Cystic fibrosis (CF) is caused by mutations in the CFTR gene, which encodes a cAMP-regulated chloride channel. Several cellular functions are altered in CF cells. However, it is not clear how the CFTR failure induces those alterations. We have found previously several genes differentially expressed in CF cells, including c-Src, MUC1, MTND4, and CISD1 (CFTR-dependent genes). Recently, we also reported the existence of several chloride-dependent genes, among them GLRX5 and RPS27. Here, varying the intracellular chloride concentration [Cl ] of IB3-1 CF bronchial epithelial cells, we show that IL-1β mRNA expression and secretion are also under Cl modulation. The response to Cl is biphasic, with maximal effects at 75 mM Cl . The regulation of the IL-1β mRNA expression involves an IL-1β autocrine effect, since in the presence of the IL-1β receptor antagonist IL1RN or anti-IL-1β blocking antibody, the mRNA response to Cl disappeared. Similar effects were obtained with the JNK inhibitor SP600125, the c-Src inhibitor PP2 and the IKK inhibitor III (BMS-345541). On the other hand, the IL-1β secretion is still modulated by Cl in the presence of IL-1RN, IL-1β blocking antibody, or cycloheximide, suggesting that Cl is affecting the IL-1β maturation/secretion, which in turn starts an autocrine positive feedback loop. In conclusion, the Cl anion acts as a second messenger for CFTR, modulating the IL-1β maturation/secretion. The results also imply that, depending on its intracellular concentration, Cl could be a pro-inflammatory mediator. J. Cell. Biochem. 118: 2131-2140, 2017. © 2016 Wiley Periodicals, Inc.
Cystic Fibrosis (CF) is a disease caused by mutations in the cystic fibrosis transmembrane conductance regulator (CFTR) gene. Previously, we found several genes showing a differential expression in CFDE cells (epithelial cells derived from a CF patient). One corresponded to c-Src; its expression and activity was found increased in CFDE cells, acting as a signaling molecule between the CFTR activity and MUC1 overexpression. Here we report that bronchial IB3-1 cells (CF cells) also showed increased c-Src activity compared to 'CFTR-corrected' S9 cells. In addition, three different Caco-2 cell lines, each stably transfected with a different CFTR-specific shRNAs, displayed increased c-Src activity. The IL-1β receptor antagonist IL1RN reduced the c-Src activity of Caco-2/pRS26 cells (expressing a CFTR-specific shRNA). In addition, increased mitochondrial and cellular ROS levels were detected in Caco-2/pRS26 cells. ROS levels were partially reduced by incubation with PP2 (c-Src inhibitor) or IL1RN, and further reduced by using the NOX1/4 inhibitor GKT137831. Thus, IL-1β→c-Src and IL-1β→NOX signaling pathways appear to be responsible for the production of cellular and mitochondrial ROS in CFTR-KD cells. In conclusion, IL-1β constitutes a new step in the CFTR signaling pathway, located upstream of c-Src, which is stimulated in cells with impaired CFTR activity.
Cystic fibrosis (CF) is an autosomal recessive disease caused by CFTR mutations. It is characterized by high NaCl concentration in sweat and the production of a thick and sticky mucus, occluding secretory ducts, intestine and airways, accompanied by chronic inflammation and infections of the lungs. This causes a progressive and lethal decline in lung function. Therefore, finding the mechanisms driving the high susceptibility to lung infections has been a key issue. For decades the prevalent hypothesis was that a reduced airway surface liquid (ASL) volume and composition, and the consequent increased mucus concentration (dehydration), create an environment favoring infections. However, a few years ago, in a pig model of CF, the Na/K concentrations and the ASL volume were found intact. Immediately a different hypothesis arose, postulating a reduced ASL pH as the cause for the increased susceptibility to infections, due to a diminished bicarbonate secretion through CFTR. Noteworthy, a recent report found normal ASL pH values in CF children and in cultured primary airway cells, challenging the ASL pH hypothesis. On the other hand, recent evidences revitalized the hypothesis of a reduced ASL secretion. Thus, the role of the ASL pH in the CF is still a controversial matter. In this review we discuss the basis that sustain the role of CFTR in modulating the extracellular pH, and the recent results sustaining the different points of view. Finding the mechanisms of CFTR signaling that determine the susceptibility to infections is crucial to understand the pathophysiology of CF and related lung diseases.
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