C.R. de Castro

N-Acetyl cysteine is an early but also a late preventive agent against carbon tetrachloride-induced liver necrosis

N-Acetyl cysteine (NAC) treatment 30 min before or 6 or 10 h after carbon tetrachloride (CCl4) administration significantly prevented the liver necrosis produced by the hepatotoxin at 24 h. NAC pretreatment was able to partially decrease the covalent binding of CCl4 reactive metabolites at 1 and 3 h of poisoning and, to a small extent, the concentration of CCl4 reaching the liver at 3 h. NAC also diminished partially the CCl4-promoted increases in lipid peroxidation at 3 h, but had an enhancing effect of its own of small intensity. Results suggest that early and late protective effects of NAC might be attributable to its prior conversion to cysteine and glutathione.

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.

Carbon tetrachloride activation by highly purified liver mitochondrial preparations

Highly purifled 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.

Effects of repeated administration of rat 2-diethylaminoethyl-2-2-diphenylvalerate-HCl (SKF 525 A) on liver

Repetitive administration to male rats of 2-diethylaminoethyl-2-2-diphenyl-valerate-HCI (SKF 525 A) (50 mg/kg, i.p.), decreases the intensity of [14C]-orotic acid incorporation/mg of RNA but not the 14C-incorporation/g liver. The RNA content/g liver is significantly higher in SKF-treated animals than in controls. Decay of label in liver RNA from [14C] orotic acid pretreated animals, is not significantly different in SKF 525 A treated animals than in controls. SKF 525 A repetitive administration, does not modify the rate of incorporation of 32P in liver microsomal lipid when results are expressed per microgram of inorganic phosphorus but it does when expressed in terms of per gram liver. There is a significant decrease in the decay rate of label from 32P-prelabeled liver microsomal phospholipids when animals are treated with SKF 525 A. There is a significant increase in the protein and phospholipid content in the smooth endoplasmic reticulum fraction. The electron microscopy of liver from SKF 525 A-treated animals, shows the presence of large areas of round vesicles of swollen endoplasmic reticulum, partly due to smooth component and part due to rough component, having detached the ribosomes from their membranes. Results suggest an inhibitory effect of SKF 525 A on RNA and phospholipid degradative processes.

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 early biochemical alterations but not necrosis in pigeon's liver.

In contrast to what is well known to occur in rats, pigeons recelving CCl4 (1 ml/kg i.p.) were not susceptible to necrogenic effects of the hepatotoxin at 24 h. There were, 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 metabolities are more relevant to early biochemical alterations induced by CCl4 than is lipid peroxidation. Absence of CCl4-induced necrosis in pigeon liver could be attributabie to a smaller intensity of covalent binding interactions observed, when compared to susceptible specles, and to absence of lipid peroxidation.

Effects of carbon tetrachloride on the liver of chickens. Early biochemical and ultrastructural alterations in the absence of detectable lipid peroxidation

Administration of CCl4 i.p. to Leghorn chickens did not promote lipid peroxidation of liver microsomal lipids, as evidenced by either increased diene conjugation or by decreased arachidonic acid content. The hepatotoxin did not produce liver necrosis 24 h after dosing, but decreased the cytochrome P-450 content, and aminopyrine N-demethylase and glucose 6 phosphatase activities at 1, 3, 6 and 24 h. CCl4 administration produced dilation of the rough endoplasmic reticulum and detachment of ribosomes from their membranes. These observations suggest that lipid peroxidation is not the key event in the production of these biochemical and ultrastructural alterations, elicited by CCl4.