All experimental procedures were approved by the Institutional Animal Care and Use Committee (protocol #2020-0052) of the Case Western Reserve University (CWRU). All animals were treated in accordance with the NIH guidelines for the care and use of laboratory animals. Nox4 ^fl/fl mice used in this study were described previously (Matsushima et al., 2013; Fu et al., 2021). To determine the role of AT2 epithelial cell NOX4 in HO-mediated lung inflammatory injury, mice harboring a deletion of Nox4 in AT2 cells (Nox4 ^−/− Spc-Cre) were generated. The Nox4 ^fl/fl and the Nox ^+/- Spc-Cre mice were gifted by Dr. V Natarajan, Dept. of Pharmacology and Regenerative Medicine, University of Illinois at Chicago. Both male and female mice, 8 weeks old, were used for the experiments. Temporal deletion of Nox4 in Nox ^+/- Spc-Cre mice was achieved by intraperitoneal injection of tamoxifen (200 mg/kg dissolved in corn oil) for five consecutive days. The animals were used for experiments 2 weeks later. Nox4 ^fl/fl mice that served as controls also received the same dosage and time course of tamoxifen injection and experimentation. The mice were exposed to room air/ normoxia (NO) or 95% hyperoxia (HO) for 66 h. A 66 h timepoint was chosen based on the preliminary data collected at either 48 or 72 h. At 48 h, there was no significant injury observed (data not shown) and at 72 h, the animals appeared seriously morbid. Following exposure to NO or HO, the mice were humanely euthanized to collect lungs for histology, bronchoalveolar lavage (BAL) and other analyses. Euthanasia was by anesthetic overdose (intraperitoneal injection of a 100 mg/kg ketamine and 10 mg/kg xylazine mix) followed by exsanguination. Treatment groups of 6–10 mice (both male and female) were used for each of the experiments and representative data are shown.

The animals were euthanized, the trachea intubated, and the left lung lobe was inflated with neutral buffered formalin at 20 cm of H₂O pressure. Following fixation for another 24 h, the lungs were processed for paraffin embedding and sectioning. Lung tissue was cut into 5 μm sections for subsequent alveolar analyses after hematoxylin and eosin (H&E) staining. We have used two serial sections (six fields/section) from each animal and a total of six animals per group. Assessment of acute lung injury was done for infiltration of neutrophils, alveolar wall thickening and deposition of proteinaceous debris (Matute-Bello et al., 2011). Briefly, a scoring system with scores of 0, 1 and 2 was used for each of the three criteria mentioned. An average score of 0 indicated absence of injury, 1–2 indicated mild to moderate injury and two indicated severe injury. Scoring was done for all animals and averaged for a group.

To assess the evaluation of Nox4 deletion in AT2 cells, the lung tissue sections from Nox4 ^fl/fl and Nox4 ^−/− Spc-Cre mice (Nox4 deleted) were pretreated with antigen retrieval buffer (10 mM citrate), followed by blocking nonspecific binding with appropriate serum. Sections were then subjected to immunofluorescence co-staining for NOX4 (1:300; 14347-1-AP; Proteintech, Rosemont, IL, United States) and surfactant protein-C/ SPC (1:50; sc-7705; Santacruz, Dallas, TX, United States) to co-localize NOX4 deletion in AT2 cells. This was followed by incubation with respective secondary antibodies (Alexa Fluor 488 and Alexa Fluor 594 from Invitrogen at 1:500) followed by mounting using Vectashield mounting medium containing 4’,6-diamidino-2-phenylindole/DAPI (Vector Laboratories, Burlingame, CA, United States). Appropriate negative controls were run by omitting the primary antibody to confirm nonspecific staining. Images of the immunostained sections were captured using a fluorescence microscope (Leica Microsystems, Wetzlar, Germany) equipped with a Rolera XR CCD camera (Q-Imaging, Surrey, BC, Canada) mounted on a microscope. ImageJ software was used to analyze the stained lung sections and the intensity of staining was measured per area.

BAL collection was based on our previous protocol (Ha et al., 2020; Sudhadevi et al., 2021). Briefly, the mice were sacrificed, the trachea were exposed, the tubing were inserted and secured, and the whole lung was lavaged with 1 ml of PBS. Cells in the BAL fluid was counted using a cell counter (Bio-Rad). The total protein concentration in BAL fluid was measured using the BCA protein assay according to the manufacturer’s instructions (#23225; Pierce). For cytokine analysis in the BAL fluid, Luminex technology and reagents (R&D Systems, Minneapolis, MN, United States) were used. Murine TNF-α, IL-6, macrophage inflammatory protein 2 (MIP-2), keratinocyte-derived chemokine (KC), and MIP-1 ∝ were analyzed according to the manufacturer’s instructions.

Terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) assay was used per manufacturer’s instructions (The ApopTag Peroxidase In Situ Apoptosis Detection Kit, S7100; Millipore Sigma, Billerica, United States). Sections were counterstained with methyl green. The number of TUNEL positive cells were counted in all areas of the section using a light microscope (×20 magnification) and the average number of TUNEL-positive cells per field per animal were calculated.

Mice after exposure to NO or HO were anesthetized intraperitoneally with ketamine (100 mg/kg) and xylazine (10 mg/kg), tracheostomized with a metal 18 G cannula and connected to a flexiVent ventilator (SCIREQ, Montréal, QC, Canada). Baseline measurements were performed using forced-oscillation maneuvers and calculated using the ventilator software (flexiWare 5.1, Version 7.2; SCIREQ). Following a recruitment breath to 30 cm H₂O, three measurements of respiratory system resistance (Rrs), respiratory system elastance (Ers), and dynamic compliance (Crs) were performed (Snapshot 150), as well as lung tissue impedance parameters of tissue resistance (G) and tissue elastance (H) (Quick Prime-3). Mean values of Rrs, Ers, Crs, G and H for each animal are reported.

Mouse lung epithelial cells (MLE-12) cultured in DMEM-F12 medium containing 10% FBS and antibiotic (Sigma) were used for the in vitro experiments. The cells (∼80% confluence) were exposed to HO (95% O₂) as described before (Harijith et al., 2016) using a humidity-controlled airtight Billups- Rothenberg modulator incubator chamber (Billups-Rothenberg, CA, United States), flushed with 95% O₂:5% CO₂ gas. The concentration of O₂ inside was continuously monitored using a digital oxygen monitor. The buffering capacity of the cell culture medium was maintained at a pH ∼7.4 during the period of HO exposure.

Protein expression was detected in the mouse lungs and MLE-12 cells by immunoblotting as described earlier (Harijith et al., 2013; Bandela et al., 2021). Lung tissues were pulverized (Bessman tissue pulverizer, # 189475; Spectrum Laboratories Inc.) using a pulverizer, sonicated in RIPA buffer (Sigma, in the ratio 10 volumes of lysis buffer to 1 part by weight of lung tissue) and centrifuged to collect the supernatant. Similarly, cells exposed to HO were lysed in RIPA buffer, sonicated and the supernatants were subjected to protein quantification using the BCA protein assay (Pierce Chemical, Rockford, IL, United States). Samples (20 µg) were subjected to SDS-gel electrophoresis (ThermoFisher, DE, United States) and immunoblotting (#03500216; Hoefer, Fisher Scientific). The following antibodies were used: NOX4 antibody (1:300; 14347-1-AP, Proteintech, IL, United States), β -actin (A15441, Sigma Aldrich, MO, United States) and GAPDH (10494-1-AP, Proteintech, IL, United States). The bands were detected using Pierce ECL (ThermoFisher, DE, United States) or Amersham ECL Prime (Cytiva) followed by exposure to light sensitive Hyperfilm (Amersham Biosciences, Little Chalfont, United Kingdom). ImageJ software (NIH, Bethesda, MD, United States) was used to quantify the relative intensities of protein bands. Results were expressed as a ratio of specific protein signal to the house keeping protein.

MLE-12 cells at ∼50% confluence were transfected with scRNA (scrambled) or siRNA specific for NOX4 (sc-41587; Santacruz, CA, United States) using Gene Silencer transfection reagent (T500750; Gelantis, San Diego, CA, United States) in serum-free DMEM medium (Sigma) according to manufacturer’s recommendations. After 3 h of transfection, the serum-free medium was replaced with complete MLE-12 medium containing 10% FBS. The cells were cultured for an additional 48h/72 h prior to experiments.

MLE-12 cells were pretreated with 10 µM   μ MitoTEMPO (Santacruz, TX, United States) or vehicle control for 2 h and subjected to NO or HO for 24 h and then assessed for mitochondrial superoxide and apoptosis.

Mitochondrial superoxide generation in MLE1-12 cells upon HO exposure and NOX4 silencing was determined using the MitoSOX Red mitochondrial superoxide indicator (Invitrogen, Greenville, NC, United States), as per the manufacturer’s protocol. The cells were loaded with 5 µM MitoSOX reagent for 15 min. The washed cells were subjected to live cell imaging using a confocal microscope (Leica HyVolution SP8) at ×63 magnification.

MLE-12 cells were cultured in phenol red free medium and then exposed to specific treatments. The cell culture supernatants were collected and H₂O₂ concentration was measured using Amplex Red Hydrogen Peroxide/Peroxidase kit (Invitrogen, United States), according to the manufacturer’s instruction.

Flow cytometry was used to assess apoptosis. Mouse lung epithelial cells subjected to various treatments were stained with Annexin V and 7-AAD (PE Annexin V apoptosis kit, #559763; BD, United States) according to the manufacturer’s instructions. Data was analyzed using a BD LSR II (BD Biosciences, United States) flow cytometer. Gating was set based on unstained and single-stained populations.

All data are expressed as mean ± SEM from a minimum of three independent experiments. GraphPad Prism 9 software was used for statistical analysis. Student’s t-test or two-way ANOVA (Tukey’s post hoc tests) were used for comparison of two or more groups respectively. The level of significance was set to ****p < 0.0001, ***p < 0.001, **p <0.01, and *p < 0.05.

Exposure of wild-type (WT) mice to HO (95% O₂) for 66 h stimulated NOX4 protein expression in the lungs (∼1.5-fold increase compared to normoxia, NO) (Figures 1A,B).

Nox4 ^−/− Spc-Cre animals were generated and validated. Immunofluorescence staining of lung tissue sections demonstrated co-localization of NOX4 (green) with SPC (red) in the lung alveolar epithelial cells of Nox4 ^fl/fl mice but not in the tamoxifen induced Nox4 ^−/− Spc-Cre mice (Figure 2A), indicating a significant knockdown of Nox4 as quantified by ImageJ analysis (2722 AU for Nox4 ^fl/fl lung tissue as compared to 932 AU for Nox4 ^−/− Spc-Cre) (Figure 2B). Western blot of lysates with AT2 cells isolated from Nox4 ^−/− Spc-Cre animals showed significant NOX4 knockdown compared to Nox4 ^fl/fl (Figure 2C).

The role of NOX4 in HALI was investigated by exposing Nox4 ^fl/fl and Nox4 ^−/− Spc-Cre mice to NO or HO. As shown in Figure 3A, H & E staining of lung tissues harvested from Nox4 ^fl/fl exposed to HO demonstrated significant HALI as determined by increased infiltration of neutrophils, alveolar wall thickening and presence of proteinaceous debris in the alveolar space. ATS scoring was used for quantification of lung injury and showed significantly less injury in the hyperoxic Nox4 ^−/− Spc-Cre mice (0.38 which is 3.5 fold compared to HO) (Figure 3B) compared to HO (1.16 which is ∼10 fold compared to NO). Increased cell count, as well as protein levels in BAL fluid, were also observed with HO exposure (Figures 3C,D). These responses were noted to be significantly lower in the Nox4 ^−/− Spc-Cre mice. A significant elevation of the inflammatory cytokines (Figure 4), (A) KC (∼91 pg/ml in HO against ∼5 pg/ml in NO), (B) TNF- ∝ (∼0.9 pg/ml in HO against ∼0.1 pg/ml in NO), (C) MIP-2 (∼36 pg/ml in HO against ∼1 pg/ml in NO), (D) IL-6 (∼25 pg/ml in HO against ∼2 pg/ml in NO) and (E) MIP-1 ∝ (∼11 pg/ml in HO against ∼0.3 pg/ml in NO) were observed in the BAL fluid from HO exposed Nox4 ^fl/fl mice. This increase was attenuated significantly for KC (∼40 pg/ml), TNF- ∝ (∼0.4 pg/ml), MIP-2 (∼8 pg/ml), IL-6 (∼10 pg/ml) and MIP-1 ∝   (∼3 pg/ml) as compared to HO Nox4 ^fl/fl controls in the Nox4 ^−/− Spc-Cre mice.

Next, we investigated epithelial cell apoptosis in HALI. TUNEL staining analysis in Nox4 ^fl/fl HO group showed a massive increase in the percentage of TUNEL-positive cells (∼10% in HO as compared to ∼1% in NO) indicating increased AT2 cell death. In contrast, no significant increase in TUNEL-positive cells (∼4% as compared to HO) was observed in Nox4 ^−/− Spc-Cre HO mice (Figure 5A). The differences between the HO control and the HO Nox4 ^−/− Spc-Cre mice were statistically significant (Figure 5B).

Hyperoxia resulted in higher baseline respiratory system resistance (Rrs: 0.75 cmH₂O.s/ml) and respiratory system elastance (Ers: 35.93 cmH₂O/ml) when compared to NO controls. These were reduced significantly to 0.44 cmH₂O.s/ml and 25.38 cmH₂O/ml in hyperoxic animals by genetic deletion of Nox4 (Figures 6A,B) as compared to control HO group. We also observed significant changes in lung tissue impedance parameters, such as tissue resistance/tissue dampening (G) and tissue elastance (H). The G increased from 3.27 to 6.4 cmH₂O/ml which is reduced to 3.36 cmH₂O/ml in the Nox4 ^−/− Spc-Cre group. H increased from 25 to 34 cmH₂O/ml but remained low in the Nox4 deleted group (∼24 cmH₂O/ml) (Figures 6C,D). Compliance is the inverse of elastance, and we noted a decrease in Crs (∼0.03 cmH₂O/ml) in the HO group which was significantly increased to ∼0.04 cmH₂O/ml in the Nox4 ^−/− Spc-Cre group (Figure 6E).

Proteins extracted from primary MLE-12 cells exposed to HO showed increased expression of NOX4. Quantitative analysis by ImageJ showed significant increase in NOX4 expression (∼1.5 fold) (Figures 7A,B).

The role of NOX4 in HO-induced mt ROS was investigated. HO considerably increased MitoSOX fluorescence intensity (∼2 fold more as compared to NO) as well as H₂O₂ release (∼2.7 µM as compared to 1.2 µM for NO). Silencing NOX4 in MLE-12 cells using NOX4 siRNA for 24 h significantly attenuated HO-induced mitochondrial superoxide production (∼1.2 fold as compared to HO) as determined by MitoSOX (Figures 8A,B) as well as H₂O₂ release (∼1.6 µM as compared to HO) determined by the Amplex red assay (Figure 8C). Western blot of MLE-12 cells confirmed NOX4 knockdown in the siRNA treated group compared to scRNA (Figure 8D). These results show a role for NOX4 in HO-mediated mt ROS production in lung epithelial cells.

Exposure of MLE-12 cells to HO for 48 h significantly increased the percentage of Annexin V positive early apoptotic cells and this increase was attenuated with NOX4 silencing (Figures 9A,B) suggesting a pathological role for NOX4 in promoting apoptosis. The average percentage fold change was ∼4.5 for HO as compared to NO and this was reduced to ∼2.5 for NOX4 silenced cells.

HO induced an increase in mt ROS production as determined by MitoSOX (∼10 AU in HO as compared to ∼5 AU for NO). Scavenging mitochondrial superoxide with MitoTEMPO reduced this HO-induced mitochondrial superoxide production to ∼4.5 AU (Figure 10). Also, the HO-induced increase in the percentage of epithelial cell apoptosis (∼5% fold change compared to NO) was attenuated (∼2.5 fold as compared to HO) by pretreatment with MitoTEMPO (Figure 11).