Vanadate inhibits urinary acidification by the turtle bladder

Physiological role for vanadate-inhibitable active H+ transport: a new model for distal urinary acidification

We have shown elsewhere that membranes isolated from the turtle bladder epithelium have both vanadate-resistant (VR) and vanadate-sensitive (VS) components of ATP-dependent H+ transport. VR appears to be due to a vacuolar-type H+ uniport while VS has properties of an H/K exchanger. In the present study we used bladders from chronically alkalotic turtles, which do not acidify urine, and found them to yield membranes which retain VR but lack VS transport. Thus VS occurs only in membranes from bladders secreting acid, implying that VS H+ transport (1) plays a physiological role in the secretion and (2) is a functional marker for the apical membrane of the acid-secreting cells. These results suggest a new model for distal urinary acidification.

ATP-dependent H+ transport by the turtle bladder: NBD-C1 preferentially inhibits the vanadate-insensitive component in isolated membranes

We investigated the inhibitory effects of 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-Cl) on ATP-dependent H+ accumulation by membrane vesicles prepared from the turtle urinary bladder epithelium. NBD-Cl at 30 microM was found to completely inhibit the vanadate-insensitive component of H+ transport, with half-maximal inhibition occurring at 4.2 to 5.4 microM. In contrast, the vanadate-inhibitable component was unaffected by 30 microM NBD-Cl. At high concentrations (300 microM), both components were fully inhibited. The results confirm the presence of two distinct H+ transport processes in turtle bladder membranes and identify selective inhibitors, NBD-Cl and vanadate, for each process.

Vanadium ion stimulation of chloride secretion by rabbit colonic epithelium

Ionized forms of vanadium are known to exert diverse biological activities. Of particular interest in the inhibitory action of the vanadium ion on (Na+ + K+)-ATPase. This report describes another action of the vanadium ion on the rabbit colonic epithelium. Micromolar quantities of vanadate, applied to the serosal side of the isolated rabbit colonic epithelium, result in a stimulation of electrogenic chloride secretion by this epithelium. Sodium transport is unaffected by the vanadium ion in the concentrations used in this study. It is proposed that the vanadyl ion activates adenylate cyclase and thereby initiates subsequent secretory events.

Effect of vanadate on water transport by the toad bladder

Vanadate increases renal Na and water excretion. The mechanism whereby vanadate impairs water transport was examined in the toad bladder. Vanadate did not alter baseline water transport but caused a significant inhibition of water transport elicited by high doses of AVP. The inhibition of AVP stimulated water flow by vanadate was dose dependent with inhibition present with concentration as low as 10(-7) and maximal inhibition occurring at 10(-5) M. Vanadate also inhibited water transport stimulated by cyclic AMP or by phosphodiesterase inhibition indicating that vanadate has an effect beyond cyclic AMP step, in addition to whatever effect it might have on adenylate cyclase. The inhibitory effect of vanadate on AVP stimulated water flow was not altered by prior Na-K-ATPase or prostaglandin inhibition. Since vanadate has been shown to stimulate adenylate cyclase in other tissues we examined whether addition of vanadate 10 minutes after addition of AVP would enhance water transport. Vanadate caused a transient enhancement of AVP stimulated water flow. These data demonstrate that vanadate can inhibit or stimulate water flow in the toad bladder.

Serosal Na/Ca exchange and H+ and Na+ transport by the turtle and toad bladders

A Na/Ca exchange system has been described in the plasma membrane of several tissues and seems to regulate the concentration of calcium in cytosol. Replacement of extracellular Na by sucrose increases calcium uptake into and decreases calcium efflux from the cell, leading to an increase in cytosolic calcium. The effect of an increase in cytosolic calcium mediated by the Na/Ca exchange system on H+ and Na transport in the turtle and toad bladder was investigated by replacing serosal Na isosmotically by sucrose or choline. Replacement of serosal by sucrose was associated with a significant inhibition of H+ secretion or Na transport which was reversible by addition of NaCl. Replacement of mucosal Na by sucrose failed to alter H+ secretion. Removal of serosal Na was associated with a significant increase in 45Ca uptake which could be blocked by pretreatment with lanthanum chloride. Pretreatment with lanthanum chloride blunted the inhibitory effect of replacement of serosal Na by sucrose on H+ and Na transport, thus suggesting that the increase in calcium uptake and the inhibition of transport are causally related. Under anaerobic conditions the rate of H+ or Na transport are linked to the rate of lactate production. The inhibition of Na or H+ transport by removal of serosal Na was accompanied by a proportional decrease in lactate production, thus suggesting that an increase in cytosolic calcium does not inhibit transport by uncoupling glycolysis from transport. Replacement of serosal Na by sucrose did not alter the force of the H+ or Na pump but led to an increase in resistance of the active pathway of H+ and Na transport. The inhibition of Na transport by replacement of serosal Na with sucrose could be reversed by addition of amphotericin B, an agent which increases luminal permeability to Na, thus suggesting that decreased Na entry across the apical membrane is the mechanism responsible for the inhibition of Na transport. The results of the present studies strongly suggest that an increase in cytosolic calcium through the serosal Na/Ca exchange system inhibits H+ and Na transport in the turtle and toad bladder probably by increasing the resistance of the luminal membrane.