Dietary sodium enhances the expression of SLC4 family transporters, IRBIT, L-IRBIT, and PP1 in rat kidney: Insights into the molecular mechanism for renal sodium handling.

The kidney plays a central role in maintaining the fluid and electrolyte homeostasis in the body. Bicarbonate transporters NBCn1, NBCn2, and AE2 are expressed at the basolateral membrane of the medullary thick ascending limb (mTAL). In a previous study, NBCn1, NBCn2, and AE2 are proposed to play as a regulatory pathway to decrease NaCl reabsorption in the mTAL under high salt condition. When heterologously expressed, the activity of these transporters could be stimulated by the InsP3R binding protein released with inositol 1,4,5-trisphosphate (IRBIT), L-IRBIT (collectively the IRBITs), or protein phosphatase PP1. In the present study, we characterized by immunofluorescence the expression and localization of the IRBITs, and PP1 in rat kidney. Our data showed that the IRBITs were predominantly expressed from the mTAL through the distal renal tubules. PP1 was predominantly expressed in the TAL, but is also present in high abundance from the distal convoluted tubule through the medullary collecting duct. Western blotting analyses showed that the abundances of NBCn1, NBCn2, and AE2 as well as the IRBITs and PP1 were greatly upregulated in rat kidney by dietary sodium. Co-immunoprecipitation study provided the evidence for protein interaction between NBCn1 and L-IRBIT in rat kidney. Taken together, our data suggest that the IRBITs and PP1 play an important role in sodium handling in the kidney. We propose that the IRBITs and PP1 stimulates NBCn1, NBCn2, and AE2 in the basolateral mTAL to inhibit sodium reabsorption under high sodium condition. Our study provides important insights into understanding the molecular mechanism for the regulation of sodium homeostasis in the body.

Molecular insight into coordination sites for substrates and their coupling kinetics in Na+ /HCO3- cotransporter NBCe1.

The secondary active transporter NBCe1 couples the transmembrane movement of Na+ and carbonate species with an apparent stoichiometry of 1Na+ :2HCO3- (the 'influx' mode) or 1Na+ :3HCO3- (the 'efflux' mode). Here, we employed molecular biology, electrophysiology and structural biology approaches to investigate the molecular mechanism for the transport coupling of Na+ and HCO3- in NBCe1. In Xenopus oocytes, decreasing extracellular [HCO3- ] from 66 to 4 mm progressively decreases the Na+ affinity of NBCe1. However, decreasing [Na+ ] from 96 to 35 mm has little effect on the HCO3- affinity. The residues responsible for the coordination of Na+ and HCO3- in the substrate pocket of NBCe1 were respectively determined by mutational and molecular simulation studies. Mutation to the residues for HCO3- coordination decreased the affinities of NBCe1 for both Na+ and HCO3- . However, mutation to the residues for Na+ coordination decreased the affinity for Na+ but had little effect on the affinity for HCO3- . Molecular simulation showed that NBCe1 has the capacity to coordinate only two ions of HCO3- or CO32- . We propose that (1) NBCe1 has an ordered substrate-binding kinetics with the binding of HCO3- preceding that of Na+ ; (2) NBCe1 operating in the influx mode moves 1Na+  + 2HCO3- , whereas NBCe1 in the efflux mode moves 1Na+  + 1HCO3-  + 1CO32- . The substrate-binding kinetics of NBCe1 is distinct from the known kinetics models of many other Na+ -coupled transporters with Na+ binding preceding the driven solute. KEY POINTS: Under physiological conditions, the secondary active transporter NBCe1 can operate in the 'influx' mode with an apparent stoichiometry of 1Na+ :2HCO3- or in the 'efflux' mode with an apparent stoichiometry of 1Na+ :3HCO3- . NBCe1 has an ordered substrate-binding kinetics with HCO3- preceding the binding of Na+ . The kinetics of NBCe1 is distinct from the known kinetics of many other Na+ -driven cotransporters for which the binding of Na+ usually precedes the driven substrate. The residues responsible for the coordination of Na+ and those for carbonate species in the substrate-binding pocket of NBCe1 were determined by mutation and molecular simulation studies. The substrate-binding pocket of NBCe1 contains just two coordination sites for HCO3- or CO32- . It is proposed that NBCe1 in the influx mode moves 1Na+  + 2HCO3- across the plasma membrane, whereas NBCe1 in the efflux mode moves 1Na+ +1HCO3- +1CO32- .