Studies on the mechanism of the protective action of 16,16-dimethyl PGE2 in carbon tetrachloride induced acute hepatic injury in the rat

We have previously demonstrated the partial protection of the rat liver by 16,16-dmPGE₂ (DMPG) against a number of hepatotoxins including carbon tetrachloride (CCl₄). However, it has not been determined whether hepatoprotection by DMPG represents a true “cytoprotective” action or if merely accomplished through inhibition of CCl₄ metabolism to reactive, toxic trichoromethyl (CCl₃·) free radicals. This report details a series of experiments in which the effects of DMPG on CCl₄ metabolism was evaluated in the rat.These data indicate that pretreatment with DMPG may reduce the hepatic concentration of the toxic CCl₃· free radicals in CCl₄ poisoned rats. Evidence is presented which suggests that this reduction in binding may have been due to a decrease in the rate of CCl₄ metabolism. However, DMPG did not affect the hepatic concentration of total microsomal cytochrome P450, the necessary enzyme in this metabolic process. On the other hand, free radical spin trapping experiments indicate that the rate of free radical formation from CCl₄ was slowed by treatment. Also, indirect evidence suggests that the metabolism of another cytochrome P450 substrate, phenobarbital, was slowed in DMPG treated rats. We conclude that the rate of CCl₄ metabolism may be reduced by pretreatment with DMPG. Furthermore, some measure of hepatic protection might be expected to occur as a result of the reduction in the rate of CCl₄ metabolism. However, we are unable to determine if this action was solely responsible for the observed hepatic protection.     

Lipid peroxidation in purified plasma membrane fractions of rat liver in relation to the hepatoxicity of carbon tetrachloride

Preparations of rat liver sinusoidal plasma membrane have been tested for their ability to metabolize the hepatotoxin carbon tetrachloride (CCl4) to reactive free radicals in vitro and compared in this respect with standard preparations of rat liver microsomes. The sinusoidal plasma membranes were relatively free of endoplasmic reticulum-associated activities such as the enzymes of the cytochrome P450 system and glucose-6-phosphatase. CCl4 metabolism was measured as (i) covalent binding of [14C]-CCl4 to membrane protein, (ii) electron spin resonance spin-trapping of CCl3. radicals and (iii) CCl4-induced lipid peroxidation. By all of these tests, purified sinusoidal plasma membranes were found unable to metabolize CCl4. The fatty acid composition of the plasma membranes was almost identical to that of the microsomal preparation and both membrane fractions exhibited similar rates of the lipid peroxidation that was stimulated non-enzymically by gamma-radiation or incubation with ascorbate and iron. The absence of CCl4-induced lipid peroxidation in the plasma membranes seems to be due, therefore, to an absence of CCl4 activation rather than an inherent resistance to lipid peroxidation. We conclude that damage to the hepatocyte plasma membrane during CCl4 intoxication is not due to a significant local activation of CCl4 to CCl3. within that membrane.     

Inhibition of CCl4 metabolism by oxygen varies between isoenzymes of cytochrome P-450

Oxygen inhibition of CCl4 metabolism by different isoenzymes of cytochrome P-450 was assessed by studying liver microsomes isolated from control rats and rats treated with phenobarbital or isoniazid. Rates of CCl4 metabolism were similar for all microsomes under a nitrogen atmosphere. An air atmosphere inhibited metabolism by microsomes from control rats to 12% of the value under nitrogen and metabolism by microsomes from rats treated with phenobarbital to 5%. It inhibited metabolism by microsomes from rats treated with isoniazid only to 32%. Rats treated with phenobarbital, which increases hepatic cytochrome P-450 content, or isoniazid, which does not increase hepatic cytochrome P-450 content, both metabolized more CCl4 than control rats as indicated by exhalation of greater quantities of CCl4 metabolites and by an increase in CCl4 toxicity. These results indicate that some isoenzymes of cytochrome P-450 are more effective than others in metabolizing CCl4 when oxygen is present.     

Hepatic protection by 16, 16-dimethyl prostaglandin E2 (DMPG) against acute aflatoxin B1-induced injury in the rat

Studies were conducted to assess the possible protective action of 16,16-dimethyl prostaglandin E2 (DMPG) against acute aflatoxin B1 (AFB1) induced hepatic injury in the rat. Evaluation of liver damage by histopathologic techniques and clinical chemistry indicated that hepatic necrosis was ameliorated by treatment with DMPG even though binding of radiolabeled (3H)-AFB1 to hepatic DNA was unaffected by this prostaglandin. However, DMPG did not protect rats against AFB1-induced mortality. These data suggest that hepatic protection by DMPG was due to mechanisms other than an interference with the activation or hepatic binding of AFB1.     

Reductive metabolism of nitroprusside in rat hepatocytes and human erythrocytes.

The metabolism of nitroprusside by hepatocytes or subcellular fractions involves a one-electron reduction of nitroprusside to the corresponding metal-nitroxyl radical. Thiol compounds also reduced nitroprusside to the metal-nitroxyl radical apparently via a thiol adduct. The nitroprusside reduction by microsomes was shown to be due to cytochrome P450 reductase as an antibody to cytochrome P450 reductase inhibits the microsomal reduction of nitroprusside, and the inhibitors of cytochrome P450 such as carbon monoxide or metyrapone had no effect. The reduction of nitroprusside by mitochondria in the presence of NADH or NADPH also produced the metal-nitroxyl radical. In hepatocytes, both mitochondria and the cytochrome P450 reductase are involved in the reduction of nitroprusside. The reductive metabolism of nitroprusside was found to produce toxic by-products, namely, free cyanide anion and hydrogen peroxide. We have also detected thiyl radicals formed in the thiol compound reduction of NP. We propose that cyanide and hydrogen peroxide are important toxic species formed in the metabolism of nitroprusside. The rate of reductive metabolism of nitroprusside by rat hepatocytes was much higher than with human erythrocytes. Therefore the major site of nitroprusside metabolism in vivo may be liver and not blood as originally proposed.     

Selective protection of curcumin against carbon tetrachloride-induced inactivation of hepatic cytochrome P450 isozymes in rats

We investigated the effects of curcumin, a major antioxidant constituent of turmeric, on hepatic cytochrome P450 (CYP) activity in rats. Wistar rats received curcumin-containing diets (0.05, 0.5 and 5 g/kg diet) with or without injection of carbon tetrachloride (CCl(4)). The hepatic CYP content and activities of six CYP isozymes remained unchanged by curcumin treatment, except for the group treated with the extremely high dose (5 g/kg). This suggested that daily dose of curcumin does not cause CYP-mediated interaction with co-administered drugs. Chronic CCl(4) injection drastically decreased CYP activity, especially CYP2E1 activity, which is involved in the bioactivation of CCl(4), thereby producing reactive free radicals. Treatment with curcumin at 0.5 g/kg alleviated the CCl(4)-induced inactivation of CYPs 1A, 2B, 2C and 3A isozymes, except for CYP2E1. The lack of effect of curcumin on CYP2E1 damage might be related to suicidal radical production by CYP2E1 on the same enzyme. It is speculated that curcumin inhibited CCl(4)-induced secondary hepatic CYPs damage through its antioxidant properties. Our results demonstrated that CYP isozyme inactivation in rat liver caused by CCl(4) was inhibited by curcumin. Dietary intake of curcumin may protect against CCl(4)-induced hepatic CYP inactivation via its antioxidant properties, without inducing hepatic CYPs.     

CCl4-induced alterations in Ca++ homeostasis in chlordecone and phenobarbital pretreated animals

Male S-D rats were maintained on normal powdered diet or on the same diet containing 10 ppm chlordecone or 225 ppm phenobarbital for 15 days. On day 15, all the animals received a single ip injection of either corn oil or a subtoxic dose of CCl4 (25-200 microliter/kg) in corn oil vehicle (1 ml/kg). The animals were sacrificed 12 hrs later. Liver microsomal cytochrome P-450 and Ca++ levels in whole liver, mitochondria, microsomes and cytosol were determined. Cytochrome P-450 induction was greater with phenobarbital pretreatment than with chlordecone but the CCl4 induced destruction of cytochrome P-450 was almost similar in both groups and progressive with the dose of CCl4. CCl4 given to animals on normal diet in a dose range of 25-200 microliter/kg did not significantly alter the cytochrome P-450 levels. These findings are consistent with greater bioactivation of CCl4 after the above two pretreatments. There was a massive accumulation of Ca++ in chlordecone and phenobarbital pretreated animals after CCl4 administration. Cytosolic Ca++ levels remained high despite the mitochondrial and microsomal sequestration. This perturbation of hepatocellular Ca++ homeostasis might lead to hepatic lesion and hepatic failure. Chlordecone or phenobarbital alone do not alter hepatic Ca++ levels. These findings suggest that excessive accumulation of Ca++ may be causally related to the progression of hepatotoxic response due to CCl4 in chlordecone treated animals.     

Interaction of metallothionein and carbon tetrachloride on the protective effect of zinc on hepatotoxicity

To study the influence of hepatic metallothionein (MT) on the hepatotoxic response to carbon tetrachloride (CCl4), adult male rats were pretreated with a 10 mg X kg-1 dose of zinc (Zn) 24 h prior to CCl4 (i.p., l mL X kg-1) treatment. Zn pretreatment increased the hepatic MT concentrations markedly and reduced the magnitudes of the CCl4-induced reduction of cytochrome P450 concentration as well as elevation of serum alanine aminotransferase and aspartate aminotransferase activities when determined at 4 or 24 h following CCl4 treatment. Treatment of Zn-exposed animals with CCl4 also resulted in significant reduction of the concentrations of hepatic MT (as determined by the cadmium-saturation method) as well as cytosolic Zn. Sephadex G-75 chromatographic study of hepatic cytosols showed that MT-bound Zn was selectively depleted by CCl4 exposure. Moreover, it was demonstrated that CCl4, after metabolic activation, reduced the cadmium binding capacity of Zn-induced hepatic MT in vitro. To examine the possible protective effect of Zn independent of induction of MT synthesis, CCl4 was administered 2 h following Zn pretreatment and the hepatotoxic response was examined 4 h later. This study revealed limited protection by Zn prior to the induction of MT synthesis. These data further support a role of MT in the modulation of CCl4 hepatotoxicity.     

Destruction of hepatic mixed-function oxygenase parameters by CCl4 in rats following acute treatment with chlordecone, Mirex, and phenobarbital

Previous work has established the marked potentiation of CCl4 hepatoxicity by prior exposure to chlordecone (CD). This study was conducted to determine if prior exposure to CD results in enhancement of CCl4-induced destruction of the hepatic microsomal mixed-function oxygenase (MFO) system. Male Sprague-Dawley rats received a single oral dose of CD (10 mg/kg) or corn oil vehicle alone (1 ml/kg) 24 hr prior to a single ip injection of CCl4 (0-100 microliter/kg). Mirex (M; 10 mg/kg) and phenobarbital (PB; 80 mg/kg/day for two days) were used as negative and positive controls respectively for the potentiation of CCl4 hepatotoxicity. Hepatotoxicity was evaluated 24 hrs after CCl4 administration by elevations of three serum enzymes (GPT, GOT, and ICD). The key hepatic microsomal MFO parameters measured were microsomal protein, cytochrome P-450 content, glucose-6-phosphatase (G-6-Pase), and aminopyrine demethylase (APD). As previously demonstrated using a subchronic dietary pretreatment protocol, CD potentiated CCl4 hepatotoxicity over a range of CCl4 doses to a greater extent than PB or M, as judged by elevations in serum enzymes. PB caused the greatest increase in total P-450 content and the greatest increase in CCl4-mediated destruction of microsomal protein and APD activity. M caused the least destruction of total hepatic cytochrome P-450, despite the same level of cytochrome P-450 as in the PB group. CD treatment caused the greatest decrease in G-6-Pase activity in comparison to PB or M pretreatments and a similar degree of P-450 destruction as observed with the PB group. These findings suggest that in general, CCl4-induced destruction of hepatic MFO parameters measured in this study is disproportional to the known degree of potentiated hepatotoxicity by the pretreatments and does not accurately reflect the potentiation of CCl4 hepatotoxicity by CD.     

The role of lipid peroxidation in CCl4-induced damage to liver microsomal enzymes: comparative studies in vitro using microsomes and isolated liver cells

The question as to whether CCl4 decreases the activities of glucose-6-phosphatase and cytochrome P-450 in liver endoplasmic reticulum mainly through its action in stimulating lipid peroxidation has been investigated using Promethazine to block lipid peroxidation. The investigation, moreover, has compared the effects of CCl4, with and without Promethazine, on isolated rat hepatocytes with corresponding effects on rat liver microsomal suspensions. Our data give no support for the view that products of lipid peroxidation are the main cause of the decrease in cytochrome P-450 observed in CCl4-intoxication. However, our present results are consistent with lipid peroxidation being a major contributory factor to the decrease in glucose-6-phosphatase activity observed in CCl4-induced liver injury.     

Hepatic microsomal warfarin metabolism in warfarin-resistant and susceptible mouse strains: influence of pretreatment with cytochrome P-450 inducers

In the present paper, the heterogeneity of hepatic cytochrome P-450 isoenzymes in the mouse has been probed, using warfarin as the substrate. Both sex and strain differences in the in vitro microsomal metabolism of warfarin have been investigated in male and female warfarin-resistant HC and warfarin-susceptible LAC-grey mouse strains. Animals were either untreated or treated with the cytochrome P-450 inducers phenobarbitone, beta-napthoflavone or clofibrate. In both sexes and strains of mice, metabolism of warfarin was stereoselective in favour of the R(+) enantiomer. However, regioselectively was different in both strains and sexes of untreated animals. After pretreatment with phenobarbitone, increases in the rate of formation of 4' and 7-hydroxy R(+) and S(-) warfarin metabolites in HC mice were observed, compared with untreated animals. In LAC-grey mice increases in 4'-, 6-, 7- and 8-hydroxy R(+) and S(-) warfarin metabolites were noted, compared with untreated animals. This data indicated that different amounts or forms of cytochrome P-450s were responsible for warfarin metabolism after phenobarbitone treatment in the two strains. Pretreatment of animals with beta-napthoflavone resulted in significant decreases in the rat of R(+) warfarin metabolism in both strains and sexes of mice indicating that the beta-naphthoflavone-inducible cytochrome P-450 isoenzymes were less active in the metabolism of warfarin, as compared to the uninduced isoenzymes. In addition, the cytochrome P-450 isoenzyme composition in the two mouse strains was different after clofibrate pretreatment, as reflected in reduced levels of some warfarin metabolites and a reduced total metabolism of warfarin, consistent with the narrow substrate specificity of clofibrate-induced cytochrome P450IVA1 for fatty acid hydroxylation. Accordingly, it is clear that both the basal and xenobiotic inducible hepatic cytochrome P-450 isoenzymes in warfarin-resistant and susceptible mice are different and therefore have implications for the in vivo disposition of warfarin.     

Leukotriene B4 metabolism by hepatic cytochrome P-450

Leukotriene B4 (LTB) was found to be metabolized by suspensions of rat liver microsomes in the presence of NADPH and oxygen. The rate of LTB metabolism was also measured in reconstituted systems of both micelles and phospholipid vesicles containing cytochrome P-450-LM2, NADPH cytochrome P-450 reductase, and cytochrome b5. A 1 microM concentration of LTB was metabolized by rat hepatic microsomes at a rate of 4 pmol LTB/min/nmole P-450, and by vesicle and micelle reconstituted systems at 3 pmole/min/nmole P-450-LM2. At this rate a 10 g rat liver exposed to 1 microM LTB can metabolize 30 micrograms per hour. In that the leukotrienes are pharmacologically active at nanomolar concentrations, hepatic metabolism may be an important pathway of leukotriene inactivation.     

Carbon tetrachloride metabolism in partially hepatectomized and sham-operated rats pre-exposed to chlordecone (Kepone)

The potentiation of CCl4 toxicity by pre-exposure to chlordecone (CD) is well established. Chlordecone-induced metabolism of CCl4 and suppressed hepatocellular repair have been offered as possible mechanisms for this potentiation. Recent work using the partially hepatectomized (PH) rat as a model for an actively regenerating liver has provided supportive evidence for the latter hypothesis. The present study was initiated to determine if metabolism and disposition of 14CC14 is altered in the PH rat, and if this is a contributing factor to the reported protective effect afforded by the PH procedure. Male Sprague-Dawley rats (150-175 g) maintained on dietary CD (10 ppm) for 15 days were partially hepatectomized or sham-operated (SH) on day 15. Another group of CD-pretreated rats received 0.9% CoCl2 (60 mg/kg, sc, qd for 2 days) in lieu of the surgical procedure. On day 16 the rats were challenged with a single dose of CCl4 (100 microL/kg, ip) containing 20 muCi 14CCl4. A radiolabel inventory consisting of exhaled 14CCl4, 14CO2 production, total hepatic 14C, free 14CCl4 and covalently bound 14C was taken over a 6-hr time period. Lipid peroxidation and serum enzyme activities [aspartate aminotransferase (AST) and alanine aminotransferase (ALT)] were measured in indices of toxicity. Neither CD pretreatment alone nor CoCl2 treatment alone produced significant alterations in metabolism of low dose (100 microliters/kg) CCl4. No significant difference in 14CCl4 recovery or 14CO2 production was detected for PH versus SH rats. Hepatic 14CCl4-derived 14C (per gram tissue) was greater in PH rats. Values for free 14CCl4, covalently bound 14C, and lipid peroxidation were similar for SH and PH rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of the administration of cobaltic protoporphyrin IX on drug metabolism, carbon tetrachloride activation and lipid peroxidation in rat liver microsomes

The effects of cobaltic protoporphyrin IX (CPP) administration on hepatic microsomal drug metabolism, carbon tetrachloride activation and lipid peroxidation have been investigated using male Wistar rats. CPP (125 mumol/kg, 72 h before sacrifice) profoundly decreased the levels of hepatic microsomal heme, particularly cytochrome P-450. Consequently, the associated mixed-function oxidase systems were equally strongly depressed. An unexpected finding was that CPP administration also greatly decreased the activity of NADPH/cytochrome c reductase, a result not generally found with the administration of the more widely used cytochrome P-450 depleting agents, cobaltous chloride. Activation of carbon tetrachloride, measured as covalent binding of [14C] CCl4, spin-trapping of CCl3 and CCl4-stimulated lipid peroxidation, was much lower in liver microsomes from CPP-treated rats. Other microsomal lipid peroxidation systems, utilising cumene hydroperoxide or NADPH/ADP-Fe2+, were also depressed in parallel with the decrease in microsomal enzyme activities.     

Possible participation of a free-radical lipid intermediate in the hydroxylation of polycyclic hydrocarbons

The effects of pro-oxidants (Fe2+, CCl4) and antioxidants (alpha-tocopherol, propyl gallate) on hydroxylation of polycyclic hydrocarbon benz(a)pyrene and on the NADPH-cytochrome P-450-reductase reaction were studied. The role of allyl radicals formed in the fatty acid chains in discussed. The binding of O2 to free radicals, i. e. formation of peroxy radicals, is regarded only as a possible reaction of the radical utilization. It is assumed that other reactions involving lipid radicals, in particular, electron transfer from the flavoprotein to cytochrome P-480 may occur in microsomal membranes.     

The characteristics of the microsomal hydroxylation of tolbutamide

The in vitro metabolism of tolbutamide to the hydroxymethyl derivative was studied using hepatic microsomal homogenates. The hydroxymethyl metabolite was quantitated by HPLC. The hepatic microsomal hydroxylase was completely inhibited by carbon monoxide and was NADPH dependent. Metyrapone, alpha-naphthoflavone, phenelzine, mercuric chloride, and nitrogen significantly inhibited the reaction indicating the involvement of the cytochrome P-450 monooxygenase. Species variation showed that the order of hepatic microsomal activity was rat greater than rabbit much greater than guinea pig much greater than mouse and hamster. The reaction increased with time up to 40 min and followed Michaelis-Menten kinetics in rat liver microsomes with apparent Km and Vmax values of 224.4 microM and 359.9 pmol.mg-1.min-1, respectively. The reaction was induced by phenobarbital but was depressed after pretreatment with 3-methylcholanthrene and isosafrole. However, expression of the hydroxylase activity per nanomoles of cytochrome P-450 showed that the activity was much higher in liver microsomes of isosafrole pretreated rats. These results indicate the involvement of different isozymes of cytochrome P-450 in the microsomal hydroxylation of tolbutamide.     

Detection of phenobarbital-induced cytochrome P-450 in rat hepatic microsomes using an enzyme-linked immunosorbent assay

The major phenobarbital-inducible form of cytochrome P-450 (cytochrome P-450 PB) was purified to homogeneity from rat liver microsomes and rabbit antibodies prepared against the purified enzyme. Using these antibodies, an enzyme-linked immunosorbent assay (ELISA) was developed for the detection of cytochrome P-450 PB in microsomes which was sensitive at the nanogram level. The content of cytochrome P-450 PB was determined in hepatic microsomes from rats treated with various xenobiotics. Phenobarbital and Aroclor 1254 pretreatments resulted in several-fold increases in immunoreactive cytochrome P-450 PB over control levels. ELISA measurements of cytochrome P-450 PB were also carried out over a 48-h time course of phenobarbital induction in liver microsomes. Significant increases over control levels were seen at 16 h and beyond. Measurements of ELISA-detectable cytochrome P-450 PB were made in microsomes following the administration of CCl4 to phenobarbital-pretreated rats. Immunoreactive cytochrome P-450 PB was observed to decrease less rapidly than the spectrally detectable enzyme in the microsomal membranes. Inhibition of heme synthesis was carried out by the administration of 3-amino-1,2,4-triazole (AT) to rats. Concomitant pretreatment with phenobarbital and AT resulted in levels of ELISA-detectable cytochrome P-450 PB which were significantly increased over control levels, while spectrally detectable levels of total holoenzyme remained unchanged. These results support the idea that this cytochrome P-450 may exist, at least partly, in the microsomal membrane in an inactive or apoprotein form.     

A new direction in the study of carbon tetrachloride hepatotoxicity

An unknown chain of causality links the early events of CCl4 metabolism to emergence of the classical spectrum of pathological changes elicited by this hepatotoxin. Recent developments suggest that an early disturbance in hepatocellular Ca2+ homeostasis may be involved. The possibility that generation of toxic products of lipid peroxidation may act as toxicological "second messengers" linking events near cytochrome P-450 to distant parts of the cell seems unlikely. This mini-review attempts to highlight major recent developments underlying the current situation.     

Protective effects of melatonin against carbon tetrachloride hepatotoxicity in rats

Melatonin is an indolamine, mainly secreted by the pineal gland into the blood of mammalian species. The potential for protective effects of melatonin on carbon tetrachloride (CCl(4))-induced acute liver injury in rats was investigated in this work. CCl(4) exerts its toxic effects by generation of free radicals; it was intragastrically administered to male Wistar rats (4 g kg(-1) body weight) at 20 h before the animals were decapitated. Melatonin (15 mg kg(-1) body weight) was administered intraperitoneally three times: 30 min before and at 2 and 4 h after CCl(4) injection. Rats injected with CCl(4) alone showed significant lipid and hydropic dystrophy of the liver, massive necrosis of hepatocytes, marked increases in free and conjugated bilirubin levels, elevation of hepatic enzymes (alanine aminotransferase and aspartate aminotransferase) in plasma, as well as NO accumulation in liver and in blood. Melatonin administered at a pharmacological dose diminished the toxic effects of CCl(4). Thus it decreased both the structural and functional injury of hepatocytes and clearly exerted hepatoprotective effects. Melatonin administration also reduced CCl(4)-induced NO generation. These findings suggest that the effect of melatonin on CCl(4)-induced acute liver injury depends on the antioxidant action of melatonin.     

Hepatic protection by 16,16-dimethyl prostaglandin E2 (DMPG) against acute aflatoxin B1-induced injury in the rat

Studies were conducted to assess the possible protective action of 16,16-dimethyl prostaglandin E₂ (DMPG) against acute aflatoxin B₁ (AFB₁) induced hepatic injury in the rat. Evaluation of liver damage of histopathologic techniques and clinical chemistry indicated that hepatic necrosis was ameliorated by treatment with DMPG even though binding of radiolabeled (3H)-AFB₁ to hepatic DNA was unaffected by this prostaglandin. However, DMPG did not protect rats against AFB₁-induced mortality. These data suggest that hepatic protection by DMPG was due to mechanisms other than an interference with the activation or hepatic binding of AFB₁.