Lipoxin A4 prevents tight junction disruption and delays the colonization of cystic fibrosis bronchial epithelial cells by Pseudomonas aeruginosa.

The specialized proresolution lipid mediator lipoxin A4 (LXA4) is abnormally produced in cystic fibrosis (CF) airways. LXA4 increases the CF airway surface liquid height and stimulates airway epithelial repair and tight junction formation. We report here a protective effect of LXA4 (1 nM) against tight junction disruption caused by Pseudomonas aeruginosa bacterial challenge together with a delaying action against bacterial invasion in CF airway epithelial cells from patients with CF and immortalized cell lines. Bacterial invasion and tight junction integrity were measured by gentamicin exclusion assays and confocal fluorescence microscopy in non-CF (NuLi-1) and CF (CuFi-1) bronchial epithelial cell lines and in primary CF cultures, grown under an air/liquid interface, exposed to either a clinical or laboratory strains of P. aeruginosa LXA4 delayed P. aeruginosa invasion and transepithelial migration in CF and normal bronchial epithelial cell cultures. These protective effects of LXA4 were inhibited by the ALX/FPR2 lipoxin receptor antagonist BOC-2. LXA4 prevented the reduction in mRNA biosynthesis and protein abundance of the tight junction protein ZO-1 and reduced tight junction disruption induced by P. aeruginsosa inoculation. In conclusion, LXA4 plays a protective role in bronchial epithelium by stimulating tight junction repair and by delaying and reducing the invasion of CF bronchial epithelial cells by P. aeruginsosa.

Estrogen modulates metabolic pathway adaptation to available glucose in breast cancer cells.

Most cancers use glucose as substrate for aerobic glycolysis in preference to oxidative phosphorylation. However, variable glucose concentrations within the in-vivo tumor microenvironment may necessitate metabolic plasticity. Furthermore, little information exists on a role for estrogen receptors in modulating possible metabolic adaptations in breast cancer cells. Here we find that MCF-7 cells switch between metabolic pathways depending on glucose availability and 17ß-estradiol (E(2)) potentiates adaptation. In high glucose conditions E(2) up-regulates glycolysis via enhanced AKT kinase activity and suppresses tricarboxylic acid cycle activity. After a decrease in extracellular glucose, mitochondrial pathways are activated in preference to glycolysis. In this setting, E(2) suppresses glycolysis and rescues cell viability by stimulating the tricarboxylic acid cycle via the up-regulation of pyruvate dehydrogenase (PDH) activity. E(2) also increases ATP in low glucose-cultured cells, and the novel phosphorylation of PDH by AMP kinase is required for these metabolic compensations. Capitalizing on metabolic vulnerability, knockdown of PDH in the low-glucose state strongly potentiates ionizing radiation-induced apoptosis and reverses the cell survival effects of E(2). We propose that lowering glucose substrate and inhibiting PDH may augment adjuvant therapies for estrogen receptor-positive breast cancer.