The aryl hydrocarbon receptor reduces LC3II expression and controls endoplasmic reticulum stress

The aryl hydrocarbon receptor (AhR) is a ligand-activated transcription factor whose physiological function is poorly understood. The AhR is highly expressed in barrier organs such as the skin, intestine, and lung. The lungs are continuously exposed to environmental pollutants such as cigarette smoke (CS) that can induce cell death mechanisms such as apoptosis, autophagy, and endoplasmic reticulum (ER) stress. CS also contains toxicants that are AhR ligands. We have previously shown that the AhR protects against apoptosis, but whether the AhR also protects against autophagy or ER stress is not known. Using cigarette smoke extract (CSE) as our in vitro surrogate of environmental tobacco exposure, we first assessed the conversion of LC3I to LC3II, a classic feature of both autophagic and ER stress-mediated cell death pathways. LC3I1 was elevated in CSE-exposed lung structural cells [mouse lung fibroblasts (MLFs), MLE12 and A549 cells] when AhR was absent. However, this heightened LC3I1 expression could not be explained by increased expression of key autophagy genes (Gabarapil, Becnl, MaplIc3b), upregulation of upstream autophagic machinery (Atg5-12, Atg3), or impaired autophagic flux, suggesting that LC3II may be autophagy independent. This was further supported by the absence of autophagosomes in Ahr(-/-) lung cells. However, Ahr(-/-) lung cells had wide-spread ER dilation, elevated expression of the ER stress markers CHOP and GADD34, and an accumulation of ubiquitinated proteins. These findings collectively illustrate a novel role for the AhR in attenuating ER stress by a mechanism that may be autophagy independent.

Automated summary

The aryl hydrocarbon receptor (AhR) plays a crucial role in protecting cells from apoptosis induced by tobacco smoke, but its role in protecting cells from autophagy or ER stress is not well understood. Using CSE as a surrogate for tobacco exposure, researchers found a novel role for AhR in attenuating ER stress through a potential autophagy-independent mechanism in lung structural cells.