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Circadian clock component REV-ERBα controls homeostatic regulation of pulmonary inflammation
Marie Pariollaud, Julie E. Gibbs, Thomas W. Hopwood, Sheila Brown, Nicola Begley, Ryan Vonslow, Toryn Poolman, Baoqiang Guo, Ben Saer, D. Heulyn Jones, James P. Tellam, Stefano Bresciani, Nicholas C.O. Tomkinson, Justyna Wojno-Picon, Anthony W.J. Cooper, Dion A. Daniels, Ryan P. Trump, Daniel Grant, William Zuercher, Timothy M. Willson, Andrew S. MacDonald, Brian Bolognese, Patricia L. Podolin, Yolanda Sanchez, Andrew S.I. Loudon, David W. Ray
Marie Pariollaud, Julie E. Gibbs, Thomas W. Hopwood, Sheila Brown, Nicola Begley, Ryan Vonslow, Toryn Poolman, Baoqiang Guo, Ben Saer, D. Heulyn Jones, James P. Tellam, Stefano Bresciani, Nicholas C.O. Tomkinson, Justyna Wojno-Picon, Anthony W.J. Cooper, Dion A. Daniels, Ryan P. Trump, Daniel Grant, William Zuercher, Timothy M. Willson, Andrew S. MacDonald, Brian Bolognese, Patricia L. Podolin, Yolanda Sanchez, Andrew S.I. Loudon, David W. Ray
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Research Article Inflammation Pulmonology

Circadian clock component REV-ERBα controls homeostatic regulation of pulmonary inflammation

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Abstract

Recent studies reveal that airway epithelial cells are critical pulmonary circadian pacemaker cells, mediating rhythmic inflammatory responses. Using mouse models, we now identify the rhythmic circadian repressor REV-ERBα as essential to the mechanism coupling the pulmonary clock to innate immunity, involving both myeloid and bronchial epithelial cells in temporal gating and determining amplitude of response to inhaled endotoxin. Dual mutation of REV-ERBα and its paralog REV-ERBβ in bronchial epithelia further augmented inflammatory responses and chemokine activation, but also initiated a basal inflammatory state, revealing a critical homeostatic role for REV-ERB proteins in the suppression of the endogenous proinflammatory mechanism in unchallenged cells. However, REV-ERBα plays the dominant role, as deletion of REV-ERBβ alone had no impact on inflammatory responses. In turn, inflammatory challenges cause striking changes in stability and degradation of REV-ERBα protein, driven by SUMOylation and ubiquitination. We developed a novel selective oxazole-based inverse agonist of REV-ERB, which protects REV-ERBα protein from degradation, and used this to reveal how proinflammatory cytokines trigger rapid degradation of REV-ERBα in the elaboration of an inflammatory response. Thus, dynamic changes in stability of REV-ERBα protein couple the core clock to innate immunity.

Authors

Marie Pariollaud, Julie E. Gibbs, Thomas W. Hopwood, Sheila Brown, Nicola Begley, Ryan Vonslow, Toryn Poolman, Baoqiang Guo, Ben Saer, D. Heulyn Jones, James P. Tellam, Stefano Bresciani, Nicholas C.O. Tomkinson, Justyna Wojno-Picon, Anthony W.J. Cooper, Dion A. Daniels, Ryan P. Trump, Daniel Grant, William Zuercher, Timothy M. Willson, Andrew S. MacDonald, Brian Bolognese, Patricia L. Podolin, Yolanda Sanchez, Andrew S.I. Loudon, David W. Ray

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Figure 1

REV-ERBα plays a critical role in regulation of lung inflammation.

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REV-ERBα plays a critical role in regulation of lung inflammation.
(A) W...
(A) Whole-lung REV-ERBα protein across the day (ZT, time from lights on). REV-ERBα densitometry (mean ± SEM) was normalized to β-actin and to WT at ZT0; n = 5 for WT and n = 3 for Rev-Erbα–/– per time point. (B) Mice were exposed to aerosolized LPS at ZT4 and culled 5 hours later; cellular infiltrates were quantified in BAL using flow cytometry. Data presented as mean ± SEM; n = 6–8, ***P < 0.001 (2-way ANOVA, post hoc Bonferroni). Veh, vehicle. (C) H&E staining and immunohistochemistry for the neutrophil maker (NIMP/R14) of lung sections from mice after LPS challenge at 2 mg/ml. Representative of n = 4; scale bars: 50 μm. (D) Cytokine/chemokine levels in BAL fluid from mice exposed to aerosolized LPS (2 mg/ml). Representative of n = 8, Student’s t test with Welch’s correction. (E) Quantitative PCR (qPCR) analysis of cytokine transcripts in alveolar macrophages isolated from mice and stimulated ex vivo with LPS at 100 ng/ml for 2 hours. Data normalized to WT and presented as mean ± SEM; n = 3, *P < 0.05, **P < 0.01, ***P < 0.001 (Student’s t test). FC, fold change. (F) Ten-day cigarette smoke exposures were performed between ZT8 and ZT10, and animals were culled 20 hours after the last exposure. Cellular infiltrates were quantified in BAL using a hemocytometer for total cell number and cytospin for neutrophil and macrophage counts. Data presented as mean ± SEM; n = 6–10, *P < 0.05, ***P < 0.001 (2-way ANOVA, post hoc Bonferroni). (G) Chemokine levels in BAL fluid after 10-day cigarette smoke exposures. Data presented as mean ± SEM; n = 6–10, **P < 0.01 (2-way ANOVA, post hoc Bonferroni).

Copyright © 2026 American Society for Clinical Investigation
ISSN: 0021-9738 (print), 1558-8238 (online)

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