Downregulation of RORα by alcohol promotes TGFβ and α-SMA expression in mouse lung fibroblasts

The circadian signaling pathway plays a pivotal role in regulating various physiological processes in the human body, including sleep–wake cycles, hormone secretion, and cellular repair mechanisms (1). This intrinsic time-keeping system is governed by a set of core clock genes that generate rhythmic oscillations over a 24-h period (2). In the lung, the circadian clock has been implicated in modulating immune responses and tissue repair, particularly following acute lung injury (ALI) (3). Dysregulation of circadian signaling can lead to impaired lung repair mechanisms, exacerbating inflammatory responses, and contributing to the development of chronic lung diseases (4–6). Studies have shown that disruptions in circadian signaling can alter the timing of cell proliferation, cytokine release, and the activation of repair pathways, all of which are crucial for effective lung recovery post-injury (6).

The circadian signaling pathway is governed by two core transcription factors, BMAL1 and CLOCK, which regulate rhythmic expression of downstream clock genes such as PER, CRY, ROR, and REV-ERB, initiating a cascade of transcriptional events (7). Emerging evidence suggests a complex interplay between circadian rhythms and ethanol exposure, indicating that ethanol may influence tissue injury and repair by disrupting molecular clocks (8). Ethanol impairs circadian regulation by altering clock gene expression and disturbing both central and peripheral clock function (9). This misalignment promotes oxidative stress, inflammation, and immune dysregulation, compromising lung tissue integrity and repair (8). Chronic ethanol consumption is associated with increased prevalence and mortality from acute respiratory distress syndrome (ARDS) (10). Although direct evidence linking alcohol consumption to pulmonary fibrosis is lacking, our rodent model demonstrates that chronic ethanol ingestion leads to fibroproliferative maladaptive repair following acute lung injury. We further show that ethanol exposure, in vivo and in vitro, upregulates transforming growth factor-β (TGFβ) in epithelial cells and lung fibroblasts, promoting fibroblast-to-myofibroblast differentiation (11–13). Ethanol also disrupts epithelial barrier integrity and extracellular matrix homeostasis, resulting in persistent collagen deposition and impaired resolution of inflammation (14–16). Mechanistically, ethanol-induced oxidative stress and altered immune signaling, including dysregulated innate lymphoid cell activity, create an environment favoring pathological tissue remodeling and fibrosis (13, 17, 18). Despite these observations, no studies have directly examined how ethanol-induced circadian disruption in the lung contributes to injury and impaired repair.

The retinoid acid-related orphan receptor (ROR) family consists of three members of the nuclear receptors; RORα, β, and γ, that function as transcription factors and play important roles in maintaining circadian rhythm, regulating oxidative stress responses, and supporting tissue repair (19). While RORβ is primarily confined to the central nervous system and RORγ to immune cells, RORα is widely expressed across multiple tissues, including the lung, and plays a central role in regulating circadian gene expression. It also influences lipid metabolism, inflammation, and oxidative stress in peripheral tissues (7, 20). ROR and REV-ERB compete for binding to the ROR response element (RORE) to regulate BMAL1 expression, thereby stabilizing the core circadian clock and downstream physiological functions (21). Previous studies have demonstrated that RORα is critical for various physiological processes, including cell differentiation and inflammatory regulation (1). For example, overexpression of RORα suppresses epithelial-to-mesenchymal transition in a breast cancer model (21, 22). However, little is known about the expression and function of ROR family members in ethanol-induced lung diseases.

In this study, we examined how ethanol-induced circadian disruption dysregulates RORα, promoting lung fibroblast’s profibrotic phenotype with upregulation of TGFβ and α-SMA expression. We speculated that disruption of the circadian signaling pathway may underlie the exaggerated fibroproliferative response following acute lung injury in ethanol-exposed experimental model and that targeting circadian signaling could provide therapeutic strategies to improve lung repair.

In this study, we demonstrate that chronic ethanol ingestion disrupts circadian rhythmicity in the lung and alters the temporal regulation of profibrotic markers, including TGFβ, α-SMA, and fibronectin. Ethanol consistently suppresses both the transcription and translation of BMAL1 (aryl hydrocarbon receptor nuclear translocator-like 1, ARNTL1), a core circadian transcription factor, as well as downstream components of the BMAL1-CLOCK network such as PER1, PER2, and RORα in lung fibroblasts. Given that RORα functions as a nuclear receptor that reinforces BMAL1 expression through a positive transcriptional feedback loop, we further examined its contribution to ethanol-induced profibrotic signaling. Pharmacologic inhibition of RORα increased TGFβ expression without affecting α-SMA or fibronectin, whereas RORα silencing elevated both TGFβ and α-SMA. Conversely, activation of RORα with the agonist SR1078 attenuated ethanol-induced increases in TGFβ and α-SMA. Together, these findings identify RORα as a key regulator of ethanol-driven profibrotic responses and provide, to our knowledge, the first evidence that chronic ethanol exposure disrupts circadian signaling pathways within the lung.

Chronic ethanol ingestion is a known risk factor for developing acute respiratory distress syndrome (ARDS) in clinical settings (10). In our experimental model, we demonstrated that ethanol promotes fibroblast-to-myofibroblast differentiation (FMD), contributing to fibroproliferative maladaptive repair through exaggerated TGFβ expression in the lung (24). Additionally, we showed that oxidative stress is an early event following ethanol exposure, initiating a feedforward loop that amplifies TGFβ induction and activation (34). Both ethanol and oxidative stress are known disruptors of circadian signaling in the brain and peripheral tissues (7). Lastly, Finger et al. (35) reported that TGFβ plays a critical role in maintaining peripheral clock synchronization among cells. Accordingly, we speculated that ethanol exposure may disrupt circadian signaling in the lung. Our data confirmed that chronic ethanol ingestion disrupts lung circadian oscillation as shown by a shift in lung’s PER2 luciferase activity in comparison to control lungs. However, the precise mechanism by which ethanol disrupts lung circadian signaling is unknown.

More than half of protein-coding genes exhibit circadian oscillation, with distinct patterns across various tissues (7). As discussed above, TGFβ and circadian signaling share a complex, bidirectional relationship (35). In this study, Tgfβ transcription exhibited a clear diurnal oscillation in control animals; however, this rhythmicity was absent in the lungs of ethanol-fed animals, which instead showed persistently elevated Tgfβ levels throughout the 24-h cycle. In contrast to Tgfβ, ethanol induced rhythmic expression of representative profibrotic markers; specifically, α-sma, and fibronectin, whereas control lungs displayed non-rhythmic and consistently suppressed expression of these genes. Further, there is also a shift in protein peaks from their corresponding mRNA rhythm supporting the idea that circadian dysregulation contributes to aberrant extracellular matrix remodeling. Whether a regulatory factor in control animals inhibits TGFβ-driven transcription of α-SMA, and fibronectin, or whether persistently elevated TGFβ in ethanol-fed animals drives altered activation of these profibrotic markers remains to be determined. These findings suggest that TGFβ oscillation plays a critical role in maintaining tissue homeostasis under normal conditions, and that disruption of this rhythmic pattern or sustained elevation of TGFβ may contribute to maladaptive tissue repair. We speculate that persistent elevation of TGFβ in ethanol-fed animals may override normal inhibitory mechanisms, promoting fibrosis through altered circadian regulation.

The circadian pathway operates through transcriptional-translational feedback loops (7). The CLOCK-BMAL1 complex activates PER and CRY, whose dimers inhibit CLOCK-BMAL1, forming a negative loop (36). ROR (α, β, γ) and REV-ERB (α, β) modulate BMAL1 by competing for ROR elements; ROR promotes, whereas REV-ERB represses its expression (36). Our next question was: how does ethanol disrupt lung circadian rhythm? Ethanol consumption has been shown to alter the expression of core circadian genes, including BMAL1, Cry1/2, and Per1/2, in immune cells, liver, and skeletal muscle, leading to desynchronization between central and peripheral clocks (37–39). Consistent with these reports, we found that chronic ethanol ingestion alters both the expression and oscillatory patterns of core circadian genes, including Bmal1, Clock, Rorα, and Rev-erbα. These findings provide a dynamic view of circadian signaling molecules in the lungs of ethanol-fed animals. To fully characterize how these transcriptional changes translate into functional alterations of the circadian clock, we next examined whether ethanol-induced disruptions in gene expression were reflected at the protein level. In the present study, chronic ethanol ingestion disrupted both the transcriptional and translational rhythms of key circadian signaling regulators, including BMAL1, CLOCK, RORα, and REV-ERBα. Notably, the frequent misalignment between mRNA and protein abundance; such as BMAL1 suppression at the transcript level during early and late phases but reduced protein only at ZT12, or the broad upregulation of CLOCK mRNA contrasted with a protein increase restricted to ZT0, suggests that ethanol alters not only gene expression but also post-transcriptional and post-translational regulatory mechanisms. Together, these findings support a model in which ethanol-induced circadian disruption contributes to maladaptive tissue remodeling and may predispose the lung to enhanced fibrotic susceptibility.

Because the lung comprises multiple cell types; and given the critical role of fibroblasts in tissue repair, along with our previous evidence that ethanol promotes a pro-fibrotic phenotype in these cells, we focused our analysis on lung fibroblasts (11, 34). We first compared the synchronized condition with an unsynchronized condition to assess whether the effect of ethanol is intrinsic or dependent on external timing cues. We found that ethanol suppresses BMAL1 gene and protein expression in both synchronized and unsynchronized conditions, while upregulating CLOCK gene transcription only in synchronized cells, without a corresponding increase in CLOCK protein levels. This pattern suggests that CLOCK upregulation may represent a compensatory response to disruption of the core circadian machinery, with BMAL1 serving as a primary and more ethanol-sensitive target. Ethanol also produced opposing effects on Rev-erbα expression; downregulating it in synchronized cells but upregulating it in unsynchronized cells, suggesting that REV-ERBα regulation is highly phase-dependent and that ethanol interacts differently with the clock network depending on cellular circadian alignment. Together, these findings indicate that while BMAL1 and RORα are consistently suppressed regardless of synchronization state, CLOCK and REV-ERBα exhibit phase-specific or low-amplitude rhythms that make their responses detectable only under synchronized conditions, highlighting differential sensitivity of circadian components to ethanol. The discrepancy between mRNA and protein levels of CLOCK and REV-ERBα may result from post-transcriptional regulatory mechanisms, such as epigenetic mechanism (i.e., micro-RNA) or environmental influences (e.g., high-fat diet, LPS, UV exposure). Specifically, ethanol has been shown to induce epigenetic changes, and future studies aimed at further dissecting this regulatory mechanism are warranted. Although our current work focuses on the role of RORα, it is important to note that REV-ERBα may also play a critical role in this model. Previous studies have demonstrated its involvement in pulmonary fibrosis pathogenesis: mutations in Rev-erbα exacerbate bleomycin-induced fibrosis whereas activation of REV-ERBα inhibits TGFβ-induced fibroblast-to-myofibroblast transition (FMT) and reduces extracellular matrix (ECM) production. Accordingly, future studies assessing the impact of RORα and REV-ERBα imbalance on ethanol-mediated BMAL1 may provide deeper insight into the mechanisms driving ethanol-induced alterations in lung molecular phenotype.

Our study provides new evidence that chronic ethanol ingestion disrupts lung circadian signaling, which may contribute to maladaptive tissue repair. Chronic ethanol exposure has previously been linked to fibroproliferative repair following acute lung injury in murine models, mediated by ethanol-induced fibroblast-to-myofibroblast differentiation (9, 22). In this study, we found that chronic alcohol ingestion significantly suppressed the expression of Bmal1 and Rorα. BMAL1, a core circadian clock component, regulates numerous downstream genes, so its modulation can broadly influence multiple physiological systems. RORα, a transcriptional activator of BMAL1, also impacts development, metabolism, and inflammation. However, as a downstream regulator of BMAL1, RORα represents a more specific and potentially therapeutic target; therefore, we prioritized investigating RORα in our experimental model. Our data reveal an inverse relationship between RORα activation and the expression of TGFβ and α-SMA under ethanol stimulation, suggesting that RORα may play a protective role against ethanol-induced profibrotic signaling. Notably, activation of RORα with SR1078 significantly suppressed TGFβ and α-SMA, whereas inhibition of RORα using an inverse agonist or siRNA did not fully replicate the profibrotic effects of ethanol. This discrepancy may indicate that ethanol-induced circadian disruption involves multiple regulatory molecules beyond RORα, including non-coding RNAs, which collectively modulate fibroblast activation. Additionally, ethanol may exert a dominant suppressive effect on BMAL1 and its downstream targets, creating a broader transcriptional imbalance that cannot be mimicked by RORα inhibition alone. Although ethanol-driven suppression of BMAL1 appears to be an early event leading to downstream effects, RORα activation can attenuate ethanol-induced profibrotic phenotypes in lung fibroblasts. Future studies are warranted to elucidate the mechanisms underlying ethanol-mediated circadian disruption. Overall, these findings underscore the complexity of circadian regulation in lung fibroblasts and suggest that targeting RORα activation, rather than inhibition, may offer therapeutic potential for mitigating ethanol-induced fibrotic remodeling.

This study has several limitations. First, we examined only a single ethanol concentration to maintain consistency with previous reports; future studies should evaluate a range of doses in vivo and ex vivo to better define dose-dependent effects. Second, we analyzed a limited set of circadian and profibrotic molecules; expanding this panel will provide a more comprehensive view of ethanol-induced signaling changes in lung cells. Third, the causal relationship between BMAL1 and RORα remains unclear. Whether ethanol-induced alterations in BMAL1 drive RORα downregulation or vice versa is unknown. Either molecule could initiate a cycle of negative regulation, creating a feedback loop. Because BMAL1 is upstream of multiple transcription factors, its manipulation may have broad off-target effects; therefore, we focused on RORα as a more specific downstream target. Fourth, our in vitro studies did not include comparisons between synchronized and unsynchronized conditions with temporal sampling across the 24-h cycle, limiting our ability to fully characterize dynamic circadian responses. Future studies will incorporate higher-resolution time-series analyses to capture these oscillatory patterns. Finally, based on the in vitro data presented here, future in vivo studies using RORα agonists or RNA silencing will be essential to confirm the effects of pharmacological modulation and determine its role in disease-relevant models, thereby assessing translational potential.

In conclusion, our findings provide new evidence that chronic ethanol ingestion disrupts lung circadian signaling, likely through initial suppression of BMAL1, which in turn downregulates downstream genes such as RORα. This disruption of circadian signaling appears to contribute to altered rhythmicity of profibrotic markers (TGFβ, α-SMA, Fn1), leading to maladaptive tissue repair. Importantly, activation of RORα mitigates ethanol-induced expression of profibrotic markers, including TGFβ and α-SMA, in primary lung fibroblasts. These results suggest a potential avenue for developing preventive or therapeutic strategies to enhance tissue repair and recovery following injury in this at-risk population.

The author(s) declared that financial support was received for this work and/or its publication. This work was supported by the National Institutes of Health (grant numbers R01 AA029690‑01A1 (VS, XF, and HT), R01 HL133053‑01A1 (B-YK), SC1 GM135112-01A1 (KB and ND), R21 EY031821-01A1 (GT), and NIAAA R01-AA026086 (SY). The contents of this report do not represent the views of the Department of Veterans Affairs or the US Government.

The raw data supporting the conclusions of this article will be made available by the authors, without undue reservation.

The animal study was approved by Emory Institutional Animal Use Committee. The study was conducted in accordance with the local legislation and institutional requirements.

XF: Supervision, Data curation, Investigation, Writing – review & editing, Writing – original draft. HT: Investigation, Writing – review & editing. B-YK: Writing – review & editing. ND: Writing – review & editing, Investigation. KB: Investigation, Writing – review & editing. GT: Writing – review & editing. JG: Writing – review & editing, Investigation. SY: Writing – review & editing. VS: Investigation, Supervision, Writing – review & editing, Funding acquisition, Writing – original draft, Conceptualization.

The author(s) declared that this work was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

The author(s) declared that Generative AI was used in the creation of this manuscript. Declaration of Generative AI and AI-assisted technologies in the writing process' Statement: During the preparation of this work the author(s) used Microsoft copilot for grammar and syntax corrections in order to improve language. After using this tool/service, the author(s) reviewed and edited the content as needed and take(s) full responsibility for the content of the publication.

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The Supplementary material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fmed.2026.1719787/full#supplementary-material↗