Cell signaling pathways mediating epidermal growth factor stimulation of Na:K:2Cl cotransport activity in rabbit corneal epithelial cells.

We characterized the signaling and ion transport pathways that mediate epidermal growth factor receptor physiological control in SV40-immortalized rabbit corneal epithelial cells (tRCEC). Our evaluation employed single-cell fluorescence imaging to measure the intracellular [Na+]i in these cells loaded with the Na+ sensitive dye, SBFI. EGF (1 to 5 ng/ml) transiently increased [Na+]i from 10 mm to as much as 35 mm after 25 min, which was followed by a decline towards its control value. These increases waned at higher EGF concentrations up to 50 ng/ml. Both inhibition of EGF receptor-linked tyrosine kinase activity (50 microm RG-13022) and cPLA2 activity (10 microm AACOCF3) obviated EGF-induced increases in [Na+]i. In contrast, PGE2 (10 microg/ml) and cAMP (2 mm) increased [Na+]i by 25 mm. Inhibition of NKCC activity through exposure to either Cl-free Ringers or 300 microm furosemide in NaCl Ringers eliminated EGF-induced increases in [Na+]i. Similarly, EGF failed to increase [Na+]i following inhibition of: 1) PKA activity (10 microm H-89); 2) Erk1/2 (15 microm PD98059) or 3) p38 (15 microm SB203580) activity. Stimulation protein kinase C activity (0.1 microm PMA) transiently increased [Na+]i followed by a decline towards its baseline value. EGF-induced increases in [Na+]i were unaltered by inhibition of K+ conductance (100 microm 4-AP). Taken together, EGF stimulates Erk1/2; p38 and cPLA2 activity. Their stimulation increases PGE2 and cAMP levels resulting in PKA and NKCC activation.