Role of Na,K-ATPase in regulating acidification of early rat liver endocytic vesicles.

Endocytic vesicles are acidified by an electrogenic proton pump and a parallel chloride conductance; however, acidification might be decreased if electrogenic transporters, such as Na,K-ATPase, that increase vesicle interior-positive membrane potential were also present. We examined this issue in early rat liver endosomes using ion substitution and inhibitors to alter Na,K-ATPase activity. These early endosomes, labeled for 2 min with the fluorescent fluid-phase marker fluorescein isothiocyanate-dextran, consistently acidified faster than endosomes similarly labeled for a 10-min period. In chloride-free media initial rates of acidification of early endosomes were faster in K+ media than in Na+ medium, although addition of K+ to Na+ or Na+ to K+ media to allow Na,K-ATPase to function did not decrease the rate of acidification. In chloride-containing media, rates were the same regardless of cation composition. The Na,K-ATPase inhibitor vanadate was prepared from orthovanadate by several methods, all of which inhibited liver ATPase activity. Two hundred mumol/L vanadate, prepared Cl(-)-free, tended to decrease rates of acidification in all media tested and these effects achieved statistical significance in Cl(-)-free media containing 150 mmol/L K+ or mixtures of Na+ and K+ and in 145 mmol/L KCl/5 mmol/L NaCl medium. Vanadate stocks pH-adjusted with hydrogen chloride increased rates of acidification in sodium gluconate buffers, probably as a result of the effects of the included Cl-. Five mmol/L ouabain (loaded into vesicles by endocytosis) and the membrane-permeable analog strophanthidin (2 mmol/L) both markedly inhibited endosome acidification, regardless of buffer ion composition. Collectively, these results suggest that Na,K-ATPase does not regulate acidification of rat liver early endocytic vesicles, that vanadate may modestly inhibit endosome acidification and that ouabain at high concentrations may inhibit acidification from the vesicle interior face.

Ethinyl estradiol decreases acidification of rat liver endocytic vesicles.

Treatment with ethinyl estradiol is known to impair bile formation, bile acid transport and Na,K-ATPase activity, to alter receptor-mediated endocytosis and transcytosis of IgA and asialoorosomucoid and to affect membrane lipid composition and fluidity. Because appropriate sorting and trafficking of asialoorosomucoid requires adequate acidification of endocytic vesicles by a lipid-sensitive electrogenic proton pump, we examined the effects of 5 days of treatment with ethinyl estradiol (5 mg/kg body wt, subcutaneously) on acidification of early endosomes prepared from male rat livers. Littermate control animals received equal volumes of the solvent propylene glycol. Pretreatment with ethinyl estradiol reduced ATP-dependent initial rates of endosome acidification by 11% to 25% when measured in potassium medium containing 0 to 140 mmol/L chloride; these differences were significant at four of six chloride concentrations tested. The proton pumps of ethinyl estradiol and propylene glycol endosomes exhibited similar Michaelis-Menten constants for MgATP (Michaelis-Menten constant of 63 and 66 mumol/L in the absence of chloride and 101 and 126 mumol/L in the presence of chloride, respectively). Acidification of ethinyl estradiol and propylene glycol endosomes changed in the same manner when various cations or anions were substituted for potassium gluconate, although the effects of ethinyl estradiol were less marked in the absence of K+. Kinetics of inhibition for ethinyl estradiol and propylene glycol endosomes were similar for the proton pump inhibitors N-ethylmaleimide (50% inhibitory concentrations of 13.5 and 18.1 mumol/L), dicyclohexylcarbodiimide (50% inhibitory concentrations of 206 and 216 mumol/L) and bafilomycin A (50% inhibitory concentrations of 11 and 6 nmol/L). Although initial rates of acidification were slower in ethinyl estradiol endosomes, ATP-dependent steady-state vesicle interior pH was the same as that of propylene glycol endosomes over a range of chloride concentrations; this appeared to be due mainly to a trend toward decreased proton leak rates in ethinyl estradiol endosomes. Overall, ethinyl estradiol treatment modestly decreased initial rates of acidification and vesicle proton leakage, perhaps because of changes in endosome lipid composition; differences in the number, density or activation state of proton pumps; or differences in endosome geometry. Because the decrease in acidification rates was small, the effects of estrogen on the efficiency of uncoupling of endocytosed ligands such as asialoorosomucoid from their receptors in early endosomes; thus the rates of sorting and distribution of ligands remain unclear.

Role of CFTR in lysosome acidification.

The role of CFTR in lysosome acidification was examined in CFPAC-1 pancreatic adenocarcinoma cells with the delta F508 mutation that were transduced with a retroviral vector (PLJ-CFPAC) or with the normal CFTR gene (CFTR-CFPAC). Steady-state lysosomal pHi in intact cells was lower in PLJ-CFPAC cells than CFTR-CFPAC cells (3.55 vs 3.80) and was not affected by cAMP or forskolin. Initial rates of ATP-dependent acidification of isolated lysosomes and steady-state ATP-dependent pHi were similar in both cell lines over a range of chloride concentrations and were not altered when cells were exposed to cAMP or to forskolin prior to preparation of lysosomes. These observations suggest that CFTR plays no role in acidification of lysosomes, possibly due to limited permeability of lysosomal membranes to chloride.

cAMP and protein kinase A stimulate acidification of rat liver endosomes in the absence of chloride.

Endosomes and lysosomes are acidified by an electrogenic proton pump in parallel with a chloride conductance and in kidney both of these may be regulated by cAMP. In vitro exposure of isolated rat liver endosomes to cAMP, PKA and GTP-gamma S stimulated acidification of "early" endosomes with or without C1-, but not in the absence of K+. cAMP and PKA also increased acidification rates of purified "late" endosomes, multivesicular bodies, CURL vesicles and lysosomes. "Early" endosomes prepared from livers perfused with cAMP also exhibited increased rates of acidification. cAMP and PKA had no consistent effects on steady-state intravesicular pH or proton efflux rates. Thus, acidification of several types of liver endocytic vesicles was stimulated by cAMP and PKA in the presence and absence of chloride, possibly due to changes in the proton pump itself and/or a cation conductance.

CFTR does not alter acidification of L cell endosomes.

Endosomes from L cells, transduced with the CFTR gene, and the parental line, which does not express detectable levels of CFTR, were loaded with FITC-dextran, isolated and the initial rates of acidification, steady-state pHi, and proton leak rates were compared over a range of chloride concentrations (0-140 mM). Values for these parameters were similar for endosomes from both cell lines in the presence and absence of cAMP and PKA. These results indicate that CFTR does not alter L cell endosome acidification, possibly due to an adequate intrinsic CI- conductance or to a failure to incorporate sufficient functional CFTR or a necessary co-factor in endocytic membranes.