Propagation of mechanically induced intercellular calcium waves via gap junctions and ATP receptors in rat liver epithelial cells

Mechanical stimulation was used to initiate Ca2+ waves in rat liver epithelial cells in order to ascertain the degree to which gap junctional intercellular communication (GJIC) is involved in communication of Ca2+ to adjacent cells and to assess alternative Ca2+ signaling pathways that may be present between these cells. In both WB-F344 cells, which show a high degree of GJIC, and WB-aB1 cells, which are GJIC deficient, mechanical stimulation of a single cell induced a Ca2+ wave which propagated away from the point of stimulation, across cell borders, to neighboring cells directly or indirectly in contact with the stimulated cell. In addition, the Ca2+ wave was transmitted to nearby isolated cells that exhibited no direct or indirect contact with the stimulated cell. Treatment of cells with 18beta-glycyrrhetinic acid, a compound that has been shown to block GJIC, did not significantly affect propagation of the Ca2+ wave. In contrast, treatment with suramin, a P2-purinergic receptor inhibitor, significantly reduced both the rate and the extent of Ca2+ wave propagation in WB-F344 cells and completely blocked its propagation in WB-aB1 cells. Cotreatment with suramin and glycyrrhetinic acid was found to completely block the mechanically induced Ca2+ wave in both cell lines. These studies indicate that mechanically induced cell injury in rat liver epithelial cells initiates signaling through at least two pathways, involving intercellular communication via gap junctions and extracellular communication via ATP activation of purinergic receptors.