A new regulator of the vacuolar H+-ATPase in the kidney

Xu et al. identify Slc26a11, a novel member of the Slc26 anion exchanger family, as an electrogenic (Cl−)n/HCO3− exchanger. Functional characterization of this transporter suggests that Slc26a11 mediates classical electroneutral Cl−/HCO3− exchange but also exhibits an electrogenic Cl− conductance. In the kidney, Slc26a11 colocalizes with the vacuolar H+-ATPase in intercalated cells, emphasizing the cooperation of the proton pump with chloride transporters

Etude de trois protéines de transport membranaire impliquées dans la régulation de l'état acide basé par le rein

PARIS-BIUSJ-Thèses (751052125) / SudocPARIS-BIUSJ-Physique recherche (751052113) / SudocSudocFranceF

La pendrine

Les mutations inactivatrices du gène de la pendrine sont responsables d’une pathologie associant des troubles de la thyroïde et de l’oreille interne. Cependant, il est rapidement apparu après sa découverte que l’échangeur d’anions codé par ce gène joue un rôle essentiel dans le rein. Cette brève revue décrit l’évolution de nos connaissances concernant ces différents rôles, jusqu’à la très récente découverte de l’implication de la pendrine dans la régulation de l’homéostasie du sodium et de la pression artérielle

RhBG and RhCG, the Putative Ammonia Transporters, Are Expressed in the Same Cells in the Distal Nephron

International audienceTwo nonerythroid homologs of the blood group Rh proteins, RhCG and RhBG, which share homologies with specific ammonia transporters in primitive organisms and plants, could represent members of a new family of proteins involved in ammonia transport in the mammalian kidney. Consistent with this hypothesis, the expression of RhCG was recently reported at the apical pole of all connecting tubule (CNT) cells as well as in intercalated cells of collecting duct (CD). To assess the localization along the nephron of RhBG, polyclonal antibodies against the Rh type B glycoprotein were generated. In immunoblot experiments, a specific polypeptide of Mr approximately 50 kD was detected in rat kidney cortex and in outer and inner medulla membrane fractions. Immunocytochemical studies revealed RhBG expression in distal nephron segments within the cortical labyrinth, medullary rays, and outer and inner medulla. RhBG expression was restricted to the basolateral membrane of epithelial cells. The same localization was observed in rat and mouse kidney. RT-PCR analysis on microdissected rat nephron segments confirmed that RhBG mRNAs were chiefly expressed in CNT and cortical and outer medullary CD. Double immunostaining with RhCG demonstrated that RhBG and RhCG were coexpressed in the same cells, but with a basolateral and apical localization, respectively. In conclusion, RhBG and RhCG are present in a major site of ammonia secretion in the kidney, i.e., the CNT and CD, in agreement with their putative role in ammonium transport

pH dependence of Na+/myo-inositol cotransporters in rat thick limb cells

pH dependence of Na+/myo-inositol cotransporters in rat thick limb cells.BackgroundTo balance medullary interstitium hypertonicity generated by transepithelial NaCl absorption, medullary thick ascending limb (MTAL) cells accumulate myo-inositol (MI). Expression of Na+-MI cotransporter (SMIT) mRNA in TAL is correlated with the NaCl absorption rate. Our present study aimed to determine the plasma membrane location and functional properties of the Na+-MI cotransporter in MTAL cells.MethodsPreparation of basolateral (BLMV) and luminal (LMV) membrane vesicles were simultaneously isolated from purified rat MTAL suspension, and uptake of [3H]myo-inositol ([3H]MI) was used to assess Na+-MI cotransport activity.ResultsIn the presence of an inside-negative membrane potential, imposing an inwardly-directed Na+-gradient versus tetramethylammonium (TMA) stimulated the initial [3H]MI uptake in BLMV and LMV. Phlorizin inhibited Na+ gradient-dependent initial [3H]MI uptake in both preparations, with IC50 values of 565 and 29 μmol/L in BLMV and LMV, respectively. 2-0,C-methylene myo-inositol (MMI), a competitive inhibitor of MI transport, only inhibited the BLMV Na+-MI cotransporter. Phlorizin-sensitive Na+ gradient-dependent initial [3H]MI uptake showed Michaelis-Menten kinetics in both preparations, with similar Vmax but different Km values of 51 and 107 μmol/L in BLMV and LMV, respectively. Finally, BLMV but not LMV Na+-MI cotransporter exhibited a marked pH dependence with sigmoidal patterns of activation, as intravesicular pH (pHi) was decreased from 8.0 to 6.0 at extravesicular pH (pHe) 8.0, and as pHe was increased from 6.0 to 8.0 at pHi 6.0. Maximal activation was observed at pHi 6.5 and pHe 7.5.ConclusionsIn rat MTAL cells, Na+-MI cotransporter activity is present in both BLM and LM, and has markedly different functional properties, indicating the presence of distinct transporters. Basolateral Na+-MI cotransporter activity is maximal at physiological pH values of MTAL cells and interstitium, and a powerful modulation of the transporter activity may be exerted by pHe and pHi

Deficiency of Carbonic Anhydrase II Results in a Urinary Concentrating Defect

Carbonic anhydrase II (CAII) is expressed along the nephron where it interacts with a number of transport proteins augmenting their activity. Aquaporin-1 (AQP1) interacts with CAII to increase water flux through the water channel. Both CAII and aquaporin-1 are expressed in the thin descending limb (TDL); however, the physiological role of a CAII-AQP1 interaction in this nephron segment is not known. To determine if CAII was required for urinary concentration, we studied water handling in CAII-deficient mice. CAII-deficient mice demonstrate polyuria and polydipsia as well as an alkaline urine and bicarbonaturia, consistent with a type III renal tubular acidosis. Natriuresis and hypercalciuria cause polyuria, however, CAII-deficient mice did not have increased urinary sodium nor calcium excretion. Further examination revealed dilute urine in the CAII-deficient mice. Urinary concentration remained reduced in CAII-deficient mice relative to wild-type animals even after water deprivation. The renal expression and localization by light microscopy of NKCC2 and aquaporin-2 was not altered. However, CAII-deficient mice had increased renal AQP1 expression. CAII associates with and increases water flux through aquaporin-1. Water flux through aquaporin-1 in the TDL of the loop of Henle is essential to the concentration of urine, as this is required to generate a concentrated medullary interstitium. We therefore measured cortical and medullary interstitial concentration in wild-type and CAII-deficient mice. Mice lacking CAII had equivalent cortical interstitial osmolarity to wild-type mice: however, they had reduced medullary interstitial osmolarity. We propose therefore that reduced water flux through aquaporin-1 in the TDL in the absence of CAII prevents the generation of a maximally concentrated medullary interstitium. This, in turn, limits urinary concentration in CAII deficient mice

A mutant alphaII-spectrin designed to resist calpain and caspase cleavage questions the functional importance of this process in vivo.

International audiencealpha- and beta-spectrins are components of molecular scaffolds located under the lipid bilayer and named membrane skeletons. Disruption of these scaffolds through mutations in spectrins demonstrated that they are involved in the membrane localization or the maintenance of proteins associated with them. The ubiquitous alphaII-spectrin chain bears in its central region a unique domain that is sensitive to several proteases such as calpains or caspases. The conservation of this region in vertebrates suggests that the proteolysis of alphaII-spectrin by these enzymes could be involved in important functions. To assess the role of alphaII-spectrin cleavage in vivo, we generated a murine model in which the exons encoding the region defining this cleavage sensitivity were disrupted by gene targeting. Surprisingly, homozygous mice expressing this mutant alphaII-spectrin appeared healthy, bred normally, and had no histological anomaly. Remarkably, the mutant alphaII-spectrin assembles correctly into the membrane skeleton, thus challenging the notion that this region is required for the stable biogenesis of the membrane skeleton in nonerythroid cells. Our finding also argues against a critical role of this particular alphaII-spectrin cleavage in either major cellular functions or in normal development