Mechanosensitive channels TMEM63A and TMEM63B mediate lung inflation–induced surfactant secretion
Gui-Lan Chen, … , Jin Zhang, Bo Zeng
Gui-Lan Chen, … , Jin Zhang, Bo Zeng
Published December 21, 2023
Citation Information: J Clin Invest. 2024;134(5):e174508. https://doi.org/10.1172/JCI174508.
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Research Article Pulmonology

Mechanosensitive channels TMEM63A and TMEM63B mediate lung inflation–induced surfactant secretion

Abstract

Pulmonary surfactant is a lipoprotein complex lining the alveolar surface to decrease the surface tension and facilitate inspiration. Surfactant deficiency is often seen in premature infants and in children and adults with respiratory distress syndrome. Mechanical stretch of alveolar type 2 epithelial (AT2) cells during lung expansion is the primary physiological factor that stimulates surfactant secretion; however, it is unclear whether there is a mechanosensor dedicated to this process. Here, we show that loss of the mechanosensitive channels TMEM63A and TMEM63B (TMEM63A/B) resulted in atelectasis and respiratory failure in mice due to a deficit of surfactant secretion. TMEM63A/B were predominantly localized at the limiting membrane of the lamellar body (LB), a lysosome-related organelle that stores pulmonary surfactant and ATP in AT2 cells. Activation of TMEM63A/B channels during cell stretch facilitated the release of surfactant and ATP from LBs fused with the plasma membrane. The released ATP evoked Ca2+ signaling in AT2 cells and potentiated exocytic fusion of more LBs. Our study uncovered a vital physiological function of TMEM63 mechanosensitive channels in preparing the lungs for the first breath at birth and maintaining respiration throughout life.

Authors

Gui-Lan Chen, Jing-Yi Li, Xin Chen, Jia-Wei Liu, Qian Zhang, Jie-Yu Liu, Jing Wen, Na Wang, Ming Lei, Jun-Peng Wei, Li Yi, Jia-Jia Li, Yu-Peng Ling, He-Qiang Yi, Zhenying Hu, Jingjing Duan, Jin Zhang, Bo Zeng

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Figure 3

Mechanosensitive currents in human and mouse AECs.

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Mechanosensitive currents in human and mouse AECs. (A) Stretch-activated...
(A) Stretch-activated currents (SACs) under a cell-attached configuration in primary human and mouse AT2 cells and mouse AT1 cells in acute lung slices. The holding potential was –80 mV, and the vacuum pressures were applied to the clamped membrane with a –20 mmHg increase for each step. Insets are pressure-current relationships of the corresponding recordings. (B) Amplitudes of SACs induced by –80 mmHg pressure in human or mouse AT2 cells and mouse AT1 cells. n = 20, 16, and 56 for human AT2 cells, mouse AT2 cells, and mouse AT1 cells, respectively. (C) Relative permeability of K+, Ca2+, and Mg2+ versus Na+ for stretch-activated currents in mouse AT2 cells. n = 12, 6, and 8 cells for K+, Ca2+, and Mg2+, respectively. (D) Nonselective blockers of ENaC (amiloride, 10 μM), K+ channels (quinine, 500 μM), gap junctions (CBX, 100 μM), and Piezo1 (ruthenium red, 50 μM), and acidic pH did not affect the stretch-activated currents in mouse AT2 cells. n = 13, 7, 6, 8, 7, and 8 cells from left to right. (E) SACs under vesicle-attached configuration in enlarged LBs and ELs (LB/EL) from mouse AT2 cells. The holding potential was –60 mV, and the vacuum pressures were applied with a –10 mmHg increase for each step. (F) Comparison of the amplitudes of stretch-activated currents from LB/EL. n = 10 and 16 human and mouse cells, respectively.