mTORC1 is a mechanosensor that regulates surfactant function and lung compliance during ventilator-induced lung injury
Hyunwook Lee, Qinqin Fei, Adam Streicher, Wenjuan Zhang, Colleen Isabelle, Pragi Patel, Hilaire C. Lam, Antonio Arciniegas-Rubio, Miguel Pinilla-Vera, Diana P. Amador-Munoz, Diana Barragan-Bradford, Angelica Higuera-Moreno, Rachel K. Putman, Lynette M. Sholl, Elizabeth P. Henske, Christopher M. Bobba, Natalia Higuita-Castro, Emily M. Shalosky, R. Duncan Hite, John W. Christman, Samir N. Ghadiali, Rebecca M. Baron, Joshua A. Englert
Hyunwook Lee, Qinqin Fei, Adam Streicher, Wenjuan Zhang, Colleen Isabelle, Pragi Patel, Hilaire C. Lam, Antonio Arciniegas-Rubio, Miguel Pinilla-Vera, Diana P. Amador-Munoz, Diana Barragan-Bradford, Angelica Higuera-Moreno, Rachel K. Putman, Lynette M. Sholl, Elizabeth P. Henske, Christopher M. Bobba, Natalia Higuita-Castro, Emily M. Shalosky, R. Duncan Hite, John W. Christman, Samir N. Ghadiali, Rebecca M. Baron, Joshua A. Englert
View: Text | PDF
Research Article Pulmonology

mTORC1 is a mechanosensor that regulates surfactant function and lung compliance during ventilator-induced lung injury

Abstract

The acute respiratory distress syndrome (ARDS) is a highly lethal condition that impairs lung function and causes respiratory failure. Mechanical ventilation (MV) maintains gas exchange in patients with ARDS but exposes lung cells to physical forces that exacerbate injury. Our data demonstrate that mTOR complex 1 (mTORC1) is a mechanosensor in lung epithelial cells and that activation of this pathway during MV impairs lung function. We found that mTORC1 is activated in lung epithelial cells following volutrauma and atelectrauma in mice and humanized in vitro models of the lung microenvironment. mTORC1 is also activated in lung tissue of mechanically ventilated patients with ARDS. Deletion of Tsc2, a negative regulator of mTORC1, in epithelial cells impairs lung compliance during MV. Conversely, treatment with rapamycin at the time MV is initiated improves lung compliance without altering lung inflammation or barrier permeability. mTORC1 inhibition mitigates physiologic lung injury by preventing surfactant dysfunction during MV. Our data demonstrate that, in contrast to canonical mTORC1 activation under favorable growth conditions, activation of mTORC1 during MV exacerbates lung injury and inhibition of this pathway may be a novel therapeutic target to mitigate ventilator-induced lung injury during ARDS.

Authors

Hyunwook Lee, Qinqin Fei, Adam Streicher, Wenjuan Zhang, Colleen Isabelle, Pragi Patel, Hilaire C. Lam, Antonio Arciniegas-Rubio, Miguel Pinilla-Vera, Diana P. Amador-Munoz, Diana Barragan-Bradford, Angelica Higuera-Moreno, Rachel K. Putman, Lynette M. Sholl, Elizabeth P. Henske, Christopher M. Bobba, Natalia Higuita-Castro, Emily M. Shalosky, R. Duncan Hite, John W. Christman, Samir N. Ghadiali, Rebecca M. Baron, Joshua A. Englert

×

Figure 5

In vitro volutrauma activates mTORC1 through reactive oxygen species-dependent activation of the ERK pathway.

Options: View larger image (or click on image) Download as PowerPoint
In vitro volutrauma activates mTORC1 through reactive oxygen species-dep...
(A) Human bronchial epithelial cells were subjected to volutrauma (20% equibiaxial stretch, 0.2 Hz, 30 min) in the presence of increasing doses of the ERK 1/2 inhibitor (SCH772984) or vehicle (DMSO) prior to immunoblotting for markers of ERK and mTORC1 activation (pooled protein from n = 2 wells/lane). (B) SAECs were subjected to volutrauma (24% biaxial stretch, 0.2 Hz, 30 min) in the presence of increasing doses of the AKT inhibitor (MK-2206) or vehicle (DMSO) prior to immunoblotting for markers of AKT and mTORC1 activation (pooled protein from n = 2 wells/lane). (C and D) HBEs were stretched (24% biaxial stretch, 0.2 Hz, 30 min) in the presence of CellRox Green and fluorescence was quantitated in each field (100×). Data log normally distributed, analyzed by Student’s t test on log2 transformed data (n = 18 fields/group). (E and F) SAECs were stretched (24% biaxial stretch, 0.3 Hz, 30 min) in the presence of mitoSOX (Red) and calcein AM (Green) prior to quantitating the intensity of MitoSOX Red staining in each field (100×). Data not normally distributed, analyzed by Mann-Whitney test (n = 27 images per condition). (G) Small airway epithelial cells were treated with 500 μM hydrogen peroxide (H2O2) for increasing amounts of time prior to immunoblotting for markers or ERK and mTORC1 activation (n = 1 well/lane). (H) SAECs were treated with increasing doses of GSH-EE 30 minutes prior to volutrauma (20% equibiaxial stretch, 0.2 Hz, 30 min) and immunoblotting for markers of mTORC1 and ERK activation (n = 2 wells/lane). Box blots show median ± interquartile range and whiskers define min and max values. *P < 0.05 for all panels.