Effect of pH on membrane potential and K+ conductance in cultured rat hepatocytes

We have investigated the effects of extracellular (pHo) and intracellular (pHi) pH on membrane potential difference (PD) and cell conductance (gcell) in rat hepatocytes in primary culture. PD and pHi were measured continuously by using intracellular microelectrodes and the pH-sensitive fluorochrome 2',7'-bis(2-carboxyethyl)-5(6)-carboxy fluorescein (BCECF), respectively, during abrupt changes in the pHo or ionic composition of extracellular perfusate. In the presence of 25 mM HCO3-, PD, gcell, and pHi averaged (+/- SE) -32 +/- 1 mV, 16.4 +/- 1.0 nS, and 7.32 +/- 0.01, respectively. The transference number for K+ (tk+), which reflects the fractional contribution of K+ conductance to gcell, averaged 0.36 +/- 0.03. Exposure to 1 mM Ba2+ produced membrane depolarization and decreased tK+ by approximately 90%. Lowering pHo by a variety of maneuvers in the presence and absence of HCO3- consistently decreased pHi, decreased gcell (approximately 30 nS per unit change in pHi), and depolarized PD. Increasing pHo had opposite effects, but the changes in gcell were generally greater with intracellular acidification than alkalinization. The decrease in PD produced by lowering pHo was associated with a decrease in tK+ of 73 +/- 2% and was inhibited by Ba2+. Exposure to butyrate or withdrawal of NH+4, which lowered pHi without changing pHo, also caused depolarization of PD and a decrease in gcell that was inhibited by Ba2+. These observations indicate that the PD of hepatocytes is strongly influenced by pHi, with or without changes in pHo, and they further suggest that the effects of pH on PD are mediated through changes in plasma membrane K+ conductance.

Hepatocellular bile acid transport and ursodeoxycholic acid hypercholeresis

This review focuses on mechanisms of bile acid transport across the basolateral and canalicular hepatocyte plasma membranes and on ursodeoxycholic acid (UDCA) hypercholeresis and biotransformation. Conjugated trihydroxy bile acids enter hepatocytes via a sodium-coupled mechanism localized to the basolateral membrane, which is saturable, concentrative, inhibited by other bile acids as well as by furosemide and bumetanide, and exhibits developmental changes in rats and probably also in humans. The stoichiometry of sodium-coupled bile acid uptake has been controversial. Hydrophobic, unconjugated dihydroxy and monohydroxy bile acids, including UDCA, enter hepatocytes more rapidly than does taurocholate, and their uptake is largely nonsaturable and sodium independent. A hydroxyl-exchange mechanism that mediates the uptake of cholic acid has also been reported, but its existence is controversial. Current evidence suggests that a 49-kDa protein mediates Na+-dependent taurocholate uptake and that a 54-kDa protein is involved in Na+-independent bile acid uptake. Studies with canalicular membrane vesicles have demonstrated saturable, sodium-independent taurocholate transport, which is sensitive to electrical potential, exhibits trans-stimulation, and appears to be mediated by a 100-kDa canalicular membrane glycoprotein. Studies in mutant rats with conjugated hyperbilirubinemia suggest the presence of a separate canalicular transport mechanism utilized by sulfated bile acids and organic anions such as bilirubin and sulfobromophthalein. UDCA produces in some species a dramatic hypercholeresis that is greater than expected based on the osmotic effect of the secreted bile acid. The hypercholeresis appears attributable to stimulation of biliary bicarbonate output and is decreased or abolished in the perfused rat liver by amiloride or perfusate Na+ substitution. These same maneuvers dramatically alter UDCA biotransformation (unconjugated UDCA disappears from bile, and UDCA glucuronide becomes a major metabolite) and lower hepatocyte intracellular pH. These and other findings indicate that UDCA hypercholeresis is tightly linked to biliary excretion of the unconjugated species and suggest that UDCA biotransformation may be influenced by intracellular pH.

Rat hepatocytes exhibit basolateral Na+/HCO3- cotransport

Primary cultures and plasma membrane vesicles were used to characterize Na+ and HCO3- transport by rat hepatocytes. Na+ uptake into hepatocytes was stimulated approximately 10-fold by 25 mM extracellular HCO3-.HCO3--stimulated Na+ uptake was saturable, abolished by 4-acetamido-4'-isothiocyano-2,2'-disulfonic acid stilbene (SITS), and unaffected by amiloride or Cl- removal. Neither propionate nor acetate reproduced this effect of HCO3-. 22Na efflux from preloaded hepatocytes was similarly increased approximately 10-fold by an in greater than out HCO3- concentration gradient. 22Na efflux was also increased by valinomycin and an in greater than out K+ concentration gradient in the presence but not absence of HCO3-. Intracellular pH (pHi) measured with the pH-sensitive fluorochrome 2',7'-bis-(2-carboxyethyl)-5-(and 6-)carboxyfluorescein (BCECF) decreased at a rate of 0.227 (+/- 0.074 SEM) pH units/min when extracellular HCO3- concentration was lowered from 25 to 5 mM at constant PCO2. This intracellular acidification rate was decreased 50-60% in the absence of Na+ or presence of SITS, and was unaffected by amiloride or Cl- removal. Membrane hyperpolarization produced by valinomycin and an in greater than out K+ concentration gradient caused pHi to fall; the rate of fall was decreased 50-70% by Na+ removal or SITS, but not amiloride. An inside positive K+ diffusion potential and a simultaneous out greater than in HCO3- gradient produced a transient 4,4'-diisothiocyano-2,2' disulfonic acid stilbene (DIDS) sensitive, amiloride-insensitive 22Na accumulation in basolateral but not canalicular membrane vesicles. Rat hepatocytes thus exhibit electrogenic basolateral Na+/HCO3- cotransport.

Electrophysiological evidence for Na+-coupled bicarbonate transport in cultured rat hepatocytes

Recent observations suggest that hepatocytes exhibit basolateral electrogenic Na+-coupled HCO3- transport. In these studies, we have further investigated this transport mechanism in primary culture of rat hepatocytes using intracellular microelectrodes to measure membrane potential difference (PD) and the pH-sensitive fluorochrome 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein to measure intracellular pH (pHi). In balanced media containing 25 mM HCO3-, PD averaged -32.1 +/- 0.6 (SE) mV and pHi averaged 7.22 +/- 0.03. PD became more negative (hyperpolarized) when extracellular [HCO3-] was increased and less negative (depolarized) when extracellular HCO3- was decreased. Acute replacement of extracellular Na+ by choline also resulted in membrane depolarization of 18.0 +/- 1.6 mV, suggesting net transfer of negative charge. This decrease in PD upon Na+ removal was HCO3- -dependent, amiloride insensitive, and inhibited by the disulfonic stilbene 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid (SITS). PD also decreased upon acute exposure to SITS. The degree of depolarization seen with removal of Na+ or HCO3- correlated directly with resting PD (r = 0.81 and 0.95, respectively), suggesting a voltage-dependent mechanism. Removal of extracellular Na+ also decreased pHi to 7.06 +/- 0.02, and this acidification was decreased in the absence of HCO3- or in the presence of SITS or amiloride. These studies provide direct evidence for electrogenic Na+-coupled HCO3- transport in rat hepatocytes. Further, they suggest that it represents a major pathway for conductive movement of Na+ across the membrane and that it contributes, along with Na+-H+ exchange, to the intracellular acidification observed upon removal of extracellular Na+.(ABSTRACT TRUNCATED AT 250 WORDS)

Hepatic oleate uptake. Electrochemical driving forces in intact rat liver

Recent observations suggest that the hepatic uptake of oleate may be sodium coupled. To assess the electrochemical forces driving fatty acid uptake, we used microelectrodes to monitor continuously the electrical potential difference across the plasma membrane in the perfused rat liver while simultaneously monitoring the rate of tracer [3H]oleate uptake from 1% albumin solutions. Isosmotic cation or anion substitution was used to vary the potential difference over the physiologic range. Depolarization of cells from -29 to -19 mV by substituting gluconate for chloride reduced steady-state oleate uptake by 34%. Conversely, hyperpolarization of cells to -52 mV by substituting nitrate for chloride increased uptake by 41%. Replacement of perfusate sodium with choline depolarized the cells to -18 mV and reduced uptake by 58%, an amount greater than expected from the degree of depolarization alone. Oleate in higher concentrations (1.5 mM in 2% albumin) depolarized cells by 3 mV in the presence of sodium, but had no effect in sodium-free buffer. These results suggest that a portion of oleate uptake in the intact liver occurs by electrogenic sodium cotransport. Uptake appears to be driven by both the electrical and sodium chemical gradients across the plasma membrane.

Na+-H+ exchange activity in rat hepatocytes: role in regulation of intracellular pH

Amiloride-sensitive Na+-H+ exchange has been identified in basolateral membrane vesicles from rat liver, but little is currently known about its regulation or its role in maintenance of resting intracellular pH (pHi) in intact hepatocytes. We have assessed Na+-H+ exchange activity in isolated or cultured rat hepatocytes in nominally HCO3- free solution under basal conditions and after intracellular acidification by an NH4Cl pulse by measuring 1) pHi, using the pH-sensitive dye 2',7'-bis(carboxyethyl)-5(6)-carboxy fluorescein, 2) net H+ efflux by pH-stat titration, and 3) amiloride-inhibitable 22Na uptake. Under resting conditions, Na+-H+ exchange did not contribute measurably to Na+ uptake and accounted for less than 20% of net H+ efflux. Hepatocyte pHi averaged 7.07 +/- 0.03, significantly above H+ electrochemical equilibrium (6.92 +/- 0.08) determined using an electrogenic proton ionophore. Transient removal of extracellular Na+ or exposure to amiloride reversibly lowered pHi by 0.09 +/- 0.01 and 0.12 +/- 0.03 pH units, respectively, within 5-10 min. After intracellular acidification by an NH4Cl pulse, Na+ uptake rate increased about twofold, the increase being entirely amiloride inhibitable. Net H+ efflux increased about threefold, and 70% of the increase was amiloride inhibitable. Recovery of pHi after an NH4Cl pulse was reversibly blocked by exposure to amiloride or removal of Na+. Na+-H+ exchange activity (calculated from the rate of change in pHi and intracellular buffering capacity) was inversely related to pHi and was estimated to approach zero at pHi 7.25-7.50.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of taurine on the isolated retinal pigment epithelium of the frog: electrophysiologic evidence for stimulation of an apical, electrogenic Na+-K+ pump

The apical surface of the retinal pigment epithelium (RPE) faces the neural retina whereas its basal surface faces the choroid. Taurine, which is necessary for normal vision, is released from the retina following light exposure and is actively transported from retina to choroid by the RPE. In these experiments, we have studied the effects of taurine on the electrical properties of the isolated RPE of the bullfrog, with a particular focus on the effects of taurine on the apical Na+-K+ pump. Acute exposure of the apical, but not basal, membrane of the RPE to taurine decreased the normally apical positive transepithelial potential (TEP). This TEP decrease was generated by a depolarization of the RPE apical membrane and did not occur when the apical bath contained sodium-free medium. With continued taurine exposure, the initial TEP decrease was sometimes followed by a recovery of the TEP toward baseline. This recovery was abolished by strophanthidin or ouabain, indicating involvement of the apical Na+-K+ pump. To further explore the effects of taurine on the Na+-K+ pump, barium was used to block apical K+ conductance and unmask a stimulation of the pump that is produced by increasing apical [K+]o. Under these conditions, increasing [K+]o hyperpolarized the apical membrane and increased TEP. Taurine reversibly doubled these responses, but did not change total epithelial resistance or the ratio of apical-to-basal membrane resistance, and ouabain abolished these responses. Collectively, these findings indicate the presence of an electrogenic Na+/taurine cotransport mechanism in the apical membrane of the bullfrog RPE. They also provide direct evidence that taurine produces a sodium-dependent increase in electrogenic pumping by the apical Na+-K+ pump.

Inhibition of Na+/H+ exchange in the rat is associated with decreased ursodeoxycholate hypercholeresis, decreased secretion of unconjugated urodeoxycholate, and increased ursodeoxycholate glucuronidation

In the perfused rat liver, ursodeoxycholate in high dose produces an HCO3- -rich hypercholeresis which we have shown previously to be inhibited by replacement of perfusate Na+ with Li+ or by addition of amiloride (or amiloride analogues). In the present studies, we have determined whether such inhibition is associated with altered ursodeoxycholate biotransformation. Under control conditions, ursodeoxycholate infusion produced a 3.7-fold increase in bile flow and a 9.2-fold increase in biliary HCO3- output. By thin-layer chromatography, ursodeoxycholate radioactivity in bile was present in unconjugated form (15%) or as glycine or taurine amidates. Glucuronide conjugates of ursodeoxycholate accounted for less than 1% of biliary bile acids. Li+/Na+ substitution decreased ursodeoxycholate-stimulated bile flow and HCO3- secretion by greater than 90%, but decreased recovery of ursodeoxycholate and metabolites by only 25%. Amiloride or amiloride analogues decreased ursodeoxycholate-stimulated choleresis and HCO3- output by 38%-76%, yet did not cause decreased recovery of ursodeoxycholate and metabolites. Inhibition of the hypercholeresis was associated with a decrease in unconjugated ursodeoxycholate to less than 2% of total biliary bile acids, a striking increase in ursodeoxycholate glucuronides, and a reciprocal decrease in glycine and taurine amidates. With Li+/Na+ substitution, the predominant metabolites were a mixture of the 24-ester and the 3-aketal (ethereal) glucuronide (29%), and amidation with glycine appeared to be selectively inhibited; with amiloride or its analogues, only the 3-ethereal glucuronide was formed (20%-60% of biliary bile acids), and both taurine and glycine amidation were inhibited. Thus, maneuvers that decrease Na+/H+ exchange inhibit ursodeoxycholate hypercholeresis and cause replacement of unconjugated ursodeoxycholate in bile by its glucuronide. The secretion of unconjugated ursodeoxycholate, a lipophilic bile acid, appears to be necessary for hypercholeresis induced by high-dose ursodeoxycholate infusion.

Amiloride and amiloride analogs inhibit Na+/K+-transporting ATPase and Na+-coupled alanine transport in rat hepatocytes

Amiloride, a commonly used inhibitor of Na+-H+ exchange, has been shown to exhibit a variety of nonspecific effects. Recently, the more potent amiloride analogs, 5-(N,N-dimethyl)amiloride hydrochloride (DMA) and 5-(N-ethyl-N-isopropyl)amiloride (EIA), have been used to control for the nonspecific effects of the parent compound. In the present study, we have explored the effects of these analogs on Na+/K+-transporting ATPase (Na+/K+-ATPase) and Na+-coupled alanine transport in primary rat hepatocyte cultures and rat liver plasma membranes, and we have compared the effects of these analogs with the effects of amiloride and ouabain. Amiloride, DMA, and EIA increased steady-state Na+ content and inhibited ouabain-sensitive 86Rb+ uptake in a reversible, concentration-dependent, ouabain-like manner, with estimated 50% inhibitory concentrations (IC50) of 3.0.10(-3) M, 5.2.10(-4) M, and 1.2.10(-4) M, respectively. Amiloride, DMA and EIA also inhibited ouabain-sensitive ATP hydrolysis in rat liver plasma membranes with similar potency (IC50 values of 2.2.10(-3) M, 2.2.10(-3) M, and 1.7.10(-4) M, respectively). In separate experiments, amiloride (5.10(-3) M), DMA (10(-3) M), and EIA (2.5.10(-4) M) decreased the uptake into hepatocytes of alanine by 20%, 61%, and 59%, respectively, and further studies with DMA (10(-3) M) demonstrated that this inhibition was largely due to a decrease in the Na+-dependent fraction of alanine uptake. These findings indicate that amiloride, DMA, and EIA inhibit hepatic Na+/K+-ATPase directly, reversibly, and with a relative rank order potency of EIA greater than DMA greater than amiloride. All three compounds also inhibit the hepatic uptake of alanine, and presumably could indirectly inhibit other Na+-coupled transport processes as well.

Ursodeoxycholic acid choleresis: relationship to biliary HCO-3 and effects of Na+-H+ exchange inhibitors

We have recently shown that substitution of Li+ for perfusate Na+ eliminates the HCO3(-)-rich choleresis produced by ursodeoxycholic acid (UDCA) in isolated perfused rat liver and that the increase in bile flow produced by both UDCA and taurocholic acid is partially inhibited by 1 mM amiloride. Although these findings are consistent with a role for Na+-H+ exchange in the choleresis produced by these bile acids, both Li+ substitution and amiloride affect other cellular processes, including Na+-K+-ATPase activity. We have now further explored both the relationship between UDCA-stimulated bile flow and biliary HCO3- secretion and the possible role of Na+-H+ exchange in this process by comparing the effects of amiloride with two of its more potent and presumably more specific analogues, 5-(N,N-dimethyl)amiloride hydrochloride (DMA) and 5-(N-ethyl-N-isopropyl)amiloride (EIA). In the absence of inhibitor, UDCA increased biliary HCO3- concentration ([HCO3-]) up to an apparent maximum of 60-70 mM, and bile flow and biliary HCO3- output appeared to be linearly related over a sixfold range of bile flow rates. Amiloride, DMA, and EIA each produced a concentration-dependent inhibition of UDCA-stimulated bile flow and biliary HCO3- output with an apparent rank order potency (EIA greater than DMA greater than amiloride) similar to that reported for inhibition of Na+-H+ exchange in other systems. None of the inhibitors significantly altered biliary UDCA output or the relationship between UDCA-induced bile flow and either biliary [HCO3-] or biliary HCO3- output. Effects of these inhibitors did not appear attributable either to nonspecific toxicity, as reflected by hepatic release of lactate dehydrogenase or K+, or to inhibition of hepatic Na+-K+-ATPase, measured as Na+-dependent uptake of 86Rb. In contrast to their effects on UDCA choleresis, these inhibitors had little or no effect on basal bile flow, biliary [HCO3-], and biliary HCO3- output. These findings indicate that UDCA-induced but not basal bile formation is closely coupled to biliary HCO3- concentration and output, and they provide additional evidence that UDCA choleresis requires an intact Na+-H+ exchange mechanism.

Effects of chlorpromazine on Na+-K+-ATPase pumping and solute transport in rat hepatocytes

Inhibition of Na+-K+-ATPase and sodium-dependent bile acid transport has been suggested as a mechanism for the cholestasis produced by certain drugs such as chlorpromazine. We examined the effects of chlorpromazine (and in selected studies, two of its metabolites) on Na+-K+-ATPase cation pumping (ouabain-suppressible 86Rb uptake), exchangeable intracellular sodium content, membrane potential (assessed by 36Cl- distribution), and sodium-dependent transport of taurocholate and alanine in primary cultures of rat hepatocytes. Chlorpromazine (10-300 microM), 7,8-dihydroxychlorpromazine (10-300 microM), and ouabain (0.1-2 mM), but not chlorpromazine sulfoxide, produced a concentration-dependent decrease in Na+-K+-ATPase cation pumping and an increase in intracellular sodium content. Chlorpromazine (100 microM) and ouabain (0.75 mM) also modestly decreased hepatocyte membrane potential. In further studies, chlorpromazine (75 and 100 microM) and ouabain (0.1, 0.5, and 0.75 mM) decreased initial sodium-dependent uptake rates of taurocholate and alanine by 18-63%. Although the steady-state intracellular content of alanine was decreased 25-53% by both agents, chlorpromazine increased the steady-state content of taurocholate by 171% and decreased taurocholate efflux, apparently related to partitioning of taurocholate into a large, slowly turning over intracellular pool. These studies provide direct evidence that chlorpromazine inhibits Na+-K+-ATPase cation pumping in intact cells and that partial inhibition of Na+-K+-ATPase cation pumping is associated with a reduction of both the electrochemical sodium gradient and sodium-dependent solute transport. These effects of chlorpromazine may contribute to chlorpromazine-induced cholestasis in animals and humans.

Intracellular chloride activity in intact rat liver: relationship to membrane potential and bile flow

Active chloride transport has been described in a variety of epithelia, and intracellular chloride activity (aiCl) in these tissues is generally elevated twofold or more above the level predicted for passive diffusion. To determine whether active chloride transport might contribute to canalicular bile formation, we have used conventional and Cl- -selective microelectrodes to measure aiCl of rat hepatocytes in vivo under a variety of conditions. Under basal conditions, the membrane potential difference averaged -33.2 +/- 3.5 mV (means +/- SD) in 29 animals, and the ratio (R) of observed aiCl (24.8 mM) to that expected for passive distribution at this membrane potential (22.6 mM) was 1.10 +/- 0.08, a value slightly but significantly greater than that predicted for passive distribution. Infusion of alanine (45-mumol bolus, 10.8-mumol/min infusion) in 5 animals hyperpolarized the membrane potential to -43.6 +/- 4.0 mV over 10-15 min and resulted in a significant fall in aiCl to 15.1 +/- 4.8 mM but with no change in R. Infusion of theophylline (577 nmol/min), taurocholate (3-mumol bolus, 810-nmol/min infusion), and ursodeoxycholic acid (4-mumol bolus, 2.13-mumol/min infusion) into 5 animals each increased bile flow by 6.1, 34.1, and 96.8%, respectively, compared with saline-infused controls but did not alter membrane potential or chloride distribution. These observations indicate that aiCl is close to the level predicted for passive distribution under basal conditions, after hyperpolarization of the membrane potential by alanine, and after stimulation of bile flow by a variety of choleretics. By analogy with Cl- -secreting epithelia, it appears unlikely that active chloride transport across the basolateral membrane contributes significantly to canalicular bile formation by the hepatocyte.

Acidic vesicles in cultured rat hepatocytes. Identification and characterization of their relationship to lysosomes and other storage vesicles

We and others recently have demonstrated adenosine triphosphate-dependent acidification in a variety of prelysosomal organelles isolated from liver including clathrin-coated vesicles, multivesicular bodies, and Golgi. Little is known, however, regarding the number or distribution of acidic compartments in intact hepatocytes. We therefore have utilized acridine orange, a fluorescent weak base, to study the number and distribution of acidic vesicles of rat hepatocytes in primary culture and compared these with the number and distribution of lysosomes and other storage vesicles. Hepatocytes were found to contain about 170 acidic compartments per cell by fluorescence microscopy. These vesicles were diffusely distributed throughout the cell cytoplasm, with about 50% in the perinuclear area by modified morphometry. The acridine orange staining of these vesicles was reversibly dissipated by monensin, NH4Cl, chloroquine, and primaquine, indicating these vesicles exhibit an acidic interior established by active proton transport. In addition, the cholestatic agent chlorpromazine reversibly inhibited, in a dose-dependent fashion, the redevelopment of a pH gradient in the acidic vesicles after dissipation by monensin. The number and distribution of these acidic vesicles were not significantly different from the number and distribution of vesicles involved in the storage (up to 6 h after internalization) of the fluid phase marker fluorescein-dextran. By contrast, histochemically identifiable lysosomes were fewer in number and significantly more restricted in their distribution to the perinuclear area (89%) than either dextran-storing or acidic vesicles. Electron microscopic studies confirmed that endocytosed dextran as well as another fluid phase marker, colloidal gold, were found predominantly in acid phosphatase- and arylsulfatase-negative vesicles for up to 6 h after internalization. These studies indicate that hepatocytes contain numerous intracellular vesicles acidified by an active H+ transport mechanism. Based on their comparative number and distribution, acidic vesicles probably include vesicles involved in fluid-phase endocytosis but only a minority are lysosomes. The findings also indicate that fluid-phase markers are stored predominantly in vesicles other than histochemically identifiable lysosomes for up to 6 h after internalization. Finally, this technique also affords the opportunity for studying the movement of such vesicles in a vital preparation.

Proton transport by hepatocyte organelles and isolated membrane vesicles

It is apparent that proton transport plays an important role in many essential hepatocyte functions. Important unanswered issues include the location of the H+-ATPase and its role in hepatic functions, the regulators of Na+-H+ exchange, the exact role of Na+-H+ exchange in bile formation and in hepatic regeneration, and the role of bile acids such as UDCA and nor-UDCA in mediating transepithelial proton transport.

Effects of Na+ replacement and amiloride on ursodeoxycholic acid-stimulated choleresis and biliary bicarbonate secretion

In these studies, we have tested the hypothesis that bile acid-dependent bile formation is attributable, in part, to the stimulation of active bicarbonate secretion and have further explored the cellular mechanism(s) possibly involved in this process using the isolated perfused rat liver. Under control conditions, ursodeoxycholic acid (UDCA) infusion (3 mumol/min X 20 min) produced a 3.7-fold increase in bile flow and a 7.4-fold increase in HCO3- output. Amiloride (an inhibitor of Na+-H+ exchange) decreased UDCA-stimulated bile flow by 20.6% and decreased biliary HCO3- output by 24.9% but increased biliary UDCA output by 42.9%. Thus amiloride decreased UDCA choleretic efficiency (microliter UDCA-stimulated bile/mumol UDCA output) by 45% and UDCA-stimulated increase in HCO3- output per unit UDCA secreted by 48%. Substitution of Li+ for Na+ in perfusate virtually abolished (greater than 95% decrease) both the UDCA choleresis and increase in biliary HCO3- output but modestly decreased (39.6%) biliary bile acid output. Li+ substitution thus decreased UDCA choleretic efficiency by 98% and the UDCA-stimulated increase in HCO3- output by 96%. Amiloride had no effect and Li+ substitution produced a modest decrease in basal bile flow (26.0%) and HCO-3 output (33.5%). Neither amiloride nor Li+ substitution significantly affected UDCA uptake by cultured hepatocytes or by perfused liver. Amiloride (1 mM) also decreased taurocholate (TC)-stimulated choleresis by 48.5%, biliary TC output by 7.2%, and the choleretic efficiency of TC by 45%.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of transmembrane electrical potential gradient in rat hepatocytes in situ

The transmembrane electrical potential gradient (Em) has been measured in hepatocytes from intact anesthetized rats using conventional intracellular microelectrodes under a variety of conditions. Em measurements in control animals were normally distributed around a mean of -35.5 +/- 4.6 mV (SD) with a coefficient of variation (CV) of 13.1% and a range of -26 to -54 mV. In individual livers, however, measurements of Em at a given point in time exhibited little cell-to-cell variation (cv of 4.5%). The Em was noted to fluctuate spontaneously over time and to change consistently in response to a variety of physiological stimuli including fasting (depolarization to -28.5 +/- 3.8 mV) and infusion of glucagon in physiological amounts (hyperpolarization to -45.0 +/- 1.8 mV). Hepatocyte Em abruptly depolarized (2-5 mV) after an intravenous bolus of taurocholate (3 mumol) or alanine (45 mumol), suggesting that both solutes exhibit electrogenic uptake. The Em returned to or below preinfusion values within 5 min. Continued infusion of alanine (10.8 mumol/min), but not taurocholate (810 nmol/min), caused a sustained and unexpected hyperpolarization of Em of 8.2 +/- 3.1 mV that lasted at least 60 min. In separate studies, alanine administration did not alter the biliary excretion of a taurocholate load. Taken together, these observations demonstrate that rat hepatocytes in situ are tightly coupled electrically and that physiological stimuli, including fasting, glucagon, and sodium-coupled solute uptake can change Em considerably over time. The late hyperpolarization of Em caused by alanine appears to offset the rise in intracellular Na+ associated with alanine uptake and preserve the Na+ electrochemical gradient such that Na+-coupled taurocholate transport is maintained.

Fluid phase endocytosis by cultured rat hepatocytes and perfused rat liver: implications for plasma membrane turnover and vesicular trafficking of fluid phase markers

Hepatocytes take up a variety of ligands via receptor-mediated endocytosis, yet little is known regarding either the volume of fluid or the amount of membrane internalized via endocytosis in liver cells. In these studies, we have utilized radiolabeled inulin to characterize fluid phase endocytosis by rat hepatocytes in primary culture and perfused rat liver. Uptake of inulin by cultured hepatocytes was nonlinear with time, occurring most rapidly during the first 2 min. Inulin uptake and efflux in cultured hepatocytes and inulin uptake by perfused rat liver were kinetically compatible with the entry of inulin into a rapidly (t1/2, 1-2 min) turning-over (presumably endosomal) compartment that exchanged contents with the extracellular space and comprised approximately 3% of hepatocyte volume, as well as entry into and concentration of inulin within slowly (t1/2, greater than 1 hr) turning-over storage compartments. Based on inulin uptake, it is estimated that cultured hepatocytes endocytosed the equivalent of 20% or more of their volume and 5 or more times their plasma membrane surface area each hour. Neither chloroquine (1 mM) nor taurocholate (200 microM) affected inulin handling by cultured cells, whereas colchicine (10 microM) inhibited transfer to storage compartments by greater than 50%. In conjunction with our previous observations, the present findings suggest that inulin endocytosed across the basolateral membrane is largely (congruent to 80%) regurgitated back into plasma, with smaller amounts transported to intracellular storage compartments (congruent to 18%) or to bile (congruent to 2%). Transport of inulin via these pathways is unaffected by taurocholate and does not require vesicle acidification, whereas intact microtubular function is required for transfer to storage compartments or biliary secretion.

Rat pancreatic zymogen granules. An actively acidified compartment

In this study, we looked for acidification in pancreatic zymogen granules as recently reported for other secretory vesicles. In intact dispersed acinar cells, acidic intracellular compartments identified by fluorescence microscopy using acridine orange corresponded exactly to the distribution of zymogen granules visualized by light microscopy. Acridine orange fluorescence in zymogen granules was reversibly dissipated by protonophores (carbonyl cyanide m-chlorophenylhydrazone, monensin) and NH4Cl; and the percentages of cytoplasmic area occupied by the acidic compartments and by zymogen granules were identical under fasting conditions and decreased in parallel after in vivo cholinergic stimulation. Zymogen granules released acutely from hypotonically disrupted cells without homogenization also accumulated acridine orange. Red-orange fluorescence in released granules was also abolished by protonophores and NH4Cl; and it reappeared after washout of protonophores in the presence, but not absence of adenosine triphosphate. Dicyclohexylcarbodiimide, which inhibits all proton pumps, and N-ethylmaleimide, which inhibits the proton pump of endocytic vesicles and lysosomes, but not mitochondria, prevented this adenosine triphosphate-dependent reappearance of acridine orange fluorescence, whereas vanadate did not. In contrast to these observations with zymogen granules in situ or acutely released from disrupted cells, granules isolated by conventional multistep homogenization/centrifugation procedures did not exhibit adenosine triphosphate-dependent acidification or development of a positive membrane potential as measured by quenching of acridine orange or Oxonol V, respectively. The latter findings may indicate release of inhibitors or granule damage during isolation. Collectively, the present results provide direct evidence that zymogen granules contain an active acidification mechanism which appears similar to that of other secretory vesicles and endosomes. This acidification process may have important implications for the storage, stabilization, and secretion of intragranular proteins including proenzymes.

Identification and characterization of ATP-dependent proton transport by rat liver multivesicular bodies

Multivesicular bodies (MVB), prelysosomal organelles in the endocytic pathway, were prepared from estrogen-treated rat livers and examined for the presence of ATP-dependent proton transport. Vesicle acidification, assessed by acridine orange fluorescence quenching, was ATP dependent (ATP much greater than GTP, UTP), was enriched 25-fold over homogenate, was abolished by pretreatment with protonophores or a nonionic detergent, exhibited a pH optimum of 7.5, was inhibited by N-ethylmaleimide (NEM) (IC50 approximately 5 microM) and N,N'-dicyclohexylcarbodiimide (IC50 approximately 5 microM), and was resistant to inhibition by vanadate, ouabain, and oligomycin. Acidification exhibited no specific cation requirement; however, maximal rates of acidification depended upon the presence of Cl- (Km approximately 20 mM). Other anions were less effective in supporting acidification (Cl- greater than Br- greater than much greater than gluconate, NO-3, SO2-4, and mannitol), and indeed NO-3 inhibited acidification even in the presence of 150 mM Cl-. The proton transport mechanism appeared to be electrogenic based on: (a) enhancement of acidification by valinomycin in the presence of K gluconate, and (b) ATP-dependent fluorescence quenching of bis(3-phenyl-5-oxoisoxasol-4-yl)pentamethine oxonol, a membrane potential-sensitive anionic dye. Furthermore, the magnitude of the pH and electrical gradients generated by the proton transport mechanism appeared to vary inversely in the presence and absence of Cl-. Finally, MVB exhibited ATPase activity that was resistant to ouabain and oligomycin, but was inhibited 32.3% by 1 mM NEM, 33.7% by 200 microM dicyclohexylcarbodiimide, and 18.7% by KNO3. In isolated MVB, therefore, the NEM-sensitive ATPase activity may represent the enzymatic equivalent of a proton pump. These studies identify and characterize an ATP-dependent electrogenic proton transport process in rat liver MVB which shares many of the properties of the proton pump described in clathrin-coated vesicles, endosomes, lysosomes, Golgi, and endoplasmic reticulum from liver and other tissues. Acidification of MVB differed somewhat from that of rat liver clathrin-coated vesicles in response to Br- and NO-3, suggesting that membrane properties of these two organelles might differ.

Biliary secretion of fluid-phase markers by the isolated perfused rat liver. Role of transcellular vesicular transport

In these studies, we have used several approaches to systematically explore the contribution of transcellular vesicular transport (transcytosis) to the blood-to-bile movement of inert fluid-phase markers of widely varying molecular weight. First, under steady-state conditions, the perfused rat liver secreted even large markers in appreciable amounts. The bile-to-plasma (B/P) ratio of these different markers, including microperoxidase (B/P ratio = 0.06; mol wt = 1,879), insulin (B/P ratio = 0.09, mol wt = 5,000), horseradish peroxidase (B/P ratio = 0.04, mol wt = 40,000), and dextran (B/P ratio = 0.09, mol wt = 70,000), exhibited no clear ordering based on size alone, and when dextrans of two different sizes (40,000 and 70,000 mol wt) were studied simultaneously, the relative amounts of the two dextran species in bile were the same as in perfusate. Taurocholate administration produced a 71% increase in bile flow but little or no (0-20%) increase in the output of horseradish peroxidase, microperoxidase, inulin, and dextran. Second, under nonsteady-state conditions in which the appearance in or disappearance from bile of selected markers was studied after their abrupt addition to or removal from perfusate, erythritol reached a B/P ratio of 1 within 2 min. Microperoxidase and dextran appeared in bile only after a lag period of approximately 12 min and then slowly approached maximal values, whereas sucrose exhibited kinetically intermediate behavior. A similar pattern was observed after removal of greater than 95% of the marker from the perfusate. Erythritol rapidly reapproached a B/P ratio of 1, whereas the B/P ratio for sucrose, dextran, and microperoxidase fell much more slowly and exceeded 1 for a full 30 min after perfusate washout. Finally, electron microscopy and fluorescence microscopy of cultured hepatocytes demonstrated the presence of horseradish peroxidase and fluorescein-dextran, respectively, in intracellular vesicles, and fractionation of perfused liver homogenates revealed that at least 35-50% of sucrose, inulin, and dextran was associated with subcellular organelles. Collectively, these observations are most compatible with a transcytosis pathway that contributes minimally to the secretion of erythritol, but accounts for a substantial fraction of sucrose secretion and virtually all (greater than 95%) of the blood-to-bile transport of microperoxidase and larger markers. These findings have important implications with respect to current concepts of canalicular bile formation as well as with respect to the conventional use of solutes such as sucrose as markers of canalicular or paracellular pathway permeability.

ATP-dependent proton transport by isolated brain clathrin-coated vesicles. Role of clathrin and other determinants of acidification

We have systematically investigated certain characteristics of the ATP-dependent proton transport mechanism of bovine brain clathrin-coated vesicles. H+ transport specific activity was shown by column chromatograpy to co-purify with coated vesicles, however, the clathrin coat is not required for vesicle acidification as H+ transport was not altered by prior removal of the clathrin coat. Acidification of the vesicle interior, measured by fluorescence quenching of acridine orange, displayed considerable anion selectively (Cl- greater than Br- much greater than NO3- much greater than gluconate, SO2-(4), HPO2-(4), mannitol; Km for Cl- congruent to 15 mM), but was relatively insensitive to cation replacement as long as Cl- was present. Acidification was unaffected by ouabain or vanadate but was inhibited by N-ethylmaleimide (IC50 less than 10 microM), dicyclohexylcarbodiimide (DCCD) (IC50 congruent to 10 microM), chlorpromazine (IC50 congruent to 15 microM), and oligomycin (IC50 congruent to 3 microM). In contrast to N-ethylmaleimide, chlorpromazine rapidly dissipated preformed pH gradients. Valinomycin stimulated H+ transport in the presence of potassium salts (gluconate much greater than NO3- greater than Cl-), and the membrane-potential-sensitive dye Oxonol V demonstrated an ATP-dependent interior-positive vesicle membrane potential which was greater in the absence of permeant anions (mannitol greater than potassium gluconate greater than KCl) and was abolished by N-ethylmaleimide, protonophores or detergent. Total vesicle-associated ouabain-insensitive ATPase activity was inhibited 64% by 1 mM N-ethylmaleimide, and correlated poorly with H+ transport, however N-ethylmaleimide-sensitive ATPase activity correlated well with proton transport (r = 0.95) in the presence of various Cl- salts and KNO3. Finally, vesicles prepared from bovine brain synaptic membranes exhibited H+ transport activity similar to that of the coated vesicles.(ABSTRACT TRUNCATED AT 400 WORDS)

Characterization of the ouabain-insensitive ATPase activity of rat liver plasma membranes

Very little is currently known about the ouabain-insensitive ATPase activity of the liver plasma membrane; we have therefore characterized it in plasma membranes from rat liver prepared using two different isolation techniques. Greater than 85% of ATPase activity in both preparations was ouabain-insensitive. Based on the effects of multiple inhibitors, including dicyclohexylcarbodiimide (DCCD), N-ethylmaleimide (NEM), vanadate, and oligomycin, the ouabain-insensitive ATPase activity of rat liver plasma membranes consists of a family of ATP-hydrolysing enzymes. Ouabain-insensitive ATPase activity was stimulated by HCO3-in both plasma membranes (13%) and mitochondria (69%) over the range of 7.5 to 9.0, and HCO3--stimulation was similarly inhibited by oligomycin in both preparations. A fraction of the ouabain-insensitive ATPase of liver plasma membranes is inhibited by DCCD and is resistent to inhibition by oligomycin; these characteristics are similar to those of the non-mitochondrial H+-ATPases recently described in lysosomes, endosomes, clathrin-coated vesicles, and Golgi from liver and other cell types.