Influenza A virus-dependent remodeling of pulmonary clock function in a mouse model of COPD

We have previously reported that mice exposed to 10 days of CS (acute exposure model) during the active phase show reduced locomotor activity associated with increased inflammation³⁰. Similarly, mice exposed to chronic CS showed significantly reduced activity beginning 5 days after the first exposure that persisted for much of the exposure period³⁰. In the present study, chronic CS-exposed mice infected with IAV (CS+Virus) showed a significant reduction in locomotor activity after infection that persisted for the duration of measurement (9 days post-infection; Fig. 1c–d). Chronic air-exposed mice infected with influenza (Air+Virus) showed an initial reduction in locomotor activity 1–5 days after infection with a trough 5–6 days after infection followed by a modest recovery by day 9 after infection (Fig. 1c–d). Actograms clearly reveal that the CS+Virus group showed significantly reduced locomotor activity post-infection (lower right panel) when compared to Air+Virus, air- and CS-exposed mice (Fig. 1d and Supplementary Fig. 2a). Limiting our analysis to the dark phase reveals that the primary influence of IAV infection was a reduction in nighttime activity, which was further suppressed in those mice previously exposed to chronic CS (Fig. 1c). The period of locomotor activity in L:D during days 1–8 post IAV infection was very similar between air and CS groups, whereas the Air+Virus and CS+Virus groups showed increased variation in period between animals although the mean was not statistically different from controls (Fig. 1e). Analysis of behavior as a function of daily distribution (day vs. night) emphasizes the effect of IAV treatment in vivo (Supplementary Fig. 3a-d). Control (air) and Air+Virus infected mice were primarily active (70–80% activity) during the dark phase and less active (20–30%) during the light phase from day 2 to day 9 post-saline infusion (Supplementary Fig. 3a and c). In three of the four groups, we detected a transient change in the distribution of activity on day 1 post-infusion regardless of treatment, suggesting that the infusion procedure acutely and temporarily altered activity (Supplementary Fig. 3a–d). In agreement with our previous report, chronic CS-exposed mice displayed a distribution of locomotor activity similar to air-exposed mice with the majority (70–80%) of activity limited to the dark phase (Supplementary Fig. 3b)³⁰. Following IAV infection in chronic CS-exposed mice nighttime activity declined and daytime activity increased from days 3–7 post-infection such that we detected no difference between day and night activity levels by day 7 (Supplementary Fig. 3d). By day 8–9 post-infection the CS+Virus mice showed recovery of their normal nighttime (70–80%) and daytime (20–30%) distribution of activity (Supplementary Fig. 3d).

Locomotor activity of BMAL1 KO and WT littermates was monitored before (5 days) and after IAV infection (1–9 days post-infection). Regardless of genotype, IAV infection significantly reduced activity (Fig. 2c–d and Supplementary Fig. 2b). Both BMAL1 KO and WT mice showed significant reductions in daily activity on days 1–9 post-infection (Fig. 2c–d and Supplementary Fig. 2b). The period of locomotor activity in L:D on days 1–8 post IAV infection was very similar between all four groups, though IAV infected BMAL1 KO mice had greater variability in period relative to the other treatment groups (Fig. 2e). Analysis of behavior as a function of daily distribution (day vs. night) emphasizes treatment and genotype specific effects (Supplementary Fig. 4a–d). As expected, WT-saline treated mice were mostly active during the dark phase (ZT12-24; 70–80% of total activity) while BMAL1 KO-saline treated mice appeared to be arrhythmic and displayed a more even distribution of activity, though levels were still slightly higher at night (Supplementary Fig. 4a–b). IAV infection altered the normal distribution of daily activity in both WT and BMAL1 KO mice, though the effects were clearly more dramatic in WT mice (Supplementary Fig. 4c-d). WT mice infected with IAV increased their daytime activity but reduced their nighttime activity, producing apparent arrhythmia marked by a near equal distribution of activity across the 24h day (50% light; 50% dark). This effect of IAV infection on daily activity was less pronounced in BMAL1 KO mice, due largely to the fact that these mice already displayed a more equal distribution of daily activity/arrhythmia. That said, within 2 days of infection mean activity was actually higher in BMAL1 KO mice during the light phase, suggesting a brief period of diurnal preference following IAV infection (Supplementary Fig. 4d). This effect was diminished by day 3–4 post-infection with mice becoming more active during the night 5–9 days post-infection in parallel with increased mortality. These data reveal that, though BMAL1 KO mice differ from WT mice in terms of activity distribution prior to infection (most likely due to entrainment deficits in KO mice) both strains show reduced nocturnal preference following IAV infection.

We also determined the effects of CS with or without IAV infection on the expression of CCGs including sirt1, ahr and muc5ac in the lungs (Supplementary Fig. 5c–d). We have previously detected a circadian rhythm of sirt1 expression that was altered by acute exposure to CS³⁰. Herein we observed daily fluctuation of all three CCGs but only ahr rhythmicity was confirmed by CircWave analysis (P < 0.05). Though not statistically rhythmic in the air-exposed lungs, CircWave analysis did confirm significant rhythms of sirt1 (P < 0.05) in the Air+Virus group that was attenuated by previous exposure to CS (Supplementary Fig. 5c-d and Table 1). Further, we detected a shift in peak sirt1 and ahr expression from the latter portion of the dark phase (ZT18) in the air-exposed group to mid-day (ZT6) in both the Air+Virus and CS+Virus groups (Supplementary Fig. 5d). In addition to these phase shifts, there was an apparent increase in the amplitude of sirt1 expression following IAV infection (Supplementary Fig. 5c). According to CircWave analyses muc5ac was not rhythmically expressed in lung tissue regardless of treatment (Supplementary Fig. 5c).

The effect of acute CS exposure combined with or without IAV infection on clock gene expression in the lung was confirmed by real-time monitoring of PER2::LUC expression in lung tissue explant cultures. Exposure to 0.1% cigarette smoke extract (CSE) in vitro produced a modest reduction in the amplitude and slight increase in the period of PER2::LUC expression in lung tissue explants in agreement with our previous report³⁰. Viral infection (300 HAU/ml) also significantly reduced the amplitude and increased the period of PER2::LUC expression in lung explants (Fig. 3c). We observed comparable effects of 0.1% CSE+Virus similar to 0.1% CSE treatment alone in the amplitude and period of PER2::LUC expression in lung tissue explants (Fig. 3c). There was a significant reduction in the period of PER2::LUC expression in lung tissue explants treated with 0.1% CSE+Virus compared to IAV infection alone (Fig. 3c). Overall, CSE+Virus and IAV infection alone both reduced the amplitude and differentially affected the period of PER2::LUC expression in lung tissue explants.

We next determined the impact of chronic CS exposure followed by IAV infection on rhythms of proinflammatory cytokine release in BAL fluid. MCP-1, IL-6 and MIP-2 levels were measured in BAL fluid at day 9 post-infection across the 24h day. The CS+Virus group showed significant increases in the expression of MCP-1 at ZT6 and ZT24 when compared to Air+Virus and air-exposed controls (Fig. 4e). We observed a significant decline in the levels of proinflammatory cytokines MIP-2 at ZT0 and ZT12 and IL-6 at ZT12 in the Air+Virus and CS+Virus groups 9 days post-infection compared to uninfected CS-exposed mice (Fig. 4f–g). Chronic CS-exposed mice showed significant increases in the levels of IL-6 and MIP-2 that peaked at ZT12 compared to air-exposed controls (Fig. 4f–g). Overall, IAV infection dampened the total number of neutrophils, MIP-2 and IL-6 levels, while it increased the total number of macrophages, lymphocytes and MCP-1 levels by day 9 post-infection. CircWave analysis confirmed significant diurnal rhythms of both IL-6 and MIP-2 levels in BAL fluid from chronic CS-exposed mice (P < 0.01). In contrast, chronic air-exposed, Air+Virus and CS+Virus groups did not show rhythmic expression of MCP-1, IL-6 and MIP-2 in BAL fluid as confirmed by CircWave analysis. The increase in levels of cytokines that we observed on day 9 post-infection was associated with influx of inflammatory cells in the lung in CS+Virus and chronic CS-exposed mice (Fig. 4a–g and Supplementary Fig. 6a-d).

We have also analyzed proinflammatory cytokine release in BAL fluid by pooling time points according to photoperiod (ZT6+ZT12 = daytime and ZT18+24 = nighttime) for MCP-1, MIP-2, IL-6 and TGF-β1. Chronic CS-exposed mice showed a significant increase in the levels of MIP-2, IL-6 at ZT6+ZT12 (daytime) and TGF-β1 at ZT18+ZT24 (nighttime) compared to controls (). Chronic CS-exposed mice infected with IAV showed a significant increase in the level of MCP-1 both at ZT6+ZT12 (daytime) and ZT18+ZT24 (nighttime). The levels of other cytokines including MIP-2, IL-6 and TGF-β1 were significantly reduced in CS+Virus group compared to CS-exposed mice at ZT6+ZT12 (). Thus, our data show that disruption of circadian clock function in the lung was associated with augmented MCP-1 levels during IAV-induced exacerbation in chronic CS-exposed mice. Supplementary Fig. 6a–d Supplementary Fig. 6a-d

To further examine the role of circadian regulatory factors on host responses to infection, we determined the total number of leukocytes in the airways. Consistent with prior reports, there was a significant increase in total cells, macrophages, lymphocytes and neutrophils in BAL fluid from WT-Virus infected mice compared to WT-Saline treated mice (Supplementary Fig. 7a–d). However, we were unable to evaluate immune cells in lungs of infected BMAL1 KO mice due to 100% mortality in this group by day-9 post-infection (see Fig. 2b). Because we observed a significant increase in inflammatory cellular influx into the lung of IAV infected WT mice, we next determined the level of proinflammatory cytokines/chemokines in BAL fluid. WT-Virus infected mice showed a significant increase in release of proinflammatory mediators such as IL-6, MCP-1, IP-10, KC, IL-10, and TNFα when compared to WT-Saline treated mice (Supplementary Fig. 8). The change in the lung proinflammatory mediators in BAL fluid observed at day 9 post-infection was correlated with influx of inflammatory cells in the lung (Supplementary Fig. 7a-d and Supplementary Fig. 8). Thus, our data show correlation of alteration in inflammatory cells in the lung with augmented pro-inflammatory cytokine responses during IAV infection in vivo.

To investigate the role of IAV-induced circadian clock disruption of the lungs and the possible impact on lung airway remodeling and pulmonary function, we examined airspace enlargement/emphysema by lung histopathologic and functional measurements in chronic CS+Virus infected mice. There was a significant difference in lung histopathological changes between chronic CS+Virus infected mice and Air+Virus infected mice 9 days post-infection, which was confirmed with measurements of the mean linear intercept (MLI; Air+Virus 43.27 ± 3.31 vs. CS+Virus 62.27 ± 3.20; P < 0.001; Supplementary Fig. 9b). These data suggest that IAV infection and chronic CS exposure can synergistically enhance airway remodeling in mice.

To investigate the role of the molecular clock in the response to IAV infection, we measured lung compliance, resistance and tissue elastance in WT mice infected with IAV on day 9 post-infection, uninfected BMAL1 heterozygous KO mice and uninfected homozygous BMAL1 KO mice. Lung compliance was significantly decreased in both WT-Virus and BMAL1 KO-Saline treated mice compared to WT-Saline and BMAL1 Het-Saline treated mice (Fig. 6c). However, lung resistance and tissue elastance were significantly increased in both WT-Virus and BMAL1 KO-Saline treated mice (Fig. 6c). BMAL1 KO-Saline treated mice displayed a significant increase in lung compliance and decrease in resistance and elastance when compared to WT-Virus infected mice suggesting an inherent defect in the lung mechanical properties of BMAL1 KO mice in the absence of infection (Fig. 6c). In a separate experiment, we determined lung function at different ZT (ZT0-ZT18; n = 1 mice/ ZT time point) in 2–3 months old BMAL1 KO mice and WT littermates. We also performed differential cell counts in BAL fluid collected from WT and BMAL1 KO mice at all the four ZT time points. We averaged the cell counts data from different time points and found that Bmal1 KO mice had a significant increase in neutrophil counts compared to WT littermates (Supplementary Fig. 10a). Total cell counts and macrophage counts were not significantly different between BMAL1 KO and WT littermates (Supplementary Fig. 10a).

We measured the rhythms of lung mechanical properties in BMAL1 KO and WT littermates at different ZT time points. BMAL1 KO mice showed similar peaks of lung function measurements as air-exposed controls but each was significantly altered (reduced compliance, increased resistance and elastance) compared to WT littermates (Supplementary Fig. 10b). We found that BMAL1 KO mice develop spontaneous pro-fibrotic lung phenotype as they age when compared to WT littermates (Supplementary Fig. 10c). The development of a fibrotic-like phenotype in BMAL1 KO mice could contribute to the altered lung function we observed in these mice (Fig. 6c). Thus, our data suggest that the clock gene activator BMAL1 may play an essential role in maintaining normal pulmonary function. Influenza A virus infection in BMAL1 KO mice further enhance the severity of virus infection resulting in increased morbidity and mortality.

Male C57BL/6J (C57) and BMAL1 knockout (KO: B6.129-Arntl^tm1Bra/J) mice were purchased from the Jackson Laboratory (Bar Harbor, ME). C57BL/6J and BMAL1 KO mice were housed under a 12:12 light-dark (LD) cycle with lights on at 6 a.m. and fed with a regular diet and water ad libitum unless otherwise indicated. For chronic (6 months) CS exposure, mice were kept in a standard 12:12 L:D cycle with lights on from 6 am-6 pm throughout the experiment. Data from animals exposed to air/CS for 6 months from a previous study were included here for comparison³⁰.

Eight week-old mice were used for tobacco/CS exposure as previously described^30,74,75. We used chronic (6 mo. exposure which causes pulmonary emphysema) CS exposure mouse models to determine the effect and mechanism of chronic CS exposure followed by influenza virus infection on circadian clock function and lung inflammation. Mice were exposed to CS using an environmental side-stream delivering Teague TE-10 smoking machine (Teague Enterprises, Davis, CA) for 6 months CS exposure in the Inhalation Facility at the University of Rochester Medical Center. The smoke was generated from 3R4F research cigarettes containing 11.0 mg of total particulate matter (TPM), 9.4 mg of tar and 0.73 mg of nicotine per cigarette (University of Kentucky, Lexington, KY). The total particulate matter (TPM) in per cubic meter of air in exposure chamber was monitored in real-time with a MicroDust Pro-aerosol monitor (Casella CEL, Bedford, UK), and verified daily by gravimetric sampling^30,74,75. Control mice were exposed to filtered air in an identical chamber according to the same protocol described for CS exposure. For chronic 6 months CS exposures, 3R4F cigarettes were used to generate a mixture of sidestream smoke (89%) and mainstream smoke (11%) at a concentration of ~100 mg/m³ TPM, so as to avoid the possible toxicity to mice at a high concentration of long-term CS exposure^30,74 according to the Federal Trade Commission protocol (1 puff/min of 2 second duration and 35 ml volume). Each smoldering cigarette was puffed for 2 seconds, once every minute for a total of 5 puffs, at a flow rate of 1.05 L/min, to provide a standard puff of 35 cm³. Mice received 5-hour exposures per day, 5 days/week for the duration of exposure and were sacrificed at 6-hour intervals 24h after the last CS exposure.

After 6 months chronic Air/CS exposure, mice were intranasally infected under anesthesia (Avertin; 2,2,2-tribromoethanol; Sigma-Aldrich) with 120 hemagglutination units (HAU) of influenza A virus (IAV), strain HKx31 (x31; H3N2) in 25 µl sterile PBS as previously described^32,76. Mock-infected control group mice received 25 µl of sterile PBS alone. After infection, survival and body weight of all the experimental groups were monitored and recorded daily until post-infection day 9. Mice were euthanized post-infection day 9 at 6 hour intervals for 24 hours (5 time points: ZT0, ZT6, ZT12, ZT18 and ZT24). The 6-hr sampling interval was based on prior studies on circadian gene expression in mice^30,37. Schematic for chronic CS exposure combined with IAV infection and IAV infection in BMAL1 KO and wild-type littermates including parameters measured from these experiments are included in the Supporting information (see Supplementary Fig. 1a-b).

Mice were individually housed and allowed free access to food and water. Locomotor activity was measured using the Photobeam Activity System (San Diego Instruments, San Diego, CA), a computerized system that measures the frequency of photobeam breaks along the side of the cage. Total cage activity (photobeam break) activity was recorded in 1-min intervals and analyzed using ClockLab software (Actimetrics, Evanston IL) as previously described³⁰. Circadian periodicity of locomotor activity in L:D was calculated during days 1-8 post IAV infection with a χ² periodogram analysis (tau range 20–28 h).

Adult male Period2::luciferase knock-in (PER2::LUC) mice⁷⁷ were euthanized three hours before lights-off (Zeitgeber Time 9–12, lights off = ZT12) by excess CO₂ exposure. Portions of the lung were removed and collected in cold sterile Hanks balanced salt solution (HBSS). Small 5 mm³ fragments of lung tissue were isolated. Lung tissues were placed in 35mm culture dishes with 1.2 ml of culture medium [DMEM supplemented with B27 (Gibco), 10 mM HEPES, 352.5 μg/ml NaHCO3, 3.5 mg/ml D- glucose, 25 U/ml penicillin, 25 μg/ml streptomycin and 0.1 mM luciferin (Promega)]. Cultures were prepared with clean media as described above (control) or the same media containing cigarette smoke extract (CSE 0.1%), media containing 300 HAU influenza A virus ( and sealed with sterile vacuum grease and a glass coverslip. Sealed cultures were maintained at 35 °C in a light-tight incubator and luminescence was continuously recorded (counts/sec) with an automated luminometer (LumiCycle, Actimetrics). Raw luminescence data were detrended (24 h moving average) and smoothed (2 h moving average; Origin Pro 8.5, OriginLabs, Northampton, MA) as previously described³⁰.

Mice were anesthetized at 24 h after the last exposure or on day 9 post-infection by an intraperitoneal injection with 100 mg/kg (BW) of pentobarbital sodium (Abbott Laboratories, Abbott Park, IL) and sacrificed by exsanguination. The heart and lungs were removed en bloc, and the lungs were lavaged three times with 0.6 ml of saline (0.9% sodium chloride) via a cannula inserted into the trachea as described previously^75,78. The lavaged fluid was centrifuged, and the cell-free supernatants were frozen at −80°C for later analysis. The BAL inflammatory cell pellet was resuspended in 1 ml saline and the total cell number was counted using a hemocytometer. Cytospin slides (Thermo Shandon, Pittsburgh, PA) were prepared using 50,000 cells per slide, and differential cell counts (~500 cells/slide) were performed on cytospin-prepared slides stained with Diff-Quik (Dade Behring, Newark, DE).

The levels of proinflammatory mediators, such as CCL2/monocyte chemotatic protein 1 (MCP-1), CXCL2/macrophage inflammatory protein 2 (MIP-2), interleukin 6 (IL-6) and TGF-β1 in bronchioalveolar lavage fluid were measured by enzyme-linked immunosorbent assay (ELISA) using respective duo-antibody kits (R&D Systems, Minneapolis, MN) according to the manufacturer’s instructions. The results were expressed in the samples as pg/ml.

Fixed tissues were H&E stained for inflammation scoring and mean linear intercept analysis. Histological analysis of H&E stained slides were used to determine bronchial inflammation using a semi-quantitative method. Briefly, the intensity of bronchial inflammation was scored on a scale of 1 to 9. 0, for no inflammation; 1–3 for scant cells but not forming a defined layer; 4–6, for one to three layers of cells surrounding the vessels; 7–9, for four or greater layers of cells surrounding the vessel or bronchial area. For each treatment multiple lung lobes from n = 4-5 slide/group were scored and average values were presented as bronchial inflammation scores.

Similarly airway mucus was identified by the Periodic Acid-Schiff (PAS) staining (Sigma-Aldrich, St. Louis, MO) and PAS positive cells were quantified by a semi-quantitative method with slight modification as previously described⁶¹. In brief, airways were examined under light microscopy and assigned a score between 0 and 3 based on the following criteria: 0, for no staining; 1, for PAS staining <25% of airway perimeter; 2, for PAS staining 25 to <50% of airway perimeter; and 3, for PAS staining >50% of airway perimeter. Mucus scores were obtained by scoring 3–4 different areas per slide from n = 4-5 slide/group. The average from all the areas scored per each treatment group was used to calculate the percentage of PAS positive cells.

Immunostaining was performed on formalin-fixed, paraffin-embedded lung tissue. Paraffin sections (4 µm thick) were deparaffinized and then rehydrated through series of xylene and graded ethanol. Antigen retrieval was performed by heating in citrate buffer (10 mM Citric acid, 0.05% Tween 20, pH 6.0). Primary antibody was incubated overnight at 4°C with rabbit anti-CCSP polyclonal antibody (Seven Hills Bioreagents, Cincinnati, OH) and mouse anti α-smooth muscle actin (Abcam, Cambridge, MA) antibodies^32,74,76,79. Appropriate fluorescently labeled secondary antibodies (FITC- or Texas red-conjugated 2° antibodies) were used to detect the immune complexes before tissues sections were counterstained with 4’,d-diamidino-2-phenylindole (dapi).

Gomori’s trichrome staining was performed according to the manufacturer’s instructions (Richard-Allan Scientific, Kalamazoo, MI). The nuclei stains black, cytoplasm and muscle fibers in red and the collagen deposition stains blue. Both double immunostaining and trichrome stained tissue sections were visualized with Nikon Eclipse Ni-U fluorescence microscope (Nikon, Melville, NY) and images were captured with a SPOT-RT3 digital camera (Diagnostic Instruments, Sterling Heights, MI). Quantification of fibrosis was done using the Ashcroft scoring system⁸⁰.

Mouse lungs (which had not been lavaged) were inflated by 1% low-melting point agarose at a pressure of 25 cm H₂O, and then fixed with 4% neutral buffered formalin^74,75. Fixed lung tissues were dehydrated, embedded in paraffin and sectioned (4 μm) using a rotary microtome (MICROM International GmbH). Lung sections were deparaffinized and rehydrated by passing through a series of xylene and graded ethanol, then stained with hematoxylin and eosin (H&E). Alveolar size was estimated from the mean linear intercept (Lm) of the airspace, which is a measure of airspace enlargement/emphysema using the MetaMorph software (Molecular Devices) as previously described^30,74,75. Lm was calculated for each sample based on 10 random fields per slide observed at a magnification of ×200. The airway and vascular structures were eliminated from the analysis.

Lung mechanical properties in mouse lung were determined using Scireq Flexivent apparatus (Montreal, Canada) as described previously^30,74,75. Briefly, lung compliance (C), lung resistance (R), and tissue elastance (E) were measured in mice, anesthetized by sodium pentobarbital (50 mg/kg BW, intraperitoneally). A tracheotomy was performed, and an 18-gauge cannula was inserted 3 mm into an anterior nick in the exposed trachea and connected to a computer controlled rodent ventilator (FlexiVent; SCIREQ). Initially, the mice were ventilated with room air (150 breaths/min) at a volume of 10 ml/kg body mass. After 3 min of ventilation, measurement of lung mechanical properties was initiated by a computer-generated program to measure quasi-static compliance, lung resistance, and tissue elastance at 3 cm H₂O positive end expiratory pressure obtained by fitting a model to each impedance spectrum. The calibration procedure removed the impedance of the equipment and tracheal tube within this system⁸¹. These measurements were repeated three times for each animal using Scireq FlexiVent apparatus (Montreal, Canada) as described previously^30,74,75,79.

Total RNA was isolated from non-lavaged lung tissue specimens (stored in RNAlater, Ambion, Austin, TX) using RNeasy kit (Qiagen, Valencia, CA). RNA yields were determined by UV absorbance using a Nanodrop instrument (ND-1000 Spectrophotometer, NanoDrop Technologies). cDNA was synthesized from 0.5 μg of total RNA using the RT² First Strand Kit (SABioscience, Frederick, MD). To validate the expression of diverse genes in lung tissue by quantitative real-time PCR (qPCR) (Bio-Rad CXF-96 real-time system) using the SYBR Green qPCR Master mix from SABioscience. In chronic Air/CS exposed mice infected with or without influenza A virus, this includes qPCR data from circadian genes at ZT0-ZT24 time point (n = 3-4 mice/group) in all datasets. All the specific primers were purchased from SABioscience. Expression of genes was normalized to RPL13 (60S ribosomal protein L13 gene) levels. The samples from chronic air- and CS-exposed mice represented in this study were obtained from our previous study that was conducted in parallel with the chronic air and CS combined with influenza A virus infection³⁰. In chronic air exposure group, qPCR data gathered from circadian gene expression at the ZT24 time point (n = 2/air group) in all qPCR datasets. Relative RNA abundance was quantified by the comparative 2^-ΔΔCt methods. Significant rhythms of gene expression were verified using CircWave software (Version 1.4). In addition, the center of gravity (COG) or peak phase was determined for each rhythm using CircWave as previously described^30,82.

The period of PER2::LUC expression in each tissue explant was determined using a chi-squared periodogram analysis (LumiCycle Analysis Software, Actimetrics). A minimum of 5 days of data were used to calculate the period of PER2::LUC expression in each explant of lung tissue. Period data from lung tissue were analyzed with two-factor ANOVA. Data are representative of mean ± SEM. For statistical analysis of qPCR data, CircWave software (Version 1.4) was employed. In addition to multiple non-linear regression analyses to determine if the data conform to a significant rhythm, CircWave also calculates the peak of gene expression or Center of Gravity (COG). The software determines a peak of gene expression even if the qPCR data do not conform to a significant circadian rhythm (P < 0.05). In addition to CircWave analysis, statistical significance between air-exposed, Air+Virus and CS+Virus groups was calculated by Fisher’s multiple comparisons using two-way ANOVA. To emphasize the waveform of the data, percentage of daily activity (light and dark phase) was subjected to nonlinear regression analysis with a 6^th order polynomial using GraphPad (Prism 6). Statistical analysis of significance was calculated using one-way Analysis of Variance (ANOVA) followed by Tukey’s post-hoc test for multi-group comparisons using StatView software. Mortality was evaluated by comparison of survival curves and analyzed for significance by Log-rank (Mantel-Cox) test using GraphPad (Prism 6). P < 0.05 was considered as significant.

Supplementary Information Supplementary Information - Suppl. Figs 1-10 and Suppl. Tables 1-3 (PDF 2825 kb)