Metabolism of Ethionine in Ethionine-Sensitive and Ethionine-Resistant Cells of the Enteric Yeast Candida slooffii

In a defined medium with added ethionine plus low methionine, phenylalanine, tryptophan, tyrosine, adenine, and additional methionine reversed inhibition of the enteric yeast Candida slooffii by ethionine. Isoleucine and 7-methylguanine restored half-maximal growth. Choline but not triethylcholine inhibited C. slooffii. 6-Mercaptopurine reversed ethionine inhibition and also synergistic inhibition by ethionine plus choline. Protection against ethionine by adenine plus aromatics was also evident with log-phase cells in the absence of methionine. Incorporation of ethionine-ethyl-1-(14)C by resting cells was partially inhibited by aromatic amino acids and methionine. Ethionine depressed incorporation of (3)H-phenylalanine but not of (3)H-adenine. Ethionine-resistant mutants were isolated which incorporated ethionine efficiently and degraded it to yet unidentified substances not including 5'-ethylthioadenosine. Ethionine-sensitive cells accumulated more S-adenosylethionine (SAE) than resistant mutants. Adenine was a good precursor of SAE. Radioactivity from ethionine-ethyl-1-(14)C was recovered from cell fractions of ethionine-sensitive cells with the following distribution: cold trichloroacetic acid-soluble > hot trichloroacetic acid-insoluble > lipids > deoxyribonucleic acid > ribonucleic acid. Total radioactivity recovered from ethionine-sensitive cells was twice as much as that from ethionine-resistant mutants.     

ISOLATION OF NITROSOGUANIDINE-INDUCED CHLORELLA VULGARIS MUTANTS WITH HIGH METHIONINE CONTENT1

Mutants of Chlorella vulgaris induced by N-methyl-N′-nitro-N-nitrosoguanidine (NG), and, selected for the resistance to either ethionine or 6-methylpurine, were tested for the relative rate of incorporation into protein of ³H-methionine and ¹⁴C-leucine. A highly significant, correlation between the ³H-to-¹⁴C ratio in the protein and its methionine content was found. 6-Methylpurine proved to be more effective than ethionine as a screening agent for high methionine strains. Screening for 6-methylpurine resistance, followed by a second screening for the highest methionine-to-leucine incorporation ratio, led to isolation of the mutants with a content up to 45% higher in methionine and up to 3 times higher in cysteine with respect to the wild strain.     

苜蓿抗乙硫氨酸愈伤组织的筛选和特性

用乙硫氨酸为筛选剂,通过幼苗和组织培养筛选得到乙硫氨酸抗性愈伤组织。该愈伤组织在含乙硫氨酸的培养基上表现出较高的半抑制剂量和相对生长量。作为天门冬氨酸途径的产物,甲硫氨酸、异亮氨酸和赖氨酸在所筛选的愈伤组织中分别增加到对照的两倍多,但苏氨酸保持正常水平,另外酪氨酸、半胱氨酸和亮氨酸也有所增加,而在所筛选的愈伤组织中缬氨酸浓度却下降。说明在所筛选愈伤组织中存在一个以上与氨基酸合成相关的酶发生改变。同工酶分析表明,该愈伤组织中出现对照中没有的分子量为44kD的超氧化物歧化酶和分子量为45kD的酯酶谱带。     

Effect of acetylcholine on incorporation of 14C-precursors into uridylic and cytidylic nucleotides of the RNA of digestive glands

The incorporation rate of [2-14C]orotic acid and [2-14C]uridine into the cytidylic RNA nucleotides is significantly lower than into the uridylic ones. In the liver it was twice as low as in the stomach mucosa or in pancreas of albino rats. The administration of acetylcholine in combination with proserine has no influence on the RNA content and its nucleotide composition in the tissues. The administered drugs however caused changes in the relation of the incorporation rates of both labels into uridylic and cytidylic RNA nucleotides, which evidences for the uridylic nucleotide synthesis. In the liver such changes are not detected, but utilization of the labeled uridine is shown to be more intensive for the cytidylic RNA nucleotides synthesis.     

Methionine metabolism in BHK cells: selection and characterization of ethionine resistant clones.

The selection of clones resistant to methionine antagonists was undertaken on baby hamster Kidney cells grown in a methionine free medium, supplemented with homocystine, folic acid and hydroxo-B12. Clones resistant to 30 mug/ml ethionine were isolated after mutagenesis at an induced mutation frequency of 2.3 X 10(-5). An ethionine resistant clone, ETH 304, was extensively studied. The resistant cells excreted methionine in the culture medium and the intracellular pools of methionine and SAM were two to five times greater in the resistant clone than in the wild type cells. A semidominant ethionine resistant phenotype was observed in hybrids between the wild type and this resistant clone. Measurement of the specific activity of menadione reductase, B12 methyltransferase and ATP: L-methionine S-adenosyl-transferase in crude extracts of the wild type showed a repressive action of methionine on the level of the three enzymes. However, the ethionine resistant clone ETH 304 was not modified in this function. Menadione reductase is feedback-inhibited by SAM in wild type cells. The enzyme of the ethionine resistant clone was significantly less sensitive to SAM. When a comparison of thermal stability was made between the wild type and ethionine resistant clone enzymes, it was found that the thermal stability of the latter was modified. Three other ethionine resistant clones, independantly isolated, were similarly affected in the properties of menadione reductase. These results suggest that the pathway of re-use of S-adenosyl homocysteine, produced during methylation reactions, is highly regulated by methionine and SAM.     

Role of Methionine in Biosynthesis of Prodigiosin by Serratia marcescens

Methionine alone did not allow biosynthesis of prodigiosin (2-methyl-3-amyl-6-methoxyprodigiosene) in nonproliferating cells (NPC) of Serratia marcescens strain Nima. However, when methionine was added to NPC synthesizing prodigiosin in the presence of other amino acids, the lag period for synthesis of prodigiosin was shortened, an increased amount of the pigment was formed, and the optimal concentrations of the other amino acids were reduced. Less prodigiosin was synthesized when addition of methionine was delayed beyond 4 h. The specific activity of prodigiosin synthesized by addition of (14)CH(3)-methionine was 40 to 50 times greater than that synthesized from methionine-2-(14)C or (14)COOH-methionine. NPC of mutant OF of S. marcescens synthesized norprodigiosin (2-methyl-3-amyl-6-hydroxyprodigiosene), and the specific activity of this pigment synthesized in the presence of (14)CH(3)-methionine was only 5 to 13 times greater than that synthesized from methionine-2-(14)C or (14)COOH-methionine. A particulate, cell-free extract of mutant WF of S. marcescens methylated norprodigiosin to form prodigiosin. When the extract was added to NPC of mutant OF synthesizing norprodigiosin in the presence of (14)CH(3)-methionine, the prodigiosin formed had 80% greater specific activity than the norprodigiosin synthesized in the absence of the extract. The C6 hydroxyl group of norprodigiosin was methylated in the presence of the extract and methionine. Biosynthesis of prodigiosin by NPC of strain Nima also was augmented by addition of S-adenosylmethionine. Various analogues of methionine such as norleucine, norvaline, ethionine, and alpha-methylmethionine did not affect biosynthesis of prodigiosin by NPC either in the presence or absence of methionine.     

Enhancement of ethylene formation by selenoamino acids

Selenomethionine and selenoethionine enhanced ethylene production in senescing flower tissue of Ipomoea tricolor Cav. and in auxin-treated pea (Pisum sativum L.) stem sections. This enhancement was fully inhibited by the aminoethoxy analog of rhizobitoxine. Methionine did not have a comparable promotive effect, and ethionine partly inhibited ethylene production. When [¹⁴C]methionine was applied to flower or pea stem tissue followed by treatment with unlabeled selenomethionine or selenoethionine, the specific radioactivity of the ethylene evolved was considerably reduced. The dilution of the specific radioactivity of ethylene by selenomethionine, and in pea stem sections also by selenoethionine, was greater than the dilution by nonradioactive methionine at the same concentration. These results indicate that both selenoamino acids serve as precursors of ethylene and that they are converted to ethylene more efficiently than is methionine.     

Dominant Mutation for Ethionine Resistance in Saccharomyces cerevisiae

An ethionine-resistant mutant of Saccharomyces cerevisiae has been investigated whose mutation (et^r2) confers resistance to the heterozygous diploid also containing the sensitive allele, et^s. The mutation is apparently specific for reversal of ethionine inhibition. The principal difference between the sensitive et^s strain and the mutant was the latter's inability to concentrate large intracellular quantities of adenosylethionine. Reduced incorporation of ethyl groups or ethionine in other cellular fractions of the mutant was also detected. The data show that the mutant has not lost the ability to form adenosylethionine. It is suggested that the mutant has an increased ability to hydrolyze this sulfonium compound after it has been synthesized. It is possible that some of the ethionine is detoxified before it can participate in protein or adenosylethionine synthesis. No mutant alteration in accumulation of ethionine from the medium was detected. In the presence of ethionine, the parental strain accumulated 25 times more adenosylethionine than did the mutant. However, with methionine, only twice as much adenosylmethionine was accumulated by the parental strain as by the mutant.     

Properties of an Ethionine-Resistant (ER) Mutant of Ochromonas danica

SYNOPSIS. On prolonged incubation of ethionine-sensitive (ES) cells of Ochromonas danica in L-ethionine-containing media, growth was resumed by an ethionine-resistant (ER) mutant. Such mutants arise at random and are selected by the ethionine-containing medium. Ethionine resistance is not lost on repeated transfers thru ethionine-less media. ES cells incubated with ethionine form a large posterior vacuole before they disintegrate. Inhibition of reserve substance utilization is suggested to underlie growth inhibition of O. danica by ethionine. In ES cells incubated with ethionine, ¹⁴C uptake from labeled methionine, ethionine or serine is reduced by 65%. In ER cells the decrease in ¹⁴C uptake is 90%. This decrease in uptake of ethionine seems to be how ER O. danica evades growth inhibition by ethionine.     

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.     

Role of Homocysteine Synthetase in an Alternate Route for Methionine Biosynthesis in Saccharomyces cerevisiae

In vivo studies have shown that, in the absence of homoserine-O-transacetylase activity (locus met(2)), the C(4)-carbon moiety of ethionine is utilized (provided the ethionine resistance gene eth-2r is present) by methionine auxotrophs, except for met(8) mutants (homocysteine synthetase-deficient). Concomitant utilization of sulfur and methyl group from methylmercaptan or S-methylcysteine has been demonstrated. In the absence of added methylated intermediates, the methyl group of methionine formed from ethionine is derived from serine. In vitro studies with crude extracts of Saccharomyces cerevisiae have demonstrated that this synthesis of methionine occurs by the following reactions: CH(3)-SH + ethionine right harpoon over left harpoon methionine + C(2)H(5)SH and S-methylcysteine + ethionine right harpoon over left harpoon methionine + S-ethylcysteine. In the forward direction, the second product of the second reaction was shown to be S-ethylcysteine; this reaction has also been found reversible, leading to ethionine formation. Genetic and kinetic data have shown that homocysteine synthetase catalyzes these two reactions, at 0.3% of the rate it catalyzes direct homocysteine synthesis: O-Ac-homoserine + Na(2)S --> homocysteine + acetate. The three reactions are lost together in a met(8) mutant and are recovered to the same extent in spontaneous prototrophic revertants from this strain. Methionine-mediated regulation of enzyme synthesis affects the three activities and is modified to the same extent by the presence of the recessive allele (eth-2r) of the regulatory gene eth-2. Affinities of the enzyme for substrates of both types of reactions are of the same order of magnitude. Moreover, ethionine, the substrate of the second reaction, inhibits the third reaction, whereas O-acetyl-homoserine, the substrate of the third reaction, inhibits the second reaction. An enzymatic cleavage of S-methylcysteine, leading to methylmercaptan production, has been shown to occur in crude yeast extracts. It is concluded that the enzyme homocysteine synthetase participates in the two alternate pathways leading to methionine biosynthesis in S. cerevisiae, one involving O-acetyl-homoserine and H(2)S, the other involving the 4-carbon chain of ethionine and a mercaptyl donor. Participation of the two types of reactions catalyzed by homocysteine synthetase, in in vivo methionine synthesis, has been shown to occur in a met(2) partial revertant.     

Pancreatic fate of 14C-labelled hexoses

In order to assess the respective contribution of the exocrine and endocrine moieties of the pancreas to the overall net uptake of selected monosaccharides by the pancreatic gland, the apparent distribution space of L-[1-14C]glucose, 3-O-[14C-methyl]-D-glucose, D-[U-14C]glucose, D-[U-14C]mannose and D-[U-14C]fructose was measured in pieces of pancreas obtained from either control rats or animals injected with streptozotocin. Although the time course for the uptake of 3-O-[14C-methyl]-D-glucose, D-[U-14C]glucose, D-[U-14C]mannose and D-[U-14C]fructose was much slower in the pieces of pancreas than that previously documented in isolated pancreatic islets, no significant difference could, as a rule, be detected between the results obtained in pancreatic pieces of control and streptozotocin rats. A comparable situation prevailed in the pancreas of animals examined 3 min after the intravenous injection of 3-O-[14C-methyl]-D-glucose. D-Glucose inhibited the uptake of 3-O-[14C-methyl]-D-glucose and that of D-[U-14C]fructose. Likewise, 3-O-methyl-D-glucose inhibited the uptake of D-[U-14C]glucose. Cytochalasin B (20 microm) also inhibited the uptake of 3-O-[14C-methyl]-D-glucose and D-[U-14C]glucose, but not that of D-[U-14C]fructose. D-Mannoheptulose hexaacetate, but not the unesterified heptose, inhibited the metabolism of tritiated and 14C-labelled D-glucose, as well as the net uptake of D-[U-14C]glucose and D-[U-14C]mannose and, to a lesser extent, that of D-[U-14C]fructose. These findings indicate that despite marked differences between endocrine and exocrine pancreatic cells in terms of both the time course for the uptake of several hexoses and the inhibition of their phosphorylation by D-mannoheptulose, little or no preferential labelling of the endocrine moiety of the pancreas by the 14C-labelled hexoses is observed, at least when judged from their distribution space in pancreatic pieces or the whole pancreatic gland. Nevertheless, the findings made with D-mannoheptulose and its hexaacetate ester raise the view that this heptose could conceivably be used to achieve a sizeable preferential labelling of the endocrine pancreas under the present experimental conditions.     

Characterization of soybean tissue culture cell lines resistant to methionine analogs

Several hundred soybean [Glycine max (L.) Merr.] cell lines resistant to ethionine were isolated either with or without chemical mutagenesis. of these, 26 were found to contain 2 to 22 times higher than normal levels of uncombined methionine. These 26 cell lines also contained higher than normal levels of S-adenosylmethionine and S-methylmethionine, but the levels of free lysine, threonine, cysteine, valine, tyrosine and phenylalanine were not elevated. Isoleucine levels were only slightly elevated. These results suggest that the regulation of methionine synthesis in vivo is more likely to be later in the pathway (after homoserine phosphate) than early in the pathway.Abbreviations AdoMet S-adenosylmethionine - SMM S-methylmethionine - trp tryptophan - met methionine - thr threonine - val valine - phe phenylalanine - lys lysine - ile isoleucine - cys cysteine     

Biosynthesis of diaporthin and orthosporin by Aspergillus ochraceus

Diaporthin and orthosporin were characterised from the fungus Aspergillus ochraceus D2306. Diaporthin was identified by high-resolution electron impact mass spectrometry and 1H and 13C NMR spectroscopy, from which new spectroscopic assignments were made. Orthosporin was also identified by mass spectrometry and both fungal metabolites are reported for the first time as co-metabolites and also as products of A. ochraceus. The methylation inhibitor ethionine affected production of both diaporthin and orthosporin in spite of no obvious methylation step in the biosynthesis of orthosporin, implying that extracellular orthosporin may arise by de-O-methylation of diaporthin. The biosynthetic origin of diaporthin was demonstrated by incorporation of [1-14C]acetate and [methyl-14C]methionine administered in early idiophase.     

Control of Free Methionine Production in Wild Type and Ethionine-resistant Mutants of Chlorella sorokiniana

Mutants of Chlorella sorokiniana selected for resistance to the methionine analogue ethionine took up ethionine at the same rate as did the wild type strain. Cells of two ethionine-resistant mutants produced severalfold higher levels of free methionine and cysteine than did wild type cells.     

Induction of S-adenosylmethionine synthetase isozymes in primary cultures of adult rat hepatocytes

The activities of S-adenosylmethionine synthetase isozymes were studied using adult rat hepatocytes in primary culture. Hepatocytes from adult rats were isolated and cultured for several days. The activities of the synthetase isozymes did not change during primary culture. The activity of the alpha-form increased with increasing ethionine plus adenine or methionine in the medium, and reached about 5 fold after 2 days. However, the increased activity of the beta-form showed less than twice.     

Altered Methionyl-tRNA Synthetase in a Spirulina platensis Mutant Resistant to Ethionine

Compared with the parental strain, a Spirulina platensis mutant that is resistant to ethionine incorporated methionine into protein at a reduced rate, whereas ethionine incorporation was practically nil. The methionyl-tRNA synthetase present in crude extracts from the resistant strain showed a reduced affinity for methionine and ethionine.     

The effect of methionine on the metabolism of serine and glycine in vitamin B-12-deficient rats.

The effect of methionine supplementation on glycine and serine metabolism was studied in vitamin B-12-deficient rats which received only 0.2% methionine in the diet. In the perfused liver, incorporation of the C-2 of glycine to the C-3 of serine was increased by addition of methionine to the perfusate. The oxidation of [1-14C]glycine to 14CO2 was however depressed. Unlike methionine, glycine did not have any significant effect on the liver folate coenzyme distribution. Oxidation of [3-14C]serine to 14CO2 both in vivo and in perfused liver was increased by methionine. A major portion of the C-3 radioactivity however was recovered in glucose. Data presented indicate that the rate of oxidation of [2-14C]histidine to 14CO2 is a more sensitive indicator of folate deficiency than the rate of oxidation of [3-14C]serine to 14CO2 although both are presumably tetrahydrofolate dependent.     

Conversion of 5-S-ethyl-5-thio-D-ribose to ethionine in Klebsiella pneumoniae. Basis for the selective toxicity of 5-S-ethyl-5-thio-D-ribose

5-S-Ethyl-5-thio-D-ribose (ethylthioribose) exhibits antiprotozoal activity against Plasmodium falciparum, Giardia lamblia, and Ochromonas malhamensis, but is nontoxic to cultured human and murine bone marrow cells (Riscoe, M. K., Ferro, A. J., and Fitchen, J. H. (1988) Antimicrob. Agents Chemother. 32, 1904-1906). We propose the following mechanism to account for the observed selective toxicity of ethylthioribose. 1) The cytocidal action of ethylthioribose against protozoa is a result of its conversion to ethionine, a well-known cytotoxic agent. 2) This transformation occurs through the pathway which normally converts 5-S-methyl-5-thio-D-ribose (methylthioribose) to methionine. 3) Conversion of ethylthioribose to ethionine cannot occur in mammalian cells since these cells cannot phosphorylate methylthioribose (ethylthioribose), a first step in the pathway to methionine (ethionine). To test this hypothesis, [5-3H]ethylthioribose has been synthesized and its metabolism by cell-free extracts of Klebsiella pneumoniae and rat liver was examined. The pathway by which methylthioribose is converted to methionine in K. pneumoniae is well characterized. When supplemented with ATP and L-glutamine, the bacterial extract efficiently converted [5-3H]ethylthioribose to [3H]ethionine. By contrast, ethionine was not produced upon incubation of [5-3H]ethylthioribose, ATP, and L-glutamine with rat liver homogenate. The mammalian cell extract lacks a kinase activity capable of converting ethylthioribose to 1-phospho-5-S-ethyl-5-thio-alpha-D-ribofuranoside, an obligate intermediate in the biosynthesis of ethionine from ethylthioribose in K. pneumoniae. These results support our hypothesis and provide a basis for understanding the apparently selective toxicity of ethylthioribose.     

Ethionine and Methionine Metabolism by the Chrysomonad Flagellate Ochromonas danica

SYNOPSIS. Growth of Ochromonas danica is competitively inhibited by ethionine. Inhibition can be reversed by methionine. Inhibition indexes of the effect of ethionine on growth and methionine incorporation into proteins are 1 and 4, respectively. Inside the cell, methionine is partially de-methylated and metabolized to form cysteine. Ethionine is partially de-ethylated, and the homocysteine moiety is either re-methylated to form methionine or further metabolized to form cysteine. Ethionine is also incorporated into proteins of O. danica. The kind of metabolic interference, expressed by inhibition of growth, and correlated with incorporation of ethionine, is yet unknown.