Effect of ethionine on synthesis and methylation of ribosomal ribonucleic acid in regenerating rat liver

Ethionine, a hepatocarcinogen, was administered into rats 24 h before partial hepatectomy and immediately thereafter. Hepatic precursor ribosomal RNA (pre-rRNA) obtained 20 h after the operation of rats injected with ethionine and adenine resulted in methyl deficiency as judged by the incorporation of [3H]methyl group of S-adenosylmethionine into nuclear rRNA by partially purified rRNA methylase. The ethionine and adenine treatment causes methyl deficiency of nuclear rRNA at 2'-hydroxyribose sites of cytidine and uridine, but not at base sites. Although the ethionine and adenine treatment produced no significant change in total hepatic RNA synthesis in vivo assayed by the incorporation of labeled orotate, a one-third increase in nuclear rRNA synthesis as well as a one-third decrease in microsomal rRNA synthesis was found under the treatment. These results suggest that the undermethylation at 2'-hydroxyribose of pre-rRNA in liver nucleus, which is caused by ethionine and adenine administration into rats, causes an inhibition of the processing of nuclear pre-rRNA to cytoplasmic rRNA.     

Poly(A)-containing RNA in the livers of ethionine-treated rats

Ethionine intoxication in nonfasted rats leads to a rapid change in the levels of poly(A)+ RNA. Prolonged fasting causes a decrease in poly(A)+ RNA which is not aggravated further by ethionine. The size distribution of poly(A) tracts at the 3' end of mRNA is not affected by ethionine. However, ethionine induces a change in the metabolism of the poly(A) sequence relative to the remainder of the mRNA.     

Functionally impaired tRNA from ethionine treated rats as detected in injected Xenopus oocytes.

Treatment of rats with ethionine was found to cause severe impairment in the aminoacylation capacity of tRNA. This effect was only observed when assayed in injected oocytes, while invitro assays of aminoacylation failed to detect differences between normal tRNA and tRNA from ethionine treated animals. The effect of ethionine on the tRNA population was not uniform and differed for various amino acid specific tRNAs. Thus liver tRNA from ethionine treated rats showed a decreased capacity for phenylalanine aminoacylation, while no change was found in the case of leucine. On the other hand, the level of histidine aminoacylation was higher for tRNA from ethionine treated animals. An even more complex response was observed with methionine aminoacylation where tRNA from ethionine treated animals showed an initially faster rate than control tRNA. With more prolonged incubation periods, the methionyl-tRNA from ethionine treated animals was deacylated at an accelerated rate while the level of normal methionyl-tRNA remained almost constant.In addition to the aminoacylation reaction, the participation of aminoacyl-tRNA in protein synthesis was severely impaired. In this case, both the injected oocyte system and the cell-free wheat germ assay revealed these differences which were manifested with various mRNA and viral RNA preparations.     

Alterations in DNA-dependent RNA polymerase I from rat liver accompanying ethionine administration

Multiple injections of ethionine plus adenine resulted in 3- to 4-fold increases in the activity of RNA polymerase I from rat liver nuclei, whereas the activity of RNA polymerase II was relatively unaffected. Methyl-deficient preribosomal RNA was present in the livers of rats after treatment for 2 days. Both incorporation of labelled orotate into rat liver ribosomal RNA and protein synthesis in polysomes gradually increased.     

Hepatic glutathione concentrations linked to ethionine toxicity in rats

1. The effect of injected ethionine on liver GSH concentrations was studied in male and female rats. 2. Liver GSH concentrations were markedly and consistently decreased in 5hr. and elevated within 24-44hr. By 72hr. the amount of liver GSH of ethionine-poisoned rats had the same values as saline-injected control rats. At no time was erythrocyte GSH concentration affected by ethionine. 3. The concentrations of non-protein thiol compounds, glycogen and ATP were also significantly decreased when the rats were killed 5hr. after ethionine injection. 4. ATP, adenine or methionine did not prevent the decrease of liver GSH produced by ethionine. From these and other observations we conclude that ethionine is not an antagonist of methionine with respect to GSH metabolism. 5. The metabolic relationship between ethionine toxicity and liver GSH concentration is briefly discussed.     

Hyperglucagonemia and altered responsiveness of hepatic adenylate cyclase-adenosine 3',5'-monophosphate system to hormonal stimulation during chronic ingestion of DL-ethionine.

Basal activity and hormonal responsiveness of the adenylate cyclase-adenosine 3',5'-monophosphate system were examined in premalignant liver from rats chronically fed the hepatic carcinogen DL-ethionine, and these data were correlated with endogenous levels of plasma glucagon. By 2 weeks basal hepatic cyclic AMP levels, determined in tissues quick-frozen in situ, were 2-fold higher in rats ingesting ethionine than in the pair-fed control. Enhanced tissue cyclic AM content was associated with an increase in the adenylate cyclase activity of whole homogenates of fresh liver from rats fed ethionine (68 +/- 5 pmol cyclic AMP/10 min per mg protein) compared to control (48 +/- 4). Cyclic AMP-dependent protein kinase activity ratios were also significantly higher (control, 0.38 +/- 0.04; ethionine 0.55 +/- 0.05) and the percent glycogen synthetase activity in the glucose 6-phosphate-independent form was markedly reduced (control, 52 +/- 7%; ethionine, 15 +/- 1.5%) in the livers of ethionine-fed rats compared to the controls, suggesting that the high total hepatic cyclic AMP which accompanied ethionine ingestion was bilogically effective. These changes persisted throughout the 38 weeks of drug ingestion. Immunoreactive glucagon levels, determined in portal venous plasma, were 8-fold higher than control after 2 weeks of the ethionine diet (control, 185 +/- 24 pg/ml; ethionine, 1532 +/- 195). Analogous to the changes in hepatic parameters, plasma glucagon levels remained elevated during the entire period of drug ingestion until the development of hepatomas. The hepatic cyclic AMP response to a maximal stimulatory dose of injected glucagon was blunted in vivo in ethionine-fed rats (control, 14 -fold increase over basal, to 8.63 +/- 1.1 pmol/mg wet weight; ethionine, 4.6-fold rise over basal, to 5.42 +/- 0.9). Reduced cyclic AMP responses to both maximal and submaximal glucagon stimulation were also evident in vitro in hepatic slices prepared from rats fed the drug, and the reduction was specific to glucagon. Absolute or relative hepatic cyclic AMP responses to maximally effective concentrations of protaglandin E1 or isoproterenol in hepatic slices from ethionine-fed rats were greater than or equal to those observed in control slices. Parallel alterations in hormonal responsiveness were observed in adenylate cyclase activity of whole homogenates of these livers, implying that the changes in cyclic AMP accumulation following hormone stimulation were related to an alteration in cyclic AMP generation in the premalignant tissue. In view of the recognized hepatic actions of glucagon and the desensitization of adenylate cyclase which can occur during sustained stimulation of the liver with this hormone, the endogenous hyperglucagonemia that accompanies ethionine ingestion could play a role in the pathogenesis of both the basal alterations in hepatic cyclic AMP metabolism and the reduced responsiveness to glucagon observed in liver from rats fed this carcinogen.     

Ethionine-induced changes in the activities of S-adenosylmethionine synthetase isozymes from rat liver

Isozyme patterns of $\text{S}$-adenosylmethionine synthetase have been measured with and without dimethylsulfoxide in rat liver incuced by ethionine. The activity of the α-form is increased following administration of ethionine plus adenine for 2 consecutive days, and gradually decreased to control level on the 7th day after treatment, whereas the activity of β-form is relatively unaffected. Methyl-deficient transfer RNA and enhanced levels of transfer RNA-methylating enzymes were found in the livers of female rats after the treatment for 2 days, following which they gradually returned to control level.     

Hyperglucagonemia and altered responsiveness of hepatic adenylate cyclase-adenosine 3′,3′-monophosphate system to hormonal stimulation during chronic ingestion of dl-ethionine

Basal activity and hormonal responsiveness of the adenylate cyclase-adenosine 3′,5′-monophosphate system were examined in premalignant liver from rat chronically fed the hepatic carcinogen DL-ethionine, and these data were correlated with endogenous levels of plasma glucagon. By 2 weeks basal hepatic cyclic AMP levels, determined in tissue quick-frozen in situ, were 2-fold higher in rats ingesting ethionine than in the pair-fed control. Enhanced tissue cyclic AMP content was associated with an increase in the adenylate cyclase activity of whole homogenates of fresh liver from rats fed ethionine (68 ± 5 pmol cyclic AMP/10 min per mg protein) compared to control (48 ± 4). Cyclic AMP-dependent protein kinase activity ratios were also significantly higher (control, 0.38 ± 0.04; ethionine 0.55 ± 0.05) and the percent glycogen synthetase activity in the glucose 6-phosphate-independent form was markedly reduced (control, 52 ± 7%; ethionine, 15 ± 1.5 %) in the livers of ethionine-fed rats compared to the controls, suggesting that the high total hepatic cyclic AMP which accompanied ethione ingestion was biologically effective. These changes persisted throughout the 38 weeks of drug ingestion. Immunoreactive glucagon levels, determined in portal venous plasma, were 8-fold higher than control after 2 weeks of the ethionine diet (contro, 185 ± 24 pg/ml; ethionine, 1532 ± 195). Analogous to the changes in hepatic parameters, plasma glucagon levels remained elevated during the entire period of drug ingestion until the development of hepatomas. The hepatic cyclic AMP response to a maximal stimulatory dose of injected glucagon was blunted in vivo in ethionine-fed rats (control, 14-fold increase over basal, to 8.63 ± 1.1 pmol/mg wet weight; ethionine, 4.6-fold rise over basal, to 5.42 ± 0.9). Reduced cyclic AMP responses to both maximal and submaximal glucagon stimulation were also evident in vitro in hepatic slices prepared from rats fed the drug, and the reduction was specific to glucagon. Absolute or relative hepatic cyclic AMP responses to maximally effective concentrations of prostaglandin E₁ or isoproterenol in hepatic slices from ethionine-fed rats were greater than or equal to those observed in control slices. Parallel alterations in hormonal responsiveness were observed in adenylate cyclase activity of whole homogenates of these livers, implying that the changes in cyclic AMP accumulation following hormone stimulation were related to an alteration in cyclic AMP generation in the premalignant tissue.In view of the recognized hepatic actions of glucagon and the desensitization of adenylate cyclase which can occur during sustained stimulation of the liver with this hormone, the endogenous hyperglucagonemia that accompanies ethionine ingestion could play a role in the pathogenesis of both the basal alterations in hepatic cyclic AMP metabolism and the reduced responsiveness to glucagon observed in liver from rats fed this carcinogen.     

The Effect of Ethionine Feeding on the Retention of A Single Per Os Dose of Methyl Mercury on Rat

Six adult female rats were daily fed a diet containing DL-ethionine during three weeks. One daily rat dose was 30 mg of ethionine. Six similar rats, the controls, were kept on the same diet without ethionine. On the 21st day of the experiment all rats were given one dose of 203Hg labeled methyl mercury by stomach tube. Each rat received 163 µg in terms of metallic mercury. Ninety hrs. after the mercury administration all rats were sacrificed and the mercury contents of the brains, livers, caudal femoral muscles, erythrocytes and blood plasma were determined. The mean plasma mercury content was significantly (P<0.01) greater in the ethionine fed rats when compared to the controls.     

Biochemical studies on the mechanism of action of liver poisons III. Depletion of liver glutathione in ethionine poisoning

Administration of ethionine to female rats was followed by rapid fall of the hepatic reduced glutathione content, concomitant with a progressive impairment of the cell-free protein-synthesizing capacity and a decline of the ATP level.In male rats and in adrenalectomized female rats, the onset of the first two alterations was considerably delayed. In contrast, the time course and the severity of the ethionine-induced ATP depletion were essentially the same in all instances.Treatment with CCl₄, despite the similarity of its hepatotoxic effects to those of ethionine, resulted in no appreciable decrease of the liver reduced glutathione level.Administration of methionine counteracted both the reduced glutathione decline and the other biochemical lesions induced by ethionine, whereas injection of adenine, though preventing the ATP depletion, failed to reverse the depression of reduced glutathione.The available evidence suggests that the decrease in the reduced glutathione level reflects a diminished capacity of the liver for oxidized glutathione reduction and its resultant inability to compensate the normal process of continuous reduced glutathione oxidation.The possible role of the altered reduced glutathione metabolism in the pathogenesis of ethionine hepatotoxicity is discussed.     

The effect of ethionine on ribonucleic acid synthesis in rat liver.

1. By 1h after administration of ethionine to the female rat the appearance of newly synthesized 18SrRNA in the cytoplasm is completely inhibited. This is not caused by inhibition of RNA synthesis, for the synthesis of the large ribosomal precursor RNA (45S) and of tRNA continues. Cleavage of 45S RNA to 32S RNA also occurs, but there was no evidence for the accumulation of mature or immature rRNA in the nucleus. 2. The effect of ethionine on the maturation of rRNA was not mimicked by an inhibitor of protein synthesis (cycloheximide) or an inhibitor of polyamine synthesis [methylglyoxal bis(guanylhydrazone)]. 3. Unlike the ethionine-induced inhibition of protein synthesis, this effect was not prevented by concurrent administration of inosine. A similar effect could be induced in HeLa cells by incubation for 1h in a medium lacking methionine. The ATP concentration in these cells was normal. From these two observations it was concluded that the effect of etionine on rRNA maturation is not caused by an ethionine-induced lack of ATP. It is suggested that ethionine, by lowering the hepatic concentration of S-adenosylmethionine, prevents methylation of the ribosomal precursor. The methylation is essential for the correct maturation of the molecule; without methylation complete degradation occurs.     

Evidence for ethylation of rat liver deoxyribonucleic acid after administration of ethionine

1. Administration of a large dose (500mg/kg body wt.) of (3)H-labelled l-ethionine to rats resulted in the incorporation of a small amount of radioactivity into the liver DNA. Considerable evidence that this radioactivity was not due to contamination of the isolated DNA with labelled protein, RNA, S-adenosyl-l-ethionine or l-ethionine was obtained. 2. After acidic hydrolysis of the DNA isolated from the livers of rats treated with labelled l-ethionine, virtually all of the radioactivity present in the DNA was found in a fraction with similar chromatographic properties to 7-ethylguanine. 3. Treatment of rats with comparable doses of l-methionine did not lead to the formation of 7-methylguanine in the liver DNA. 4. These results are discussed in relation to the induction of liver tumours by ethionine.     

The control of nucleic acid and nicotinamide nucleotide synthesis in regenerating rat liver

1. The effect of injecting nicotinamide on the incorporation of [(14)C]orotate into the hepatic nucleic acids of rats after partial hepatectomy was investigated. 2. At 3h after partial hepatectomy the rapid incorporation of [(14)C]orotate into RNA, and at 20h after partial hepatectomy the incorporation of [(14)C]orotate into both RNA and DNA, were inhibited in a dose-dependent fashion by the previous injection of nicotinamide. 3. The injection of nicotinamide at various times before the injection of [(14)C]orotate at 20h after partial hepatectomy revealed an inhibition of the incorporation of orotate into RNA and DNA which was non-linear with respect to the duration of nicotinamide pretreatment. 4. The induction of a hepatic ATP depletion by ethionine demonstrated that the synthesis of hepatic NAD and NADP in partially hepatectomized rats was more susceptible to an ATP deficiency than in control rats. 5. The total hepatic activity of ribose phosphate pyrophosphokinase (EC 2.7.6.1) was assayed at various times after partial hepatectomy and found to be only marginally greater than the maximum rate of hepatic NAD synthesis induced in vivo by nicotinamide injection between 12 and 24h after partial hepatectomy. 6. It is suggested that a competition exists between NAD synthesis and purine and pyrimidine nucleotide synthesis for available ATP and particularly 5-phosphoribosyl 1-pyrophosphate. In regenerating liver the competition is normally in favour of the synthesis of nucleic acid precursors, at the expense of NAD synthesis. This situation may be reversed by the injection of nicotinamide with a subsequent inhibition of nucleic acid synthesis.     

The effect of thermally stable factors from cytosol of regenerating liver cells on the processes of cholesterol esterification in rat blood serum after administration of ethionine

In the trials on rats it has been found that ethionine injection damages the system of cholesterol esterification in the blood serum. The factors stimulating hepatocyte proliferation prevent partially the toxic action of ethionine.     

Further observations on the effect of ethionine on the synthesis of β-galactosidase inEscherichia coli: Formation of an immunologically cross-reacting protein

It was found that ethionine partially inhibits the transport of the inducer (TMG) of β-galactosidase into the cells ofEscherichia coli ML-30. The synthesis of β-galactosidase-specific messenger RNA is not inhibited. Ethionine appears to be incorporated into proteins synthesized by the strains used. The incorporation of ethionine into the molecule of β-galactosidase results in the synthesis of an enzymically inactive, immunologically cross-reacting protein.     

Effect of ethionine on the rough endoplasmic reticulum from male and female rat liver

Ethionine causes a decrease in the amount of rough endoplasmic reticulum in rat liver, the effect being greater in female than in male rats. Rough endoplasmic reticulum isolated from rat liver 24 hr after ethionine injection and stripped of its ribosomes partially lost itsin vitro ribosome binding capacity. However, no differences were detected between the binding affinities of ribosomes, isolated from either untreated animals or intoxicated rats, to stripped rough membranes derived from normal rats. Structural changes occur in the rough endoplasmic reticulum of the ethionine treated rats, while the ribosomes are still bound to the membrane.     

Gibberellin-induced Yeast Sporulation in Relation to RNA and Protein Metabolism

Gibberellic acid (GA) promoted sporulation in yeast when added to the sporulation medium. When added together with GA, metabolic inhibitors of RNA synthesis such as 8-azaguanine, 2-thiouracil, and actinomycin D suppressed selectively the promoting effect of GA on sporulation. The effect of 8-azaguanine and 2-thiouracil was alleviated by simultaneous addition of guanine and uracil, respectively. The promoting effect of GA on sporulation was also suppressed by inhibitors of protein synthesis such as ethionine, chloramphenicol, and puromycin. Methionine eliminated the inhibitory effect of ethionine on the GA action.     

Poly(A) polymerase activity in ethionine-intoxicated rats: the relative effectiveness of disaggregated and intact polyribosomes as primers for poly(A) polymerase

Ethionine intoxication causes a change in the metabolism of poly(A) sequences on the 3' OH terminus of mRNA in rat liver in vivo. In an attempt to determine the factors responsible for these changes, nuclear and cytoplasmic poly(A) polymerase activities and the state of the primer were examined in vitro. Requirements for optimal enzyme activities were determined. The nuclear and cytoplasmic enzymes had different K+, Mn2+, and poly(A) primer optima. The levels of nuclear and cytoplasmic poly(A) polymerase activity were shown to decrease following ethionine intoxication. Poly(A)+ RNA isolated from the livers of saline- and ethionine-treated rats served equally well as primers for the cytoplasmic poly(A) polymerase.Disaggregated polysomes were seven times more effective as primers than were intact polysomes. The results suggest that the mRNP particle which is released from polysomes as a result of ethionine intoxication functions better as a poly(A) polymerase primer than does the intact polysome.     

Ethionine regulates cell motile activity through LPA receptor-3 in liver epithelial WB-F344 cells

Lysophosphatidic acid (LPA) receptors (LPA₁ to LPA₆) indicate a variety of cellular responses, such as cell proliferation, migration, differentiation, and morphogenesis. However, the role of each LPA receptor is not functionally equivalent. Ethionine, an ethyl analog of methionine, is well known to be one of the potent liver carcinogens in rats. In this study, to assess whether ethionine may regulate cell motile activity through LPA receptors, rat liver epithelial (WB-F344) cells were treated with ethionine for 48 h. In cell motility assay with a cell culture insert, the treatment of ethionine at 1.0 and 10 μM enhanced significantly high cell motile activity, compared with untreated cells. The expression levels of LPA receptor genes in cells treated with ethionine were measured by quantitative real time RT-PCR analysis. The expression of the Lpar3 gene in ethionine-treated cells was significantly higher than that in untreated cells. Furthermore, to confirm an involvement of LPA₃ on cell motility increased by ethionine, the Lpar3 knockdown cells were also used. The cell motile activity by ethionine was completely suppressed in the Lpar3 knockdown cells. These results suggest that LPA signaling through LPA₃ may be involved in cell motile activity stimulated by ethionine in WB-F344 cells.     

Effects of ethionine on tRNA methylation in male and female rats

Administration of hepatocarcinogens to rats results in an increase in tRNA methyltransferase activity in the target tissues. Ethionine is active as a carcinogen only in female rats and only in females is this increase in enzyme activity seen. However, ethionine also causes the formation of methyl-deficient tRNA in the liver. Other hepatocarcinogens do not do this. Ethionine is equally effective in this action in males and females. Thus, the two actions of ethionine are completely separable, and the methyl-deficiency of tRNA is caused by an activity not identical with the carcinogenic one.