis—intensities
Proteins were identified by database search against the UniprotKB database restricted to Mus musculus (November 2019) using MaxQuant (version 1.6.10.43, Max Planck Institute) with a parent ion tolerance of 3 ppm and a fragment ion tolerance of 0.5 Da. Protein identifications were accepted if they could be established with less than 1.0% false discovery and contained at least 2 identified peptides. Protein probabilities were assigned by the Protein Prophet algorithm28. Proteins were normalized to iBAQ MS1 intensities within MaxQuant and quality was assessed using the UAMS Bioinformatics core in-house ProteiNorm tool, a user-friendly tool for a systematic evaluation of normalization methods, imputation of missing values, and comparisons of different differential abundance methods. Popular normalization methods are evaluated including log2 normalization (Log2), median normalization (Median), mean normalization (Mean), variance stabilizing normalization (VSN)29, quantile normalization (Quantile)30, cyclic loess normalization (Cyclic Loess)31, global robust linear regression normalization (RLR)32, and global intensity normalization (Global Intensity)32. The individual performance of each method can be evaluated by comparing the following metrices: total intensity, Pooled intragroup Coefficient of Variation (PCV), Pooled intragroup Median Absolute Deviation (PMAD), Pooled intragroup estimate of variance (PEV), intragroup correlation, sample correlation heatmap (Pearson), and log2-ratio distributions. The data were normalized using VSN as this method had the lowest intragroup variance and highest intragroup correlation. The Log2 VSN normalized iBAQ MS1 intensities were used to perform statistical analysis using Linear Models for Microarray Data (limma) with empirical Bayes (eBayes) smoothing to the standard errors31. Proteins with an adjusted p-value < 0.05 and a fold change (FC) > 2 were considered to be significant. Significant proteins were used to identify important protein networks and pathways using the Ensemble of Gene Set Enrichment Analyses (EGSEA) Bioconductor package33.
Ingenuity pathway and protein interaction networks analyses
The Ingenuity pathway analysis (IPA) identifies canonical pathways and biological networks that are activated in the queried data set. The differentially enriched proteins in ozone-exposed mice were subjected to IPA to investigate the biological networks and pathways that were enriched in the exosomes (Qiagen, Redwood City, CA). Core analysis function was selected to screen proteins that met our cutoff criteria (FC > 2, FDR < 0.05). STRING analysis was performed to identify protein–protein interaction network enrichment in enriched proteins34. The STRING (https://string-db.org; version 11.0) maintains a database of known and predicted protein–protein interaction (PPI) networks.
Analyses of BALF for cytokines
Cell-free BALF was assessed for granulocyte-colony stimulating factor (G-CSF), keratinocyte chemoattractant (KC/CXCL1), IP-10, IL-6, and IL-5 using a Luminex XMAP-based assay (MCYTOMAG-70 K), according to manufacturer’s instructions (EMD Millipore, Billerica, MA).
Immunohistochemistry for MUC5B and RETNLA (FIZZ1/RELMα)
A separate cohort of mice was exposed to air or ozone to harvest unlavaged lung lobes for histopathological tissue preparation. Lungs were inflated with a calculated volume (Body weight in grams × 0.035 × 1000 = volume in µl) of 10% neutral buffered formalin. Formalin-fixed left lung lobes were transversally sectioned twice along the main stem bronchus, i.e., at the hilum and 2 mm caudally to the hilum. Sections were paraffin-embedded and 5 µm thick sections were mounted onto glass slides. Sections were processed for immunohistochemical staining, as previously described.35,36 Lung sections were processed to assess immunohistochemical localization of MUC5B, as previously described35,36. Rabbit monoclonal RETNLA (FIZZ1) primary antibody (ab39626; ABCAM Cambridge, MA) was used to probe lung sections. To quantify MUC5B/RETNLA stained cells, the number of MUC5B/RETNLA stained cells and the total number of cells in the airways were manually counted.
Statistical analyses
Data were analyzed using Shapiro Wilk’s and Levene’s test for the determination of normality and equality of variances, respectively. If any one of these assumptions, that are critical for the application of parametric ANOVA, were violated, non-parametric Kruskal Wallis ANOVA was used to detect the significant differences in the main effect. In case of significant main effect, Dunn’s post hoc test was used for multiple comparisons to determine the significant differences among groups. All data were expressed as mean ± standard deviation (SD). Outliers were eliminated by using Grubb’s test application. Statistical analyses were performed using GraphPad Prism 9.0 (GraphPad Software, La Jolla, CA). A p-value of less than 0.05 was considered statistically significant.
Results
Ozone exposure results in exaggerated lung injury and a robust increase in BALF cytokine levels
To assess lung injury in response to ozone, we analyzed the total protein contents of cell-free BALF, an indicator of alveolar-endothelial gas exchange barrier damage37,38. While the BALF protein contents in air-exposed mice were comparable between males (122.5 ± 8.9 µg/ml) and females (124.3 ± 7.1 µg/ml), both ozone-exposed males (568.8 ± 42.5 µg/ml) and females (1012.0 ± 159.9 µg/ml) had significantly elevated protein contents (Fig. 1A). Further, BALF protein contents in ozone-exposed females trended higher than those in ozone-exposed males (Fig. 1A).
To determine the levels of soluble inflammatory mediators in the airspaces, we assessed levels of 25 cytokines in the BALF from the air- and the ozone-exposed mice. Only five of the analyzed cytokines showed a significant main effect (Fig. 1B–F). While air-exposed males and females had basal or undetectable levels of all these five cytokines, ozone exposure resulted in a significant elevation in the concentration of these five cytokines, i.e., G-CSF, KC, IP-10, IL-6, and IL-5 in both the sexes (Fig. 1B–F). No significant difference was observed between ozone-exposed males versus ozone-exposed females for any of the five cytokines.
Next, we assessed the concentration of double-stranded DNA (dsDNA), an indicator of cellular injury associated with neutrophilic inflammation39,40,41. BALF dsDNA levels were comparable between air-exposed males and air-exposed females (Fig. 1G). BALF from both ozone-exposed males and ozone-exposed females had significantly elevated levels of dsDNA as compared to the respective control groups. The dsDNA levels trended higher in ozone-exposed females versus ozone-exposed males (Fig. 1G).
Isolation of BALF exosomes and assessment for exosome-specific markers
Cell-free BALF was subjected to differential centrifugation to sediment exosomes (Fig. 2A). The total protein contents in the exosomes from air-exposed males (41.2 ± 1.6 µg) were comparable with air-exposed females (39.7 ± 0.7 µg). The total protein contents in the exosomes from ozone-exposed mice trended higher as compared to air-exposed mice (Fig. 2B). The protein contents were comparable between ozone-exposed male (91.7 ± 3.6 µg) and ozone-exposed female (87.2 ± 4.4 µg) mice (Fig. 2B).
Next, a list of 1225 exosomal protein signatures was retrieved from the Exocarta Vesiclepedia database. This list contained proteins that fulfilled designated criteria (Species-Mus Musculus; Tissues/cell type-Lung cells, macrophages, mast cells, fibroblast, BALF, B cells, Plasma, Serum and thymus; Cell line-dendritic cells, macrophages, mast cells, myeloid-derived suppressor cells, and T-cells; Isolation methods-all reported; Detection methods-ELISA, Mass spectrophotometry, immunoelectron microscopy, and western blotting; Vesicle types-Exosomes). Out of 1225 exosomal protein signatures, 822 were identified in BALF exosomes collected in this study (Fig. 2C). Next, through a manual literature search, we generated a list of 50 proteins that are known to be exosome-specific signatures. While all of these 50 known exosome markers were present in all the 12 exosome samples, at least 29 of these proteins were represented in the top 20% of the most abundant proteins (Fig. 2D).
Exosomes from filtered air-exposed mice contain lung cell-specific proteins
A total of 3258 proteins were identified in exosomes from air-exposed mice. While 2361 proteins were present in all six (3 males; 3 females) exosome samples from air-exposed mice, 320, 185, 137, 129, and 126 additional proteins were identified in at least 5, 4, 3, 2, and 1 exosome samples from air-exposed mice, respectively. A list of 50 most-abundant proteins in exosomes from air-exposed mice is included in Table 1. Our analyses revealed that exosomes from air-exposed mice contain protein signatures known to be expressed in the lungs including club cell-specific protein (SCGB1A1; uteroglobin; CCSP), surfactant-associated protein D (SFTPD), surfactant-associated protein B (SFTPB), surfactant-associated protein A1 (SFTPA1), chitinase-like protein 3 (CHIL3), chitinase-3-like protein 1 (CHI3L1), alpha-1-antitrypsin 1–2 (SERPINA1B), serotransferrin (TF), superoxide dismutase (SOD1), and platelet glycoprotein 4 (CD36). The presence of these proteins suggests that; 1) the exosome populations are representative of the homeostatic airspaces and, 2) the proteins detected within the exosomes may have potential roles in immune defense and antioxidant responses.
Principal component (PC) analyses revealed clear clustering of air-exposed male samples, but the air-exposed female samples were somewhat dispersed (Fig. 3A). Next, employing stringent cutoff criteria (Log2 Fold change > 1, FDR < 0.05), we compared differentially enriched protein signatures in air-exposed females versus air-exposed males (Table 2A and Fig. 3B). Our analyses identified only 15 differentially enriched (5 upregulated and 10 downregulated) proteins (Table 2A and Fig. 3B).
Exosomes from ozone-exposed mice contain unique protein signatures relevant to lung inflammation
A total of 3421 proteins were identified in exosomes from ozone-exposed mice. A total of 2756 proteins were present in all six exosome samples from ozone-exposed mice. 288, 139, 108, 75, and 55 proteins were identified in at least 5, 4, 3, 2, and 1 exosome samples from ozone-exposed mice, respectively. A list of 50 most-abundant proteins in exosomes from ozone-exposed mice is included in Table 1. Comparison of lists indicating 50 most-abundant proteins in exosomes from air-exposed and ozone-exposed mice identified 33 common signatures and 17 treatment-specific signatures. Most abundant proteins from the top 50 in exosomes that were specific to ozone treatment included RETNLA, AQP5, HSPA, S100A6, S100A11, HIST1H4A, HIST1H1C, HIST1H2A’s, HIST1H2B’s, HIST1H3B, and APOA1, a majority of which are known lung inflammatory proteins.
PC analyses revealed a clear separation of ozone-exposed female and ozone-exposed male samples. The separation was contributed by PC2 that accounts for ~ 11% variance (Fig. 3A). Next, we compared differentially enriched protein signatures in ozone-exposed females and ozone-exposed males (Table 2B and Fig. 3C). Our analyses identified an enrichment of 5 proteins and a reduced abundance of 6 proteins (Table 2B and Fig. 3C).
Of note, we found additional differentially enriched proteins that were eliminated from the analyses because those proteins were not detected in one of the groups being compared and were assigned NA designation during the normalization process. In total, 22 such proteins were exclusively present in air-exposed females (Supplemental Table 1A) and 56 such proteins were exclusively present in air-exposed males (Supplemental Table 1B). Further, 23 proteins were exclusively present in ozone-exposed females (Supplemental Table 2A) and 53 proteins were exclusively present in ozone-exposed males (Supplemental Table 2B). Finally, 27 and 168 proteins were exclusively present in the air- and ozone-exposed mice, respectively (Supplemental Table 3).
Exosomes from ozone-exposed mice are enriched in stress-response proteins in a sex-specific manner
The top two principal components (PC1 and PC2), that contribute to ~ 48% variance, revealed that treatment and sex were the primary drivers of variation in overall protein contents. The PC1, which accounts for 37.19% of the variance, separated air-exposed mice from ozone-exposed mice. PC2, which accounts for 10.69% of overall variance, distinctly separated ozone-exposed males and ozone-exposed females (Fig. 3A). Next, a comparison of ozone-exposed males and air-exposed males identified 818 differentially expressed (380, enriched; 438, low abundance) proteins (Fig. 3D and Supplemental Table 4). Similarly, a comparison of ozone-exposed females and air-exposed females identified 901 differentially expressed (427, enriched; 474, low abundance) proteins (Fig. 3E and Supplemental Table 4). Using cutoff criteria (Log2FC > 1, FDR < 0.05), a comparison of ozone-exposed mice (mixed sex) with air-exposed mice (mixed sex) identified 1255 differentially expressed (568, enriched; 687, low abundance) proteins (Fig. 3F and Supplemental Table 4).
Next, a comparison of proteins that were differentially enriched in ozone-exposed males and ozone-exposed females as compared to sex-matched air-exposed mice identified shared and sex-specific signatures. A total of 575 proteins (263, enriched; 312, low abundance) were found differentially expressed in both ozone-exposed males and ozone-exposed females as compared to respective sex-matched air-exposed mice (Fig. 3G, H). As compared to exosomes from air-exposed males, exosomes from ozone-exposed males contained an additional 243 (117, enriched; 126, low abundance) uniquely expressed proteins. As compared to exosomes from air-exposed females, exosomes from ozone-exposed females contained 326 (164, enriched; 162, low abundance) uniquely expressed proteins (Fig. 3G, H).
A list of top shared and sex-specific proteins, relevant to the stress responses, that were found upregulated in ozone-exposed mice is included in Table 3 (Top 50) and Supplemental Table 4 (complete list). Shared protein signatures that were found upregulated in both ozone-exposed males and ozone-exposed females included EPHA2, SLC23A2, SLC26A4, MUC5AC, FN1, POSTN, RETNLA, and various histones (Histone 1, 2, 3). Interestingly, ozone-exposed male mice had significantly upregulated proteins including ITGB6, HSPA2, PTGS2, endophilin-B1 (SH3GLB1), and KEAP1. On the other hand, ozone-exposed female mice had significantly upregulated proteins including PTPN3, APOD, MMP3/MMP10, TSPO, PLA2G7, SH3GL1, and PKP3 (Table 3; Top 50).
A summary of the top 50 proteins that had reduced abundance in ozone-exposed mice are included in Table 4 (Top 50) and Supplemental Table 4 (complete list). Proteins that were found downregulated in both ozone-exposed males and ozone-exposed females included MLF1, LSP1, MERTK, CHID1, THBS3, LYZ2, and FGFR2. Interestingly, ozone-exposed male mice had significantly downregulated proteins including FABP1, AFP, VAMP5, and SGSH. Similarly, ozone-exposed female mice had significantly downregulated proteins including TLR5, PRSS1, LMF1, SLC27A1, and MIA3 (Table 4; Top 50).
Macrophage activation-associated proteins are differentially enriched in exosomes from ozone-exposed mice
Macrophages within the airspaces have been reported to be activated following ozone exposure42,43,44. Next, through a manual literature search, we prepared a list of proteins that determine the activation status of the macrophages and categorized them into one of the two activation categories, i.e., classically-activated macrophages (CAM, M1) and alternatively-activated macrophages (AAM, M2). Significantly upregulated proteins in exosomes from ozone-exposed mice included LGALS3, TGM2, FN1, LMNA, RETNLA, MRC2, ASS1, and PLA2G7 (Fig. 4A). Significantly downregulated proteins in exosomes from ozone-exposed mice included MRC1, CHI3L1, CHIA, CHI3L3 (YM1), PTGS1, and MERTK. Interestingly, MARCKS, CD200, CD36, LCN2, and CHI3L4 (YM2) were found elevated only in the females, regardless of their treatment groups.
Next, we hypothesized that the macrophage activation protein signatures in the exosomes reflect macrophage activation status following ozone exposure. Our data did not clearly categorize macrophage activation markers into M1 or M2 categories. While overall, a relatively larger number of M2-associated proteins were upregulated in the exosomes from ozone-exposed mice, the protein signatures largely reflected a mixed phenotype. For example, while some M2-associated proteins including RETNLA, TGM2, FN1, MRC2, ASS1, LCN2, and LGALS3 were enriched upon ozone exposure, other M2-associated proteins either remained unchanged (CLEC7A, FCERG1, STAT6) or were present in low abundance (ALOX15, CHIA, CHIL3, CHI3L1, PTGS1, MRC1). Four M2-associated proteins, i.e., CD200, CD36, CHIL4, and LCN2 were specifically upregulated in the females regardless of their exposure status. While some M1-associated markers were enriched (PLA2G7, FCGR2, and LMNA) in the exosomes following ozone exposure, others, such as MARCKS and PTGS2 remained unchanged (Fig. 4A).
RETNLA, commonly known as FIZZ1 (Found in Inflammatory Zone 1), is a well-known marker for alternative macrophage activation, particularly in mice. To determine the cellular source of this protein in the exosomes of ozone-exposed airspaces, we performed immunohistochemical staining on lungs from the air- and ozone-exposed mice (Fig. 4B–G). The majority of the RETNLA-stained cells in air-exposed mice were club cells, however, the staining intensity was very low (Fig. 4B). In contrast, club cells were intensely stained in the ozone-exposed mice (Fig. 4C). In addition to the contrasting staining intensities, an indicator of the differential expression levels of intracellular proteins, the number of RETNLA-stained cells was significantly greater in the ozone-exposed male and trended higher in ozone-exposed female mice (Fig. 4D). Next, we compared RETNLA staining in alveolar macrophages between air- and ozone-exposed mice. The alveolar macrophages did not show any RETNLA staining in air-exposed mice (Fig. 4E). Interestingly, the RETNLA staining in alveolar macrophages from ozone-exposed mice was location-dependent, i.e., intense staining in alveoli adjacent to the terminal bronchioles (Fig. 4F) and no staining in alveoli distal to the terminal bronchioles (Fig. 4G). These findings are consistent with the previous report demonstrating prominent pathological changes in the bronchoalveolar duct regions45.
Mucoinflammatory disease response proteins were differentially enriched in exosomes from ozone-exposed mice
Elevated levels of ozone contribute to the exacerbation of pulmonary symptoms in patients with mucoinflammatory lung diseases including asthma46,47,48 and chronic obstructive pulmonary disease49,50. Accordingly, through a manual literature search, we customized a list of proteins that have been reported to be associated with mucoinflammatory lung diseases and assessed their levels in the exosomes from the air- and ozone-exposed mice. Ozone exposure resulted in the enrichment of known mucoinflammatory proteins including LGALS3, FN1, POSTN, S100A9, MUC5AC, MUC5B, APOA1, APOA2, FGA, FGB, and FGG (Fig. 5A). Simultaneously, other known mucoinflammatory proteins showed low abundance in exosomes from ozone-exposed mice versus air-exposed mice. These proteins include MRC1, PLG, ADIPOQ, CHIA, LYZ2, CSF1R, SERPIND1, SFTPB, CHI3L1, SFTPA1, LRG1, and HMGB1 (Fig. 5A).
MUC5B is overproduced in the airspaces of patients with mucoinflammatory lung diseases including COPD51. To determine the effect of ozone exposure on the intracellular levels of MUC5B in the large versus small airways, we immunohistochemically stained the lung sections and quantified the proportion of cells expressing MUC5B in ozone-exposed versus air-exposed mice (Fig. 5B–G). First-and second-generation airways from air-exposed males and females contained ~ 16% and ~ 35% MUC5B positive epithelial cells, respectively (Fig. 5B, D). In contrast, first-and second-generation airways from ozone-exposed males and females contained ~ 83% and ~ 61% MUC5B positive epithelial cells, respectively (Fig. 5C, D). The preterminal and terminal bronchioles from air-exposed males and females had only ~ 2% and ~ 1% MUC5B positive epithelial cells, respectively (Fig. 5E, G). On the other hand, the preterminal and terminal bronchioles from ozone-exposed males and females had ~ 55% and ~ 67% MUC5B positive epithelial cells, respectively (Fig. 5F, G). These data suggest that the enrichment of MUC5B in the exosomal fraction from ozone-exposed mice is a result of the overproduction of this protein in both large and small airways.
BALF exosomes carry proteins associated with homeostatic and perturbed lung environment
To identify the signaling pathways that are enriched within the exosomal proteins from air-exposed mice, we performed Ingenuity pathway analysis (IPA) on the most abundant (top 10%; 326 out of 3258 identified proteins) proteins. The abundance of proteins was determined by Log2 VSN normalized iBAQ MS1 intensities, i.e., proteins with the highest intensity values were considered most abundant. We searched enrichment of pathways related to “molecular and cellular functions” and “Physiological system development and function” categories. Our analyses identified a number of pathways including protein synthesis, cellular movement, cell death and survival, molecular transport, tissue morphology, protein degradation, organismal development, immune cell trafficking, cellular assembly and organization, cellular function and maintenance, cellular compromise, cell–cell signaling and interaction, and hematological system development and function (Fig. 6A). Similarly, we performed IPA on the most abundant (top 10%; 342 out of 3421 identified proteins) proteins in exosomes harvested from ozone-exposed mice. While most of the pathways, except for tissue morphology and protein degradation, that were enriched in the air-exposed exosomes were also enriched in ozone-exposed exosomes, additional pathways identified in ozone-exposed exosomes were RNA damage and repair, free-radical scavenging, lipid metabolism, and small molecule biochemistry (Fig. 6B). These data show that BALF exosomes carry signatures of the homeostatic lung environment as well as the diseased state.
Comparative analysis of proteins in BALF exosomes from ozone- vs air-exposed mice reveals enrichment of inflammation/injury-associated pathways and protein interaction networks
Next, we analyzed disease-associated and functional pathways altered in the exosomes from ozone-exposed mice. Top enriched pathways included cellular compromise, inflammatory responses, cellular movement, immune cell trafficking, lipid metabolism, molecular transport, small molecular biochemistry, cell–cell interaction, hematological system development and function, immunological diseases, inflammatory diseases, respiratory diseases, cell death and survival, and free radical scavenging (Fig. 7A).
To determine the canonical pathways that are associated with the proteins that are enriched in the exosomes of ozone-exposed mice, we subjected differentially (FC > 2, FDR < 0.05) expressed proteins (total, 1255; enriched, 568; low abundance, 687) in exosomes from ozone-exposed mice to pathway analysis using IPA application. Of the top 14 pathways, 9 were upregulated that included micropinocytosis, coagulation system, acute phase response, lipid antigen presentation by CD1, phagosome formation, leukocyte extravasation, calcium-induced T lymphocyte apoptosis, CTLA4 signaling in cytotoxic T lymphocytes, IL-3 signaling, GM-CSF signaling, and Oncostatin M signaling (Fig. 7B). Further, to identify the sex-dependent enrichment of canonical pathways, we performed a comparative analysis between differentially expressed signatures in ozone-exposed males (versus air-exposed males; 380, enriched; 438, low abundance) and ozone-exposed females (versus air-exposed females; 427, enriched; 474, low abundance). The analyses revealed a relatively higher z-score for the majority of pathways in ozone-exposed females versus ozone-exposed males (Fig. 7C and Supplemental Fig. 2). Together, these analyses indicate ozone-induced stress within the airspaces that is reflected within the proteomic signatures of the exosomes present within these airspaces.
Next, to identify enriched protein–protein interaction (PPI) networks, we performed STRING analysis on 568 proteins that were enriched in ozone-exposed mice versus air-exposed mice. The significantly influenced PPI networks due to enriched exosomal protein signatures in the BALF of ozone-exposed mice versus air-exposed mice included extracellular matrix (ECM) organization, ECM-receptor interaction, cell junction organization, membrane trafficking, and neutrophil degranulation (Supplemental Fig. 3).
Comparative analysis between enriched BALF exosomes proteins and previously published upregulated gene signatures from ozone-exposed mice
In our recent publication17, we profiled transcriptomic changes from three distinct lung compartments from ozone-exposed mice. To determine whether the enriched protein signatures reflect upregulation of their transcripts, and to identify the potential source of exosomes carrying these proteins, we interrogated a list of significantly enriched exosomal proteins (568 identified proteins; FC > 2; adj p-value < 0.05) against the transcriptome from the airways, parenchyma, and macrophages. Each protein signature was used to extract fold-change and adj p-values from the three lung compartments. Transcriptomic signatures meeting cutoff criteria (FC > 1; adj p-value < 0.05) from each tissue were considered significantly upregulated. We categorized the compartment-specific association of transcripts with exosomal protein signatures, based on the comparative analyses of gene expression changes across the three lung compartments.
Transcripts encoding 180 enriched protein signatures were upregulated in all three compartments (Table 5). The enrichment of 47 proteins was reflected in the upregulated DEGs from airways. Similarly, transcripts for 38 and 59 enriched proteins in the BALF exosomes were differentially upregulated exclusively in the parenchyma and the alveolar macrophages, respectively. Transcripts for 66 enriched proteins in the BALF exosomes were differentially upregulated in both airways and parenchyma. Similarly, transcripts for 44 and 63 enriched proteins in the BALF exosomes were differentially upregulated in extrapulmonary airways as well as airspace macrophages and parenchyma as well as alveolar macrophages, respectively. Finally, the enrichment of 71 proteins in the BALF exosomes did not reflect upregulated transcripts in any of the three compartments.
Discussion
Upon encountering abiotic and biotic inhaled insults, the resident lung cells, including epithelial cells and macrophages, orchestrate intercellular communication-dependent coordinated responses to restore airspace homeostasis52. Apart from the classical mechanisms for intercellular communication, i.e., direct cell–cell interaction or via soluble mediators, the exosomal cargo biomolecules contribute to the intercellular communication across various physio-pathological conditions53,54,55. Exosomes contain biologically active cargo including proteins, lipids, RNA, and DNA that are known to modulate the functioning of the recipient or target cells56. These biomolecular signatures also provide insights into the identity and the well-being of cells that secrete these exosomes. Like most other cell types, lung epithelial cells and alveolar macrophages, are known to release exosomes into their extracellular spaces3,14,15,55. In this study, to examine the exosomal protein signatures in the airspaces of healthy as well as ozone-stressed lungs of mice, we hypothesized that repetitive ozone exposure triggers the release of exosome-bound inflammatory proteins from various cells that reflect the mucoobstructive lung disease, and that exosomes from ozone-exposed females possess unique protein signatures that cause exaggerated inflammatory responses. This study identified various sex-dependent as well as sex-independent inflammatory proteins that are relevant to mucoobstructive lung diseases.
Under homeostatic conditions, epithelial cells and macrophages are known to communicate with each other to restrict their proinflammatory characteristics57,58. This adaptive phenomenon is critical in effectively curbing the exaggerated immune responses and disruption of the gas exchange function of the respiratory tract. To address our first question, i.e., Which proteins are present in the airspace-derived exosomes from healthy lungs, we analyzed the exosomes harvested from the air-exposed males and females (Table 1). Club cell-specific protein (CCSP; also known as SCGB1A1 or uteroglobin), a product of club cells that possesses anti-inflammatory and immunosuppressive properties59,60, was the second most abundant protein present within the exosomes from air-exposed mice. Similarly, alveolar epithelial cell-derived pulmonary surfactant proteins (SFTPA, SFTPB, and SFTPD), also known to be immunosuppressive61,62,63, were enriched within the exosomes from air-exposed mice. Other immunosuppressive proteins, MUC164,65,66,67 and MUC5B68, products of mucous cells, were also recovered within the exosomes from air-exposed mice (data not shown).
Antioxidant host defense system protects the cells of the respiratory mucosal surfaces from the reactive species generated from the relatively high concentration of inhaled oxygen (~ 150 mmHg at sea level in the conducting airways and ~ 100 mmHg at sea level in the alveolar spaces) at basal levels69. Consistent with this, exosomes harvested from the air-exposed mice were enriched in antioxidant-response proteins including peroxiredoxin-6 (PRDX6), superoxide dismutase (SOD1), paraoxonase 1 (PON1), NADPH-cytochrome P450 reductase (POR), Microsomal glutathione S-transferase 1 (MGST1), and Carbonyl reductase [NADPH] 2 (CBR2). These data indicate that exosomes harbor biomolecules critical for antioxidant defense mechanisms under homeostatic conditions. Together, our proteomic data from air-exposed exosomes suggest that, under homeostasis, exosomes carry protein signatures that are involved in anti-inflammatory responses and antioxidant defense.
Interestingly, we found protective protein signatures that were specifically upregulated in the females regardless of their exposure status. CD200 is expressed on the airway epithelial cells and is known to restrain lung macrophages70, innate lymphoid cells71, and lymphoid cells72 via binding to CD200R receptor. A higher level of CD200 in the BALF of air-exposed mice suggests its protective role in the airspaces of females under homeostasis. Of note, the alveolar macrophages from ozone-exposed mice had significantly upregulated expression of Cd200r17. Lipocalin-2 (LCN2), a neutrophil protein that was also elevated in the air-exposed females, is involved in antibacterial defense73,74. These data suggest that female lung airspaces contain protective proteins that likely counter the higher susceptibility of females to inflammatory lung diseases75,76,77.
Exposure to inhaled pollutants is known to induce airspace stress, increase the release rate of exosomes, and alter the composition of the exosomes78,79. Consistent with these reports, the total protein yield for exosomes trended higher in ozone-exposed mice versus air-exposed mice. Approximately 16.4% of identified proteins (568 out of 3457) were significantly enriched in the exosomes from ozone-exposed mice versus air-exposed mice (Table 3; Fig. 3F). Apart from this, 4.86% (168 out of 3457) proteins (Histones, S100A8, Elastin, Laminins, FGBP1, MPO, FCGR3, Claudin4, 7, Calpain-6, SEMA3F) were found exclusively in the exosomes from ozone-exposed mice (Supplemental Table 3). Collectively, these data indicate that exposure to ozone not only significantly enhances the enrichment of exosomal proteins that were already present under homeostatic conditions, but also induces the secretion and transport of new proteins within the exosomes.
Ozone, being a highly oxidative gas, is known to cause oxidative stress80,81, therefore, an efficient antioxidant system is required to minimize the detrimental effects of reactive oxygen species. Interestingly, however, known antioxidant proteins (EPHX1, SOD1, GSTM1, PRDX6, PON1, MGST1, and POR) were significantly suppressed within the exosomes from ozone-exposed mice. Furthermore, the NRF2-mediated oxidative stress response pathway was also suppressed within the exosomes from ozone-exposed versus air-exposed mice. These findings are consistent with the previous report where antioxidative stress response was active after 1 week of exposure but lost after 3 and 6 weeks of ozone exposure81.
While resident alveolar macrophages generally remain quiescent under homeostatic conditions, their functionality is significantly enhanced upon stimulation by the microenvironmental cues that are released by the adjoining cells within the stressed airspaces82. Macrophage activation, i.e., enhanced functionality, is a known response to ozone inhalation42,43,44,17. Various macrophage activation markers including arginase 1 (ARG1), NOS2, Galectin 3 (LGALS3), and PTGS2 (COX2) have been reported to be increased in mice following acute exposure to ozone42,83,84,85. Here, we hypothesized that the macrophage activation markers will be enriched within the exosomes harvested from the ozone-exposed airspaces. Our analyses revealed significant enrichment of the alternative activation markers within the exosomes of ozone-exposed mice. For example, Galectin 3 (LGALS3), a carbohydrate-binding lectin, highly expressed in the macrophages and epithelial cells, was upregulated in exosomes from ozone-exposed mice. Galectin 3 expression promotes alternative macrophage activation. TGM2, a member of the transglutaminase family of enzymes, that is known to promote alternative activation of macrophages as well as clearance of apoptotic cells by macrophages (efferocytosis)86,87 was also enriched in exosomes from ozone-exposed mice. Of note, TGM2 is a consistent marker of alternative activation of macrophages in humans as well as in mice. Similarly, Resistin-like alpha (RETNLA/FIZZ1), another robust marker of alternative activation of macrophages was upregulated in exosomes from ozone-exposed mice. These data suggest that alternatively activated macrophages from ozone-exposed airspaces release their signature proteins within the exosomes. Interestingly, our histochemical analyses suggest that RETNLA protein expression is dramatically upregulated in ozone-exposed airway epithelial (club) cells as well as macrophages, therefore, it is unclear whether the exosomal RETNLA originates from both or one of the two cell types, i.e., macrophages and airway epithelial cells.
The presence of histones in the BALF has been reported in mice with acute lung injury88 and patients with acute respiratory distress syndrome89. Extracellular histones are known to act as damage-associated molecular patterns leading to proinflammatory outcomes90. Although the mechanisms are unclear, the extracellular histones cause cytotoxic effects on endothelial and epithelial cells89,90,91. Interestingly, BALF from ozone-exposed mice were enriched in histones including HIST1H4A, HIST1H1C, HIST1H2A’s, HIST1H2B’s, and HIST1H3B. While the cellular source of these histones remains unclear, their appearance in the BALF is clearly associated with pathological responses such as granulocyte recruitment, macrophage activation, and airway epithelial remodeling.
Enrichment of certain proteins within the exosomes from stressed airspaces may contribute to the activation of functional and disease pathways. IP analyses on enriched proteins within the exosomes from ozone-exposed mice revealed the activation of several canonical pathways including acute phase response signaling, leucocyte extravasation signaling, production of reactive oxygen species by macrophages, micropinocytosis, phagosome formation, phagosome maturation, lipid antigen presentation, GM-CSF signaling, and IL-3 signaling pathways. These data suggest that the exosomes from ozone-exposed airspaces contain proteins that influence pathways relevant to the inflammatory responses.
Ozone exposure results in the exacerbation of the respiratory symptoms in patients with mucoinflammatory lung diseases such as COPD and asthma46,47,48. Exposure to high levels of ozone for nearly a decade increases the susceptibility to the development of COPD92. Similarly, ozone exposure is associated with a decline in lung function and increase in the levels of biomarkers of airway inflammation in asthmatic patients93. To observe the effects of ozone exposure in healthy mice and their likelihood of developing hallmarks of mucoinflammatory lung disease, we examined the enrichment of protein markers of mucoobstructive lung diseases within the exosomes from ozone-exposed mice. A large number of proteins that have been previously associated with the mucoobstructive lung diseases were enriched within the exosomes from ozone-exposed mice. These proteins include Galectin 3 (LGALS3), GCA, S100A9, Periostin (POSTN), MUC5AC, MUC5B, FGA, FGB, FGG, FN1, APOC1, IL1RN, and TOLLIP.
Previous reports have demonstrated that female mice show exaggerated inflammatory responses to ozone inhalation as compared to their male counterparts. In our recent report17, we also reported that, as compared to ozone-exposed males, ozone-exposed females exhibit exaggerated recruitment of inflammatory cells including macrophages, neutrophils, eosinophils, and lymphocytes. Consistent with cellular recruitment, the levels of total protein trended higher within the lungs of the ozone-exposed females versus ozone-exposed males. Further, the inflammatory mediators including G-CSF, KC, IP-10, IL-6, and IL-5 were significantly elevated in ozone-exposed females versus air-exposed females (Fig. 1). Accordingly, we hypothesized that the exosomes from ozone-exposed females either have significant enrichment of proteins relevant to proinflammatory responses or a significant reduction in the abundance of proteins relevant to anti-inflammatory responses.
Regardless of the comparable amounts of total protein contents within the exosomes of the ozone-exposed male and female mice, exosomes from ozone-exposed females were different from those of the ozone-exposed males in multiple ways. First, although both ozone-exposed sexes shared enrichment of 263 proteins in their exosomes, exosomes from ozone-exposed females had an exclusive enrichment of 164 proteins as compared to 117 in ozone-exposed males (Fig. 3G, H). Second, in addition to 312 proteins that were suppressed upon ozone exposure in both sexes, additional 162 and 126 proteins were exclusively suppressed in ozone-exposed females and ozone-exposed males, respectively. Third, comparative analyses of the canonical pathways between ozone-exposed females and ozone-exposed males revealed higher z-scores in females (Fig. 7C and Supplemental Fig. 2). While these findings point towards an increased enrichment of airspace-relevant stress proteins in ozone-exposed females, the causal-effect relationship between exaggerated inflammatory responses and enrichment of inflammation-relevant exosomal proteins in females remains unexplored.
Identification of the cellular sources of exosomes within the lungs is often challenging because all the resident cells present within the airspaces are known to release exosomes. In exosomes from air-exposed mice, macrophage-specific (CHIL3, LYZ2), airway epithelial cell-specific (SCGB1A1), and alveolar epithelial cell-specific (SFTPA1, SFTPB, SFTPC) proteins were among the most abundant proteins. While these data suggest that, under steady-state, epithelial cells as well as macrophages actively release exosomes into the airspaces, the relative contribution of individual cell types towards the overall exosome populations in the airspaces remains challenging to determine. Proteins including Histones, Annexins, S100s, and RETNLA that were relatively less abundant in exosomes from air-exposed mice were highly abundant in exosomes from ozone-exposed mice suggesting the increased release of these proteins in ozone-exposed airspaces. We hypothesized that the exosomal enrichment of these proteins is contributed by the cellular compartment that overexpresses their respective transcripts. Accordingly, comparative analyses between exosomal proteins and their respective transcripts from the three compartments (airway, parenchyma, macrophages) revealed interesting findings. Transcript levels of the enriched exosomic proteins including histones, RETNLA, Annexins, and S100s were elevated in more than one compartment, if not all three. These data suggest that the ozone stimulates the release of certain proteins from multiple cellular types.
In conclusion, this study reveals various interesting findings. First, under unchallenged conditions, resident cells shed exosomes that contain protein signatures relevant to homeostasis, cell-specificity, and antioxidant defense. Second, ozone exposure contributes to a significant enrichment of those proteins within the exosomes that were present under the homeostatic state. Third, ozone exposure, in addition, stimulates the release of stress-related proteins within the exosomes. Fourth, proteins enriched within the exosomes from ozone-exposed mice represent activation of pathways associated with stress-response. Fifth, comparative analyses of the exosomes from ozone-exposed mice identified sex-specific protein signatures. This is also true for the secretory proteins present within the cell-free BALF following ozone exposure. Sixth, cellular localization of selected muco-inflammatory disease-related proteins revealed the potential cellular contributors of these proteins in the exosomal compartment following ozone exposure. Finally, comparative analyses between the exosomal proteins and the lung compartment-specific transcriptomic signatures revealed compartment-specific contribution towards exosomal protein contents. Collectively, this study presents detailed proteomic analyses of exosomes from homeostatic and ozone-stressed airspaces in mice. These data will aid in future mechanistic studies to unravel underlying inflammation-relevant pathways in ozone-exposed lungs.
References
Colombo, M., Raposo, G. & Thery, C. Biogenesis, secretion, and intercellular interactions of exosomes and other extracellular vesicles. Annu. Rev. Cell Dev. Biol. 30, 255–289 (2014).
Thery, C., Zitvogel, L. & Amigorena, S. Exosomes: Composition, biogenesis and function. Nat. Rev. Immunol. 2, 569–579 (2002).
McVey, M. J., Maishan, M., Blokland, K. E. C., Bartlett, N. & Kuebler, W. M. Extracellular vesicles in lung health, disease, and therapy. Am. J. Physiol. Lung Cell. Mol. Physiol. 316, L977–L989 (2019).
Muller, L., Hong, C. S., Stolz, D. B., Watkins, S. C. & Whiteside, T. L. Isolation of biologically-active exosomes from human plasma. J. Immunol. Methods 411, 55–65 (2014).
Grant, R. et al. A filtration-based protocol to isolate human plasma membrane-derived vesicles and exosomes from blood plasma. J. Immunol. Methods 371, 143–151 (2011).
Paredes, P. T. et al. Bronchoalveolar lavage fluid exosomes contribute to cytokine and leukotriene production in allergic asthma. Allergy 67, 911–919 (2012).
Admyre, C. et al. Exosomes with major histocompatibility complex class II and co-stimulatory molecules are present in human BAL fluid. Eur. Respir. J. 22, 578–583 (2003).
Pisitkun, T., Shen, R. F. & Knepper, M. A. Identification and proteomic profiling of exosomes in human urine. Proc. Natl. Acad. Sci. U. S. A. 101, 13368–13373 (2004).
Gonzales, P. A. et al. Isolation and purification of exosomes in urine. Methods Mol. Biol. 641, 89–99 (2010).
Chanteloup, G. et al. Monitoring HSP70 exosomes in cancer patients’ follow up: A clinical prospective pilot study. J. Extracell. Vesicles 9, 1766192 (2020).
Amiri, A. et al. Exosomes and Lung cancer: Roles in pathophysiology, diagnosis and therapeutic applications. Curr. Med. Chem. 28, 308 (2020).
McVey, M. J., Spring, C. M., Semple, J. W., Maishan, M. & Kuebler, W. M. Microparticles as biomarkers of lung disease: Enumeration in biological fluids using lipid bilayer microspheres. Am. J. Physiol. Lung Cell. Mol. Physiol. 310, L802-814 (2016).
Mathieu, M., Martin-Jaular, L., Lavieu, G. & Thery, C. Specificities of secretion and uptake of exosomes and other extracellular vesicles for cell-to-cell communication. Nat. Cell Biol. 21, 9–17 (2019).
Wahlund, C. J. E., Eklund, A., Grunewald, J. & Gabrielsson, S. Pulmonary extracellular vesicles as mediators of local and systemic inflammation. Front. Cell Dev. Biol. 5, 39 (2017).
Andres, J. et al. Role of extracellular vesicles in cell-cell communication and inflammation following exposure to pulmonary toxicants. Cytokine Growth Factor Rev. 51, 12–18 (2020).
Lee, H., Zhang, D., Laskin, D. L. & Jin, Y. Functional evidence of pulmonary extracellular vesicles in infectious and noninfectious lung inflammation. J. Immunol. 201, 1500–1509 (2018).
Choudhary, I., Vo, T., Paudel, K., Patial, S. & Saini, Y. Compartment-specific transcriptomics of ozone-exposed murine lungs reveals sex- and cell type-associated perturbations relevant to mucoinflammatory lung diseases. Am. J. Physiol. Lung Cell. Mol. Physiol. 320, L99–L125 (2021).
Harkema, J. R. et al. Strain differences in a murine model of air pollutant-induced nonatopic asthma and rhinitis. Toxicol. Pathol. 45, 161–171 (2017).
Hatch, G. E. et al. Progress in assessing air pollutant risks from in vitro exposures: Matching ozone dose and effect in human airway cells. Toxicol. Sci. 141, 198–205 (2014).
Hatch, G. E. et al. Biomarkers of dose and effect of inhaled ozone in resting versus exercising human subjects: Comparison with resting rats. Biomark. Insights 8, 53–67 (2013).
Hatch, G. E. et al. Ozone dose and effect in humans and rats. A comparison using oxygen-18 labeling and bronchoalveolar lavage. Am. J. Respir. Crit. Care Med. 150, 676–683 (1994).
Cabello, N. et al. Sex differences in the expression of lung inflammatory mediators in response to ozone. Am. J. Physiol.-Lung Cell. Mol. Physiol. 309, L1150–L1163 (2015).
Birukova, A. et al. Sex modifies acute ozone-mediated airway physiologic responses. Toxicol. Sci. 169, 499–510 (2019).
Tashiro, H. et al. Sex differences in the impact of dietary fiber on pulmonary responses to ozone. Am. J. Respir. Cell Mol. Biol. 62, 503–512 (2020).
Cho, Y. et al. Sex differences in pulmonary responses to ozone in mice. Role of the microbiome. Am. J. Respir. Cell Mol. Biol. 60, 198–208 (2019).
Peirson, S. N. & Foster, R. G. Bad light stops play. EMBO Rep. 12, 380 (2011).
Thery, C., Amigorena, S., Raposo, G. & Clayton, A. Isolation and characterization of exosomes from cell culture supernatants and biological fluids. Curr. Protoc. Cell Biol. 3, 22 (2006).
Nesvizhskii, A. I., Keller, A., Kolker, E. & Aebersold, R. A statistical model for identifying proteins by tandem mass spectrometry. Anal. Chem. 75, 4646–4658 (2003).
Huber, W., von Heydebreck, A., Sultmann, H., Poustka, A. & Vingron, M. Variance stabilization applied to microarray data calibration and to the quantification of differential expression. Bioinformatics 18(Suppl 1), S96-104 (2002).
Bolstad, B. M. Preprocess core: A collection of pre-processing functions. R package version 1.48.0. (2019).
Ritchie, M. E. et al. limma powers differential expression analyses for RNA-sequencing and microarray studies. Nucl. Acids Res. 43, e47 (2015).
Chawade, A., Alexandersson, E. & Levander, F. Normalyzer: A tool for rapid evaluation of normalization methods for omics data sets. J. Proteome Res. 13, 3114–3120 (2014).
Alhamdoosh, M. et al. Easy and efficient ensemble gene set testing with EGSEA. F1000Res 6, 2010 (2017).
Szklarczyk, D. et al. STRING v11: Protein-protein association networks with increased coverage, supporting functional discovery in genome-wide experimental datasets. Nucl. Acids Res. 47, D607–D613 (2019).
Lewis, B. W. et al. Ablation of IL-33 suppresses Th2 responses but is accompanied by sustained mucus obstruction in the Scnn1b transgenic mouse model. J. Immunol. 204, 1650–1660 (2020).
Lewis, B. W. et al. The innate lymphoid system is a critical player in the manifestation of mucoinflammatory airway disease in mice. J. Immunol. 205, 1695–1708 (2020).
Nadadur, S. S., Costa, D. L., Slade, R., Silbjoris, R. & Hatch, G. E. Acute ozone-induced differential gene expression profiles in rat lung. Environ. Health Perspect. 113, 1717–1722 (2005).
Hu, P. C. et al. Protein accumulation in lung lavage fluid following ozone exposure. Environ. Res. 29, 377–388 (1982).
Joyner, B. L. et al. DNA and inflammatory mediators in bronchoalveolar lavage fluid from children with acute inhalational injuries. J. Burn Care Res. 34, 326–333 (2013).
Kirchner, K. K., Wagener, J. S., Khan, T. Z., Copenhaver, S. C. & Accurso, F. J. Increased DNA levels in bronchoalveolar lavage fluid obtained from infants with cystic fibrosis. Am. J. Respir. Crit. Care Med. 154, 1426–1429 (1996).
Choudhary, I. et al. Postnatal ozone exposure disrupts alveolar development, exaggerates mucoinflammatory responses, and suppresses bacterial clearance in developing Scnn1b-Tg+ mouse lungs. J. Immunol. accepted (2021).
Sunil, V. R., Patel-Vayas, K., Shen, J., Laskin, J. D. & Laskin, D. L. Classical and alternative macrophage activation in the lung following ozone-induced oxidative stress. Toxicol. Appl. Pharmacol. 263, 195–202 (2012).
Groves, A. M. et al. Age-related increases in ozone-induced injury and altered pulmonary mechanics in mice with progressive lung inflammation. Am. J. Physiol. Lung Cell. Mol. Physiol. 305, L555-568 (2013).
Mathews, J. A. et al. Gammadelta T cells are required for M2 macrophage polarization and resolution of ozone-induced pulmonary inflammation in mice. PLoS ONE 10, e0131236 (2015).
Pinkerton, K. E., Menache, M. G. & Plopper, C. G. Consequences of prolonged inhalation of ozone on F344/N rats: Collaborative studies. Part IX: Changes in the tracheobronchial epithelium, pulmonary acinus, and lung antioxidant enzyme activity. Res. Rep. Health Eff. Inst. 41–98; discussion 99–110 (1995).
McDonnell, W. F., Abbey, D. E., Nishino, N. & Lebowitz, M. D. Long-term ambient ozone concentration and the incidence of asthma in nonsmoking adults: The AHSMOG Study. Environ. Res. 80, 110–121 (1999).
Anenberg, S. C. et al. Estimates of the global burden of ambient [formula: see text], ozone, and [formula: see text] on asthma incidence and emergency room visits. Environ. Health Perspect. 126, 107004 (2018).
Tetreault, L. F. et al. Childhood exposure to ambient air pollutants and the onset of asthma: An administrative cohort study in Quebec. Environ. Health Perspect. 124, 1276–1282 (2016).
Strosnider, H. M. et al. Age-specific associations of ozone and fine particulate matter with respiratory emergency department visits in the United States. Am. J. Respir. Crit. Care Med. 199, 882–890 (2019).
Paulin, L. M., Kaufman, J. D. & Hansel, N. N. Concerns remain regarding long-term ozone exposure and respiratory outcomes-reply. JAMA Intern. Med. 180, 804 (2020).
Kirkham, S. et al. MUC5B is the major mucin in the gel phase of sputum in chronic obstructive pulmonary disease. Am. J. Respir. Crit. Care Med. 178, 1033–1039 (2008).
Boitano, S., Safdar, Z., Welsh, D. G., Bhattacharya, J. & Koval, M. Cell-cell interactions in regulating lung function. Am. J. Physiol. Lung Cell. Mol. Physiol. 287, L455-459 (2004).
Gupta, R. et al. Intercellular communication between airway epithelial cells is mediated by exosome-like vesicles. Am. J. Respir. Cell Mol. Biol. 60, 209–220 (2019).
Lee, H., Abston, E., Zhang, D., Rai, A. & Jin, Y. Extracellular vesicle: An emerging mediator of intercellular crosstalk in lung inflammation and injury. Front. Immunol. 9, 924 (2018).
Moon, H. G. et al. Lung epithelial cell-derived extracellular vesicles activate macrophage-mediated inflammatory responses via ROCK1 pathway. Cell Death Dis. 6, e2016 (2015).
Yanez-Mo, M. et al. Biological properties of extracellular vesicles and their physiological functions. J. Extracell. Vesicles 4, 27066 (2015).
Haggadone, M. D. & Peters-Golden, M. Microenvironmental influences on extracellular vesicle-mediated communication in the lung. Trends Mol. Med. 24, 963–975 (2018).
Fujita, Y., Kosaka, N., Araya, J., Kuwano, K. & Ochiya, T. Extracellular vesicles in lung microenvironment and pathogenesis. Trends Mol. Med. 21, 533–542 (2015).
Levin, S. W., Butler, J. D., Schumacher, U. K., Wightman, P. D. & Mukherjee, A. B. Uteroglobin inhibits phospholipase A2 activity. Life Sci. 38, 1813–1819 (1986).
Hayashida, S., Harrod, K. S. & Whitsett, J. A. Regulation and function of CCSP during pulmonary Pseudomonas aeruginosa infection in vivo. Am. J. Physiol. Lung Cell. Mol. Physiol. 279, L452-459 (2000).
Rosseau, S. et al. Surfactant protein A down-regulates proinflammatory cytokine production evoked by Candida albicans in human alveolar macrophages and monocytes. J. Immunol. 163, 4495–4502 (1999).
Ikegami, M. et al. Surfactant protein-D and surfactant inhibit endotoxin-induced pulmonary inflammation. Chest 132, 1447–1454 (2007).
Allen, J. N., Moore, S. A., Pope-Harman, A. L., Marsh, C. B. & Wewers, M. D. Immunosuppressive properties of surfactant and plasma on alveolar macrophages. J. Lab. Clin. Med. 125, 356–369 (1995).
Ueno, K. et al. MUC1 mucin is a negative regulator of toll-like receptor signaling. Am. J. Respir. Cell. Mol. Biol. 38, 263–268 (2008).
Sheng, Y. H. et al. MUC1 and MUC13 differentially regulate epithelial inflammation in response to inflammatory and infectious stimuli. Mucosal Immunol. 6, 557–568 (2013).
Li, Y., Dinwiddie, D. L., Harrod, K. S., Jiang, Y. & Kim, K. C. Anti-inflammatory effect of MUC1 during respiratory syncytial virus infection of lung epithelial cells in vitro. Am. J. Physiol. Lung Cell. Mol. Physiol. 298, L558-563 (2010).
Guang, W. et al. Muc1 cell surface mucin attenuates epithelial inflammation in response to a common mucosal pathogen. J. Biol. Chem. 285, 20547–20557 (2010).
Roy, M. G. et al. Muc5b is required for airway defence. Nature 505, 412–416 (2014).
Cantin, A. M., Fells, G. A., Hubbard, R. C. & Crystal, R. G. Antioxidant macromolecules in the epithelial lining fluid of the normal human lower respiratory tract. J. Clin. Invest. 86, 962–971 (1990).
Snelgrove, R. J. et al. A critical function for CD200 in lung immune homeostasis and the severity of influenza infection. Nat. Immunol. 9, 1074–1083 (2008).
Shafiei-Jahani, P. et al. CD200-CD200R immune checkpoint engagement regulates ILC2 effector function and ameliorates lung inflammation in asthma. Nat. Commun. 12, 2526 (2021).
Rijkers, E. S. et al. The inhibitory CD200R is differentially expressed on human and mouse T and B lymphocytes. Mol. Immunol. 45, 1126–1135 (2008).
Berger, T. et al. Lipocalin 2-deficient mice exhibit increased sensitivity to Escherichia coli infection but not to ischemia-reperfusion injury. Proc. Natl. Acad. Sci. U. S. A. 103, 1834–1839 (2006).
Bachman, M. A., Miller, V. L. & Weiser, J. N. Mucosal lipocalin 2 has pro-inflammatory and iron-sequestering effects in response to bacterial enterobactin. PLoS Pathog. 5, e1000622 (2009).
Barnes, P. J. Sex differences in chronic obstructive pulmonary disease mechanisms. Am. J. Respir. Crit. Care Med. 193, 813–814 (2016).
Kokturk, N., Kilic, H., Baha, A., Lee, S. D. & Jones, P. W. Sex difference in chronic obstructive lung disease. Does it matter? A concise review. COPD 13, 799–806 (2016).
Tam, A. et al. Sex differences in airway remodeling in a mouse model of chronic obstructive pulmonary disease. Am. J. Respir. Crit. Care Med. 193, 825–834 (2016).
Lee, H., Zhang, D., Wu, J., Otterbein, L. E. & Jin, Y. Lung epithelial cell-derived microvesicles regulate macrophage migration via microRNA-17/221-induced integrin beta1 recycling. J. Immunol. 199, 1453–1464 (2017).
Bourdonnay, E. et al. Transcellular delivery of vesicular SOCS proteins from macrophages to epithelial cells blunts inflammatory signaling. J. Exp. Med. 212, 729–742 (2015).
Mudway, I. S. et al. Compromised concentrations of ascorbate in fluid lining the respiratory tract in human subjects after exposure to ozone. Occup. Environ. Med. 56, 473–481 (1999).
Wiegman, C. H. et al. A comprehensive analysis of oxidative stress in the ozone-induced lung inflammation mouse model. Clin. Sci. (Lond.) 126, 425–440 (2014).
Mosser, D. M. & Edwards, J. P. Exploring the full spectrum of macrophage activation. Nat. Rev. Immunol. 8, 958–969 (2008).
Sunil, V. R. et al. Regulation of ozone-induced lung inflammation and injury by the beta-galactoside-binding lectin galectin-3. Toxicol. Appl. Pharmacol. 284, 236–245 (2015).
Sunil, V. R. et al. Ozone-induced injury and oxidative stress in bronchiolar epithelium are associated with altered pulmonary mechanics. Toxicol. Sci. 133, 309–319 (2013).
Cabello, N. et al. Sex differences in the expression of lung inflammatory mediators in response to ozone. Am. J. Physiol. Lung Cell. Mol. Physiol. 309, L1150-1163 (2015).
Martinez, F. O. et al. Genetic programs expressed in resting and IL-4 alternatively activated mouse and human macrophages: Similarities and differences. Blood 121, e57-69 (2013).
Eligini, S., Fiorelli, S., Tremoli, E. & Colli, S. Inhibition of transglutaminase 2 reduces efferocytosis in human macrophages: Role of CD14 and SR-AI receptors. Nutr. Metab. Cardiovasc. Dis. 26, 922–930 (2016).
Yue, X. & Guidry, J. J. Differential protein expression profiles of bronchoalveolar lavage fluid following lipopolysaccharide-induced direct and indirect lung injury in mice. Int. J. Mol. Sci. 20, 3401 (2019).
Bosmann, M. et al. Extracellular histones are essential effectors of C5aR- and C5L2-mediated tissue damage and inflammation in acute lung injury. FASEB J. 27, 5010–5021 (2013).
Huang, H. et al. Endogenous histones function as alarmins in sterile inflammatory liver injury through toll-like receptor 9 in mice. Hepatology 54, 999–1008 (2011).
Xu, J. et al. Extracellular histones are major mediators of death in sepsis. Nat. Med. 15, 1318–1321 (2009).
Paulin, L. M. et al. Association of long-term ambient ozone exposure with respiratory morbidity in smokers. JAMA Intern. Med. 180, 106 (2019).
Khatri, S. B. et al. Association of ambient ozone exposure with airway inflammation and allergy in adults with asthma. J. Asthma 46, 777–785 (2009).
Acknowledgements
We thank Thaya Stoufflet for assistance with multiplex cytokine assays. We thank Sherry Ring for histological tissue processing. We thank Dr. Camille Ehre (University of North Carolina at Chapel Hill) for providing MUC5B antibody. We acknowledge the GeneLab for providing core services and access to Bioinformatics software. The GeneLab is supported by Institutional Development Awards (IDeA) from the National Institute of General Medical Sciences (Grants P20 GM103424 and P20 GM130555).
Funding
This work was supported by National Institute of Environmental Health Sciences Grant R01ES030125 (to Y.S.).
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Y.S. conceived and designed the research; I.C., T.V., K.P., and Y.S. maintained the animal colony, performed ozone exposures, conducted animal necropsies, and performed cytokine measurement experiments; I.C. harvested exosomes. K.P. and Y.S. performed the immunohistochemical analysis. M.K. and R.G. performed exosome analyses. I.C., S.P. and Y.S. analyzed the histopathological and immunohistochemical data. X.W. provided assistance with the statistical analyses. S.P. and Y.S. wrote and reviewed the manuscript for intellectual contents.
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Choudhary, I., Vo, T., Paudel, K. et al. Vesicular and extravesicular protein analyses from the airspaces of ozone-exposed mice revealed signatures associated with mucoinflammatory lung disease. Sci Rep 11, 23203 (2021). https://doi.org/10.1038/s41598-021-02256-5
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DOI: https://doi.org/10.1038/s41598-021-02256-5
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