Prostaglandins: a possible mediator to inhibit hepatic drug metabolism in adjuvant arthritic rats

In the liver of adjuvant arthritic rats perfused with a hemoglobin-free buffer solution, the rate of metabolism of a model drug, 2,6-dichloro-4-nitroanisole, was approximately half that of the control, while the bile flow rate was normal. Granulation tissue extracts and arthritic rat serum had no effect on the activity of CNA metabolism in normal rat liver preparations. In the perfused normal rat liver, the rate of CNA metabolism was inhibited by addition of prostaglandin (PG) E1, PGE2, and PGF2 alpha, respectively, in a final concentration of 0.5 microM. The inhibition by PGE1 was increased in the concentration range from 0.1 to 2.5 microM. The bile flow rate was not affected by the added PGs. However, these PGs had no direct effect on the CNA demethylating activity of the isolated hepatocytes from normal rat liver in a high concentration of 10 microM. Serotonin stimulated slightly CNA metabolism and bile production in the perfused livers by the intermittent infusion, but was without effect in the isolated hepatocytes. Epinephrine and histamine had no significant effect on CNA metabolism in both liver preparations. A similar pattern of the inhibition of CNA metabolism by PGs was reproduced in the normal rat liver perfused with the medium containing the supernatant of the hepatic nonparenchymal cells incubated in the presence of PGE1. The involvement of liver sinusoidal cells as secretory cells in depression of hepatic drug metabolism has been discussed.     

The effect of chlordiazepoxide hydrochloride on the isolated perfused rat liver.

The effects of chlordiazepoxide-hydrochloride (CDZ) on the isolated perfused rat liver were examined. CDZ administration decreased bile flow, biliary excretion of sulfobromophthalein (BSP) and hepatic uptake of BSP. The addition of CDZ to the perfusate of livers obtained from phenobarbital (Pb) pretreated rats led to 50% greater reductions in bile flow, concentration of BSP in bile and hepatic uptake of BSP. The adverse effects of CDZ on BSP excretion per g liver, however, did not appear to be enhanced by Pb pretreatment. The complex nature of the interrelationship of the effects of Pb and of CDZ on the control liver prevented differentiation of the role of CDZ from that of a metabolite on the adverse effect on liver function.     

Hepatocellular bioactivation and cytotoxicity of the synthetic endoperoxide antimalarial arteflene

Arteflene is a synthetic endoperoxide antimalarial. Its peroxide bridge undergoes iron(II)-mediated reduction in vitro which yields a carbon-centered cyclohexyl radical and a mixture of cis- and trans-alpha,beta-unsaturated ketones (enones). The enones are biliary metabolites in rats and therefore surrogate markers of bioactivation. Arteflene is reported to be more cytotoxic to primary rat hepatocytes than some non-endoperoxide antimalarials. Hepatic metabolism of arteflene was investigated in recirculating isolated perfused rat livers, and the drug's metabolism and cytotoxicity were compared using hepatocytes from male rats. Both preparations metabolized [(14)C]arteflene to cis- and trans-[(14)C]enone, 8-hydroxyarteflene glucuronide and an unassigned isomeric glucuronide. During a 2 h liver perfusion, the cis- and trans-enones recovered in bile represented 8.1 +/- 3.4 and 11.3 +/- 4.6% (mean +/- S.D., N=6), respectively, of the [(14)C]arteflene (52 microM) added to the perfusate. After a 3 h incubation of [(14)C]arteflene (10 microM) with hepatocytes in suspension, the cis- and trans-enones comprised, respectively, 14.8 +/- 7.1 and 2.1 +/- 1.0% (N = 4) of the recovered radioactivity; the corresponding data for cultured hepatocytes being 18.6 +/- 6.9 and 3.3 +/- 2.2%. Arteflene was significantly (P < 0.05) toxic to isolated hepatocytes with reference to extramitochondrial reductase activity (tetrazolium reduction) but not enzyme leakage when the cells were exposed to drug concentrations > or =50 microM for 24 h. Cellular glutathione was depleted under these conditions. Therefore arteflene was acutely cytotoxic, though only at relatively high concentrations, when it was metabolized via a pathway which generates carbon-centered radicals.     

Influence of dietary selenium on the mutagenic activity of perfusate and bile from rat liver, perfused with 1,1-dimethylhydrazine

The mutagenic effect of 1,1-dimethylhydrazine (UDMH) was studied in the liver perfusion/cell culture system. Male Wistar rats, fed a selenium-deficient diet with or without selenium supplementation in the drinking water, were used as liver donors. UDMH caused an increased mutation frequency in Chinese hamster V79 cells exposed in the perfusate. The effect was statistically significant with both selenium-deficient and selenium-supplemented livers. With selenium-deficient livers, a significant mutagenic effect was also obtained when V79 cells were treated with bile collected after the administration of UDMH. Bile flow and bile acid excretion were not affected by UDMH treatment of selenium-deficient or selenium-supplemented livers. There was a tendency towards reduced C-oxygenation of N,N-dimethylaniline in microsomes from selenium-deficient livers perfused with UDMH. The lactate/pyruvate ratio in the perfusate was increased by UDMH, the effect being more pronounced with selenium-deficient than selenium-supplemented livers.     

Troxerutin protects the isolated perfused rat liver from a possible lipid peroxidation by coumarin

For more than 40 years coumarin has been successfully used in the therapy of chronic venous insufficiency (CVI). The occurrence of liver injuries is rather rare and happens predominantly when doses are administered which are significantly higher than necessary for therapeutical use. Such effects caused by high coumarin concentrations are reproducible in in vivo experiments in mice or rats and HepG2-cells. In order to characterize the mechanism of liver injuries, the isolated perfused rat liver has been chosen as model. Since liver injuries are quite rare, if coumarin is used in co-medication with troxerutin, a possible protective influence of this flavonoid has been investigated. In concentrations higher than 4 mmol/l, coumarin alone is effective in the isolated perfused rat liver. Then the release of the enzymes alanine aminotransferase (ALT) and lactate dehydrogenase (LDH) increases and there is a measurable reduction of perfusion flow, oxygen consumption and rate of bile secretion. Additionally, the concentrations of hepatic adenosine triphosphate (ATP) and oxidized and total glutathione (GSSG/GSH) decrease. In the livers of fasting animals, coumarin doubles the concentration of hepatic malondialdehyde (MDA). This effect cannot be detected if troxerutin is added. In general, troxerutin reduces the concentration of all coumarin-metabolites in the perfusate and bile and changes the ratio of the main metabolites, coumarin: 3-hydroxycoumarin: 7-hydroxycoumarin. An analysis of the metabolic steps also shows that the amount of coumarin eliminated via faeces does not stem from absorbed coumarin, because the amount of orally applied coumarin detectable in the bile is less than 1%. The study demonstrates that troxerutin has hepatoprotective properties and thus protects the liver from a possible lipid peroxidation caused by coumarin. However, it is necessary to point out that these adverse effects caused by coumarin can be detected only in very high concentrations considerably above the regular therapeutical dosage. This allows the conclusion that troxerutin is a beneficial cofactor in coumarin preparations used for the therapy of chronic venous insufficiency.     

Influence of glucocorticoid on the metabolism of aldosterone in the isolated perfused rat liver and kidney.

The effect of glucocorticoid deficiency and excess on the extraadrenal metabolism of D-[4-14C]aldosterone (at 4 nM) was studied by radioimmunoassay and by high-performance liquid chromatography in the isolated perfused liver and kidney of adult Wistar rats. Bilateral adrenalectomy was performed 3 weeks before experiments. In nonadrenalectomized rats, 0.3 mg/kg/day dexamethasone was continuously infused subcutaneously for 1 week before experiments. Adrenalectomy did not affect hepatic or renal metabolism of aldosterone. Dexamethasone treatment did not change the renal handling of aldosterone. However, the hepatic clearance of aldosterone was 19% lower (P less than 0.05) in livers of dexamethasone treated rats than in livers of normal rats. After 5 minutes, perfusate [4-14C]aldosterone metabolites were lower in livers of dexamethasone-treated than in livers of normal rats (P less than 0.05). Similar perfusate levels were then obtained. Radiometabolite peaks with similar relative retention times were found in the hepatic perfusate of all groups. However, the ratio between circulating polar metabolites of aldosterone and the metabolites less polar than tetrahydroaldosterone, after 5 and 15 minutes, was highest in livers of dexamethasone-treated rats. Biliary elimination of 14C was similar in all groups. Significant amounts of conjugated tetrahydroaldosterone were only excreted in the bile of dexamethasone-treated rats. In conclusion, glucocorticoid excess reduced the hepatic clearance of aldosterone and changed the pattern of the hepatic metabolites of aldosterone both in circulation and in bile.     

Stimulation of hepatic glycogenolysis by phorbol 12-myristate 13-acetate.

In isolated perfused rat livers, infusion of phorbol 12-myristate 13-acetate (PMA) (150 nM) resulted in a 3-fold stimulation of the rate of glucose production. This response was maximal at a perfusate PMA concentration of 150 nM, and was significantly diminished at higher concentrations of PMA (e.g. 300 nM). Stimulation of glycogenolysis by PMA was greatly decreased in livers perfused with Ca2+-free medium. PMA infusion into livers perfused in the absence of Ca2+ did not result in Ca2+ efflux from the livers. Additionally, in hepatocytes isolated from livers of fed rats, neither PMA nor 1-oleoyl-2-acetyl-rac-glycerol stimulated the rate of glucose production. Although indomethacin has been demonstrated to block PMA-stimulated hepatic glycogenolysis [Garcia-Sainz & Hernandez-Sotomayor (1985) Biochem. Biophys. Res. Commun. 132, 204-209], infusion of PMA into perfused rat livers did not alter the rates of production of either prostaglandin E2 or 6-oxo-prostaglandin F1 alpha in the livers. These data, along with the observed increases in the perfusion pressure and decrease in O2 consumption in isolated perfused livers suggest that phorbol-ester-stimulated glycogenolysis is not a consequence of a direct effect of phorbol ester on liver parenchymal cells.     

Sodium valproate inhibits the movement of secretory vesicles in rat hepatocytes.

Sodium valproate (VPA), a simple 8-carbon branched chain fatty acid, is an effective anti-epileptic drug with an occasional serious side effect of liver damage, including the accumulation of triacylglycerols within hepatocytes, and reductions in serum protein concentrations. By investigating the effects of VPA, using biliary fistula rats and isolated perfused rat livers, we have shown that secretion of triacylglycerols and rat serum albumin at the sinusoidal pole of hepatocytes, and of phospholipids, lysosomal contents, and IgA at their biliary pole, are all reduced, to somewhat different extents, by acute VPA administration. In addition, the vesicular transcytosis of exogenous protein (i.e. bovine serum albumin) from the perfusion fluid into bile is also decreased by VPA administration. To determine whether the phenomena were specific to VPA, a control series of experiments was also performed using octanoate (a straight-chain analogue of VPA). With the biliary fistula rats, octanoate did not show inhibition of secretion as compared with the saline controls; with the isolated perfused livers, however, octanoate did show such an inhibition. These phenomena suggest that VPA inhibition of secretion may be a factor in its hepatotoxicity, as the effects are apparent in both the whole animal and the isolated perfused liver, whereas octanoate is not hepatotoxic in the whole animal. Since when octanoate is administered to the isolated liver it causes an inhibition in secretion similar to that caused by VPA, it may be that the large dose of this compound reaching the liver affects a key step in liver metabolism or vesicle transport under these circumstances. Since octanoate does not normally reach the liver in such amounts, as it will normally be metabolized by other tissues, it is not hepatotoxic in the whole animal as is VPA.     

Relation between glutathione redox changes and biliary excretion of taurocholate in perfused rat liver

The influence of the intracellular glutathione status on bile acid excretion was studied in the perfused rat liver. Perturbation of the thiol redox state by short term additions of diamide (100 microM) or hydrogen peroxide (250 microM) or t-butyl hydroperoxide (250 microM) led to a reversible inhibition of biliary taurocholate release without affecting hepatic uptake; inhibition amounted to 45% for diamide and 90% for the hydroperoxides. Concomitantly, the bile acid accumulated intracellularly. Bile flow increased from 1.3 to 2.0 microliters X min-1 X g liver-1 upon infusion of taurocholate (10 microM); the latter value was suppressed to 1.2 microliters X min-1 X g liver-1 by the addition of t-butyl hydroperoxide (250 microM). Similarly, the hepatic disposition of another bile constituent, bilirubin, was suppressed by 70% upon addition of hydrogen peroxide. While the addition of hydrogen peroxide inhibited also the endogenous release of bile acids almost completely, endogenous bile flow was much less affected, decreasing from 1.3 to 1.0 microliters X min-1 X g liver-1. Measurement of [14C]erythritol clearance showed bile/perfusate ratios of about unity both in the absence and presence of hydrogen peroxide, suggesting canalicular origin of the bile under both conditions. In livers from Se-deficient rats low in Se-GSH peroxidase (less than 5% of controls), hydrogen peroxide inhibited taurocholate transport substantially less, providing evidence for the involvement of glutathione in mediating the inhibition observed in normal livers. The percentage inhibition of taurocholate release and intracellular glutathione disulfide (GSSG) content were closely correlated. The addition of t-butyl hydroperoxide caused a several-fold increase of biliary GSSG release, whereas biliary GSH release was even decreased. The results establish a role of glutathione in canalicular taurocholate disposition.     

Hepatic metabolism of vasoactive intestinal polypeptide (VIP) in the rat

Vasoactive intestinal polypeptide (VIP) is released into the portal circulation by a meal stimulus, but is rapidly cleared from plasma. Although it is known to bind to receptors on liver cells, the role of the liver in the clearance of VIP is not clearly defined. We therefore studied the disappearance of VIP in recirculating and in single pass isolated perfused rat liver (IPRL) preparations. Disappearance of added VIP was rapid in recirculating IPRL experiments with a half life of ca. 30 min. In single-pass steady-state studies in which livers were perfused at 16 ml/min for 30 min, clearance of VIP was complete (16 ml/min) at concentrations of 500 fmol/ml, but clearance fell to 3 and 1 ml/min at perfusate concentrations of 8 and 40 pmol/ml respectively. Further experiments to evaluate whether VIP was disappearing in perfusate itself demonstrated substantial metabolism of VIP in perfusate which had previously been circulated through a liver for 90 min. The products of metabolism were identical to those found in the IPRL. We conclude that VIP is rapidly cleared as it passes through the isolated perfused rat liver model with a significant proportion of clearance attributable to release of a peptidase from the liver into the perfusate.     

Biliary excretion of flavopiridol and its glucuronides in the isolated perfused rat liver: role of multidrug resistance protein 2 (Mrp2)

Flavopiridol (FLAP) is a novel anticancer agent that is extensively glucuronidated in patients. Biliary excretion is the main elimination pathway of FLAP conjugates responsible for enterohepatic recirculation and for the main side effect diarrhea. To investigate the hepatic transport system for FLAP glucuronides, livers of Wistar and Mrp2-deficient TR- rats were perfused with FLAP (30 microM) in a single pass system. Biliary excretion and efflux into perfusate during a 60 min period greatly differ in TR- rats. While cumulative biliary excretion of M1 and M2 was significantly reduced to 4.3% and 5.4% efflux into perfusate was increased by 1.5 and 4.2-fold. This indicates that in control rats, M1 and M2 are almost exclusively eliminated into bile by Mrp2. Cumulative FLAP secretion into bile and perfusate, however, was non-significantly reduced by 36.7% and 43.2% in the mutant rat strain, suggesting that besides Mrp2, other transporters might also be involved in FLAP elimination. FLAP stimulates bile flow up to 24% in control rats, but secretion is nearly absent in TR- rats further supporting an efficient transport of FLAP glucuronides by Mrp2. FLAP (30 microM) also reversibly inhibited the Mrp2-mediated biliary elimination of bilirubin and bromsulphthalein in Wistar rats by 54% and 51%, respectively, indicating a competition with the elimination of Mrp2-specific substrates. In summary, we found that FLAP glucuronides are substrates of Mrp2 effectively inhibiting the biliary excretion of bilirubin. This may explain the increased serum bilirubin levels observed in cancer patients during FLAP therapy.     

Impaired sensitivity to insulin of rat livers perfused with blood of diminished haematocrit.

1. In livers from fed rats perfused with homologous whole blood of a haematocrit value of 37%, insulin decreased the perfusate concentrations of glucose and amino acids, production of ketone bodies (3-hydroxybutyrate + acetoacetate) and increased bile flow. 2. Perfusion with blood diluted with buffer to a haematocrit value of 17% decreased hepatic O2 consumption by 40-50%. Perfusate concentrations of glucose and lactate, the rate of ketogenesis and the ratios [lactate]/[pyruvate] and [3-hydroxybutyrate]/[acetoacetate] were all increased. 3. In livers perfused with blood of diminished haematocrit, effects of insulin on perfusate glucose an amino acids, ketogenesis and bile flow were abolished.     

Rapid stimulation of calcium uptake into rat liver by L-tri-iodothyronine.

The short-term effect of L-tri-iodothyronine (T3) on hepatic Ca2+ uptake from perfusate was compared with changes induced by T3 on cellular respiration and glucose output in isolated perfused livers from fasted and fed rats. The same parameters were also studied after the addition of glucagon or vasopressin. T3 (1 microM) induced Ca2+ uptake from the perfusate into the liver within minutes, and the time course was similar to that for stimulation of respiration and gluconeogenesis in livers from fasted rats, and for the stimulation of respiration and glucose output in livers from fed rats. The effects were dose-dependent in the range 1 microM-0.1 nM. Similar changes in the same parameters could be observed with glucagon and vasopressin, but with a completely different time course. Also, the influence of the T3 analogues L-thyroxine (L-T4), 3,5-di-iodo-L-thyronine (L-T2) and 3,3',5-tri-iodo-D-thyronine (D-T3) on hepatic energy metabolism was examined. Whereas D-T3 had practically no effect, L-T4 and L-T2 caused changes in Ca2+ uptake, O2 consumption and gluconeogenesis in livers from fasted rats similar to those with T3. It is concluded that changes in mitochondrial and cytosolic Ca2+ concentrations are involved in the stimulation of respiration and glucose metabolism observed with T3, glucagon and vasopressin.     

Pathophysiological consequences of enhanced intracellular superoxide formation in isolated perfused rat liver.

The potential toxicity of enhanced intracellular reactive oxygen formation was investigated in isolated perfused livers of male Fischer rats. The presence of the redox-cycling agent diquat in the perfusate (200 microM) increased the basal efflux of glutathione disulfide (GSSG) into bile (2.65 +/- 0.26 nmol GSH-equivalents/min per g liver wt.) and perfusate (0.55 +/- 0.15 nmol/min per g) approximately 10-fold. Since no evidence was found for degradation of GSSG in the biliary tract of these animals, it could be estimated that diquat induced a constant O2- generation of approximately 1000 nmol/min per g liver wt for 1 h. Thus, reactive oxygen formation under these conditions was 1-2 orders of magnitude higher than under various pathophysiological conditions. Only minor liver injury (release of lactate dehydrogenase activity) was observed. To increase the susceptibility of the liver to the oxidant stress, animals were pretreated in vivo with 200 mg/kg body wt. phorone, which caused a 90% depletion of the hepatic glutathione content, 100 mg/kg ferrous sulfate, a combination of phorone and ferrous sulfate, or 40 mg/kg BCNU, which caused a 60% inhibition of hepatic GSSG reductase. Only the combined treatment of phorone + ferrous sulfate or BCNU caused a significant increase of the diquat-induced liver injury. Our results demonstrated an extremely high resistance of the liver against intracellular reactive oxygen formation (even with impaired detoxification systems) and can serve as reference for the evaluation of potential contributions of reactive oxygen to liver injury in various disease states.     

The role of conjugation reactions in enhancing biliary secretion of bile acids.

Shortening the five-carbon carboxylic acid side chain of cholic acid by one methylene group gave rise to a bile acid (norcholate) that was not a substrate for the bile acid-conjugating enzymes. The metabolism and biliary secretion of norcholate in intact liver was examined in the isolated perfused rat liver system. When rat livers were perfused with 14-20 microM solutions of norcholate for 10 min, norcholate was found in the unconjugated form in liver, venous effluent and bile. Neither tauronorcholate nor glyconorcholate was detectable by high-pressure liquid chromatography or fast-atom-bombardment mass spectrometry. The kinetics of hepatic uptake and biliary secretion of norcholate was compared with that for cholate, taurocholate and chemically synthesized tauronorcholate. The latter three bile acids were completely cleared from the perfusate and efficiently secreted into the bile. However, norcholate was incompletely extracted from the perfusate, and this was shown to be at least partially due to its relatively lower rate of hepatic uptake. Furthermore, the rate of norcholate secretion into bile was greatly reduced relative to the secretion of cholate or chemically synthesized tauronorcholate, even though the concentration of norcholate in the liver was comparatively high. These data demonstrate that the conjugation of bile acids greatly facilitates their secretion into bile.     

Increased uptake of fatty acids by the isolated rat liver after raising the fatty acid binding protein concentration with clofibrate

Following the administration of clofibrate to rats, the concentration of Z protein or fatty acid binding protein in liver cytosol increases by 98 %. Ligandin concentration remains unchanged. Isolated perfused livers of clofibrate-treated rats take up free fatty acids from the perfusate at a significantly higher rate (+ 76 %) than controls. Lipid synthesis from radioactive fatty acids is not modified by clofibrate administration. The yield of plasma membranes obtained from liver homogenates as well as their lipid composition are similar in control and clofibrate treated livers. These results seem to exclude the possibility that the enhancement of FFA uptake could result from an indirect effect of the drug on FFA metabolism and/or plasma membrane surface and thus support the view that Z protein plays a role in intracellular fatty acid transport in the liver.     

Influence of tauroursodeoxycholic and taurodeoxycholic acids on hepatic metabolism and biliary secretion of phosphatidylcholine in the isolated rat liver

Studies were carried out using an isolated rat liver system to define: the contribution of exogenous phosphatidylcholine (PC) to biliary phospholipid secretion; and its hepatic metabolism during perfusion of the livers with conjugated bile salts with different hydrophilic/hydrophobic properties. A tracer dose of sn-1-palmitoyl-sn-2-[14C]linoleoylPC was injected as a bolus into the recirculating liver perfusate, under constant infusion of 0.75 mumol/min of tauroursodeoxycholate or taurodeoxycholate. The effects on bile flow, biliary lipid secretion, 14C disappearance from the perfusate and its appearance in bile, as well as hepatic and biliary biotransformation were determined. With both the bile salts, about 40% of the [14C]PC was taken up by the liver from the perfusate over 100 min. During the same period less than 2% of the given radioactivity was secreted into bile. More than 95% of the 14C recovered in bile was located within the identical injected PC molecular species. The biliary secretion of labeled as well as unlabeled PC, however, was significantly higher in livers perfused with taurodeoxycholate than tauroursodeoxycholate, while the reverse was observed with respect to bile flow and total bile salt secretion. The exogenous PC underwent extensive hepatic metabolization which appeared to be influenced by the type of bile salt perfusing the liver. After 2 h perfusion, the liver radioactivity was found, in decreasing order, in PC, triacylglycerol, phosphatidylethanolamine and diacylglycerol. In addition, the specific activity of triacylglycerol was significantly higher in tauroursodeoxycholate than in taurodeoxycholate-perfused livers (P less than 0.025), while the reverse was true for the specific activity of hepatic PC (P less than 0.01). Because taurodeoxycholate and tauroursodeoxycholate showed opposite effects on both biliary lipid secretion and hepatic PC biotransformations, we conclude that the hepatic metabolism of glycerolipids is influenced by the physiochemical properties of bile salts.     

The functional effects of suppression of hypothermia-induced cell swelling in liver preservation by cold storage

It is known that cellular edema and functional impairment develop during anaerobic cold storage of organs. The extent of both is related to the storage time and the composition of the preservation solution used. We studied hypothermia-induced cell swelling and its effect on liver function after cold storage preservation with either Eurocollins (EC), a number of modified EC solutions in which glucose was replaced by various concentrations of raffinose, or UW solution. After 24 h storage, tissue swelling as determined by total tissue water (TTW) in rat liver tissue slices was most pronounced in slices incubated in Eurocollins, whereas the TTW was only moderately increased in slices stored in modified Eurocollins containing 90 to 120 mM raffinose. In contrast, slices incubated in UW solution had a TTW equal to normal rat liver tissue. Furthermore, intact rabbit livers preserved with Eurocollins had an increase in the whole organ weight, while there was no weight change after preservation with the modified solution containing 120 mM raffinose (M120). In contrast, a pronounced weight loss was observed after preservation with UW solution. After cold storage, the livers were reperfused for 2 h at 38 degrees C in an isolated perfusion circuit (IPL) with an acellular perfusate. Bile flow was significantly greater in livers preserved in M120 than in those preserved with the conventional Eurocollins. However, the bile flow in the livers stored in M120 was inferior to that in the livers preserved with UW solution, which in turn was equal to that in control livers. The release of alanine-aspartate-aminotransferase into the perfusate was higher in livers preserved with Eurocollins, with or without modification, than in the livers preserved with UW solution.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mobilization of hepatic calcium pools by platelet activating factor

In the perfused rat liver, platelet activating factor, 1-O-hexadecyl-2-acetyl-sn-glycero-3-phosphocholine (AGEPC), infusion produces an extensive but transient glycogenolytic response which at low AGEPC concentrations (i.e., 10(-11) M) is markedly dependent upon the perfusate calcium levels. The role of calcium in the glycogenolytic response of the liver to AGEPC was investigated by assessing the effect of AGEPC on various calcium pools in the intact liver. Livers from fed rats were equilibrated with 45Ca2+, and the kinetics of 45Ca2+ efflux were determined in control, AGEPC-stimulated, and phenylephrine-stimulated livers during steady-state washout of 45Ca2+. AGEPC treatment had only a slight if any effect on the pattern of steady-state calcium efflux from the liver, as opposed to major perturbations in the pattern of calcium efflux effected by the alpha-adrenergic agonist phenylephrine. Infusion of short pulses of AGEPC during the washout of 45Ca2+ from labeled livers caused a transient release of 45Ca2+ which was not abolished at low calcium concentrations in the perfusate. Moreover, there occurred no appreciable increase in the total calcium content in the liver perfusate at either high or low concentrations of calcium in the perfusion fluid. Infusion of latex beads, which are removed by the reticuloendothelial cells, caused the release of hepatic 45Ca2+ in a fashion similar to the case with AGEPC. Our findings indicate that AGEPC does not perturb a major pool of calcium within the liver as occurs upon alpha-adrenergic stimulation; it is likely that AGEPC mobilizes calcium from a smaller yet very important pool, very possibly from nonparenchymal cells in the liver.     

Effects of ethynyloestradiol on the metabolism of [1-14C]-oleate by perfused livers and hepatocytes from female rats

Normal female rats were given 15mug of ethynyloestradiol/kg body wt. for 14 days and were killed on day 15 after starvation for 12-14h. The livers were isolated and were perfused with a medium containing washed bovine erythrocytes, bovine serum albumin, glucose and [1-(14)C]oleic acid; 414mumol of oleate were infused/h during a 3h experimental period. The output of bile and the flow of perfusate/g of liver were decreased in livers from animals pretreated with ethynyloestradiol, whereas the liver weight was increased slightly. The rates of uptake and of utilization of [1-(14)C]oleate were measured when the concentration of unesterified fatty acid in the perfusate plasma was constant. The uptake of unesterified fatty acid was unaffected by pretreatment of the animal with oestrogen; however, the rate of incorporation of [1-(14)C]oleate into hepatic and perfusate triacylglycerol was stimulated, whereas the rate of conversion into ketone bodies was impaired by treatment of the rat with ethynyloestradiol. Pretreatment of the rat with ethynyloestradiol increased the output of very-low-density lipoprotein triacylglycerol, cholesterol, phospholipid and protein. The production of (14)CO(2) and the incorporation of radioactivity into phospholipid, cholesteryl ester and diacylglycerol was unaffected by treatment with the steroid. The net output of glucose by livers from oestrogen-treated rats was impaired despite the apparent increased quantities of glycogen in the liver. The overall effect of pretreatment with oestrogen on hepatic metabolism of fatty acids is the channeling of [1-(14)C]oleate into synthesis and increased output of triacylglycerol as a moiety of the very-low-density lipoprotein, whereas ketogenesis is decreased. The effect of ethynyloestradiol on the liver is apparently independent of the nutritional state of the animal from which the liver was obtained. It is pertinent that hepatocytes prepared from livers of fed rats that had been treated with ethynyloestradiol produced fewer ketone bodies and secreted more triacylglycerol than did hepatocytes prepared from control animals. In these respects, the effects of the steroid were similar in livers from fed or starved (12-14h) rats. Oestrogens may possibly inhibit hepatic oxidation of fatty acid, making more fatty acid available for the synthesis of triacylglycerol, or may stimulate the biosynthesis of triacylglycerol, or may be active on both metabolic pathways.