The biosynthesis of ascorbate protects isolated rat hepatocytes from cumene hydroperoxide-mediated oxidative stress

Most animals synthesize ascorbate. It is an essential enzymatic cofactor for the synthesis of a variety of biological molecules and also a powerful antioxidant. There is, however, little direct evidence supporting an antioxidant role for endogenously produced ascorbate. Recently, we demonstrated that incubation of rat hepatocytes with 1-bromoheptane or phorone simultaneously depleted glutathione (GSH) and triggered rapid ascorbate synthesis. The present study investigates the hypothesis that endogenous ascorbate synthesis can confer protection against oxidative stress. Rat and guinea pig hepatocytes were depleted of GSH with 1-bromoheptane and subsequently treated with the oxidative stressor cumene hydroperoxide (CHP) in the presence or absence of the ascorbate synthesis inhibitor sorbinil. In rat hepatocytes, ascorbate content increased linearly (from 15.1 to 35.8 nmol/10(6) cells) over a 105-min incubation. Prior depletion of GSH increased CHP-induced cellular reactive oxygen species (ROS) production, lipid peroxidation, and cell death in rat and guinea pig hepatocytes. Inhibiting ascorbate synthesis, however, further elevated ROS production (2-fold), lipid peroxidation (1.5-fold), and cell death (2-fold) in rat hepatocytes only. This is the first time that endogenous ascorbate synthesis has been shown to decrease cellular susceptibility to oxidative stress. Protection by endogenously produced ascorbate may therefore need to be addressed when extrapolating data to humans from experiments using rodents capable of synthesizing ascorbate.     

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.     

Studies on the in vitro effects of insulin on glycogen synthesis and ultrastructure in isolated rat liver hepatocytes

Rat liver hepatocytes were isolated by collagenase $\text{in vitro}$ perfusion technique and effect of insulin on glycogen synthesis and ultra-structure was studied. Addition of insulin stimulated glycogen synthesis and maintained better cellular structure. Synthesis of glycogen was linear in isolated hepatocytes when incubated with various concentrations of glucose (0–800 mg%) reaching initial levels. Concanavaline A inhibited epinephrine stimulated glycogenolysis but had no effect on glucagon stimulated glycogenolysis. These studies indicate that insulin is required for glycogen synthesis and for maintaining hepatocytes ultrastructure. Furthermore, isolated hepatocytes retain various receptors and that different hormones utilize different receptor sites.     

Effect of metal ion catalyzed oxidation of rifamycin SV on cell viability and metabolic performance of isolated rat hepatocytes

The effect of rifamycin SV on metabolic performance and cell viability was studied using isolated hepatocytes from fed, starved and glutathione (GSH) depleted rats. The relationships between GSH depletion, nutritional status of the cells, glucose metabolism, lactate dehydrogenase (LDH) leakage and malondialdehyde (MDA) production in the presence of rifamycin SV and transition metal ions was investigated. Glucose metabolism was impaired in isolated hepatocytes from both fed and starved animals, the effect is dependent on the rifamycin SV concentration and is enhanced by copper (II). Oxygen consumption by isolated hepatocytes from starved rats was also increased by copper (II) and a partial inhibition due to catalase was observed. Cellular GSH levels which decrease with increasing the rifamycin SV concentration were almost depleted in the presence of copper (II). A correlation between GSH depletion and LDH leakage was observed in fed and starved cells. Catalase induced a slight inhibition of the impairment of gluconeogenesis, GSH depletion and LDH leakage in starved hepatocytes incubated with rifamycin SV, iron (II) and copper (II) salts. Lipid peroxidation measured as MDA production by isolated hepatocytes was also augmented by rifamycin SV and copper (II), especially in hepatic cells isolated from starved and GSH depleted rats. Higher cytotoxicity was observed in isolated hepatocytes from fasted animals when compared with fed or GSH depleted animals. It seems likely that in addition to GSH level, there are other factors which may have an influence on the susceptibility of hepatic cells towards xenobiotic induced cytotoxicity.     

Correlation between cAMP, activation of cAMP-dependent protein kinase(s), and rate of glycogenolysis in isolated rat hepatocytes.

We have studied the correlation between cAMP-dependent protein kinase activation and rates of glycogenolysis in hepatocytes isolated from fed rats. With doses of 20 μM glucagon, the protein kinase was activated to a -cAMP/+cAMP ratio of 0.8 within 10 min and remained activated for up to 2 hours. A dose-response relationship between protein kinase activation and rates of glycogenolysis can be demonstrated to 0–20 μM glucagon. Glycogenolysis was stimulated greater than 2-fold after 2 hours of incubation with the higher doses of glucagon. Protein kinase activity ratios correlated well with the rates of glycogenolysis as the ratios varied from control levels of about 0.25 to the stimulated values of 0.5–0.6. However, as the ratios increased from 0.6 to 0.8, with higher doses of glucagon, there were no corresponding increases in the rates of glycogenolysis. These data may indicate (1) that activation of all of the protein kinase present in the liver cells is not necessary for maximal stimulation of glycogenolysis, or (2) that a specific protein kinase is involved in the intracellular control of glycogen breakdown in isolated rat hepatocytes.     

Inhibition of glucagon-stimulated cAMP accumulation and fatty acid oxidation by E-series prostaglandins in isolated rat hepatocytes

E-series prostaglandins have been shown to inhibit hepatic glucagon-stimulated glycogenolysis without inhibiting glycogenolysis stimulated by cAMP analogs. In the present studies, prostaglandin E2 and 16,16-dimethylprostaglandin E2 inhibited glucagon-stimulated cAMP accumulation in isolated rat hepatocytes by 25% and 46%, respectively, without affecting basal cAMP levels. Half-maximal inhibition of glucagon-stimulated cAMP accumulation occurred at approx. 10(-7) M 16,16-dimethylprostaglandin E2. 16,16-Dimethylprostaglandin E2 inhibited glucagon-stimulated palmitate oxidation in intact hepatocytes without affecting basal rates of palmitate oxidation. 16,16-Dimethylprostaglandin E2 had no effect on palmitate oxidation in a liver homogenate system. These studies demonstrate that prostaglandin E antagonizes the effects of glucagon on hepatic metabolism by inhibiting glucagon-stimulated cAMP accumulation.     

Studies on the inhibition of glycogenolysis by D-galactosamine in rat liver hepatocytes.

Effect of galactosamine on glycogenolysis was studied in isolated hepatocytes. It was found that addition of galactosamine strongly inhibited glycogenolysis in normal hepatocytes. Galactosamine-inhibited glycogenolysis was not stimulated by epinephrine or glucagon. This inhibition was specific as no such inhibition was observed with galactose, 2-deoxy-glucose or glucosamine. The glucagon-stimulated cyclic AMP formation in galactosamine-treated hepatocytes was the same as in normal cells; Glc-1-P and Glc-6-P did not accumulate nor was lactate formation enhanced. The glucose production by hepatocytes from regenerating liver was only slightly inhibited by galactosamine and glucagon addition stimulated glycogenolysis in the presence of the amino sugar.     

Multiple requirements for glycogen synthesis by hepatocytes isolated from fasted rats

Glycogen synthesis from various combinations of substrates by hepatocytes isolated from rats fasted 24 h was studied. As reported by Katz et al. (Katz, J., Golden, S., and Wals, P. A. (1976) Proc. Natl. Acad. Sci. U. S. A. 73, 3433-3437), appreciable rates of glycogen synthesis occurred only in the presence of gluconeogenic precursors and one of several amino acids, which includes L-glutamine. L-Leucine had negligible effects on glycogen synthesis from 20 mM dihydroxyacetone and/or 15 mM glucose when L-glutamine was not added to the medium. In the presence of 10 mM L-glutamine, L-leucine greatly increased glycogen synthesis from these substrates. alpha-Ketoisocaproate was ineffective, as was oleate. NH4Cl depressed glycogen synthesis from 10 mM glucose plus 20 mM dihydroxyacetone in the absence of added L-glutamine and enhanced that in its presence, but these effects were weak compared to those of L-leucine. The amino acid analogues L-norvaline and L-norleucine exerted effects that were similar to those exerted by L-leucine. Under all conditions studied, cycloheximide and puromycin inhibited net glycogen synthesis. Cycloheximide did not stimulate gluconeogenesis from dihydroxyacetone, or phosphorylase in hepatocytes from starved rats, or glycogenolysis in hepatocytes from fed rats. Puromycin, however, stimulated glycogenolysis in hepatocytes from fed rats. Glycogen synthesis from 20 mM dihydroxyacetone proceeds with a pronounced initial lag phase that can be shortened by incubation of cells with glutamine plus leucine before addition of dihydroxyacetone. Concurrent measurements of glycogen synthesis, glycogen synthase, and gluconeogenesis under different conditions reveal that in addition to protein synthesis, activation of glycogen synthase, which must occur to allow glycogen synthesis in hepatocytes, requires a second component which can be satisfied by addition of dihydroxyacetone or fructose to the cells.     

Critical role of mitochondrial glutathione in the survival of hepatocytes during hypoxia

Hypoxia is known to stimulate reactive oxygen species (ROS) generation. Because reduced glutathione (GSH) is compartmentalized in cytosol and mitochondria, we examined the specific role of mitochondrial GSH (mGSH) in the survival of hepatocytes during hypoxia (5% O2). 5% O2 stimulated ROS in HepG2 cells and cultured rat hepatocytes. Mitochondrial complex I and II inhibitors prevented this effect, whereas inhibition of nitric oxide synthesis with Nomega-nitro-L-arginine methyl ester hydrochloride or the peroxynitrite scavenger uric acid did not. Depletion of GSH stores in both cytosol and mitochondria enhanced the susceptibility of HepG2 cells or primary rat hepatocytes to 5% O2 exposure. However, this sensitization was abrogated by preventing mitochondrial ROS generation by complex I and II inhibition. Moreover, selective mGSH depletion by (R,S)-3-hydroxy-4-pentenoate that spared cytosol GSH levels sensitized rat hepatocytes to hypoxia because of enhanced ROS generation. GSH restoration by GSH ethyl ester or by blocking mitochondrial electron flow at complex I and II rescued (R,S)-3-hydroxy-4-pentenoate-treated hepatocytes to hypoxia-induced cell death. Thus, mGSH controls the survival of hepatocytes during hypoxia through the regulation of mitochondrial generation of oxidative stress.     

Studies on alpha-adrenergic activation of hepatic glucose output. Studies on role of calcium in alpha-adrenergic activation of phosphorylase.

The role of Ca2+ ions in alpha-adrenergic activation of hepatic phosphorylase was studied using isolated rat liver parenchymal cells. The activation of glucose release and phosphorylase by the alpha-adrenergic agonist phenylephrine was impaired in cells in which calcium was depleted by ethylene glycol bis(beta-aminoethyl ether)N,N'-tetraacetic acid (EGTA) treatment and restored by calcium addition, whereas the effects of a glycogenolytically equivalent concentration of glucagon on these processes were unaffected. EGTA treatment also reduced basal glucose release and phosphorylase alpha activity, but did not alter the level of cAMP or the protein kinase activity ratio (-cAMP/+cAMP) or impair viability as determined by trypan blue exclusion, ATP levels, or gluconeogenic rates. The effect of EGTA on basal phosphorylase and glucose output was also rapidly reversed by Ca2+, but not by other ions. Phenylephrine potentiated the ability of low concentrations of calcium to reactivate phosphorylase in EGTA-treated cells. The divalent cation inophore A23187 rapidly increased phosphorylase alpha and glucose output without altering the cAMP level, the protein kinase activity ratio, and the levels of ATP, ADP, or AMP, The effects of the ionophore were abolished in EGTA-treated cells and restored by calcium addition. Phenylephrine rapidly stimulated 45Ca uptake and exchange in hepatocytes, but did not affect the cell content of 45Ca at late time points. A glycogenolytically equivalent concentration of glucagon did not affect these processes, whereas higher concentrations were as effective as phenylephrine. The effect of phenylephrine on 45Ca uptake was blocked by the alpha-adrenergic antagonist phenoxybenzamine, was unaffected by the beta blocker propranolol, and was not mimicked by isoproterenol. The following conclusions are drawn: (a) alpha-adrenergic activation of phosphorylase and glucose release in hepatocytes is more dependent on calcium than is glucagon activation of these processes; (b) variations in liver cell calcium can regulate phosphorylase alpha levels and glycogenolysis; (c) calcium fluxes across the plasma membrane are stimulated more by phenylephrine than by a glycogenolytically equivalent concentration of glucagon. It is proposed that alpha-adrenergic agonists activate phosphorylase by increasing the cytosolic concentration of Ca2+ ions, thus stimulating phosphorylase kinase.     

Characterization of gluconeogenesis in hepatocytes isolated from the American eel,Anguilla rostrata LeSueur,

Summary Isolated hepatocyte preparations from fed immature American eels,Anguilla rostrata Le Sueur, were used to study gluconeogenic, lipogenic, glycogenic and oxidative rates of radioactively labelled lactate, glycerol, alanine and aspartate. Eel hepatocytes maintain membrane integrity and energy charge during a 2 h incubation period and are considered a viable preparation for studying fish liver metabolism.Incubating eel hepatocytes with 10 mM substrates, the following results were obtained: glycerol, alanine and lactate, in that order, were effective gluconeogenic substrates; these three substrates reduced glucose release from glycogen stores, while aspartate had no such effect; lactate, alanine and aspartate led to high rates of glycerol production, with subsequent incorporation into lipid; incorporation into glycogen was low from all substrates; and, alanine oxidation was seven times higher than that observed with other substrates.When eel hepatocytes were incubated with low or physiological substrate concentrations gluconeogenic rates from lactate were twice those from alanine; rates from aspartate were very low. Glucagon stimulated lactate gluconeogenesis, but not amino acid gluconeogenesis, and had no significant effect on glycogenolysis. Cortisol increased gluconeogenic rates from 1 mM lactate.Thus, in the presence of adequate substrate, eel liver gluconeogenesis is preferentially stimulated relative to glycogenolysis to produce plasma glucose. These data support three important roles for gluconeogenesis: the recycling of muscle lactate, the synthesis of glucose from dietary amino acids to supplement glucose levels, and the production of glycerol for lipogenesis.This work was supported from operating grants to TWM from the National Research Council of Canada (A6944)     

Effects of glutathione depletion on gluconeogenesis in isolated hepatocytes

Glutathione-depleted hepatocytes, by incubation with diethylmaleate (DEM) or phorone (2,6-dimethyl-2,5-heptadiene-4-one), i.e., substrates of the GSH S-transferases (EC 2.5.1.18), showed rates of gluconeogenesis from various precursors significantly lower than controls; however the rate of glucose synthesis from fructose was similar to that of controls. Isolated hepatocytes from rats pretreated with those substrates 1 h before isolation to deplete hepatic glutathione (GSH) also showed a decrease of the rate of gluconeogenesis from lactate plus pyruvate. Incubation of hepatocytes with L-buthionine sulfoximine, a specific inhibitor of gamma-glutamyl-cysteine synthetase (EC 6.3.2.2), resulted in a decreased rate of gluconeogenesis from lactate plus pyruvate only when GSH values were lower than 1 mumol/g cells. Freeze-clamped livers from GSH-depleted rats showed a higher concentration of malate and glycerol 3-phosphate, indicating that GSH depletion probably affects phosphoenolpyruvate carboxykinase and glycerol-3-phosphate dehydrogenase activities. Several indicators of cell viability, such as lactate dehydrogenase leakage, malondialdehyde accumulation, ATP concentration, or urea synthesis from different precursors, were not affected by GSH depletion under the experimental conditions used here. Besides, the GSH/GSSG ratio remained unchanged in all cases.     

Influence of cAMP and calcium on epinephrine-mediated hepatic glycogenolysis in rainbow trout,Oncorhynchus mykiss

1. The role of cAMP and of calcium in mediating epinephrine-stimulated glycogenolysis was studied by incubating rainbow trout liver in vitro.2. Epinephrine significantly stimulates glucose release from liver pieces incubated in either calciumcontaining or calcium-free medium. However, the development of the glycogenolytic profile occurred more rapidly in the presence of calcium.3. The β-antagonist, propranolol, inhibited epinephrine-stimulated glucose release from liver pieces incubated in either calcium-containing or calcium-free medium.4. Calcium ionophore, A3187, stimulated glucose release from liver pieces incubated in calciumcontaining medium. Verapamil, a putative calcium channel blocker, had no effect on A23187-stimulated glycogenolysis. However, verapamil completely inhibited epinephrine-stimulated glycogenolysis.5. Dibutyryl cAMP and IBMX, singly or together, stimulated glucose release from liver pieces. cAMP-mediated glycogenolysis was more pronounced in liver pieces incubated in calcium-containing medium.6. These results indicate that epinephrine-stimulated hepatic glycogenolysis in rainbow trout proceeds through the activation of β-adrenergic receptors and that both cAMP and calcium are involved in the post-receptor signal transduction process.     

Culture duration alters the glutathione content and sensitivity to ethacrynic acid of rat hepatocyte monolayer cultures

Many of the differentiated functions of hepatocytes are lost in culture, yet addition of certain medium supplements can aid in the retention of differentiated character. Therefore, the effect of time in monolayer culture on rat hepatocyte glutathione (GSH) synthesis and sensitivity to the GSH detoxicated xenobiotic ethacrynic acid was examined in cultures with and without medium supplementation by transferrin and sodium selenite. GSH content was found to be about 12 nmol/µg DNA at 4 hr in culture and to approximately triple by 24 hr. Intracellular GSH levels continued to increase in transferrin/sodium selenite-supplemented cultures, from 32 to 41.6 nmol/µg DNA, while GSH levels in unsupplemented cultures declined to 18 nmol/µg DNA. However, the rate of GSH synthesis after diethylmaleate depletion was found to decrease from 4.2 to 2.8 nmol/hr/µg DNA at 4 and 24 hr after inoculation, respectively. GSH repletion rate increased to 3.9 nmol/hr/µg DNA at 48 hr. The GSH accumulation rate after depletion in supplemented cultures did not vary significantly over the initial 48 hr. Incubation for 3 hr with 100 µM ethacrynic acid (EA) did not elicit an increase in LDH leakage in hepatocyte monolayers after 4 or 48 hr in culture or in cultures with supplemented medium at any time point tested. Cultures 24 hr in medium without transferrin/sodium selenite supplementation exhibited significant LDH leakage after 3 hr of EA treatment. Over the 3 hr EA treatment, intracellular GSH content was decreased in all cultures. Only in the 24 hr unsupplemented cultures did GSH depletion exceed the 90% level previously associated with depletion of the mitochondrial pool of GSH and EA toxicity in hepatocytes. The experiments show that during the redifferentiation of hepatocytes in culture, a transient period occurs when apparent GSH synthesis is depressed and enhanced sensitivity to GSH-detoxicated compounds is observed. This period of increased sensitivity is prevented or at least delayed by inclusion of supplemental transferrin and sodium selenite, suggesting that redifferentiation can be regulated by extracellular influences.Abbreviations CYSSG cysteine-glutathione mixed disulfide - DEM diethyl maleate - EA ethacrynic acid - GSH reduced glutathione - GSSG oxidized glutathione - HBS HEPES buffered saline - HWME hepatocyte Williams' Medium E (WME with insulin, corticosterone and 0.5 mM methionine) - LDH lactate dehydrogenase - TS-HWME transferrin/sodium selenite-supplemented HWME - WME Williams' Medium E     

The Identification of Novel Protein-Protein Interactions in Liver that Affect Glucagon Receptor Activity

Glucagon regulates glucose homeostasis by controlling glycogenolysis and gluconeogenesis in the liver. Exaggerated and dysregulated glucagon secretion can exacerbate hyperglycemia contributing to type 2 diabetes (T2D). Thus, it is important to understand how glucagon receptor (GCGR) activity and signaling is controlled in hepatocytes. To better understand this, we sought to identify proteins that interact with the GCGR to affect ligand-dependent receptor activation. A Flag-tagged human GCGR was recombinantly expressed in Chinese hamster ovary (CHO) cells, and GCGR complexes were isolated by affinity purification (AP). Complexes were then analyzed by mass spectrometry (MS), and protein-GCGR interactions were validated by co-immunoprecipitation (Co-IP) and Western blot. This was followed by studies in primary hepatocytes to assess the effects of each interactor on glucagon-dependent glucose production and intracellular cAMP accumulation, and then in immortalized CHO and liver cell lines to further examine cell signaling. Thirty-three unique interactors were identified from the AP-MS screening of GCGR expressing CHO cells in both glucagon liganded and unliganded states. These studies revealed a particularly robust interaction between GCGR and 5 proteins, further validated by Co-IP, Western blot and qPCR. Overexpression of selected interactors in mouse hepatocytes indicated that two interactors, LDLR and TMED2, significantly enhanced glucagon-stimulated glucose production, while YWHAB inhibited glucose production. This was mirrored with glucagon-stimulated cAMP production, with LDLR and TMED2 enhancing and YWHAB inhibiting cAMP accumulation. To further link these interactors to glucose production, key gluconeogenic genes were assessed. Both LDLR and TMED2 stimulated while YWHAB inhibited PEPCK and G6Pase gene expression. In the present study, we have probed the GCGR interactome and found three novel GCGR interactors that control glucagon-stimulated glucose production by modulating cAMP accumulation and genes that control gluconeogenesis. These interactors may be useful targets to control glucose homeostasis in T2D.     

Methylisobutylxanthine blocks insulin antagonism of cAMP-stimulated glycogenolysis at a site distinct from phosphodiesterase. Evidence favoring an insulin-insensitive calcium release mechanism

The widely used phosphodiesterase inhibitor MIX (1-methyl 3-isobutyl xanthine) blocked insulin antagonism of cAMP-stimulated glycogenolysis in rat hepatocytes but other phosphodiesterase inhibitors including Ro 20-1724 had no effect. Dose-response curves for MIX potentiation of cAMP-stimulated glycogenolysis and for MIX inhibition of the effects of insulin on cAMP-stimulated glycogenolysis suggested that at higher concentrations (250 microM) MIX may act at a site other than phosphodiesterase inhibition. MIX, at 250 microM, attenuated the insulin antagonism of glucose release stimulated by 8-bromo-cAMP, an extremely poor substrate for phosphodiesterase; other phosphodiesterase inhibitors did not. The possibility that MIX acts as an adenosine antagonist interfering with a postulated role for adenosine in insulin action was examined using N6-phenylisopropyladenosine (PIA), an Ra adenosine receptor agonist which increases hepatic cAMP levels. MIX inhibited insulin antagonism of PIA-stimulated glycogenolysis under conditions where it did not act as an adenosine antagonist (MIX and Ro 20-1724 both increased the response to PIA equally). The effect of concanavalin A on cAMP-stimulated glycogenolysis was antagonized by MIX, suggesting a post-receptor site of action for MIX. MIX paradoxically increased lactate production in the presence of 8-bromo-cAMP, reminiscent of the reported actions of calcium mobilizing hormones on lactate formation in fed hepatocytes. Cytosolic free Ca2+, as measured in Quin 2-loaded cells, was increased by MIX. In cells depleted of calcium, MIX no longer blocked insulin antagonism of 8-bromo-cAMP-stimulated glucose release, suggesting that MIX may function through an insulin-insensitive release of calcium. MIX greatly potentiated the stimulation of glycogenolysis by phenylephrine but did not alter the response to vasopressin. The relationship of this effect of MIX to the mechanism of insulin action and the ability of insulin to antagonize only alpha-adrenergic responses and not those of vasopressin is discussed.     

Metabolic activation and hepatotoxicity. Toxicity of bromobenzene in hepatocytes isolated from phenobarbital-and diethylmaleate-treated rats.

Hepatocytes freshly isolated from diethylmaleate-treated rats exhibited a markedly decreased concentration of reduced glutathione (GSH) which increased to the level present in hepatocytes from nontreated rats upon incubation in a complete medium. When bromobenzene was present in the medium, however, this increase in GSH concentration upon incubation was reversed and a further decrease occurred that resulted in GSH depletion and cell death. This was prevented by metyrapone, an inhibitor of the cytochrome P-450-linked metabolism of bromobenzene. Bromobenzene metabolism in hepatocytes was accompanied by a fraction of metabolites covalently binding to cellular proteins. The size of this fraction, relative to the amount of total metabolites, was increased in hepatocytes isolated from diethylmaleate-treated rats and in hepatocytes from phenobarbital-treated rats incubated with bromobenzene in the presence of 1,2-epoxy-3,3,3-trichloropropane, an inhibitor of microsomal epoxide hydrase which, however, also acted as a GSH-depleting agent. In addition, the metabolism of bromobenzene by hepatocytes was associated with a marked decrease in various coenzyme levels, including coenzyme A, NAD(H), and NADP(H). Cysteine and cysteamine inhibited the formation of protein-bound metabolites of bromobenzene in microsomes, but did not prevent bromobenzene toxicity in hepatocytes when added at higher concentrations to the incubation medium (containing 0.4 mm cysteine). Methionine, on the other hand, did not cause a significant effect on bromobenzene metabolism in microsomes and prevented toxicity in hepatocytes, presumably by stimulating GSH synthesis and thereby decreasing the amount of reactive metabolites available for interaction with other cellular nucleophiles. It is concluded that, in contrast to hepatocytes with normal levels of GSH, hepatocytes from diethylmaleate-treated rats were sensitive to bromobenzene toxicity under our incubation conditions. In this system, bromobenzene metabolism led to GSH depletion and was associated with a progressive decrease in coenzyme A and nicotinamide nucleotide levels and a moderate increase in the formation of metabolites covalently bound to protein. Methionine was a potent protective agent which probably acted by enhanced GSH synthesis via the formation of cystathionine.     

Interleukin-2 mRNA expression, lymphokine production and DNA synthesis in glutathione-depleted T cells

The stimulation of DNA synthesis in lymphocyte populations was previously shown to depend strongly on the intracellular glutathione (GSH) level. Since T cell growth is known to depend on interleukin 2 (IL-2), the experiments in this report were designed to determine whether intracellular GSH depletion may inhibit IL-2 production or the IL-2 dependent DNA synthesis. Our experiments revealed that IL-2 production and DNA synthesis of mitogenically stimulated splenic T cells have indeed different requirements for GSH. The addition of relatively high concentrations of GSH (5 mM) to cultures of concanavalin A (Con A)-stimulated splenic T cells was found to augment strongly the DNA synthesis but inhibited the production of IL-2. Moderate intracellular GSH levels, however, are apparently not inhibitory for IL-2 production, since intracellular GSH depletion by cysteine starvation or by graded concentrations of DL-buthionine sulfoximine (BSO) had virtually no effect on IL-2-specific mRNA expression and the production of T cell growth factor (TCGF). The DNA synthesis activity, in contrast, was strongly suppressed after GSH depletion with either method. As in cultures of splenic T cells, GSH depletion had no substantial effect on the induction of IL-2 mRNA and TCGF production in several mitogenically stimulated T cell clones. Taken together, our experiments suggest that complex immune response may operate best at intermediate GSH levels that are not too high to inhibit IL-2 production but sufficient to support DNA synthesis.