Retinoic acid signaling is essential for airway smooth muscle homeostasis
Felicia Chen, Fengzhi Shao, Anne Hinds, Sean Yao, Sumati Ram-Mohan, Timothy A. Norman, Ramaswamy Krishnan, Alan Fine
Felicia Chen, Fengzhi Shao, Anne Hinds, Sean Yao, Sumati Ram-Mohan, Timothy A. Norman, Ramaswamy Krishnan, Alan Fine
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Research Article Pulmonology

Retinoic acid signaling is essential for airway smooth muscle homeostasis

Abstract

Airway smooth muscle (ASM) is a dynamic and complex tissue involved in regulation of bronchomotor tone, but the molecular events essential for the maintenance of ASM homeostasis are not well understood. Observational and genome-wide association studies in humans have linked airway function to the nutritional status of vitamin A and its bioactive metabolite retinoic acid (RA). Here, we provide evidence that ongoing RA signaling is critical for the regulation of adult ASM phenotype. By using dietary, pharmacologic, and genetic models in mice and humans, we show that (a) RA signaling is active in adult ASM in the normal lung, (b) RA-deficient ASM cells are hypertrophic, hypercontractile, profibrotic, but not hyperproliferative, (c) TGF-β signaling, known to cause ASM hypertrophy and airway fibrosis in human obstructive lung diseases, is hyperactivated in RA-deficient ASM, (d) pharmacologic and genetic inhibition of the TGF-β activity in ASM prevents the development of the aberrant phenotype induced by RA deficiency, and (e) the consequences of transient RA deficiency in ASM are long-lasting. These results indicate that RA signaling actively maintains adult ASM homeostasis, and disruption of RA signaling leads to aberrant ASM phenotypes similar to those seen in human chronic airway diseases such as asthma.

Authors

Felicia Chen, Fengzhi Shao, Anne Hinds, Sean Yao, Sumati Ram-Mohan, Timothy A. Norman, Ramaswamy Krishnan, Alan Fine

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Figure 1

Disruption of RA signaling in vivo for 5 days results in airway hyperresponsiveness and airway remodeling.

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Disruption of RA signaling in vivo for 5 days results in airway hyperres...
(A) RA activity is downregulated in RA-deficient lung as evidenced by the reduction of lacZ expression in VAD (compared with VAS) and BMS (compared with CTR) in RARE-lacZ lungs (n = 6 per group). (B and C) Airway resistance (Res) is higher in the VAD (B) and BMS (C) mice compared with VAS (B) and CTR (C) mice when challenged with increasing doses of the bronchoconstrictor methacholine (MeCh), indicating higher airway responsiveness in RA-deficient animals (n = 9 per group). (DG) Plastic sections of mouse lungs showing thicker ASM layer (delineated by yellow dotted lines) in VAD (E) and BMS (G) airways compared with VAS (D) and CTR (F) airways (n = 3 per group). Epi labels the airway epithelial layer. (H and I) Immunostaining of smooth muscle–specific marker α-SMA showing an increase in ASM mass in BMS (I) airway compared with the CTR (H) airway (n = 3 per group). (J and K) Trichrome staining revealing increased collagen content (stained blue) in the BMS (K) airway compared to CTR (J) airway (n = 3 per group). Data represent the mean ± SEM (A) or mean ± range (B and C). Statistical significance was calculated using Student’s t test (A) and 2-way ANOVA (B and C). *P < 0.05. Scale bars: 10 μm (D, H, and J).