Axial heterogeneity of superficial proximal tubule paracellular transport in mice.

A considerable amount of NaCl reabsorption in proximal tubules (PTs) occurs via the paracellular transport regulated by the tight junction proteins claudins (Cldns). However, the paracellular transport properties in mouse superficial PTs remain unclear. We characterized these properties in superficial PT S1-S3 segments from mice expressing [wild-type (WT, WTS1-WTS3)] or lacking [knockout (KO, KOS1-KOS3)] claudin-2. We isolated and perfused segments with symmetrical solutions in the presence of bath ouabain and measured the diffusion potential upon changing the salt composition of the lumen or bath. Based on the diffusion potential corrected for the liquid junction potential (d), we calculated the paracellular Na over Cl permeability (/) ratio. The / values upon reducing luminal NaCl averaged 1.27, 1.04, and 0.85 in WTS1, WTS2, and WTS3 and 0.34, 0.55, and 0.80 in KOS1, KOS2, and KOS3, respectively. The d values exhibited a symmetrical response to bidirectional NaCl concentration gradients in WTS1-WTS3 and KOS1-KOS3. WTS1 and WTS3 were monovalent cation-selective, with WTS1 demonstrating stronger cation selectivity. The order of permeabilities relative to Cl was K > Rb > Na > Li, whereas both KOS1 and KOS3 exhibited monovalent cation selectivity loss and, consequently, enhanced anion selectivity, especially in KOS1. Protamine addition to the lumen and bath similarly decreased / values upon reduced luminal NaCl in the order of WTS1 > WTS3 > KOS3 > KOS1. Therefore, this study presents evidence of axial heterogeneity in paracellular transport across superficial PTs in mice. Research on isolated perfused S2 segments of proximal tubules in mice, both expressing and lacking claudin-2, indicates that claudin-2 forms leaky monovalent cation-selective paracellular channels within the tight junctions of proximal tubules. This study characterized the paracellular transport properties in isolated and perfused superficial proximal tubule S1-S3 segments in both groups of mice. The findings demonstrate, for the first time, functional heterogeneity in the paracellular pathway along the axis of the superficial proximal tubules.