Christoph Rahner

Tight junctions regulate paracellular conductance and ionic selectivity. These properties vary among epithelia but the molecular basis of this variation remains unknown. To test whether members of the claudin family of tight junction proteins influence paracellular ionic selectivity, we expressed human claudin-4 in cultured MDCK cells using an inducible promoter. Overexpression increased the complexity of tight junction strands visible by freeze-fracture microscopy without affecting the levels of claudin-1, -2, or -3, occludin, or ZO-1. A decrease in conductance correlated directly with the kinetics of claudin-4 induction. Dilution potentials revealed that the decrease in paracellular conductance resulted from a selective decrease in Na(+) permeability without a significant effect on Cl(-) permeability. Flux for an uncharged solute, mannitol, and the rank order of permeabilities for the alkali metal cations were unchanged. A paracellular site for these effects was supported by the lack of apical/basal directionality of the dilution potentials, the linearity of current-voltage relationships, and the lack of influence of inhibitors of major transcellular transporters. These results provide, to our knowledge, the first direct demonstration of the ability of a claudin to influence paracellular ion selectivity and support a role for the claudins in creating selective channels through the tight-junction barrier.

Epithelia separate tissue spaces by regulating the passage of ions, solutes, and water through both the transcellular and paracellular pathways. Paracellular permeability is defined by intercellular tight junctions, which vary widely among tissues with respect to solute flux, electrical resistance, and ionic charge selectivity. To test the hypothesis that members of the claudin family of tight junction proteins create charge selectivity, we assessed the effect of reversing the charge of selected extracellular amino acids in two claudins using site-directed mutagenesis. Claudins were expressed in cultured Madin-Darby canine kidney cell monolayers under an inducible promoter, and clones were compared with and without induction for transmonolayer electrical resistance and dilution potentials. Expression and localization of claudins were determined by immunoblotting, immunofluorescence microscopy, and freeze-fracture electron microscopy. We observed that substituting a negative for a positive charge at position 65 in the first extracellular domain of claudin-4 increased paracellular Na+ permeability. Conversely, substituting positive for negative charges at three positions in the first extracellular domain of claudin-15, singly and in combination, reversed paracellular charge selectivity from a preference for Na+ to Cl-. These results support a model where claudins create charge-selective channels in the paracellular space.

Tight junctions (TJs) regulate paracellular permeability across epithelia and vary widely in their transepithelial electrical resistance (TER) and charge selectivity. The claudin family of transmembrane proteins influences these properties. We previously reported that claudin-4 increased TER approximately 300% when expressed in low-resistance Madin-Darby canine kidney (MDCK) II cells and decreased the paracellular permeability for Na(+) more than Cl(-) (Van Itallie C, Rahner C, and Anderson JM. J Clin Invest 107: 1319-1327, 2001). In comparison, we report here that expression of claudin-2 increases TER by only approximately 20% and does not change the ionic selectivity of MDCK II cells from their cation-selective background. To test whether the extracellular domains of claudins-4 and -2 determine their unique paracellular properties, we determined the effects of interchanging these domains between claudins-4 and -2. Inducible expression of wild-type claudins and extracellular domain chimeras increased both the number and depth of fibrils, but the characteristic fibril morphologies of claudin-4 or -2 were not altered by switching extracellular domains. Like claudin-4, chimeras expressing the first or both extracellular domains of claudin-4 on claudin-2 increased TER severalfold and profoundly decreased the permeability of Na(+) relative to Cl(-). In contrast, chimeras expressing the first or both extracellular domains of claudin-2 on claudin-4 increased the TER by only approximately 60 and approximately 40%, respectively, and only modestly altered charge selectivity. These results support a model in which the claudins create paracellular channels and the first extracellular domain is sufficient to determine both paracellular charge selectivity and TER.