Carbon tetrachloride hepatotoxicity: an example of lethal cleavage

Comparative cytopathology of primary rat hepatocyte cultures exposed to aflatoxin B1, acetaminophen, and other hepatotoxins

The cytomorphological alterations in primary monolayer cultures of Fischer 344 rat hepatocytes exposed continuously to lethal concentrations of various hepatotoxins were compared. Aflatoxin B1 (AFB1) at concentrations of 1 and 10 microM killed 67 and 97% hepatocytes, respectively, at 48 hr, as determined by release of lactate dehydrogenase (LDH) into culture medium, or by trypan blue uptake. AFB1 produced numerous radial finger-like projections (blebs) at attached margins of cytoplasm in almost all hepatocytes between 6 and 24 hr. Formation of blebs was dose dependent and preceded release of LDH and trypan blue uptake. Similar marginal blebs were produced by cycloheximide, 2-acetylaminofluorene, N-hydroxy-2-acetylaminofluorene, and senecionine. By comparison, acetaminophen, at equivalently lethal concentrations (4 or 16 mM) did not cause marginal blebs, but resulted in a similar time course of LDH release and trypan blue uptake. Carbon tetrachloride and bromobenzene also failed to produce blebs at lethal concentrations. Phalloidin and cytochalasin B rapidly produced smaller spherical blebs over the entire surface of all hepatocytes, distinct from the finger-like blebs produced only at the free attached margins of cells exposed to AFB1. Blebs and lethal injury by AFB1 were reduced by phenobarbitone or 3-methylcholanthrene pretreatments and by SKF-525-A in culture. The demonstration of morphological prelethal changes in hepatocytes injured by different classes of hepatotoxins in culture provides a means of differentiating the early biochemical mechanisms by which hepatotoxins and hepatocarcinogens lethally injure hepatocytes before membrane permeability to LDH and trypan blue is detectable.

The lipid peroxidation model for halogenated hydrocarbon toxicity. Kinetics of peroxyl radical processes involving fatty acids and Fe(III) porphyrins

The toxicity of halogenated alkanes originates from their metabolism by cytochrome P-450 which leads to the formation of reactive intermediates. In particular, peroxyl radicals derived from the halogenated compounds are believed to induce peroxidative chain degradation of lipids. To examine this hypothesis, radical reactions in a system involving FeIII-deuteroporphyrin as a model of cytochrome P-450, fatty acids or cholesterol, and carbon tetrachloride or the anesthetic agent halothane are studied by means of pulse radiolysis. It is shown that haloperoxyl radicals react with the fatty acids in competition with their reaction with the ferriporphyrin. Moreover, the secondary fatty acid peroxyl radicals also react efficiently with the porphyrin. A model for halogenated alkane toxicity is discussed in terms of these new findings. The importance of local oxygen concentration and structural arrangement of fatty acids around cytochrome P-450 are emphasized.

16,16-Dimethyl PGE2 and fatty acids protect hepatocytes against CCl4-induced damage

16,16-Dimethyl PGE2 (dmPGE2) has previously been shown to protect the in vivo rat liver against CCl4-induced damage. These studies were undertaken to determine if this protection could be demonstrated in vitro where factors of absorption, secretion, and blood flow are not present. Primary hepatocyte cultures were established by perfusing rat liver with collagenase. Hepatocytes were plated at a density of 2 X 10(4) cells/cm, allowed 90 min to attach, then stabilized in L15 medium for 18 h. Hepatocytes were then challenged with CCl4 with concomitant exposure to 10(-9) to 10(-5) M dmPGE2, stearic acid, oleic acid, or ethanol vehicle (0.00001 to 0.1%). After 1 h, challenge was aspirated and cells were stained with 0.04% trypan blue to determine viability. Hepatocytes in the vehicle groups took up more trypan when exposed to CCl4 than those treated with dmPGE2, stearic acid, or oleic acid at concentrations of 10(-9) to 10(-7) M. At 0.1% ethanol vehicle protected as well as all other treatments. Protection against CCl4 by dmPGE2, stearic, and oleic acids as well as high concentrations of ethanol may occur by altering the metabolism of CCl4.

Lipid peroxidation decreases the rotational mobility of cytochrome P-450 in rat liver microsomes

Phenobarbital-induced rat liver microsomes were subjected to NADPH- and Fe2+-catalyzed lipid peroxidation. The formation of approx. 95 nmol malondialdehyde/mg protein during 18 min peroxidation at 37 degrees C was observed. Membrane rigidity measured by means of the steady-state fluorescence anisotropy rs of diphenylhexatriene increased in parallel with the malondialdehyde formation. Both the amount of malondialdehyde and rs remained constant thereafter during incubation of the peroxidized membranes for 2 h. The aminopyrine demethylase activity decreased by about 60% upon lipid peroxidation for 18 min, whereas no significant loss of benzphetamine demethylase activity within the same time range was observed. A time-dependent formation of protein complexes of high molecular weight, comprising most of the microsomal polypeptides, upon lipid peroxidation was observed in SDS-polyacrylamide gel electrophoresis. The effect of microsomal lipid peroxidation on protein-protein interactions was examined by measuring the rotational mobility of intact cytochrome P-450. Rotational diffusion was measured by observing the decay of flash-induced absorption anisotropy r(t) of the P-450 X CO complex. Analysis was based on a 'rotation-about-membrane normal' model with the equation r(t) = r1exp(-t/phi 1) + r2exp(-t/phi 2). In control microsomes, two classes (rapid and slow) of rotating populations of cytochrome P-450 were observed with phi 1 approximately equal to 150 microseconds, fraction r1/(r1 + r2) approximately equal to 40% and phi 2 approximately equal to 2 ms, fraction r2/(r1 + r2) approximately equal to 60%. A relatively small decrease in the rotational mobility of P-450 was observed by a 18-min lipid peroxidation, while a subsequent incubation of peroxidized microsomes for 2 h at 37 degrees C resulted in a dramatic immobilization of P-450 by the increase of both r2/(r1 + r2) approximately equal to 75% and phi 2 approximately equal to 10-25 ms. The decrease in the P-450 mobility during 18-min lipid peroxidation would be due to the rigidification of the lipid bilayer. However, because the lipid fluidity remained unchanged thereafter, the significant immobilization of P-450 by the subsequent 2-h incubation is deduced to be due to formation of protein aggregates.

Carbon tetrachloride-induced eicosanoid synthesis and enzyme release from rat peritoneal leucocytes

When rat peritoneal leucocytes were incubated with carbon tetrachloride, a PLA2 was activated, eicosanoids were generated and lysosomal and cytoplasmic enzymes were released. The predominant eicosanoid generated was TXB2 with lesser amounts of PGE2, 6-keto PGF1 alpha and LTB4. Preincubation of the cells with two structurally unrelated thromboxane synthetase inhibitors reduced PLA2 activity and enzyme release and also reduced the total amounts of eicosanoids liberated. An anti-PGI2 antibody partially reversed the effects of thromboxane synthetase inhibitors indicating a role for endogenous PGI2 generation in the cytoprotective effects of these agents in this system. Exogenous PGI2 was also cytoprotective but the timing of its administration was critical. The cytoprotective effect of PGI2 was potentiated by a phosphodiesterase inhibitor, indicating a possible pivotal role of cAMP in cell protection.

Comparison of ballooned hepatocytes in alcoholic and non-alcoholic liver injury in rats

Ballooned hepatocytes are commonly observed in alcoholic and sometimes in non-alcoholic liver diseases. To clarify whether pathogenesis of this change is different in alcoholic and non-alcoholic liver diseases, changes of the livers in rats fed alcohol with pyrazole for 12 weeks were compared with those of CCl4 treated rats. Both groups of rats showed marked ballooning of the hepatocytes in the centrolobular area. Immunohistochemically, the ballooned hepatocytes in alcohol-pyrazole treated rats reacted strongly with transferrin and albumin staining. However, staining reaction of the ballooned hepatocytes in the CCl4 treated rats was slight. In alcohol-pyrazole treated rats, hepatic microtubules were significantly decreased. Retention of transferrin and albumin were found only in the ballooned hepatocytes of alcohol-pyrazole treated rats. However, in the CCl4 treated rats, neither microtubular alteration nor retention of the exportable proteins was observed. These findings indicate that the pathogenesis of ballooning of hepatocytes is different in alcoholic and non-alcoholic liver injuries. In alcoholic liver injury, microtubular alteration may lead to retention of protein and ballooning of hepatocytes by interfering with the hepatic secretion of proteins.

The formation of chlorobenzene and benzene by the reductive metabolism of lindane in rat liver microsomes

The major metabolite produced by incubating [14C]lindane with rat liver microsomes under anaerobic conditions was determined to be chlorobenzene, with lesser amounts of benzene also being formed. Using relatively high lindane concentrations (250 microM), four nonvolatile metabolites of lindane were also produced anaerobically, the predominant one being identified by mass spectrometry as tetrachlorocyclohexene (TCCH). TCCH, likewise, was reduced to chlorobenzene and benzene in microsomes under anaerobic conditions. Binding of [14C]lindane to microsomal protein occurred under aerobic as well as anaerobic incubation conditions; however, lindane protein binding was greatest in anaerobic incubations compared to those containing an atmosphere of air or 100% oxygen. Hemin reduced by dithionite also readily produced chlorobenzene and benzene from lindane. These results indicate that lindane interacts readily with heme and heme proteins, including cytochrome P-450, in the absence of oxygen to undergo multiple chloride eliminations forming chlorobenzene and benzene as end products.

Structural changes of rat liver microsomal membranes induced by the oral administration of carbon tetrachloride. 31P-NMR and spin-label studies

The acute effects of carbon tetrachloride (CCl4) on the membrane structure of rat liver microsomes were studied using 31P-NMR and spin-labeling techniques. 31P-NMR spectra of rat liver microsomes were not changed appreciably after the oral administration of CCl4, indicating that the surface structures of microsomal membranes probably are not influenced by the oral administration of CCl4. Four different spin-labeled stearic acids, 5-(N-oxyl-4',4'-dimethyloxazolidine)-stearic acid (5SLS), its methyl ester (5SLSM), 12-(N-oxyl-4',4'-dimethyloxazolidine)-stearic acid (12SLS) and its methyl ester (12SLSM), were used for the estimation of membrane fluidity. The apparent rotational correlation time of 12SLS decreased from 4.0 nsec to 3.0 nsec after the oral administration of CCl4, while the order parameter of 5SLS did not change. The results suggest that CCl4 or its metabolites increase the membrane fluidity of liver microsomes primarily at hydrophobic regions rather than at the surface layer. The ESR spectrum of 5SLSM in microsomal membranes comprised two different signals; one was an anisotropic signal and the other was a rather isotropic one. The ratio of the anisotropic signal to the isotropic one decreased markedly after the oral administration of CCl4 and depended on the dose of CCl4. The suitability of this ESR technique with 5SLSM for the estimation of membrane damage is discussed.

Enhanced metabolism of volatile hydrocarbons in rat liver following food deprivation, restricted carbohydrate intake, and administration of ethanol, phenobarbital, polychlorinated biphenyl and 3-methylcholanthrene: a comparative study

The effects of food deprivation, carbohydrate restriction and ethanol consumption on the metabolism of eight volatile hydrocarbons (benzene, toluene, styrene, chloroform, carbon tetrachloride, 1,2-dichloroethane, 1,1-dichloroethylene and trichloroethylene) in rats were compared with the effects of enzyme induction by phenobarbital (PB), polychlorinated biphenyl (PCB) and 3-methylcholanthrene (MC) on the metabolism of these compounds. Although causing a marked increase both in microsomal protein and cytochrome p-450 contents, PB (80 mg/kg per day for three days) and PCB (a single dose of 500 mg/kg) induced only a limited range of enzyme activity: PB increased the metabolism of toluene, styrene, chloroform, carbon tetrachloride and trichloroethylene, and PCB only increased those of toluene, styrene and trichloroethylene. MC (20 mg/kg per day for three days) had no effect on the metabolism of any of the hydrocarbons studied. In contrast, food deprivation, carbohydrate restriction and three-week ingestion of ethanol (2.0 g/day), each enhanced the metabolism of all the hydrocarbons with little or no increase in microsomal protein and cytochrome P-450 contents. PB, PCB and MC treatments enhanced the activity of enzymes involved in conjugation reactions, UDP-glucuronyltransferase and glutathione S-transferase, whereas the dietary manipulation and ethanol consumption produced no significant effect on these enzymes. It is concluded that ethanol consumption. lowered carbohydrate intake and food deprivation affect the metabolism and toxicity of volatile hydrocarbons differently from PB, PCB or MC.

Pathological mechanisms in carbon tetrachloride hepatotoxicity

Liver cell injury induced by carbon tetrachloride involves initially the metabolism of carbon tetrachloride to trichloromethyl free-radical by the mixed function oxidase system of the endoplasmic reticulum. It is postulated that secondary mechanisms link carbon tetrachloride metabolism to the widespread disturbances in hepatocyte function. These secondary mechanisms could involve the generation of toxic products arising directly from carbon tetrachloride metabolism or from peroxidative degeneration of membrane lipids. The possible involvement of radical species such as trichloromethyl (.CCl3), trichloromethylperoxy (.OOCCl3), and chlorine (.Cl) free radicals, as well as phosgene and aldehydic products of lipid peroxidation, as toxic intermediates is discussed. Data do not support the view that an increase in cytosolic free calcium is important in the toxic action of carbon tetrachloride or bromotrichloromethane. In addition, carbon tetrachloride-induced inhibition of very low density lipoprotein secretion by hepatocytes is not a result of elevated levels of cytosolic free calcium.

Halomethane-induced inhibition of protein synthesis in isolated hepatocytes

The effect of several halomethanes on protein synthesis has been studied in isolated hepatocytes. When cells are added to medium preequilibrated with CCl4 or CBrCl3, protein synthesis is inhibited after a lag period of 4 to 10 min. The concentrations of CBrCl3, CCl4, and CHCl3 which cause a 50% inhibition of protein synthesis are about 6 microM, 400 microM, and 4 mM, respectively. This order of potency parallels the rate at which these compounds are metabolized by the hepatic mixed function oxidase, suggesting that metabolism is required for toxicity. The inhibitory effect caused by 18 min of exposure to CBrCl3 is not reversed when the toxin is removed, indicating that inhibition involves some irreversible modification of cellular material. Unexpectedly, the inhibitory effect caused by 18 min of exposure of CCl4 is about 30-40% reversed when the toxin is removed. This suggests that CCl4 causes inhibition not only by a metabolism-dependent (irreversible) pathway, but by a metabolism-independent (reversible) mechanism as well. Extracellular Ca2+ is not required for CCl4 inhibition of protein synthesis.

Isolated rat hepatocytes in suspension: potential hepatotoxic effects of six different drugs

Isolated rat hepatocytes in suspension were studied with regard to various measures of hepatic toxicity. We compared enzyme leakage (ASAT, ALAT, LDH), cell viability (trypan blue exclusion), intracellular ATP content, and incorporation of 14C-valine into stationary and export proteins while the cells were exposed to six different drugs at two different concentrations. The drugs were oxytetracycline, paracetamol, carbon tetrachloride, ethanol, methotrexate and fentanyl. The results were compared to known in vivo responses, in particular to see whether concentrations resulting in dose-related in vivo effects would similarly affect the functions tested in vitro. Leakage of enzymes exhibited a graded increase with a corresponding rise in the concentration of oxytetracycline and carbon tetrachloride. Reduction in incorporation of 14C-valine into cell and medium proteins showed a similar graded effect with rising concentrations of paracetamol, carbon tetrachloride, and ethanol. Intracellular levels of ATP gradually decreased with increasing concentrations of carbon tetrachloride and ethanol. An obvious reduction in viability was only registered with increasing concentrations of carbon tetrachloride, while paracetamol tended to give a similar response. We found no major discrepancies between already known in vivo effects and our in vitro results when testing paracetamol, carbon tetrachloride, ethanol, methotrexate, and fentanyl. We could not, however, demonstrate inhibition of protein synthesis by oxytetracycline at the concentrations tested. No single measurement was adequate for testing all drugs. The test of 14C-valine incorporation into hepatocyte export proteins plus LDH leakage seemed to constitute a useful combination in detecting drug toxicity in hepatocyte suspensions.

Reductive metabolism of 1,1,1,2-tetrachloroethane and related chloroethanes by rat liver microsomes

The susceptibility of polychlorinated ethanes to reductive metabolism was evaluated by measuring the amount of each compound consumed during anaerobic incubations with rat live microsomes; 1,1,1,2-tetrachloroethane, pentachloroethane and hexachloroethane were metabolized extensively, 1,1,1,2-tetrachloroethane and the trichloroethanes were metabolized very slowly and the dichloroethanes were not metabolized at a detectable rate. The electron affinity of the chloroethanes was determined by measuring electrochemical half-wave reduction potentials. Chloroethanes with an E1/2 of - 1.35 V or less negative were reduced readily in microsomes while those with an E1/2 equal to or more negative than -1.90 V were not good substrates for enzymatic reduction. Metabolites produced from 1,1,1,2-tetrachloroethane in vitro were 1,1-dichloroethylene (DCE) and 1,1,2-trichloroethane (TCEA) and the ratio DCE/TCEA was about 25:1. These conversions were NADPH-dependent and were inhibited by air, CO and metyrapone. In the presence of SKF 525-A, DCE formation was inhibited by 47%. Microsomes from untreated or beta-naphthoflavone-treated rats were 70-90% less active than microsomes from phenobarbital-treated rats. The Km was 0.50 mM and the Vmax was 66 nmol min-1 mg-1 protein for DCE formation. The results are consistent with the proposal that 1,1,1,2-tetrachloroethane is reduced by hepatic cytochrome(s) P-450 to a free radical intermediate which, for the most part, remains closely associated with the enzyme, is reduced further and undergoes beta-elimination of a chloride ion to form DCE. The occurrence of this reductive pathway in vivo was demonstrated by the quantitation of DCE and TCEA in blood from rats treated with 1,1,1,2-tetrachloroethane.

Effect of halomethanes on intracellular calcium distribution in hepatocytes

Exposure of isolated rat hepatocytes to hepatotoxic halomethanes results in a 40-60% decrease in intracellular Ca2+ content. The order of halomethane potency (CBrCl3 CCl4 CHCl3) suggests that this effect requires halomethane metabolism by the hepatic mixed function oxidase system. Although the Ca2+ sequestering ability of the endoplasmic reticulum is destroyed by CBrCl3 and CCl4, it appears that much of the Ca2+ lost from the cell is mitochondrial in origin. Paradoxically, saturating concentrations of CCl4 cause a marked increase in cell Ca2+. CCl4 also causes an acute increase in cytoplasmic free Ca2+ (from about 60 nM to about 90 nM), but this effect does not appear to require CCl4 metabolism and is probably a result of direct action of CCl4 on the plasma membrane.

On the mechanism of butylated hydroxytoluene-induced hepatic toxicity in rats

The relations between serum transaminase activity and the hepatic contents of glutathione and lipid peroxide were examined following oral administration to rats of butylated hydroxytoluene (BHT; 500 or 1000 mg/kg). The glutathione level rapidly diminished and reached a minimum at 6 hr after BHT administration. The period of depletion was dependent on dose: restoration of the glutathione level took longer in high-dose rats than in low-dose rats. The content of hepatic lipid peroxide was not markedly changed by BHT throughout the experimental period. The activity of glutathione S-transferase was not affected until 12 hr after BHT administration but, thereafter, it increased with time and was accompanied by elevation of the glutathione level. Though the activities of serum glutamate-oxaloacetate transaminase and glutamate-pyruvate transaminase were not affected by low-dose BHT, they increased rapidly in the high-dose rates after a lag period of about 6 hr and reached a maximum at 24 hr after administration; at that time, the livers of the high-dose rats showed centrilobular necrosis. The results indicate that acute hepatic injury was induced by the high-dose BHT. Pretreatment with cobaltous chloride inhibited the increase in the activities of the serum transaminases produced by the high-dose of BHT accompanying the depletion of microsomal cytochrome P-450 content and the induction of glutathione content. These observations suggest that hepatic damage was associated with prolonged depletion of glutathione rather than with lipid peroxidation in the liver, and that the activated metabolites of BHT rather than the parent compound induced the tissue damage.

Evidence against involvement of calcium in carbon tetrachloride-dependent inhibition of lipid secretion by isolated hepatocytes

Carbon tetrachloride (CCl4)-induced inhibition of very low density lipoprotein (VLDL) secretion was studied in isolated hepatocytes. The hypothesis that inhibition of secretion is due to altered calcium homeostasis following CCl4-dependent inhibition of endoplasmic reticulum calcium sequestration was investigated. Inhibition of VLDL secretion by CCl4 was not dependent on extracellular calcium, since inhibition occurred when extracellular calcium was reduced to 0.1 microM. CCl4 inhibited hepatocyte VLDL secretion more rapidly than it inhibited microsomal calcium sequestration. Further, the concentration of CCl4 that produced half-maximal inhibition of VLDL secretion was about one-half the concentration required to produce half-maximal inhibition of microsomal calcium sequestration. The calcium ionophore A23187 did not mimic the action of CCl4 in inhibiting VLDL secretion under conditions in which A23187 altered cellular calcium homeostasis. The results that an alteration of calcium homeostasis is not involved in inhibition of VLDL secretion by carbon tetrachloride.

Circadian periodicity of tissue glutathione and its relationship with lipid peroxidation in rats

Circadian fluctuations in tissue glutathione (GSH) concentrations and lipid peroxidation in male Sprague-Dawley rats were investigated. Blood and all the organs studied exhibited distinct circadian variation both in GSH concentrations and peroxidation of polyunsaturated fatty acids. There was a great variation among organs in the periodicity and amplitude of the fluctuations in GSH concentrations. Liver displayed the highest variation (approximately 50%) followed by stomach (approximately 37%), heart (approximately 25%) and kidney (approximately 19%). The changes in other organs were significant but of less magnitude. Implications of such variations and caution in interpretation of experimental results in response to the exposure of animals to xenobiotics are discussed.

Protection of hepatocytes with hyperoxia against carbon tetrachloride-induced injury

Hyperbaric oxygen (HPO) was administered to rats (100% O2 at 2.8 atm for 90 min) immediately or 1 hr after severe carbon tetrachloride (CCl4) intoxication in order to study the mechanisms of protection against hepatocellular injury by hyperoxia. Slight to moderate hepatocellular injury was observed, particularly by morphologic criteria, 4 hr after CCl4 intoxication. Little cell death was observed; 24 hr after CCl4, 20% of the untreated animals died. In the survivors, the following typical changes occurred in the liver: extensive hepatocellular swelling, vacuolization and necrosis; severe ultrastructural alterations; binding of CCl4 to microsomal lipids; elevation of lipid peroxidation products (conjugated dienes); little decrease in cytochrome b5 and severe decrease in cytochrome P-450 levels. Serum transaminase (alanine aminotransferase and aspartate aminotransferase) levels were elevated. Immediate treatment with HPO prevented the mortality and markedly decreased the hepatocellular necrosis 24 hr after intoxication. Immediate HPO treatment did not lower the levels of free CCl4 in the liver. However, the rise in lipid peroxidation products caused by CCl4 intoxication at 4 hr was reduced. Delayed treatment with HPO (1 hr after CCl4) prevented the mortality but was less effective in preventing necrosis. Some hepatocellular protection was still demonstrable. In particular, the rise in lipid peroxidation products was reduced. Hyperoxia protects hepatocytes against CCl4 toxicity. The rapid decline in protective effect within 60 min of intoxication suggests that hyperoxia inhibits CCl4 activation and/or damage from molecular intermediates. Hyperoxia has little effect on the progression of sublethal injury to cell death in the livers of CCl4-intoxicated rats.

Interaction of the oncolytic drug, 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea with the mixed-function oxidase system in rats

Effects of 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea (CCNU) on the hepatic mixed-function oxidase system in male rats were studied both in vivo and in vitro. A single dose of CCNU (40 mg/kg) caused a significant reduction in hepatic mixed-function oxidase activities within 3 days after administration. The depression was prolonged for cytochrome P-450, total haem and the metabolism of several type I substrates lasting up to 10 weeks after a single dose. By contrast, aniline hydroxylase, cytochrome b5 and NADPH-cytochrome c reductase activities returned to near control levels after week two. Microsomal enzymes in the kidneys of treated animals however, were unaltered. Serum glutamic pyruvic and glutamic oxaloacetic transaminase and bilirubin levels, indicators of hepatotoxicity, were greatly elevated 3 days after CCNU treatment. These parameters fell rapidly but were still above control levels to the end of the 10-week study. When added in vitro, CCNU reduced apparent cytochrome P-450 content and the metabolism of type I substrates in microsomes from untreated, phenobarbital (PB) and 3-methylcholanthrene (3-MC)-pretreated rats. Total haem and NADPH-cytochrome c reductase were not affected whereas aniline hydroxylase activity was activated. CCNU interacted with hepatic microsomes to produce a type I difference spectrum.

Proliferative response and renewal of hepatic function following cocaine administration in mice

Experiments were undertaken to investigate the hepatic, temporal and spatial sequence of events following a single injection of cocaine, a known hepatotoxin. Centrilobular necrosis was induced in male mice (DBA/2Ha) 24 hr post-injection (PI). The time course of hepatic damage was monitored by assaying microsomal cytochrome P450 content, the activity of microsomal FAD-containing monooxygenase (FAD-M) and by determining the levels of serum glutamic pyruvic transaminase (SGPT). Kinetics of the onset of DNA synthesis were determined by autoradiography of thin liver sections and the incorporation of 3H-methyl thymidine into perchloric-acid-precipitable material. There was no increase in the labelling index (LI) and thymidine (TdR) incorporation in the first 24 hr PI. The LI rose to 14.6% and TdR incorporation showed a 5-fold increase over control values 48 hr PI. Both indices declined slightly at 72 hr PI and returned to control values by 96 hr PI. In contrast, the cytochrome P450 content declined by 69%, the FAD-M activity dropped by 40% and the SGPT levels showed an 18-fold increase at 24 hr PI, coincident with cytological signs of necrosis. Although the patterns of recovery differed between these selected enzymes, normal values were attained by 96 hr PI. These results demonstrate that cell damage and hepatic dysfunction precede the onset of DNA synthesis and subsequent proliferation.

Mechanisms of the killing of cultured hepatocytes by hydrogen peroxide

Mechanisms of H2O2-induced cell injury were explored in primary cultures of rat hepatocytes. Cells prepared from male rats and cultured for 1 day prior to treatment were killed by H2O2 either added directly to the medium at 0.25-2 mM or generated in situ by glucose oxidase (0.25-2 U/ml) or xanthine oxidase (20-120 mM/ml) and 2 mM xanthine. Catalase protected the cells in each case. Lipid peroxidation as measured by the accumulation of malondialdehyde (MDA) preceded the cell death due to H2O2 added directly to the cultures or generated in the medium. The antioxidants N,N'-diphenyl-p-phenylenediamine (DPPD) and promethazine prevented the accumulation of MDA in both cases and protected the cells treated with H2O2 directly. DPPD and promethazine did not react directly with H2O2. Other antioxidants including butylated hydroxytoluene, vitamin E, and N-propylgallate had varied protective activity against the addition of H2O2 in proportion to their ability to reduce MDA accumulation. In glucose oxidase-treated cultures, DPPD and promethazine prevented the cell killing during the first hour but failed to protect between 1 and 3 h despite prevention of lipid peroxidation. The cell killing between 1 and 3 h in the presence of DPPD was prevented by catalase indicating its dependence upon continued generation of H2O2. Further addition of H2O2 in the presence of DPPD also increased the number of dead cells without lipid peroxidation. The data are consistent with at least two mechanisms of hepatocyte killing by H2O2. The first pathway is prevented by the antioxidants DPPD and promethazine and is very likely related to the peroxidation of membrane phospholipids. The second is independent of lipid peroxidation yet dependent upon the continued presence of H2O2.

An investigation of the mechanism of hepatotoxicity of the antitumour agent N-methylformamide in mice

N-Methylformamide (NMF) has been reported to cause liver damage in animals and man. This hepatotoxicity was characterized in BALB/c mice by the release of liver enzymes into the plasma and by histopathological examination of livers after single and repeated administration of NMF. Whereas plasma levels of sorbitol dehydrogenase were elevated dramatically 24 hr after 400 mg/kg given as a single dose, the glutathione content of the livers was not different from controls even after repeated administration. Liver damage was apparent on gross inspection and was defined as periacinar necrosis on histopathology. A dose of 100 mg/kg did not cause damage even after repeated injections on five consecutive days. The hypothesis that NMF is metabolized to a chemically reactive species was tested. Incubation of mouse hepatocytes with 7 mM NMF for 80 min produced a decrease in intracellular glutathione. Exposure of hepatocytes to NMF for 240 min led to the production of breakdown products of lipid peroxides at levels significantly above controls. However, incubation of microsomes or mitochondria with NMF and NADPH did not lead to raised levels of lipid peroxides. The effects described were specific to NMF as incubation of N,N-dimethylformamide, N-hydroxymethylformamide or formamide with hepatocytes did not result in glutathione depletion or increased lipid peroxidation. NMF undergoes extensive metabolism in vivo and the results indicate that NMF forms a chemically reactive metabolite, even though incubation of the drug with liver fractions or hepatocytes did not lead to metabolites at levels which were analytically identifiable.

New developments in the regulation of heme metabolism and their implications

Various endogenous and exogenous chemicals, such as hormones, drugs, and carcinogens and other environmental pollutants are enzymatically converted to polar metabolites as a result of their oxidative metabolism by the mixed-function oxidase system. This enzyme complex constitutes the major detoxifying system of man and utilizes the hemoprotein--cytochrome P-450--as the terminal oxidase. Recent studies with trace metals have revealed the potent ability of these elements to alter the synthesis and to enhance the degradation of heme moiety of cytochrome P-450. An important consequence of these metal actions is to greatly impair the ability of cells to oxidatively metabolize chemicals because of the heme dependence of this metabolic process. In this report the effects of exposure to trace metals on drug oxidations is reviewed within the framework of metal alterations of heme metabolism, including both its synthesis and degradation, since these newly discovered properties of metals have made it possible to define a major dimension of metal toxicity in terms of a unified cellular mechanism of action.

Chemically induced nephrotoxicity: role of metabolic activation

Renal xenobiotic metabolism can result in production of electrophiles or free radicals that may covalently bind macromolecules or initiate lipid peroxidation. The mechanisms of renal xenobiotic metabolism may vary in different anatomical regions. Kidney cortex contains a cytochrome P-450 system while medulla contains a prostaglandin endoperoxidase. Recently cysteine conjugated-lyase has been implicated in production of reactive intermediates. Metabolic activation may be amplified by accumulation of xenobiotics within renal cells due to tubular concentrating and/or secretory mechanisms. Additionally, renal xenobiotic detoxicification can occur by conjugation with glucuronide, sulfate or glutathione.

Interaction of metals and carbon tetrachloride on lipid peroxidation and hepatotoxicity

Rats were administered ferrous sulfate, cadmium chloride, or sodium vanadate alone and in combination with carbon tetrachloride (CCl4) to determine if lipid peroxidation is associated with the toxicity of the three metals and to determine if there is an interaction between these metals and CCl4 in producing lipid peroxidation and hepatotoxicity. Expired ethane was used as an index of lipid peroxidation while serum alanine aminotransferase (ALT) and histopathology were used to assess liver damage. Lipid peroxidation did not appear to be associated with the hepatotoxicity of cadmium since no measurable increase in ethane production was observed when serum ALT concentrations were doubled relative to controls. Cadmium did not increase ethane when administered with CCl4 and the increase in ALT was additive. Iron and vanadate produced small significant increases in ethane production but no increase in ALT and only minor histopathologic changes, yet potentiated lipid peroxidation and liver damage when administered with CCl4. Thus, Cd did not produce lipid peroxidation and did not potentiate the lipid peroxidation and hepatotoxicity of CCl4, while iron or vanadate which produced lipid peroxidation alone potentiated the lipid peroxidation and hepatotoxicity of CCl4.

Isopropanol enhancement of cytochrome P-450-dependent monooxygenase activities and its effects on carbon tetrachloride intoxication

Acute or chronic treatment of rats with isopropanol caused a significant increase in hepatic cytochrome P-450 content and a two- to threefold increase in aniline hydroxylase and 7-ethoxycoumarin O-deethylase activities, but no significant change in ethylmorphine N-demethylase or benzo(a)pyrene hydroxylase activity. In rats treated with isopropanol and challenged with CCl4, liver toxicity of CCl4 was characteristically potentiated, as assessed by elevation of serum glutamic-pyruvic transaminase (SGPT) levels. Isopropanol pretreatment also potentiated CCl4-induced damage to the hepatic monooxygenase system. In addition to a decrease in cytochrome P-450, rats treated with isopropanol and challenged with CCl4 showed a nonspecific decrease not only in aniline hydroxylase and 7-ethoxycoumarin O-deethylase activities, but also in ethylmorphine N-demethylase, benzo(a)pyrene hydroxylase, and NADPH-cytochrome c reductase activities. These results were confirmed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of solubilized microsomes. The electrophoretic results showed that isopropanol pretreatment markedly potentiated the CCl4-caused destruction of cytochrome P-450 hemeproteins. The data strongly suggest that isopropanol increases one or more forms of cytochrome P-450 which selectively enhance the metabolism of CCl4 to an active metabolite. This active metabolite then causes a nonselective damage to the microsomal mixed-function oxidase system.

Enzymes involved in glutathione metabolism in rat liver and blood after carbon tetrachloride intoxication

Some glutathione-metabolizing enzymes in rat liver cytosol, blood plasma and urine of rats administered carbon tetrachloride (CCl4) were investigated. After CCl4 at different doses (0.3, 1.2, 2.5 ml/kg at 24, 12 and 3 or 6 h, respectively) liver glutathione reductase (GR), glyoxalase I (GLY-I) and glutathione S-transferases (GST) significantly decreased, while thioltransferase and glutathione peroxidase (GPX) did not change their activity. At the times under investigation the glutathione level significantly increased in the liver and the above-mentioned enzymes in plasma, thus evidencing a liver injury. The GR, GPX and GST assayed in urine within 72 h after CCl4 administration showed a maximum of activity at 35-48 h.

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.

A study of hepatic protein synthesis, three subcellular enzymes, and liver morphology in chronically ethanol fed rats

Male Wistar rats were given ethanol chronically (20-30% of the energy as ethanol) in a nutritionally sufficient regimen. Controls received lipid as isoenergetic substitute for ethanol. Treatment lasted for 2 or 8 weeks. Hepatic protein synthesis was measured in fasted rats during a 32 min. continuous infusion of 3H-valine. After 2 weeks of treatment accumulation of hepatic protein was observed in the ethanol group, but there was no change in hepatic protein synthesis or morphology. After 8 weeks the rate of hepatic protein synthesis was decreased by 35% in the ethanol group, but there was no accumulation of protein and a slight accumulation of intracellular lipid droplets. Neither the subcellular distribution of incorporated 3H-valine, nor the activities and distributions of alcohol dehydrogenase and NADPH cytochrome c reductase were changed. Mitochrondrial cytochrome c oxidase activity was decreased in the ethanol group, and cytosolic and microsomal fractions showed higher cytochrome c oxidase activity in this group. Chronic ethanol treatment for 8 weeks had an adverse effect on general protein synthesis as well as on a specific enzyme in the liver in the absence of serious morphologic abnormalities.

Reaction of the trichloromethyl and halothane-derived peroxy radicals with unsaturated fatty acids: a pulse radiolysis study

The absolute rates of reaction of the trichloromethylperoxy radical, CCl3OO., derived from carbon tetrachloride and the halothane peroxy radical, CF3CHClOO., with oleic, linoleic, linolenic and arachidonic acids have been determined using the fast reaction technique of pulse radiolysis. In general, the rates of reaction of the radical derived from carbon tetrachloride are approximately five times greater than those for the halothane related radical. In both cases the rate constant increases with increasing unsaturation of the fatty acid in agreement with the known greater susceptibility of polyunsaturated fatty acids to peroxidative decomposition.

Carbon tetrachloride and bromotrichloromethane toxicity. Dual role of covalent binding of metabolic cleavage products and lipid peroxidation in depression of microsomal calcium sequestration

We have investigated the importance of covalent binding and lipid peroxidation on the depression of microsomal calcium sequestration associated with in vitro metabolism of 14CCl4. Studies with CBrCl3 are also reported. In aerobic systems, promethazine was used to block lipid peroxidation, measured as malondialdehyde (MDA) generation. Effects of low levels of lipid peroxidation were tested in Fe2+-supplemented systems free of halogenated hydrocarbons. The results indicate that microsomal calcium sequestration can be depressed significantly by metabolism of either CCl4 or CBrCl3 in the absence of MDA generation, or by lipid peroxidation occurring in the absence of halogenated hydrocarbons.

Fasting increases the concentrations of carbon tetrachloride and of its metabolite chloroform in the liver of mice

Fasting mice for 24 h strongly enhanced hepatic triglyceride concentrations as well as the hepatic levels of carbon tetrachloride (CCl4) and chloroform (CHCl3) after i.p. injection of 0.1 ml/kg CCl4. The ratio CHCl3:CCl4 was lower in the livers of the fasted than in those of the fed mice. Fasting-induced steatosis leading to an increased affinity of the liver to a lipophilic compound like CCl4 is considered to be the cause for the increase in CCl4 hepatotoxicity induced by fasting in mice.

Interaction between ethanol and carbohydrate on the metabolism in rat liver of aromatic and chlorinated hydrocarbons

Metabolic rates of eight hydrocarbons (benzene, toluene, styrene, chloroform, carbon tetrachloride, 1,2-dichloroethane, 1,1-dichloroethylene, and trichloroethylene) were measured in vitro with the livers from rats that had consumed ethanol for 3 weeks in combination with various diets. Ethanol and carbohydrate antagonized each other in connection with activity of hepatic drug-metabolizing enzymes (mixed-function oxidases); the former increased and the latter decreased these enzymes. A decrease (increase) in carbohydrate intake augmented (suppressed) the action of ethanol in a dose-related manner. In particular, a combination of ethanol with a low-carbohydrate diet (DeCarli and Lieber diet) enhanced enzyme activity and potentiated carbon tetrachloride-induced hepatotoxicity. Enhancement of metabolism and potentiation of toxicity were due to the combination rather than to ethanol per se.

Application and results of whole-body autoradiography in distribution studies of organic solvents

With the growing concern for the health hazards of occupational exposure to toxic substances attention has been focused on the organic solvents, which are associated with both deleterious nervous system effects and specific tissue injuries. Relatively little is known about the distribution of organic solvents and their metabolites in the living organism. Knowledge of the specific tissue localizations and retention of solvents and solvent metabolites is of great value in revealing and understanding the sites and mechanisms of organic solvent toxicity. Whole-body autoradiography has been modified and applied to distribution studies of benzene, toluene, m-xylene, styrene, methylene chloride, chloroform, carbon tetrachloride, trichloroethylene and carbon disulfide. The high volatility of these substances has led to the development of cryo-techniques. Whole-body autoradiographic techniques applicable to the study of volatile substances are reviewed. The localizations of nonvolatile solvent metabolites and firmly bound metabolites have also been examined. The obtained results are discussed in relation to toxic effects and evaluated by comparison with other techniques used in distribution studies of organic solvents and their metabolites.

The effects of ethylene chlorohydrin on fatty acid synthesis

Male chicks weighing 700 to 900 g. received an acute or eight doses IG of 60 or 40 mg/kg ethylene chlorohydrin (ECH) respectively and were sacrificed eighteen hours after the last dose. Mitochondrial elongation of fatty acids was decreased significantly while fatty acid synthetase activity was not significantly affected by ECH treatment. Cytochrome c oxidase activity in fresh whole liver homogenate was significantly higher in chicks subjected to acute exposure with ECH when compared to the controls. Upon freezing and thawing of homogenates, cytochrome c oxidase activity increased significantly in the control group but was unchanged in the ECH group which suggests that the mitochondrial membrane integrity is compromised by the ECH treatment. Serum and liver triglyceride levels were significantly elevated in both the single and multiple ECH dose groups. Liver to body weight ratios were significantly higher in both treatment groups when compared to their controls. Histological examination of the liver of ECH-treated chicks showed cytoplasmic clearing of the cells but no vacuolization or centrilobular necrosis. Serum isocitrate dehydrogenase levels were significantly higher in the multiple treatment ECH group than in the control group.

Evidence of enhanced in vivo lipid peroxidation after acute cocaine administration

An acute intraperitoneal dose (60 mg/kg) of cocaine to DBA/2Ha male mice results in enhanced lipid peroxidation in vivo, as measured by an increase in conjugated diene absorption in hepatic microsomal lipids. The initiation of this lipid peroxidation is an early consequence of cocaine administration; as early as 1 h after cocaine, peroxidized lipids are significantly greater in treated animals than in controls. This cocaine-induced lipid peroxidation remains at a maximal level from 2 to 4 h and returns approximately to control levels by 8 h. The metabolites of cocaine also produce lipid peroxidation in vitro. Liver microsomes from phenobarbital-treated DBA/2Ha male mice, incubated aerobically in the presence of NADPH, cocaine or the cocaine oxidative metabolites, norcocaine and norcocaine nitroxide, induced lipid peroxidation as measured by an increase in the production of thiobarbituric acid (TBA)-reactive products. The extent of lipid peroxidation is greater for the oxidative metabolites of cocaine than for cocaine itself.

Studies on hydrazine hepatotoxicity. 2. Biochemical findings

Hydrazine causes a dose-related increase in liver triglycerides and in liver weight and causes a decrease in hepatic glutathione. The threshold dose for the toxic effect is around 10 mg/kg, and the optimal effect is seen after a dose of 40 mg/kg. The effect of hydrazine on liver weight and glutathione was detectable within 30 min of dosing, but the elevation of hepatic triglycerides was not detectable until 4 h after dosing. At 24 h after a dose of 60 mg hydrazine/kg, hepatic reduced glutathione was approximately 50% of the control value and triglycerides were about 7 times the normal level. In vitro studies indicated that hydrazine is metabolized by rat liver microsomal enzymes, this being dependent on NADPH and oxygen. Pretreatment of animals with phenobarbital or piperonyl butoxide respectively decreases and increases the hepatotoxicity. Prior depletion of hepatic glutathione by administration of diethyl maleate had no effect on the toxicity. Pyruvate azine, a probable metabolite of hydrazine, is much less toxic than hydrazine itself on a molar basis. These and other results suggest that although hydrazine is metabolized via several routes, the hepatotoxicity may well be due to the parent compound rather than a metabolite.

Studies on hydrazine hepatotoxicity. 1. Pathological findings

The pathogenesis and factors affecting hydrazine-induced fatty liver have been investigated in rats using histological and ultrastructural examination. A dose of 20 mg hydrazine/kg caused the accumulation of lipid, swelling of mitochondria, and the appearance of microbodies in both periportal and midzonal hepatocytes and in the proximal tubular cells of the kidney. These changes were detectable by light or electron microscopy 24 h after dosing with hydrazine. A dose of 60 mg/kg was the highest dose tolerated for 24 h, but the severity of the fatty liver was similar to that after a dose of 40 mg/kg. The accumulation of lipid droplets and the swelling of mitochondria were detectable by electron microscopy 30 min after dosing, but the accumulation of fat could not be detected by light microscopy until 4 h after dosing. Pretreatment of animals with phenobarbital or piperonyl butoxide respectively reduced and increased the severity of the fatty liver. Pyruvate azine was much less toxic than the parent hydrazine on a molar basis, although some fatty vacuolation was detectable in midzonal hepatocytes.

Effect of hypoxia on carbon tetrachloride hepatotoxicity

The effect of hypoxia on carbon tetrachloride-induced hepatotoxicity was studied. Male rats were exposed to carbon tetrachloride for 2 hr in the presence of differing oxygen concentrations. Serum glutamate-pyruvate transaminase (SGPT) activities were measured 24 hr after the end of the exposure. Exposure of rats to 5000 ppm carbon tetrachloride in the presence of 100, 21, 12, or 6% oxygen resulted in SGPT activities of 489, 420, 3768, and 1788 I.U./l respectively. Exposure of rats to air and 0, 1250, 2500, 5000, or 7500 ppm carbon tetrachloride gave SGPT activities of 35, 32, 69, 420, and 2188 I.U./l respectively; when 12% oxygen was used, the corresponding SGPT activities were 32, 665, 691, 3768, and 4200 I.U./l respectively. Exposure of rats to hypoxia produced histopathologically detectable condensation of hepatic cytoplasmic material, and exposure to 5000 ppm carbon tetrachloride in the presence of air produced mild centrilobular necrosis, which was much more severe when rats were exposed to 5000 pm carbon tetrachloride in the presence of 12% oxygen. Hepatic microsomal conjugated diene concentrations were increased by hypoxia and by exposure to carbon tetrachloride, but no synergistic interaction was observed. Hepatic microsomal cytochrome P-450 concentrations were decreased after exposure to carbon tetrachloride, but were the same after exposure to carbon tetrachloride and 12 or 21% oxygen. Hepatic carbon tetrachloride concentrations were the same in rats exposed to carbon tetrachloride in the presence of 12 or 21% oxygen; hepatic chloroform concentrations were higher in rats exposed to carbon tetrachloride in the presence of air than in the presence of 12% oxygen. The covalent binding of [14C]carbon tetrachloride metabolites to hepatic microsomal lipids and proteins was increased markedly by hypoxia as compared with normoxia. The covalent binding of metabolites of carbon tetrachloride to cellular macromolecules may play a role in the potentiation of carbon tetrachloride toxicity by hypoxia.

Alcohol ingestion, liver glutathione and lipoperoxidation: metabolic interrelations and pathological implications

Data reviewed here indicate that acute and chronic ethanol ingestion induce a decrease in the concentration of GSH and an increase in lipoperoxidation in the liver both in experimental animals and in man, changes that are closely interrelated GSH depletion is suggested to be due to an oxidation in the liver tissue and to a translocation into the extrahepatic medium as free glutathione and/or as conjugates with ethanol-derived acetaldehyde. As a result, the hepatic GSH/GSSG ratio is drastically reduced. Lipoperoxidation seems to be related to the metabolism of ethanol and acetaldehyde by secondary pathways that are known to generate oxygen-related free radicals. Being lipoperoxidation a process associated with cell damage and death, its stimulation by ethanol ingestion could play a role in the production of alcoholic liver damage in man. The involvement of several contributory factors in the development of a high lipoperoxidative index in the liver in this situation is discussed.

Separation and characterization of the aldehydic products of lipid peroxidation stimulated by ADP-Fe2+ in rat liver microsomes

1. Methods using t.l.c. and high-pressure liquid chromatography (h.p.l.c.) have been used to separate the complex variety of substances possessing a carbonyl function that are produced during lipid peroxidation. 2. The major type of lipid peroxidation studied was the ADP-Fe2+-stimulated peroxidation of rat liver microsomal phospholipids. Preliminary separation of the polar and non-polar products was achieved by t.l.c.: further separation and identification of individual components was performed by h.p.l.c. Estimations were performed on microsomal pellets and the supernatant mixture after incubation of microsomes for 30 min at 37 degrees C. 3. The polar fraction was larger than the non-polar fraction when expressed as nmol of carbonyl groups/g of liver. In the non-polar supernatant fraction the major contributors were n-alkanals (31% of the total), alpha-dicarbonyl compounds (22%) and 4-hydroxyalkenals (37%) with the extraction method used. 4. Major individual contributors to the non-polar fraction were found to be propanal, 4-hydroxynonenal, hexanal and oct-2-enal. Other components identified include butanal, pent-2-enal, hex-2-enal, hept-2-enal, 4-hydroxyoctenal and 4-hydroxyundecenal. The polar carbonyl fraction was less complex than the non-polar fraction, although the identities of the individual components have not yet been established. 5. Since these carbonyl compounds do not react significantly in the thiobarbituric acid reaction, which largely demonstrates the presence of malonaldehyde, it is concluded that considerable amounts of biologically reactive carbonyl derivatives are released in lipid peroxidation and yet may not be picked up by the thiobarbituric acid reaction.

Isotoxic oral and inhalation exposure of carbon tetrachloride in Porton-Wistar and Fischer rats

Male Fischer or Porton-Wistar rats were exposed for 4 h to different atmospheric concentrations of CCl4 or were given increasing oral doses, of CCl4 in order to estimate isotoxic exposures or doses. Animals were killed 20 h after treatment, their serum glutamic-pyruvic transaminase activities were measured and their livers were processed for histological examination. It has been found that the equitoxic oral dose in Wistars is 1.5 times that in Fischer rats and more than 3 times after inhalation. Therefore, the conversion factors from inhalation exposure to oral dose were much higher for Fischer than for Porton-Wistar rats. After oral dosing, the extent of centrilobular damage in Fischer rats was approximately twice that in Porton-Wistar rats. After inhalation exposure, the extent of damage was the same in the two strains, but at least at the two lower exposure levels hydropic degeneration definitely contributed to the size of the damaged areas more in Porton-Wistar than in Fischer rats.

Bioactivation of halogenated hydrocarbons

Halogenated hydrocarbons are an economically and toxicologically important group of chemicals. These compounds may produce toxic effects after metabolism to stable, but toxic, products or to reactive, electrophilic intermediates. The biotransformation reaction may involve oxidative or reductive reactions or may proceed with no change in oxidation state. The bioactivation reactions are catalyzed most frequently by cytochrome P-450-dependent monooxygenases, but glutathione S-transferases may also catalyze bioactivation reactions. Detailed reaction mechanism studies are useful in understanding the biotransformation and bioactivation pathways of halogenated hydrocarbons.

Pharmacological properties of Dibenzo[a,c]cyclooctene derivatives isolated from Fructus Schizandrae Chinensis III. Inhibitory effects on carbon tetrachloride-induced lipid peroxidation, metabolism and covalent binding of carbon tetrachloride to lipids

Fructus Schizandrae, a traditional Chinese tonic, has been shown to lower the elevated serum glutamic pyruvic transaminase (SGPT) levels of patients with chronic viral hepatitis and several of its components decrease the hepatotoxicity of carbon tetrachloride (CCl4) in animals. This paper deals with the mechanism of protection against CCl4-hepatotoxicity of these compounds as well as of DDB, a synthetic analogue of Schizandrin (Sin) C. Of the seven components, Sin B and C, Schizandrol (Sol) B, Schizandrer (Ser) A and B, as well as dimethyl-4,4'-dimethoxy-5,6,5',6'-dimethylenedioxy-biphenyl-2,2'-dicarboxylate (DDB) were shown to inhibit CCl4-induced lipid peroxidation and [14C]Cl4 covalent binding to lipids of liver microsomes from phenobarbital(PB)-treated mice. The compounds also decreased carbon monoxide (CO) production and cofactor (NADPH, oxygen) utilization during CCl4 metabolization by liver microsomes. It may be postulated, therefore, that the hepatoprotective effect of certain components isolated from Fructus Schizandrae as well as DDB is due to their inhibitory effect on CCl4-induced lipid peroxidation and the binding of CCl4-metabolites to lipids of liver microsomes.

Effect of lipid peroxidation on p-aminohippurate transport by rat kidney cortical slices

1 The effect of lipid peroxidation on p-aminohippurate transport by rat kidney slices was examined. 2 Ascorbic acid and Fe2+ promoted lipid peroxidation of rat renal cortical slices in a dose-related manner. 3 Ascorbic acid (1.0 mM) and Fe2+ (0.4 mM) increased tissue water and decreased the accumulation of p-aminohippurate. 4 The addition of N,N'-diphenyl-p-phenylenediamine (antioxidant), at a concentration of 1 x 10(-6) M, completely inhibited the peroxidation and recovered the accumulation of p-aminohippurate. 5 The apparent Km of p-aminohippurate uptake was increased by ascorbic acid and Fe2+ with no change in the apparent V. 6 These data suggest that ascorbic acid and Fe2+ can cause a significant alteration in p-aminohippurate and water transport of renal cortical slices and that these effects can be correlated with lipid peroxidation.