Epithelial miR-206 targets CD39/extracellular ATP to upregulate airway IL-25 and TSLP in type 2–high asthma
Kan Zhang, Yuchen Feng, Yuxia Liang, Wenliang Wu, Chenli Chang, Dian Chen, Shengchong Chen, Jiali Gao, Gongqi Chen, Lingling Yi, Dan Cheng, Guohua Zhen
Kan Zhang, Yuchen Feng, Yuxia Liang, Wenliang Wu, Chenli Chang, Dian Chen, Shengchong Chen, Jiali Gao, Gongqi Chen, Lingling Yi, Dan Cheng, Guohua Zhen
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Research Article Pulmonology

Epithelial miR-206 targets CD39/extracellular ATP to upregulate airway IL-25 and TSLP in type 2–high asthma

Abstract

The epithelial cell–derived cytokines IL-25, IL-33, and thymic stromal lymphopoietin (TSLP) initiate type 2 inflammation in allergic diseases, including asthma. However, the signaling pathway regulating these cytokines expression remains elusive. Since microRNAs are pivotal regulators of gene expression, we profiled microRNA expression in bronchial epithelial brushings from type 2–low and type 2–high asthma patients. miR-206 was the most highly expressed epithelial microRNA in type 2–high asthma relative to type 2–low asthma but was downregulated in both subsets compared with healthy controls. CD39, an ectonucleotidase degrading ATP, was a target of miR-206 and upregulated in asthma. Allergen-induced acute extracellular ATP accumulation led to miR-206 downregulation and CD39 upregulation in human bronchial epithelial cells, forming a feedback loop to eliminate excessive ATP. Airway ATP levels were markedly elevated and strongly correlated with IL-25 and TSLP expression in asthma patients. Intriguingly, airway miR-206 antagonism increased Cd39 expression; reduced ATP accumulation; suppressed IL-25, IL-33, and Tslp expression and group 2 innate lymphoid cell expansion; and alleviated type 2 inflammation in a mouse model of allergic airway inflammation. In contrast, airway miR-206 overexpression had opposite effects. Overall, epithelial miR-206 upregulates airway IL-25 and TSLP expression by targeting the CD39–extracellular ATP axis, which represents a potentially novel therapeutic target in type 2–high asthma.

Authors

Kan Zhang, Yuchen Feng, Yuxia Liang, Wenliang Wu, Chenli Chang, Dian Chen, Shengchong Chen, Jiali Gao, Gongqi Chen, Lingling Yi, Dan Cheng, Guohua Zhen

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Figure 2

Acute extracellular ATP accumulation is responsible for allergen-induced miR-206 downregulation and CD39 upregulation in bronchial epithelial cells.

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Acute extracellular ATP accumulation is responsible for allergen-induced...
(A) ATP levels in BALF from healthy control (n = 26), type 2–low (n = 20), and type 2–high asthma patients (n = 37) were determined by luciferase bioluminescence. Data are expressed as median values withIQRs. The lines within the boxes represent medians, and the bounds of the boxes represent IQRs. The whiskers are plotted using Tukey method. One-way ANOVA with Bonferroni’s post hoc test was performed. (B) ATP concentration in culture medium collected at indicated time points after HDM stimulation was measured using luciferase bioluminescence. (C and D) Transcript levels of miR-206 (C) and CD39 (D) in HBE cells harvested at the indicated time points after HDM stimulation were determined by qPCR. n = 4 wells per time point combined from 2 experiments using HBE cells from 2 healthy donors. The data are represented as mean ± SD. *P < 0.05; **P < 0.01; ***P < 0.001 (1-way ANOVA with Bonferroni’s post hoc test). (E and F) miR-206 transcript levels in HBE cells pretreated with apyrase or saline for 2 hours before addition of HDM and stimulation for 6 hours (E), and treated with ATPγS or saline with or without HDM for 6 hours (F). (G and H) CD39 transcript levels in HBE cells pretreated with apyrase or saline for 2 hours before addition HDM and stimulation for 6 hours (G), and treated with ATPγS or saline with or without HDM for 6 hours (H). The transcript levels are relative to the mean value of control group and log2 transformed. n = 4 wells per group combined from 2 experiments using HBE cells from 2 healthy donors. The data are represented as mean ± SD. *P < 0.05; **P < 0.01; ***P < 0.001 (1-way ANOVA with Bonferroni’s post hoc test).