OSMOTIC WATER-FLOW PATHWAYS ACROSS NECTURUS GALLBLADDER - ROLE OF THE TIGHT JUNCTION

To explore the quantitative significance of passive water flow through tight junctions of leaky epithelia, transepithelial water flow rates were measured in Necturus gallbladder mounted in chambers. Osmotic flows generated by raffinose gradients were asymmetrical with the greater flow in the mucosal-to-serosal direction. In tissue fixed in situ, intercellular spaces were dilated during mucosal-to-serosal flow and closed during serosal-to-mucosal flow. Tight junctions were focally separated (blistered), which correlated with the magnitude of mucosal-to-serosal flow. Blisters were not observed during serosal-to-mucosal flow or in nontransporting gallbladders. In freeze-fracture replicas, blisters appeared as pockets between intramembranous strands. Protamine, which decreases electrical conductance and increases depth and complexity of the tight junction, reduced osmotic water flow by similar to 30% in the mucosal-to-serosal direction (100 mosmol/kg gradient) without altering serosal-to-mucosal flow. We suggest that in the steady state, at least 30% of osmotically driven water passes transjunctionally in the mucosal-to-serosal direction, but flow is transcellular in the serosal-to-mucosal direction. Directionally divergent pathways may account for flow asymmetry.