Angiotensin II (ANG II) regulates whole kidney ion transport, yet its effects in the collecting duct are unknown. The purpose of these studies was to determine whether ANG II regulates luminal alkalinization and acidification in the rabbit cortical collecting duct (CCD). The rate of luminal alkalinization or acidification was measured as the rate of change of luminal fluid pH under stop-flow conditions using in vitro microperfused CCD segments. Outer CCD alkalinized the luminal fluid, consistent with net HCO3- secretion. Addition of ANG II, 10(-7) M, to the peritubular solution for 30 min significantly stimulated luminal alkalinization. The stimulatory effect of ANG II was not due to time-dependent effects and was blocked by peritubular addition of the ANG II type 1 (AT1) receptor antagonist, losartan, at 10(-6) M. Losartan, 10(-6) M, when added to the peritubular solution, did not alter the rate of luminal alkalinization independent of ANG II. In contrast, peritubular ANG II, 10(-7) M, did not alter inner CCD luminal acidification. Addition of ANG II to the peritubular solution at the lower concentration of 10(-10) M did not alter the rates of luminal alkalinization and acidification in the outer and inner CCD, respectively. Peritubular ANG II, 10(-7) M, but not vehicle, stimulated B cell apical HCO3- secretion occurring in response to peritubular Cl- removal. These studies demonstrate that ANG II acts through a basolateral AT1 receptor to stimulate outer CCD luminal alkalinization via, at least in part, B cell stimulation.
At least two cortical collecting duct (CCD) intercalated cell populations mediate HCO3- secretion and reabsorption. The present study examined the membrane location of intercalated cell Cl-/base exchange activity and the axial distribution of CCD intercalated cells. CCD were studied using in vitro microperfusion in CO2/HCO3(-)-containing solutions; intracellular pH was measured using 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein. The A-type intercalated cell (A cell) and B-type intercalated cell (B cell) were identified functionally by the absence and presence of apical Cl-/HCO3- exchange activity, respectively. When a 0 mM Cl-, 0 mM HCO3- luminal solution was used, removal of Cl- from the peritubular solution caused intracellular alkalinization in all B cells. The alkalinization required neither extracellular Na+ nor changes in membrane potential. Peritubular 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) (10(-4) M) inhibited A cell but not B cell basolateral Cl-/base exchange activity. In comparison to studies performed with a 0 mM Cl- 0 mM HCO3- luminal solution, the use of a 0 mM Cl-, 25 mM HCO3- luminal solution inhibited both the identification and the magnitude of B cell basolateral Cl-/base exchange activity. When CCD from the inner and outer cortex were separately studied, only 7% of outer CCD intercalated cells were A cells, whereas 93% were B cells. In contrast, in the inner CCD, 58% of intercalated cells were A cells and 42% were B cells. Under stop-flow conditions, outer CCD alkalinized the luminal fluid, whereas inner CCD acidified the luminal fluid. These results indicate that all CCD intercalated cells possess basolateral Cl-/base exchange activity; however, A cell and B cell basolateral Cl-/base exchange activity differs, at least in terms of sensitivity to DIDS. Furthermore, there is axial heterogeneity in both intercalated cell type and function.
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