Airway epithelial homeostasis and planar cell polarity signaling depend on multiciliated cell differentiation
Eszter K. Vladar, Jayakar V. Nayak, Carlos E. Milla, Jeffrey D. Axelrod
Eszter K. Vladar, Jayakar V. Nayak, Carlos E. Milla, Jeffrey D. Axelrod
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Research Article Cell biology Pulmonology

Airway epithelial homeostasis and planar cell polarity signaling depend on multiciliated cell differentiation

Abstract

Motile airway cilia that propel contaminants out of the lung are oriented in a common direction by planar cell polarity (PCP) signaling, which localizes PCP protein complexes to opposite cell sides throughout the epithelium to orient cytoskeletal remodeling. In airway epithelia, PCP is determined in a 2-phase process. First, cell-cell communication via PCP complexes polarizes all cells with respect to the proximal-distal tissue axis. Second, during ciliogenesis, multiciliated cells (MCCs) undergo cytoskeletal remodeling to orient their cilia in the proximal direction. The second phase not only directs cilium polarization, but also consolidates polarization across the epithelium. Here, we demonstrate that in airway epithelia, PCP depends on MCC differentiation. PCP mutant epithelia have misaligned cilia, and also display defective barrier function and regeneration, indicating that PCP regulates multiple aspects of airway epithelial homeostasis. In humans, MCCs are often sparse in chronic inflammatory diseases, and these airways exhibit PCP dysfunction. The presence of insufficient MCCs impairs mucociliary clearance in part by disrupting PCP-driven polarization of the epithelium. Consistent with defective PCP, barrier function and regeneration are also disrupted. Pharmacological stimulation of MCC differentiation restores PCP and reverses these defects, suggesting its potential for broad therapeutic benefit in chronic inflammatory disease.

Authors

Eszter K. Vladar, Jayakar V. Nayak, Carlos E. Milla, Jeffrey D. Axelrod

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Figure 7

Notch inhibition restores planar cell polarity and improves epithelial function in cystic fibrosis (CF) human nasal epithelial cells (HNECs).

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Notch inhibition restores planar cell polarity and improves epithelial f...
(A) Healthy and CF HNECs were labeled with VANGL1 (green), acetylated α-tubulin (cilia, red), and ECAD (blue) antibodies at air-liquid interface (ALI)+10 (early) and ALI+30 (late) days. VANGL1 crescents become robust in well-ciliated healthy HNECs, but fail to do so in poorly ciliated CF HNECs. DAPT treatment of CF HNECs from ALI+0 to +30 days restores multiciliated cell (MCC) differentiation and robust VANGL1 crescent formation. Manders’ overlap coefficient ± standard error indicated on merged images. Scale bars: 10 μm. Images are representative of n = 3 drug treatments of CF HNECs from n = 5 donors. (B) Quantification of the fraction of MCCs in healthy HNECs and untreated and DAPT-treated CF HNECs; n > 1,000 cells were evaluated in triplicate. One-way ANOVA with post-hoc Dunnett’s multiple comparison test; *P < 0.0001. (C) Healthy HNECs and untreated and DAPT-treated CF HNECs were injured in a scratch wound assay at ALI+30 days and allowed to regenerate. Depending on donor, CF HNECs mostly failed to repair the wound; however, DAPT-treated CF HNECs were able to robustly close the wound (see Supplemental Figure 7B). Wound healing was measured in n = 3 cultures in triplicate, CF HNEC and CF+DAPT HNEC values were compared using a 2-way ANOVA and were found to be significantly different at P < 0.0001. (D) Transepithelial electrical resistance (TEER) measurements at ALI+30 days for IL-13– or DAPT-treated healthy HNECs and untreated and DAPT-treated CF HNECs show that IL-13–treated healthy HNECs and untreated CF HNECs have lower TEER than healthy HNECs. TEER can be increased in both healthy and CF cultures by DAPT treatment. TEER was measured in n = 3 cultures in triplicate. One-way ANOVA with post-hoc Bonferroni’s multiple comparison test; *P < 0.05, **P < 0.0001, ***P < 0.00001. Box and whisker plots show the minimum, lower quartile, median, upper quartile, and maximum values.