Prevention of CCl4-induced liver necrosis by the calcium chelator arsenazo III.

Arsenazo III (AIII) (100 mg/kg ip in saline) administration to Sprague-Dawley male rats 30 min before or 6 or 10 hr after CCl4 [1 ml/kg ip as a 20% (v/v) solution in olive oil] significantly prevented liver necrosis but not fatty liver caused by the hepatotoxin at 24 hr as demonstrated either by histology or by determination of isocitric acid dehydrogenase in plasma. AIII did not modify the CCl4 concentrations reaching the liver, the intensity of the covalent binding of CCl4-reactive metabolites to hepatic microsomal lipids, or the CCl4-promoted lipid peroxidation process at either 1 or 3 hr of poisoning. AIII administration enhanced glutathione (GSH) levels in liver and significantly prevented the CCl4-induced minor decreases in GSH content and the CCl4-induced increases in calcium content at 24 hr of intoxication. AIII treatment further enhanced the CCl4-induced decreases in body temperature of the poisoned rats. Results suggest that AIII's preventive effects might be related to its very well-known calcium-chelating properties, but that additional factors related to AIII's ability to increase GSH content in liver or to decrease body temperature of CCl4-intoxicated animals may also play a role.

Prevention of carbon tetrachloride-induced liver necrosis by the chelator alizarin sodium sulfonate.

The administration of the calcium chelator alizarin sodium sulfonate (ASR) (100 mg/kg ip in saline) 30 min before or 6 or 10 hr after CCl4 (1 ml/kg ip as a 20% v/v solution in olive oil) partially prevents the necrogenic effect of the hepatotoxin at 24 hr, but prevention of CCl4 fat accumulation was not observed. Protective action cannot be attributed to potential decreasing effects of ASR on CCl4 levels reaching the liver, on the covalent binding of CCl4-reactive metabolites to cellular components, or on CCl4-induced lipid peroxidation because ASR does not modify these parameters significantly. ASR administration increases GSH levels in livers of both control and CCl4-poisoned animals and decreases the calcium content of intoxicated animals at 24 hr of poisoning. ASR significantly lowers the body temperature of CCl4-treated animals at different times of the intoxication process. Present and previous results from our laboratory on the preventive effects of another very specific calcium chelator, calcion, and several anticalmodulins suggest that the beneficial effects of ASR might be associated with its calcium chelating ability. Other protective effects of ASR, such as lowering body temperature or increasing GSH content in liver, cannot be excluded.

Modulation of the course of CCl4-induced liver injury by the anti-calmodulin drug thioridazine.

Thioridazine (TDZ) administration to rats (50 mg/kg i.p.) 6 or 10 h after CCl4 treatment (1 ml/kg in olive oil i.p.) partially prevented necrogenic effects of this compound at 24 h but not at 72 h. TDZ did not have inhibitory effects on CCl4 activation, covalent binding (CB) of reactive metabolites to cellular constituents or CCl4-induced lipid peroxidation (LP). Moreover, TDZ had enhancing effects on both LP and CB. TDZ was able to increase protein and phospholipid synthesis and slightly but significantly enhanced protein but not phospholipid degradation in livers from control rats. TDZ administration decreased calcium liver content in CCl4-poisoned animals but did not change the intensity of CCl4-induced fatty liver. TDZ lowered body temperature in CCl4-treated animals during the 24 h observation period. These results and previous studies from our laboratory suggest calcium and calmodulin (CaM) participation in the CCl4 necrogenic effects on the liver but not in the hepatotoxin-induced fatty liver. TDZ-lowering effects on body temperature might also be a determinant in the delaying effects of this drug on the onset of CCl4-induced necrosis. Present experiments did allow discrimination between these two or other possible mechanisms for TDZ modulation effects.

Further studies on the mechanism of the late protective effects of phenylmethylsulfonyl fluoride on carbon tetrachloride-induced liver necrosis.

We previously reported that phenylmethylsulfonyl fluoride (PMSF) administration to rats (100 mg/kg, ip in olive oil) as late as 6 or 10 hr after CCl4 (1 ml/kg, ip as a 20% v/v solution in olive oil) can partially prevent the necrogenic response to the hepatotoxin at 24 hr. Here we confirm that observation by electron microscopy and provide further evidence that only in these circumstances were nuclear clumping of chromatin, slight dilatation of the endoplasmic reticulum, myelin figures and lipid droplets in the cytoplasm, large numbers of lysosomes and peroxisomes, glycogen, and slightly swollen mitochondria observable in the protected animals. A very minor part of the late protective effects of PMSF might be due to the effects of this drug on decreasing the intensity of covalent binding of CCl4-reactive metabolites or the intensity of CCl4-induced lipid peroxidation still occurring 6 or 10 hr after CCl4. PMSF administration did not prevent CCl4-induced decreases in cytochrome P450 content or glucose-6-phosphatase activity but partially prevented CCl4-induced calcium accumulation in liver. PMSF treatment increased glutathione and glycogen content in CCl4-poisoned animals, but did not markedly modify protein/phospholipid synthesis or degradation processes. Results suggest that the late protective effects of PMSF administration in CCl4-induced liver necrosis might be due to a favorable modulation of the calcium-calmodulin system similar to that previously described for other drugs.

Carbon tetrachloride-induced liver cell injury in the Mongolian gerbil (Meriones unguiculatus).

1. Male Mongolian gerbils (Meriones unguiculatus) liver activates CCl4 to free radicals that bind covalently to cellular components (CB) and stimulate a lipid peroxidation (LP) process to a larger extent than the rat liver. 2. CCl4 administration results in a less intense necrogenic effect in gerbils than in rats and does not cause fatty liver. 3. CCl4 causes less intense effects on liver ultrastructure or calcium metabolism but more marked depression of glucose 6 phosphatase activity (G6P-ase) in gerbils than in rats. 4. Results suggest that a better ability of gerbil liver to keep calcium homeostasis than rat liver might be the cause of their relative resistance to necrosis. Higher intensity of CB and LP in gerbils than in rats might explain more intense effects on G6P-ase.

Late preventive effects against carbon tetrachloride-induced liver necrosis of the calcium chelating agent Calcion.

In agreement with the hypothesis that changes in calcium homeostasis might be significant in late stages of chemically-induced liver cell injury, a calcium chelating agent, Calcion, was able to partially prevent CCl4-induced liver necrosis observed at 24 h, when treatment was given as late as 6 or 10 h after the hepatotoxin. Calcion had minor or no effects on covalent binding of reactive metabolites to cellular components, or on lipid peroxidation or on CCl4 levels reaching the liver. Calcion treatment of CCl4-poisoned animals decreased CCl4-induced calcium increases in liver and increased glutathione levels decreased by hepatotoxin at 24 h. Calcion treatment was not able to prevent CCl4-induced fatty liver. Calcion protective effects were body temperature dependent but they were cancelled when Calcion-treated poisoned animals were kept normothermic. Results suggest that Calcion protective effects might be linked to calcium chelation or alternatively that they might derive from decreases in body temperature.

Further studies on the late preventive effects of the anticalmodulin trifluoperazine on carbon tetrachloride-induced liver necrosis.

Trifluoperazine (TFP) (50 mg/kg ip) administration to rats 6 or 10 hr after CCl4 (1 ml/kg ip in olive oil) significantly prevented liver necrosis but not fatty liver caused by the hepatotoxin at 24 hr as evidenced by either histology or electron microscopy. TFP given 6 hr after CCl4 significantly decreased the CCl4-induced increases in liver calcium content. TFP raised four to five times the liver glycogen content in control rats but was unable to modify decreased glycogen content of CCl4 poisoned animals. TFP administration increased phospholipid and protein synthesis as evidenced by studies on 32P incorporation into microsomal phospholipid and by experiments on [14C]leucine incorporation in microsomal protein fractions from control rat livers. No significant changes were observed in microsomal phospholipid degradation as studied by decay of label from 32P-prelabeled microsomal lipids or in increased protein degradation as evidenced by decay of label from [14C-guanidino]arginine-prelabeled microsomal proteins found in livers of control rats after TFP treatment. Electron microscopy observations of liver from control animals treated with TFP evidenced accumulation of glycogen in areas close to smooth endoplasmic reticulum (SER); large Golgi areas with an abundant number of lysosomes, and minor dilatation effects on the rough endoplasmic reticulum (RER) and nuclear membrane. Results suggest that TFP preventive effects might be due to the anticalmodulin actions of this drug.

Glutathione (GSH) content in livers from control and carbon tetrachloride poisoned rats treated with the calmodulin inhibitors thioridazine, imipramine or chlorpromazine.

Administration to rats of the calmodulin (CaM) inhibitors Thioridazine (TDZ) or Imipramine (IMP) (50 mg/kg ip) or Chlorpromazine (CPZ) at a dose of 25 mg/kg, ip 6 hr after olive oil or CCl4 (1 ml/kg, ip as a 20% olive oil solution) significantly increased the GSH content in liver of CCl4 poisoned animals but not in controls. The analysis of present observations and past results with Trifluoperazine, suggest that increases in GSH content in CCl4 poisoned animals treated with protective anticalmodulins are a consequence of prevention and not the cause of their preventive effects.

Early biochemical alterations in liver mitochondria from carbon tetrachloride poisoned rats.

Covalent binding of reactive metabolites of 14CCl4 were found 1 or 3 h after treatment with the solvent in the lipid and protein fractions of highly purified liver mitochondrial of rats. Most of the label was found in the phospholipid (PL) fraction, much less in cholesterol esters (ChE), and only minor quantities in other lipids. The reactive metabolites of 14CCl4 activated by isolated mitochondria interact mostly with ChE and far less with PL and other fractions. Both in vivo and in vitro covalent binding to PL is decreasing in the following order: phosphatidylethanolamine greater than diphosphatidylglycerol greater than phosphatidylcholine greater than sphingomyelin greater than lysophosphatidyl choline. No evidence of lipid peroxidation was found in liver mitochondrial lipids in the first 6 h and only a slight tendency of decrease in arachidonic acid concentration at 24 h. The incorporation of [14C] leucine in mitochondrial, microsomal or cytosolic proteins decreased as early as 1 h after treatment. These results, in agreement with previous reports suggest the existence of multiple sites in liver cells for the activation of CCl4. The transport of altered phospholipids and proteins and the inhibition of protein synthesis might contribute to the propagation of damage from the endoplasmic reticulum to other organelles.

Imipramine prevention of carbon tetrachloride-induced liver necrosis at late states of the intoxication process.

Imipramine administration (50 mg kg-1, i.p.) to Sprague-Dawley male rats (240-290 g) 6 or 10 h after CCl4 (1 ml kg-1, i.p.) partially prevents liver necrosis induced by the hepatotoxin. When imipramine is given 30 min before CCl4, it inhibits in part the CCl4-induced lipid peroxidation and the covalent interactions of reactive metabolites with microsomal lipids or proteins and partially prevents CCl4-induced cytochrome P-450 destruction, but not glucose 6 phosphatase activity depression. Imipramine administration prior to CCl4 does not modify levels of the hepatotoxin reaching the liver or the body temperature of CCl4 treated animals. Early preventive effects of imipramine on cytochrome P-450, might be attributed to inhibition of covalent interactions of reactive metabolites. The hypothesis that imipramine exerted late preventive effects by interfering with calcium deleterious effects or by modulation of protein and phospholipid synthesis or degradation is analyzed.

Late preventive effects of trifluoperazine on carbon tetrachloride-induced hepatic necrosis.

As a very preliminary test for a possible role of calmodulin in CCl4-induced hepatic injury, we studied the effects of the anticalmodulin drug trifluoperazine (TFP) on several deleterious actions of CCl4 on the liver. TFP administrated 30 min before or 6 or 10 hr after CCl4 significantly prevented hepatic necrosis induced by the hepatotoxin at 24 hr but not at 72 hr. TFP did not modify the CCl4 concentrations reaching the liver, or the intensity of the covalent binding of CCl4-reactive metabolites to hepatic microsomal proteins or lipids or the CCl4-induced cytochrome P-450 and glucose 6 phosphatase destruction. TFP administration decreased body temperature between 0 and 1 degree C in controls and between 1.2 and 3.5 degrees C in CCl4-treated animals during the 24-hr observation period. When TFP-treated CCl4-poisoned animals were kept normothermic, protective effects were eliminated. One possibility is that the protective effect of TFP might be due to a nonspecific action related to decreased body temperature. Alternatively, prevention might result from TFP inhibition of a late-occurring process critical for CCl4-induced cell necrosis requiring calmodulin participation. If this alternative were in operation, protective consequences of this inhibitory effect of TFP should be either canceled or counteracted in the normothermic TFP + CCl4-treated animal.

Effect of chlorpromazine on protein, phospholipid and RNA synthesis or degradation in rat liver.

Chlorpromazine (CPZ) administration to rats (25 mg/kg ip) significantly stimulated (14C)-leucine incorporation to liver microsomal proteins, (14C)-orotic acid incorporation to liver RNA and (32P) incorporation to liver microsomal lipids. CPZ administration did not modify the decay of radioactivity of liver microsomal lipids prelabeled with (32P) or that of microsomal proteins prelabeled with [(14C)-guanidino]-arginine. Results suggest that CPZ administration stimulates protein, phospholipids and RNA synthesis but does not affect their degradation. The relation of these findings with CPZ preventive effects on CCl4-induced liver injury is discussed.

Carbon tetrachloride activation by highly purified liver mitochondrial preparations.

Highly purified rat liver mitochondrial preparations were found to be able to activate CCl4 to reactive metabolites that bind covalently to lipids. Part of the process is of an enzymatic nature, but most of it is non-enzymatic. The enzymatic mitochondrial CCl4 activation operates more efficiently under anaerobic conditions; it requires NADPH, is CO sensitive, is inducible by phenobarbital pretreatment and is only weakly inhibited by high concentrations of cyanide or azide. The non-enzymatic mitochondrial CCl4 activation is not inhibited by CO and proceeds equally well under air or nitrogen.

Carbon tetrachloride-induced early biochemical alterations but not necrosis in pigeon's liver.

In contrast to what is well known to occur in rats, pigeons receiving CCl4 (1 ml/kg i.p.) were not susceptible to necrogenic effects of the hepatotoxin at 24 h. There were, however, other early biochemical alterations observable, such as depression of glucose 6 phosphatase activity, decrease in the cytochrome P-450 content and in aminopyrine-N-demethylase activity in pigeon liver microsomes at 3 and 6 h after CCl4 administration. Pigeon liver was able to activate CCl4 to reactive metabolites that bind covalently to lipids, but no CCl4-induced lipid peroxidation was proved by the diene hyperconjugation technique in pigeon liver microsomes at 1, 3 or 6 h after administration. Results suggest that covalent binding of CCl4-reactive metabolites are more relevant to early biochemical alterations induced by CCl4 than is lipid peroxidation. Absence of CCl4-induced necrosis in pigeon liver could be attributable to a smaller intensity of covalent binding interactions observed, when compared to susceptible species, and to absence of lipid peroxidation.

Effect of cystamine on protein, phospholipid and RNA synthesis or degradation.

Cystamine administration to rats partially inhibited (14C)-leucine incorporation to microsomal proteins, and (14C) orotic acid incorporation to RNA but markedly stimulated (32P) incorporation to liver microsomal phospholipids. Cystamine administration did not modify the decay of radioactivity of liver microsomal lipids prelabeled with (32P) or of microsomal protein prelabeled with [(14C)-guanidino]arginine. Notwithstanding cystamine increased the RNA content in total liver. Results suggest that cystamine inhibits protein synthesis, stimulates phospholipid synthesis and inhibits RNA synthesis and degradation.

Studies on the mechanism of glutathione prevention of carbon tetrachloride-induced liver injury.

The prior administration of reduced glutathione (GSH) partially prevents carbon tetrachloride (CCl4)-induced liver necrosis observed at 24 h after administration of the hepatotoxin. No prevention occurs when observations are made at 72 h. GSH pretreatment does not significantly modify the intensity of the covalent binding of CCl4 reactive metabolites to microsomal lipids or the intensity of the CCl4-induced lipid peroxidation process at either 1, 3 or 6 h after poisoning. GSH administration does not significantly prevent CCl4-induced cytochrome P-450 destruction or glucose 6 phosphatase activity depression. Pretreatment with GSH does not significantly modify the levels of CCl4 or i.p. administered CCl4 reaching the liver at 1, 3 or 6 h after intoxication. Pretreatment with GSH significantly prevents CCl4-induced decreases in body temperature. Results are interpreted as suggesting that GSH prevents CCl4-induced liver necrosis by changing the liver cell's response to injury rather than by modification of early events of the process such as lipid peroxidation or covalent binding of reactive metabolites.

Carbon tetrachloride-induced liver injury in the rabbit.

CCl4 administration to rabbits leads to early destruction of liver microsomal cytochrome P-450, to depression of glucose 6 phosphatase, to ultrastructurally revealable alterations and to an intense necrosis and fat accumulation in liver. Despite the known resistance of rabbit liver microsomes to lipid peroxidation, CCl4 administration to rabbits promoted lipid peroxidation of their liver microsomal lipids as revealable by the diene hyperconjugation technique, at periods of time from 1 to 12 h. Nevertheless, the intensity of this process is not equivalent to that occurring in rat liver microsomes, since the arachidonic acid content of rabbit liver microsomal lipids does not decrease at either 6 or 24 h after CCl4 administration. Rabbit liver is able to activate CCl4 to reactive metabolites that bind covalently to lipids. Relevance of covalent binding of CCl4 reactive metabolites and CCl4-promoted lipid peroxidation to CCl4-induced rabbit liver injury is analysed.

No response of pigeon liver to dimethylnitrosamine acute effects.

No evidence for liver necrosis was observed at 24, 48 or 72 h after injection of dimethylnitrosamine (DMN) (70 mg/kg, i.p.) to pigeons. The assessment of possible liver necrosis was made by determination of isocitric dehydrogenase (ICD), glutamate oxalacetate transaminase (GOT) and glutamate pyruvate transaminase (GPT) in plasma. The ability of pigeon liver slices to metabolize CO2 or to give covalent binding of reactive metabolites to nucleic acids was 24 times smaller than that for rat. Similarly, the pigeon liver microsomes or 9000 X g supernatant have DMN-demethylase activity or ability to activate DMN to reactive metabolites that bind covalently to proteins very close to zero. Results suggest that resistance of pigeon liver to DMN acute effects is related to its lack of ability for DMN metabolic activation.

Studies on the mechanism of alloxan-diabetes potentiation of carbon tetrachloride-induced liver necrosis.

Carbon tetrachloride (CCl4)-induced liver necrosis in alloxan diabetic rats is markedly more intense than in controls as established by determination of isocitric dehydrogenase activity in plasma or by histological techniques. The covalent binding (CB) of CCl4 reactive metabolites to liver microsomal lipids is higher in alloxan diabetic rats than in controls. Cytochrome c reductase activity remains unchanged in alloxan diabetic rats. All the alterations described above observed in the diabetic animals are reverted by insulin administration. CCl4-induced lipid peroxidation of microsomal lipids, in contrast, is equally intense in controls than in alloxan diabetic animals and it is not modified by insulin treatment. Body temperature in alloxan diabetic animals treated with CCl4 is lower than in controls treated with the hepatotoxin. Results suggest that part of the enhanced necrogenic response of the liver observed in alloxan diabetic rats is due to increased CB to liver cell constituents but available evidence from the present and another work suggest that increased susceptibility of the liver from alloxan diabetic animals play a major role in the potentiation of CCl4 deleterious effects.

Covalent binding of carbon tetrachloride metabolites to the heme moiety of cytochrome P-450 and its degradation products.

Trichloromethyl free radicals (. CCI) produced during a benzoyl peroxide decomposition of CCl4 covalently bind to hemin. Enzymatically produced . CCl3 by an NADPH anaerobic liver microsomal activation of CCl4, covalently binds to heme and heme degradation products from CO-binding particles. 14C from CCl4 covalently binds to heme and heme degradation products from liver CL-binding particles from rats treated with 14CCl4. In vivo covalent binding of 14CCl4 reactive metabolites to proteins from CO-binding particles is higher than that to the whole microsomal proteins. The possible correlation between binding of . CCl3 to heme and protein moieties of P-450 and CCl4 induced P-450 destruction is discussed.