Regulation of Na+, K(+)-ATPase in the rat outer medullary collecting duct during potassium depletion.

Because in outer medullary collecting ducts (OMCD) of K(+)-depleted rats, K+ secretion is abolished, whereas Na+, K(+)-ATPase, which energizes this secretion, is markedly stimulated, it has been proposed that Na+, K(+)-ATPase was mislocated to the apical cell membrane and energized K+ reabsorption. This hypothesis has been supported by paradoxical effects of ouabain in K(+)-depleted compared with normal rats. However, we have recently shown that ouabain inhibits not only Na+, K(+)-ATPase but also apical H+, K(+)-ATPase in the OMCD of K(+)-depleted rats. Therefore, this study was designed to evaluate whether previous observations were accounted for by Na+, K(+)-ATPase or by ouabain-sensitive H+, K(+)-ATPase. Na+, K(+)-ATPase was distinguished from H+, K(+)-ATPase by its insensitivity to Sch-28080. Results indicate that the hydrolytic and transport activities of Na+, K(+)-ATPase, the number of its functional units, and the expression of mRNA of its alpha 1 and beta 1 subunits were increased threefold or more in the OMCD of rats fed a K(+)-depleted diet for 2 wk. By immunofluorescence, Na+, K(+)-ATPase staining was strongly increased in K(+)-depleted rats but remained localized to the basolateral pole of OMCD principal cells. In conclusion, K+ depletion is associated with marked induction of functional Na+, K+ pumps at the basolateral pole of rat OMCD. Therefore, reduced K+ secretion might result from inhibition of apical K+ conductances and stimulation of basolateral K+ recycling. It is proposed that increased Na+, K(+)-ATPase participates in the increased Na+ reabsorption prevailing in collecting ducts of K(+)-depleted rats.

Apical structures of "mitochondria-rich" alpha and beta cells in euryhaline fish gill: their behaviour in various living conditions.

BACKGROUND: One of the characteristic features of the two types (alpha and beta) of "mitochondria-rich" (chloride) cells in the gill epithelium of freshwater fishes is the presence in their apical region of tubulovesicular structures. A further analysis of the ultrastructural features of these apical elements as well as that of their modifications under various living conditions should help to understand better the respective rôle of both alpha and beta cells in these conditions. METHODS: Atlantic salmon (Salmo salar) maintained in fresh water as well as tilapia (Oreochromis niloticus) maintained either in fresh water or in deionized water or in 20% saltwater were examined. Measurements of surface areas of apical structures in the various living conditions were also performed. RESULTS: In the alpha cells of freshwater fishes, the apical structures consisted of isolated vesicles containing a filamentous material resembling that coating the apical surface. They were closely related to the apical plasma membrane and did not penetrate the region containing the tubular system. When fishes were transferred to deionized water, the number of the apical membrane folds increased significantly, as did the number and size of apical structures which became elongated. In saltwater-adapted fishes, the apical structures showed a tendency to collapse and took the appearance of flattened and slightly curved elements. These observations tended to indicate that in alpha cells the apical structures were extensions of the apical plasma membrane and thereby might be implicated in sodium uptake when fishes are placed in fresh or deionized water and in chloride excretion when they are transferred to salt water. In beta cells, the apical structures were usually separated from the apical plasma membrane by a zone rich in cytoskeleton elements. They penetrated deeply into the supranuclear region, where they intermingled with the elements of the tubular system. They consisted mainly of tubular elements that contained a material resembling that present in the trans tubular Golgi network from which they might originate. The apical structures remained unaltered in beta cells whatever the medium (fresh or deionized water) in which the fish was placed. CONCLUSIONS: The alpha cells which are usually thought to be mainly involved in chloride excretion when fishes are transferred into seawater might also be implicated in sodium uptake in freshwater living conditions. The rôle of beta cells, in contrast, still remains to be established.

Principal and intercalated cells in primary cultures of rabbit renal collecting tubules revealed by monoclonal antibodies.

In this study we describe the production and characterization of two monoclonal antibodies (mAb 503 and mAb 703) raised against the apical membrane of rabbit cortical collecting tubule (CCT) cells. The specificity of the two monoclonal antibodies was studied by immunoelectron microscopy on kidney sections. These antibodies were used to identify principal and intercalated cells in primary cultures of CCT. To assess the maintenance of the basic characteristics of the cortical collecting cells during the growth process we determined the biochemical and electrophysiological properties of cultured CCT. Of the monoclonal antibodies produced mAb 503 was specifically directed against the luminal membrane of intercalated cells as shown by immunoelectron microscopy. mAb 703 bound specifically the apical membrane of the principal cells. In primary cultures of CCT mAb 503 and mAb 703 bound antigens present on the apical membrane of different cells and permitted the study of the distribution of the two cell types. Results showed the maintenance of the epithelial polarity of cultured CCT and the expression of specific antigens.