Radiation inactivation studies of hepatic sinusoidal reduced glutathione transport system.

Sinusoidal transport of reduced glutathione (GSH) is a carrier-mediated process. Perfused liver and isolated hepatocyte models revealed a low-affinity transporter with sigmoidal kinetics (K(m) approximately 3.2-12 mM), while studies with sinusoidal membrane vesicles (SMV) revealed a high-affinity unit (K(m) approximately 0.34 mM) besides a low-affinity one (K(m) approximately 3.5-7 mM). However, in SMV, both the high- and low-affinity units manifested Michaelis-Menten kinetics of GSH transport. We have now established the sigmoidicity of the low-affinity unit (K(m) approximately 9) in SMV, consistent with other models, while the high-affinity unit has been retained intact with Michaelis-Menten kinetics (K(m) approximately 0.13 mM). We capitalized on the negligible cross-contributions of the two units to total transport at the low and high ends of GSH concentrations and investigated their characteristics separately, using radiation inactivation, as we did in canalicular GSH transport (Am. J. Physiol. 274 (1998) G923-G930). We studied the functional sizes of the proteins that mediate high- and low-affinity GSH transport in SMV by inactivation of transport at low (trace and 0.02 mM) and high (25 and 50 mM) concentrations of GSH. The low-affinity unit in SMV was much less affected by radiation than in canalicular membrane vesicles (CMV). The target size of the low-affinity sinusoidal GSH transporter appeared to be considerably smaller than both the canalicular low- and high-affinity transporters. The high-affinity unit in SMV was markedly inactivated upon irradiation, revealing a single protein structure with a functional size of approximately 70 kDa. This size is indistinguishable from that of the high-affinity GSH transporter in CMV reported earlier.

Novel properties of hepatic canalicular reduced glutathione transport revealed by radiation inactivation.

Transport of GSH at the canalicular pole of hepatocytes occurs by a facilitative carrier and can account for approximately 50% of total hepatocyte GSH efflux. A low-affinity unit with sigmoidal kinetics accounts for 90% of canalicular transport at physiological GSH concentrations. A low-capacity transporter with high affinity for GSH has also been reported. It is not known whether the same or different proteins mediate low- and high-affinity GSH transport, although they do differ in inhibitor specificity. The bile of rats with a mutation in the canalicular multispecific organic anion transporter (cMOAT or MRP-2, a 170-kDa protein) is deficient in GSH, implying that cMOAT may transport GSH. However, transport of GSH in canalicular membrane vesicles (CMV) from these mutant rats remains intact. We examined the functional size of the two kinetic components of GSH transport by radiation inactivation of GSH uptake in rat hepatic CMV. High-affinity transport of GSH was inactivated as a single exponential function of radiation dose, yielding a functional size of approximately 70 kDa. In contrast, low-affinity canalicular GSH transport exhibited a complex biexponential response to irradiation, characterized by an initial increase followed by a decrease in GSH transport. Inactivation analysis yielded a approximately 76-kDa size for the low-affinity transporter. The complex inactivation indicated that the low-affinity transporter is associated with a larger protein of approximately 141 kDa, which masked approximately 80% of the potential transport activity in CMV. Additional studies, using inactivation of leukotriene C4 transport, yielded a functional size of approximately 302 kDa for cMOAT, indicating that it functions as a dimer.

Role of the liver in interorgan homeostasis of glutathione and cyst(e)ine.

The most widely recognized function of reduced glutathione (GSH) is its defense against toxic compounds, whether exogenous, such as electophilic xenobiotics, or endogenous, such as reactive oxygen species, generated during normal oxidative metabolism and/or stress. However another no less significant role of GSH-namely its function as a reservoir and vehicle for packaging and transport of cyst(e)ine-has been receiving increasing attention. Because GSH is relatively more auto-oxidation resistant and stable than cyst(e)ine (CYSH), it serves as the preferred form for storage and transport of the latter especially in the extracellular and relatively much less reduced (than intracellular) milieu, where CYSH oxidizes to cystine (CYSS) rapidly. Over the past two decades, significant work has been going on to delineate the intra- and extrahepatic (interorgan) turnover, transport, and disposal of GSH and define the quantitative role of these processes in interorgan homeostasis of GSH, CYSH, and CYSS. These studies have identified the liver as the central organ of interorgan GSH homeostasis, with sinusoidal GSH efflux as the major determinant of plasma GSH, CYSH, CYSS, and thiol-disulfide status of plasma. This article focuses on the principal components and determinants of interorgan homeostasis of GSH and its breakdown products. It also presents the current state of knowledge under both normal and diseased states.

Transport of reduced glutathione in hepatic mitochondria and mitoplasts from ethanol-treated rats: effect of membrane physical properties and S-adenosyl-L-methionine.

Ethanol intake depletes the mitochondrial pool of reduced glutathione (GSH) by impairing the transport of GSH from cytosol into mitochondria. S-Adenosyl-L-methionine (SAM) supplementation of ethanol-fed rats restores the mitochondrial pool of GSH. The purpose of the current study was to determine the effect of ethanol feeding on the kinetic parameters of mitochondrial GSH transport, the fluidity of mitochondria, and the effect of SAM on these changes. Male Sprague-Dawley rats were fed ethanol-liquid diet for 4 weeks supplemented with either SAM or N-acetylcysteine (NAC). SAM-supplementation of ethanol-fed rats restored the mitochondrial GSH pool but NAC administration did not. Kinetic studies of GSH transport in isolated mitochondria revealed two saturable, adenosine triphosphate (ATP)-stimulated components that were affected significantly by chronic ethanol feeding: lowering Vmax (0.22 and 1.6 in ethanol case vs. 0.44 and 2.7 nmol/15 sec/mg protein in controls) for both low and high affinity components with the latter showing an increased Km (15.5 vs. 8.9, mmol/L in ethanol vs. control). Mitochondria from SAM-supplemented ethanol-fed rats showed kinetic features of GSH transport similar to control mitochondria. Determination of membrane fluidity revealed an increased order parameter in ethanol compared with control mitochondria, which was restricted to the polar head groups of the bilayer and was prevented by SAM but not NAC supplementation of ethanol-fed rats. The changes elicited in mitochondria by ethanol were confined to the inner membrane; mitoplasts from ethanol-fed rats showed features similar to those of intact mitochondria such as impaired transport of GSH and increased order parameter. A different mitochondrial transporter, adenosine diphosphate (ADP)/ATP translocator, was unaffected by ethanol feeding. Furthermore, fluidization of mitochondria or mitoplasts from ethanol-fed rats by treatment with a fatty acid derivative restored their ability to transport GSH to control levels. Thus, ethanol-induced impaired transport of GSH into mitochondria is selective, mediated by decreased fluidity of the mitochondrial inner membrane, and prevented by SAM treatment.

Evidence that interference with binding to hepatic cytosol binders can inhibit bile acid excretion in rats.

We previously identified that Y' bile acid binders (3alpha-hydroxysteroid dehydrogenases) interact with bile acids in intact rat hepatocytes using [3beta-3H, C24-14C]bile acids and that indomethacin, a competitive inhibitor of 3alpha-hydroxysteroid dehydrogenase, inhibits 3H-loss from the C3-position of bile acids as well as inhibits hepatic bile acid removal and excretion. To study the kinetics of these inhibitory effects, glycocholate transport was studied in the absence and presence of indomethacin in the single-pass perfused rat liver. Indomethacin decreased net hepatic glycocholate uptake in the perfused liver, which was confirmed in isolated hepatocytes and basolateral liver plasma membrane vesicles. However, indomethacin markedly increased the sinusoidal efflux and decreased the biliary excretion of glycocholate in the perfused liver. These observations indicate that the effect of indomethacin to delay biliary glycocholate excretion is related to either intracellular or canalicular glycocholate transport. The latter possibility seemed unlikely because indomethacin did not inhibit electrogenic or adenosine triphosphate (ATP)-dependent glycocholate uptake by canalicular liver plasma membrane vesicles. Thus, the current data support an important role for binding of bile acids to cytosolic proteins in overall hepatic transport and suggest that specific interference with cytosolic binding can interfere with the excretion of bile acids.

GSH transporters: molecular characterization and role in GSH homeostasis.

Considerable progress has been made in the last few years in the molecular identification and characterization of hepatic GSH transporter-associated polypeptides. We are now poised to determine their precise mechanisms of action and regulation at the transcriptional and post-translational level. It is also anticipated that molecular characterization of the mitochondrial GSH transporter and sodium GSH co-transporters will be accomplished in the near future. With this information, a more complete understanding of GSH/cysteine homeostasis can be achieved which can be applied to furthering the prevention and treatment of the diseases of oxidative stress, such as aging, HIV, cataract, atherosclerosis, cancer and alcoholic liver disease.

Plasma membrane and mitochondrial transport of hepatic reduced glutathione.

The tripeptide glutathione (GSH) is a key nonprotein thiol that plays multiple critical functional and regulatory roles in cells. Hepatic transport of GSH is a key process in the interorgan homeostasis of GSH. Hepatocellular GSH is available to other extrahepatic organs by its release into blood and bile through the sinusoidal and canalicular GSH carriers, respectively. Their characterization at the molecular level has been recently accomplished using the functional expression cloning strategy utilizing Xenopus laevis oocytes microinjected with the corresponding cRNA from the sinusoidal (RsGshT) and canalicular (RcGshT) clones previously isolated and identified from cDNA libraries constructed from hepatic size-fraction mRNAs expressing separately the sinusoidal and canalicular GSH transporters. These clones of 2.8 and 4.0 kb encode for proteins of 39.9 and 95.8 kD for RsGshT and RcGshT, respectively, with 3 to 5 and 6 to 10 putative membrane-spanning domains. Their tissue distribution reveals that RsGshT is exclusively found in liver, contrasting with the distribution of RcGshT, which is found in nearly all tissues examined. Cellular GSH is also found in the mitochondrial matrix at a concentration similar to that in cytosol. However, mitochondria do not synthesize their own GSH, which originates from the operation of a transport carrier localized within the inner mitochondrial membrane. Its role is critical in maintaining a functionally competent organelle and in cell viability. Expression studies in Xenopus oocytes have allowed the identification of the hepatic mitochondrial GSH carrier (RmGshT), which displays distinct functional features from both RsGshT and RcGshT, such as ATP stimulation and inhibitor specificity, suggesting that RmGshT is encoded by a gene distinct from that of the plasma membrane GSH carriers.

Role of two recently cloned rat liver GSH transporters in the ubiquitous transport of GSH in mammalian cells.

Recently our laboratory has cloned both the rat canalicular and sinusoidal GSH transporters (RcGshT and RsGshT, respectively; Yi, J., S. Lu, J. Fernandez-Checa, and N. Kaplowitz. 1994. J. Clin. Invest. 93:1841-1845; and 1995. Proc. Natl. Acad. Sci. USA. 92:1495-1499). The current work characterized GSH transport and the expression of these two GSH transporters in various mammalian cell lines. The average cell GSH levels (nmol/10(6) cells) were 25, 22, 32, 13, and 13 in HepG2, HeLa, CaCo-2, MDCK, and Cos-1 cells, respectively. GSH efflux was temperature dependent and averaged 0.018, 0.018, 0.012, 0.007, and 0.019 nmol/10(6) cells/min from HepG2, HeLa, CaCo-2, MDCK, and Cos-1 cells, respectively. Dithiothreitol (DTT), which stimulates rat sinusoidal GSH efflux, stimulated GSH efflux only in HepG2 and HeLa cells which was partially reversed by subsequent cystine treatment. GSH uptake (1 mM plus 35S-GSH) was temperature dependent, linear up to 45 min, and Na+-independent with average rates of 1.12, 0.91, 0.45, and 0.45 nmol/10(6) cells/30 min for HepG2, HeLa, CaCo-2, MDCK, and Cos-1 cells, respectively. BSP-GSH (2mM), which cis-inhibits sinusoidal GSH uptake in rat liver and HepG2 cells, inhibited GSH uptake only in HeLa cells. mRNA and polypeptide of RcGshT are expressed in all cells whereas those of RsGshT are expressed only in HepG2 and HeLa cells. In conclusion, bidirectional GSH transport, mediated by the "canalicular" GSH transporter, is ubiquitous in mammalian cells. Sinusoidal GSH transporter expression is more restricted, being present in HepG2 and HeLa cells. DTT and BSP-GSH affect GSH transport only in cells expressing the sinusoidal transporter confirming their selective action on this transporter.

Developmental changes in plasma thiol-disulfide turnover in rats: a multicompartmental approach.

Plasma glutathione (GSH), derived principally from the liver, has been proposed as the main endogenous source of plasma cysteine (CYSH). In an earlier study in immature (I) and mature (M) rats, with the use of tracer boluses of intravenous [35S]GSH, we found the movement of the label through plasma GSH, CYSH, and cystine (CYSS) pools to be incompatible with a series of precursor-product compartments (GSH-->CYSH-->CYSS). Thus plasma GSH did not appear to account for sole source of plasma CYSH. To delineate the quantitative interrelationships of plasma GSH, CYSH, and CYSS in I and M rats, we used tracer bolus injections of intravenous [35S]CYSH and [35S]CYSS. The data from the present and previous studies were then used to develop a comprehensive multicompartmental model that fits the data from all experiments. Our analysis indicates the following. 1) Plasma CYSH does not account for the sole intermediate, kinetically homogeneous pool for the movement of label from GSH to CYSS. 2) Only one-half of the irreversible disposal rate (IDR; nmol.min-1.ml-1) of plasma GSH in I rats, but all of it in M rats, is accounted for by hydrolysis to CYSH+CYSS. Thus I rats appear capable of taking up substantial amounts of plasma GSH intact. 3) Significant age-related declines take place in the following IDRs: GSH, from 38 to 18 (approximately 55%); CYSH, from 81 to 11 (approximately 85%); CYSS (in CYSH equivalents), from 30 to 10 (approximately 67%). 4) Hydrolysis of GSH supplies only approximately 22% of plasma IDR of CYSH in I rats vs. approximately 78% in M rats. Thus, in I rats, a sizable inflow of CYSH from other sources than GSH is required to maintain plasma CYSH. 5) In contrast, plasma CYSS appears fully supplied through circulating GSH and CYSH.

Changes in plasma glutathione concentrations, turnover, and disposal in developing rats.

We have previously shown that sinusoidal reduced glutathione (GSH) efflux declines during development because of a declining maximum transport rate [Am. J. Physiol. 261 (Gastrointest. Liver Physiol. 24): G648-G656, 1991]. Because rat liver serves as the principal source of plasma GSH, we studied the response of plasma GSH to this declining inflow from liver. In immature (28- to 42-day) and mature (90- to 151-day) rats we injected tracer boluses of [35S]GSH intravenously and collected arterial samples over a 0.75- to 8-min interval while plasma GSH pool remained at steady state. Concentrations and radioactivities of GSH, oxidized glutathione (GSSG), cysteine (CYSH), cystine (CYSS), and cysteine-glutathione disulfides (CYSSG) and the radio-activities of proteins were measured in plasma. Our results show the following changes in plasma concentrations (microM): decreases in unbound (free) GSH (26.0 +/- 2.1 to 12.4 +/- 0.98; P < 0.001), total unbound GSH equivalents GSH + 2GSSG (29.1 +/- 2.1 to 15.3 +/- 1.2; P < 0.001), total reducible (unbound + bound) GSH (39.3 +/- 2.2 to 28.9 +/- 2.6; P < 0.025), and free CYSH (57.6 +/- 8.5 to 29.9 +/- 4.0; P < 0.05); no changes in GSSG (1.57 +/- 0.27 vs. 1.47 +/- 0.41), CYSS (36.7 +/- 12 vs. 43.4 +/- 17), and total unbound CYSH equivalents CYSH + 2CYSS (131 +/- 15 vs. 117 +/- 18); increases in total reducible (unbound + bound) CYSH (158 +/- 8.1 to 203 +/- 24; P < 0.05) and CYSSG (1.80 +/- 0.42 to 4.94 +/- 1.4 in microM GSH equivalents; P < 0.05). A concurrent decline occurred in irreversible disposal rate (IDR) of plasma GSH from 38.5 +/- 4.9 to 16.4 +/- 1.4 nmol.min-1.ml-1 (P < 0.001) as determined by compartmental analysis of tracer data. This 57% decrease in IDR parallels a decrease of 53% in the inflow of GSH estimated by perfused livers (17.0 to 8.0 nmol.min-1.ml plasma-1). However, perfused liver estimates do not match > 44-49% of plasma IDR. Thus perfused liver appears to underestimate the true rate of sinusoidal GSH efflux taking place in vivo. Some earlier arteriovenous data and our present portal vein-to-hepatic vein difference measurements appear to corroborate this view.

Bidirectional membrane transport of intact glutathione in Hep G2 cells.

Rat hepatocytes exhibit bidirectional carrier-mediated transport of reduced glutathione (GSH) across the plasma membrane. Transport of GSH has not been well characterized in human-derived cells. We examined Hep G2 cells as a possible human liver model for GSH homeostasis. Hep G2 cell GSH averaged 25.9 +/- 1.4 nmol/10(6) cells. When Hep G2 cells were incubated in buffer, no GSH appeared in the medium over 2 h. However, after pretreatment with acivicin to inhibit gamma-glutamyl transpeptidase activity, GSH efflux was unmasked and measured 30 +/- 4 pmol x 10(6) cells-1 x min-1, which is comparable to rat hepatocytes. GSH efflux was inhibited by sulfobromophthalein GSH adduct (BSP-GSH) and cystathionine, agents that inhibit sinusoidal efflux in the rat, and was stimulated by adenosine 3',5'-cyclic monophosphate-dependent agents. GSH uptake was measured after cells were pretreated with acivicin and buthionine sulfoximine to prevent breakdown of GSH and resynthesis of GSH from precursors, respectively. In the presence of 4 microCi/ml of [35S]GSH and 10 mM unlabeled GSH, GSH uptake was linear up to 45 min and did not require Na+ or Cl-. GSH uptake exhibited saturability with a maximal velocity of 4.15 +/- 0.23 nmol.mg-1 x 30 min-1, a Michaelis constant of 2.36 +/- 0.26 mM, and two interactive transport sites. BSP-GSH cis-inhibited GSH uptake in a dose-dependent manner with an inhibitory constant of 0.46 +/- 0.05 mM. Inhibition by BSP-GSH (1 mM) of GSH uptake was through a single inhibitor site and was overcome at > 10 mM GSH, which is consistent with competitive inhibition. Similar to the rat, 10 mM extracellular GSH trans-stimulated GSH efflux. These findings may be important in gaining better insights into GSH homeostasis in human liver cells.

Selective induction by phenobarbital of the electrogenic transport of glutathione and organic anions in rat liver canalicular membrane vesicles.

Glutathione is excreted into bile via a low affinity, electrogenic, ATP-independent transport system which is cis-inhibited and trans-stimulated by certain organic anions (Fernández-Checa, J. C., Takikawa, H., Horie, T., Ookhtens, M., and Kaplowitz N. (1992) J. Biol. Chem. 267, 1667-1673). This transport system differs from the sinusoidal carrier in several respects, such as affinity for transport and inhibitor specificity. Another differential aspect is the selective increase by phenobarbital pretreatment of GSH excretion into bile without changing the sinusoidal release into blood. To determine if phenobarbital induces the GSH transporter in the canalicular membrane and if this is reflected in the induction of organic anion transport, we have used rat liver canalicular (cLPM) and sinusoidal (bLPM) enriched membrane vesicles from liver of control (saline) and phenobarbital-treated rats. cLPM vesicles prepared from phenobarbital-pretreated rats exhibited a significant, 46% increase in Vmax for transport (9.02 +/- 0.3 versus 6.17 +/- 0.5 nmol/mg/15 s) without a change in the Km for GSH transport (14.0 +/- 1.1 versus 16.7 +/- 2.7 mM, respectively). Kinetic parameters for GSH transport in bLPM vesicles remained unchanged after phenobarbital treatment versus control (Vmax, 4.67 +/- 0.2 versus 4.77 +/- 0.2 nmol/mg/15 s; Km, 7.79 +/- 0.8 versus 6.95 +/- 0.8 mM, respectively). Phenobarbital treatment increased the electrogenic transport of [35S]sulfobromophthalein (BSP) (5 and 50 microM) but not the electrogenic uptake of [14C] glycocholic acid (10 and 200 microM). In addition, the ATP-dependent transport of [35S]BSP, [3H]leukotriene C4, and [14C]glycocholic acid into cLPM vesicles was not altered by phenobarbital treatment. The ATP-independent transport of [35S]BSP in cLPM was cis-inhibited and trans-stimulated by GSH, supporting the view that BSP and GSH share a common multispecific transporter. Thus, among the various canalicular transport systems, the multispecific electrogenic organic anion and GSH transport system is selectively induced by phenobarbital treatment.

Transport of glutathione at blood-brain barrier of the rat: inhibition by glutathione analogs and age-dependence.

We showed previously that glutathione (GSH) may cross the blood-brain barrier intact by a saturable low affinity transport process (Km approximately 6 mM) (Kannan et al., J. Clin. Invest. 85: 2009-2013, 1990). In the present report, breakdown and resynthesis of GSH as the mechanism of apparent GSH uptake were excluded further because > 87% of injected 35S-cysteine taken up at the blood-brain barrier remained unchanged with negligible incorporation into GSH. In an effort to characterize further this GSH transport system, we have studied the influence of a number of potential inhibitors on brain uptake index (BUI) of GSH in rats pretreated with a gamma-glutamyl transpeptidase inhibitor, acivicin. The BUIs of tracer 35S-GSH uptake in the presence or absence of 1 to 20 mM cysteine, glutathione disulfide, gamma-glutamylglutamate, gamma-glutamyl-p-nitroanilide and 2-aminobicyclo(2,2,1)heptane-2-carboxylic acid did not differ significantly from each other. However, S-alkyl glutathiones (hexyl and octyl), sulfobromophthalein-glutathione, glutathione monoethyl ester, probenecid (5 mM) and ophthalmic acid (10 mM) inhibited GSH uptake significantly. Inhibition of GSH uptake by sulfobromophthalein-glutathione and GSH-monoethyl ester was concentration-dependent with apparent Ki approximately 0.016 and 0.083 mM, respectively. There was a decline in GSH-BUI as a function of age in both acivicin and nonacivicin-pretreated rats during the growth and developmental period from 25 to 135 days of age (100-500 g b.wt.). The decrease in BUI with age was specific for GSH; cysteine uptake did not change and no difference in diffusible (H2O) and nondiffusible (sucrose) components was found in this age range.(ABSTRACT TRUNCATED AT 250 WORDS)

Zonal distribution of cysteine uptake in the perfused rat liver.

When in situ perfused rat livers were administered tracer or physiologic concentrations of [35S]cysteine, a zone III (perivenous) predominance of uptake was observed in either antegrade or retrograde single-pass perfusion, as determined by quantitative densitometry of autoradiographs of liver section. This pattern remained unchanged from 30 s to 5 min observed. At higher supraphysiologic doses a more uniform acinar distribution of cysteine uptake was observed. Uptake rates of cysteine in antegrade perfusion indicated an apparent saturable component at low but physiologic cysteine concentrations. That uptake rather than metabolic trapping accounts for this perivenular pattern was supported by finding identical zonal distribution under conditions in which GSH and protein synthesis were markedly inhibited. Furthermore, increasing or decreasing hepatic cysteine pool sizes did not affect the extraction or zonation. These results suggest that a low Km transport system for cysteine is localized in zone III of the hepatic acinus.

Canalicular transport of reduced glutathione in normal and mutant Eisai hyperbilirubinemic rats.

We have characterized the transport of GSH and the mechanism for impaired GSH transport in mutant Eisai hyperbilirubinemic rats (EHBR) using isolated canalicular membrane-enriched vesicles (cLPM). In control animals, the transport of GSH is an electrogenic process and is trans-stimulated by preloading the vesicles with GSH and is not enhanced in the presence of ATP. GSH transport in cLPM is saturable with a single component having a Km of approximately 16 mM and a Vmax of 6.7 nmol/mg/15 s. EHBR is a Sprague-Dawley rat with hyperbilirubinemia due to impaired bile secretion of organic anions by the ATP-dependent organic anion/GSH-conjugate transporter. In cLPM from EHBR we confirmed the defective stimulation by ATP of the transport of LTC4 and GSSG. In the mutant cLPM, the characteristics and kinetics of GSH transport were the same as in the controls. 2,4-(dinitrophenyl)-glutathione (DNP-GSH), which is a substrate for the ATP-dependent canalicular organic anion carrier, in the absence of ATP, cis-inhibited the transport of GSH into cLPM vesicles; however, when the vesicles were preloaded with DNP-GSH, there was a dose-dependent trans-stimulation of GSH transport. In contrast, in the presence of ATP, DNP-GSH enhanced GSH transport in cLPM vesicles; at 0.25 mM DNP-GSH, a concentration which did not cis-inhibit GSH, addition of ATP resulted in accelerated GSH transport; at 1.0 mM DNP-GSH, cis-inhibition was completely reversed by the addition of ATP despite a negligible fall in the medium DNP-GSH. Interestingly, sulfobromophthalein-glutathione (BSP-GSH) neither cis-inhibited nor trans-stimulated GSH transport in cLPM. This contrasts with bLPM where BSP-GSH interacts with the GSH carrier. Therefore, GSH is transported into bile by a multispecific low affinity electrogenic carrier which is distinct from the multispecific high affinity ATP-driven organic anion transporter. Although both carriers have overlapping specificities, BSP-GSH and GSH are uniquely specific for only one of the carriers. The near absence of GSH in the bile of mutant rats can be best explained as a secondary defect due to cis-inhibition from retained substrates for the defective carrier and/or loss of trans-stimulation by these same substrates which normally are concentratively transported into the bile. Other possibilities such as change in GSH carrier activity upon isolation or loss of a negative protein regulator during membrane isolation, although theoretical alternatives are less easily reconciled with the defect in the ATP-driven organic anion transporter.

Mechanism of changes in hepatic sinusoidal and biliary glutathione efflux with age in rats.

To delineate the kinetic mechanism(s) of declining sinusoidal reduced glutathione (GSH) efflux with age, we perfused livers of male rats ages approximately 1-1.5, approximately 2-3, and approximately 3.5-6 mo old and measured sinusoidal and biliary GSH and oxidized glutathione (GSSG) effluxes. Our results showed declining GSH transport to be solely due to a falling maximum transport rate (Vmax) and not an increasing Michaelis constant (Km)(Vmax = 24.2 +/- 2.95, 15.8 +/- 1.51, and 8.61 +/- 0.75 nmol. min-1.g-1; Km = 3.0 +/- 0.42, 2.6 +/- 0.31, and 2.6 +/- 0.43 mumol/g for the three age groups, respectively). Because hepatocyte membrane potential was earlier implicated as a driving force for GSH efflux and hepatocytes of female rats were reported to be less polarized than those of males, we likewise studied the kinetics of sinusoidal GSH efflux from livers of female rats of three age groups comparable to our males. Vmax in females tended to be lower than in males. This was more pronounced in the youngest group but was diminished in the older groups. Vmax was again the only parameter declining with age in the female livers, from 19.1 +/- 2.25 to 15.0 +/- 0.95 and 7.83 +/- 0.99 nmol.min-1.g-1, whereas Km remained unchanged at 3.0 +/- 0.45, 3.1 +/- 0.35, and 3.2 +/- 0.72 mumol/g, respectively. Age-dependent changes in GSH efflux were not due to a changing membrane potential. There was no appreciable change in the paracellular permeability with age either.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of indomethacin on the uptake, metabolism and excretion of 3-oxocholic acid: studies in isolated hepatocytes and perfused rat liver.

3 alpha-Hydroxysteroid dehydrogenase catalyzes the reduction of 3-oxo-bile acids and binds 3 alpha-hydroxy bile acids. Indomethacin is a competitive inhibitor of the enzyme. In incubations of isolated rat hepatocytes, indomethacin delayed the intracellular reduction and the initial uptake of 3-oxocholic acid. Following a tracer dose of 3-oxocholic acid in perfused rat liver, rapid biliary excretion was observed mainly as taurocholic acid. Only 1.1% of the dose was recovered in the caval outflow and nearly all appeared in the first 5 min collection. When the tracer dose was given after initiating a constant infusion of indomethacin (50 microM), a dramatic decrease in biliary excretion was observed, still mainly as taurocholic acid, and 14% of the dose was recovered in the caval effluent: 10% in the first 5 min collection, mainly as 3-oxocholic acid, followed by a steady, slow release of mainly taurocholic acid. The increased intrahepatic retention of bile acids and slow release into perfusate and bile in response to indomethacin are consistent with displacement of bile acids from cytosolic protein.

Impaired uptake of glutathione by hepatic mitochondria from chronic ethanol-fed rats. Tracer kinetic studies in vitro and in vivo and susceptibility to oxidant stress.

Isolated hepatocytes incubated with [35S]-methionine were examined for the time-dependent accumulation of [35S]-glutathione (GSH) in cytosol and mitochondria, the latter confirmed by density gradient purification. In GSH-depleted and -repleted hepatocytes, the increase of specific activity of mitochondrial GSH lagged behind cytosol, reaching nearly the same specific activity by 1-2 h. However, in hepatocytes from ethanol-fed rats, the rate of increase of total GSH specific radioactivity in mitochondria was markedly suppressed. In in vivo steady-state experiments, the mass transport of GSH from cytosol to mitochondria and vice versa was 18 nmol/min per g liver, indicating that the half-life of mitochondrial GSH was approximately 18 min in controls. The fractional transport rate of GSH from cytosol to mitochondria, but not mitochondria to cytosol, was significantly reduced in the livers of ethanol-fed rats. Thus, ethanol-fed rats exhibit a decreased mitochondrial GSH pool size due to an impaired entry of cytosol GSH into mitochondria. Hepatocytes from ethanol-fed rats exhibited a greater susceptibility to the oxidant stress-induced cell death from tert-butylhydroperoxide. Incubation with glutathione monoethyl ester normalized the mitochondrial GSH and protected against the increased susceptibility to t-butylhydroperoxide, which was directly related to the lowered mitochondrial GSH pool size in ethanol-fed cells.

Hormonal regulation of glutathione efflux.

The efflux of GSH has been shown previously to be a saturable process in both isolated rat hepatocytes and perfused liver, suggesting a carrier-mediated transport mechanism. The possibility in hormonal regulation of this process has been raised by recent reports. Our present work examined the role of hormones known to affect intracellular signal transduction mechanisms on GSH efflux in cultured rat hepatocytes and perfused rat livers. We found that cAMP-dependent factors, such as cholera toxin (CT), dibutyryl cAMP, forskolin, and glucagon all stimulated GSH efflux in cultured rat hepatocytes. The efflux kinetics were compared in cultured cells incubated with or without CT; the stimulation of GSH efflux was related to a near doubling of the Vmax while exhibiting no significant alteration of the Km. The increase in intracellular cAMP level associated with the threshold for this stimulatory effect was 25% above control. The stimulatory effect of CT could not be blocked by cyclohexamide pretreatment or reversed by colchicine treatment. The stimulatory effect of glucagon was abolished in the presence of ouabain but not in the presence of barium. On the other hand, hormones which act through Ca2+ and protein kinase C, such as phenylephrine and vasopressin, had no effect on GSH efflux in the cultured cells. In the perfused liver model, glucagon (10 nM) and dibutyryl cAMP (8 microM) stimulated sinusoidal GSH efflux to 130 and 144% of control values, respectively, and increased bile flow while not affecting biliary GSH efflux. Finally, the physiological significance of glucagon-mediated stimulation of sinusoidal GSH efflux was assessed by both plasma GSH and glucose levels in response to in vivo glucagon infusion. The threshold dose of glucagon for significant increase in plasma GSH (5.21 pmol/min) was lower than for glucose (15.61 pmol/min). At the highest glucagon infusion rate (261 pmol/min), plasma GSH level doubled while glucose level increased 80%. In conclusion, increased cAMP stimulates GSH efflux in cultured rat hepatocytes and perfused livers. The stimulatory effect of cAMP is exerted at the sinusoidal pole and appears to be mediated by hyperpolarization of hepatocytes by stimulation of Na(+)-K(+)-ATPase. In vivo studies confirmed the importance of cAMP-mediated stimulation of sinusoidal GSH efflux as it resulted in significant elevation of the plasma GSH level.

Inhibition of GSH efflux from rat liver by methionine: effects of GSH synthesis in cells and perfused organ.

The inhibition of efflux of intracellular reduced glutathione (GSH) by methionine was determined in isolated rat hepatocytes suspended either in Krebs-Henseleit buffer or in modified Fisher's medium. Methionine (1 mM) added to Krebs-Henseleit suspensions of isolated rat hepatocytes inhibited GSH efflux, with greater retention of GSH in the cells compared with control. Results were similar with methionine and 0.3 mM propargylglycine cystathionase inhibitor), suggesting no net synthesis of GSH from methionine. In Fisher's medium, the inhibitory effect of methionine on GSH efflux was masked due to increasing cellular GSH; however, the inhibitory effect of methionine was unmasked by propargylglycine, which prevented the utilization of methionine for GSH synthesis. The addition of serine (0.1 mM) to methionine in Krebs-Henseleit buffer raised cellular GSH, overcoming the inhibition of GSH efflux. In the perfused liver, infusion of 1 and 5 mM methionine initially inhibited GSH efflux, but the inhibition was reversed with continued methionine infusion. After removal of methionine, GSH efflux increased immediately. The reversal and rebound were blocked by propargylglycine, revealing concentration-dependent inhibition of sinusoidal GSH efflux by methionine. Thus, when methionine is utilized to promote GSH synthesis, its inhibitory effect on GSH efflux tends to be overcome.