Inhibition of the sodium-dependent HCO3 -transporter SLC4A4, produces a cystic fibrosis-like airway disease phenotype.

Bicarbonate secretion is a fundamental process involved in maintaining acid-base homeostasis. Disruption of bicarbonate entry into airway lumen, as has been observed in cystic fibrosis, produces several defects in lung function due to thick mucus accumulation. Bicarbonate is critical for correct mucin deployment and there is increasing interest in understanding its role in airway physiology, particularly in the initiation of lung disease in children affected by cystic fibrosis, in the absence of detectable bacterial infection. The current model of anion secretion in mammalian airways consists of CFTR and TMEM16A as apical anion exit channels, with limited capacity for bicarbonate transport compared to chloride. However, both channels can couple to SLC26A4 anion exchanger to maximise bicarbonate secretion. Nevertheless, current models lack any details about the identity of the basolateral protein(s) responsible for bicarbonate uptake into airway epithelial cells. We report herein that the electrogenic, sodium-dependent, bicarbonate cotransporter, SLC4A4, is expressed in the basolateral membrane of human and mouse airways, and that it’s pharmacological inhibition or genetic silencing reduces bicarbonate secretion. In fully differentiated primary human airway cells, SLC4A4 inhibition induced an acidification of the airways surface liquid and markedly reduced the capacity of cells to recover from an acid load. Studies in the Slc4a4-null mice revealed a previously unreported lung phenotype, characterized by mucus accumulation and reduced mucociliary clearance. Collectively, our results demonstrate that the reduction of SLC4A4 function induced a CF-like phenotype, even when chloride secretion remained intact, highlighting the important role SLC4A4 plays in bicarbonate secretion and mammalian airway function.

Impact of hypoxia and AMPK on CFTR-mediated bicarbonate secretion in human cholangiocyte organoids.

Background and Aims: Cholangiocytes express cystic fibrosis transmembrane conductance regulator (CFTR) which is involved in bicarbonate secretion for the protection against bile toxicity. During liver transplantation prolonged hypoxia of the graft is associated with cholangiocyte loss and biliary complications. Hypoxia is known to diminish CFTR activity in the intestine, but whether it effects CFTR activity in cholangiocytes remains unknown. Thus, the aim of this study is to investigate the effect of hypoxia on CFTR activity in intrahepatic cholangiocyte organoids (ICOs) and test drug-interventions to restore bicarbonate secretion. Methods: Fifteen different human ICOs were cultured as monolayers and ion channel (CFTR and ANO1) activity was determined using an Ussing chamber assay with or without AMP kinase (AMPK)-inhibitor under hypoxic and oxygenated conditions. Bile-toxicity was tested by apical exposure of cells to fresh human bile. Results: Overall gene-expression analysis showed a high similarity between ICOs and primary cholangiocytes. Under oxygenated conditions, both CFTR and ANO1 channels were responsible for forskolin and UTP activated anion-secretion. Forskolin-stimulation in absence of intracellular chloride showed ion-transport, indicating that bicarbonate could be secreted by CFTR. During hypoxia, CFTR activity significantly decreased (p=0.01). Switching from oxygen to hypoxia during CFTR-measurements, reduced CFTR activity (p=0.03). Consequently, cell death increased when ICO-monolayers were exposed to bile during hypoxia compared to oxygen (p=0.04). Importantly, addition of AMPK-inhibitor restored CFTR-mediated anion-secretion during hypoxia. Conclusion: ICOs provide an excellent model to study cholangiocyte anion channels and drug-related interventions. Here, we demonstrate that hypoxia affects cholangiocyte ion-secretion, leaving cholangiocytes vulnerable to bile toxicity. The mechanistic insights from this model maybe relevant for hypoxia-related biliary injury during liver transplantation.