Methionine excess in diet induces acute lethal hepatitis in mice lacking cystathionine γ-lyase, an animal model of cystathioninuria

Physiological roles of the transsulfuration pathway have been recognized by its contribution to the synthesis of cytoprotective cysteine metabolites, such as glutathione, taurine/hypotaurine, and hydrogen sulfide (H(2)S), whereas its roles in protecting against methionine toxicity remained to be clarified. This study aimed at revealing these roles by analyzing high-methionine diet-fed transsulfuration-defective cystathionine γ-lyase-deficient (Cth(-/-)) mice. Wild-type and Cth(-/-) mice were fed a standard diet (1 × Met: 0.44%) or a high-methionine diet (3 × Met or 6 × Met), and hepatic conditions were monitored by serum biochemistry and histology. Metabolome analysis was performed for methionine derivatives using capillary electrophoresis- or liquid chromatography-mass spectrometry and sulfur-detecting gas chromatography. The 6 × Met-fed Cth(-/-) (not 1 × Met-fed Cth(-/-) or 6 × Met-fed wild type) mice displayed acute hepatitis, which was characterized by markedly elevated levels of serum alanine/aspartate aminotransferases and serum/hepatic lipid peroxidation, inflammatory cell infiltration, and hepatocyte ballooning; thereafter, they died of gastrointestinal bleeding due to coagulation factor deficiency. After 1 week on 6 × Met, blood levels of ammonia/homocysteine and hepatic levels of methanethiol/3-methylthiopropionate (a methionine transamination product/methanethiol precursor) became significantly higher in Cth(-/-) mice than in wild-type mice. Although hepatic levels of methionine sulfoxide became higher in 6 × Met-fed wild-type mice and Cth(-/-) mice, those of glutathione, taurine/hypotaurine, and H(2)S became lower and serum levels of homocysteine became much higher in 6 × Met-fed Cth(-/-) mice than in wild-type mice. Thus, transsulfuration plays a critical role in the detoxification of excessive methionine by circumventing aberrant accumulation of its toxic transamination metabolites, including ammonia, methanethiol, and 3-methylthiopropionate, in addition to synthesizing cysteine-derived antioxidants to counteract accumulated pro-oxidants such as methionine sulfoxide and homocysteine.     

Rerouting Citrate Metabolism in Lactococcus lactis to Citrate-Driven Transamination

Oxaloacetate is an intermediate of the citrate fermentation pathway that accumulates in the cytoplasm of Lactococcus lactis ILCitM(pFL3) at a high concentration due to the inactivation of oxaloacetate decarboxylase. An excess of toxic oxaloacetate is excreted into the medium in exchange for citrate by the citrate transporter CitP (A. M. Pudlik and J. S. Lolkema, J. Bacteriol. 193:4049-4056, 2011). In this study, transamination of amino acids with oxaloacetate as the keto donor is described as an additional mechanism to relieve toxic stress. Redirection of the citrate metabolic pathway into the transamination route in the presence of the branched-chain amino acids Ile, Leu, and Val; the aromatic amino acids Phe, Trp, and Tyr; and Met resulted in the formation of aspartate and the corresponding α-keto acids. Cells grown in the presence of citrate showed 3.5 to 7 times higher transaminase activity in the cytoplasm than cells grown in the absence of citrate. The study demonstrates that transaminases of L. lactis accept oxaloacetate as a keto donor. A significant fraction of 2-keto-4-methylthiobutyrate formed from methionine by citrate-driven transamination in vivo was further metabolized, yielding the cheese aroma compounds 2-hydroxy-4-methylthiobutyrate and methyl-3-methylthiopropionate. Reducing equivalents required for the former compound were produced in the citrate fermentation pathway as NADH. Similarly, phenylpyruvate, the transamination product of phenylalanine, was reduced to phenyllactate, while the dehydrogenase activity was not observed for the branched-chain keto acids. Both α-keto acids and α-hydroxy acids are known substrates of CitP and may be excreted from the cell in exchange for citrate or oxaloacetate.     

l-Cysteine metabolism via 3-mercaptopyruvate pathway and sulfate formation in rat liver mitochondria

Summary We have studied the 3-mercaptopyruvate pathway (transamination pathway) ofl-cysteine metabolism in rat liver mitochondria.l-Cysteine and other substrates at 10 mM concentration were incubated with mitochondrial fraction at pH 8.4, and sulfate and thiosulfate were determined by ion chromatography. Whenl-cysteine alone was incubated, sulfate formed was 0.7µmol per mitochondria from one g of liver per 60 min. Addition of 2-oxoglutarate and GSH resulted in more than 3-fold increase in sulfate formation, and thiosulfate was formed besides sulfate. The sum (A + 2B) of sulfate (A) and thiosulfate (B) formed was approximately 7-times that withl-cysteine alone. Incubation with 3-mercaptopyruvate resulted in sulfate and thiosulfate formation, and sulfate was formed with thiosulfate. These reactions were stimulated with glutathione. Sulfate formation froml-cysteinesulfinate and 2-oxoglutarate was not enhanced by glutathione and thiosulfate was not formed. These findings indicate thatl-cysteine was metabolized and sulfate was formed through 3-mercaptopyruvate pathway in mitochondria.     

Methanogenic Conversion of 3-S-Methylmercaptopropionate to 3-Mercaptopropionate

Anaerobic metabolism of dimethylsulfoniopropionate, an osmolyte of marine algae, in anoxic intertidal sediments involves either cleavage to dimethylsulfide or demethylation to 3-S-methylmercaptopropionate (MMPA) and subsequently to 3-mercaptopropionate. The methanogenic archaea Methanosarcina sp. strain MTP4 (DSM 6636), Methanosarcina acetivorans DSM 2834, and Methanosarcina (Methanolobus) siciliae DSM 3028 were found to use MMPA as a growth substrate and to convert it stoichiometrically to 3-mercaptopropionate. Approximately 0.75 mol of methane was formed per mol of MMPA degraded; methanethiol was not detected as an intermediate. Eight other methanogenic strains did not carry out this conversion. We also studied the conversion of MMPA in anoxic marine sediment slurries. Addition of MMPA (500 (mu)M) resulted in the production of methanethiol which was subsequently converted to methane (417 (mu)M). In the presence of the antibiotics ampicillin, vancomycin, and kanamycin (20 (mu)g/ml each), 275 (mu)M methane was formed from 380 (mu)M MMPA; no methanethiol was formed during these incubations. Only methanethiol was formed from MMPA when 2-bromoethanesulfonate (25 mM) was added to a sediment suspension. These results indicate that in natural environments MMPA could be directly or indirectly a substrate for methanogenic archaea.     

Glutathione changes occurring after S-adenosylhomocysteine hydrolase inhibition

Freshly isolated rat hepatocytes, which metabolize methionine through the cystathionine pathway, and cultured L5178Y cells, which do not, were compared for their response to the inhibition of S-adenosylhomocysteine (SAH) hydrolase (EC 3.3.1.1). When cells were incubated in Fischer's medium lacking cystine but containing 0.67 mM methionine and 10% serum, the addition of periodate-oxidized adenosine (POA), an inhibitor of SAH hydrolase, increased the level of SAH approximately 4-fold in L5178Y cells (5 mM POA) and 30-fold in hepatocytes (1 mM POA). POA treatment also decreased the amount of intracellular glutathione (GSH) in hepatocytes by 6-fold, and in L5178Y cells by 3-fold. Incubation of hepatocytes with adenosine plus homocysteine, 2-chloroadenosine, or 2',3'-acyclic adenosine increased intracellular SAH and also lowered GSH levels. Neither GSH oxidation nor efflux of GSH or GSH conjugates appeared to account for the GSH loss. Intracellular GSH, covalently bound to proteins as mixed disulfides, increased when hepatocytes were incubated with POA, but the increase was insufficient to account for the total GSH loss. In hepatocytes with prelabeled [35S]GSH, POA caused the cellular GSH content to decrease while the specific activity of [35S]GSH remained constant, suggesting that inhibitor treatments that caused elevated SAH levels may have increased the degradation of GSH while GSH synthesis was inhibited.     

Isolation of a dimethylsulfide-utilizingHyphomicrobium species and its application in biofiltration of polluted air

The methylotrophic bacteriumHyphomicrobium VS was enriched and isolated, using activated sewage sludge as inoculum in mineral medium containing dimethylsulfide (DMS) at a low concentration to prevent toxicity. DMS concentrations above 1 mM proved to be growth inhibiting.Hyphomicrobium VS could use DMS, dimethylsulfoxide (DMSO), methanol, formaldehyde, formate, and methylated amines as carbon and energy source. Carbon was assimilated via the serine pathway. DMS-grown cells respired sulfide, thiosulfate, methanethiol, dimethyldisulfide and dimethyltrisulfide.To testHyphomicrobium VS for application in biofiltration of air polluted with volatile sulfur compounds two laboratory scale trickling biofilters with polyurethane and lava stone as carrier material were started up by inoculation with this bacterium. Both methanol- and DMS-grown cells could be used. Only a short adaptation period was needed. Short term experiments showed that high concentrations of DMS (1–2 µmol 1^–1) were removed very efficiently by the biofilters at space velocities up to 100 h^–1.Abbreviations VSC volatile sulfur compounds - DMS dimethylsulfide - DMDS dimethyldisulfide - DMTS dimethyltrisulfide - MT methanethiol - DMSO dimethylsulfoxide     

Production of intracellular 35S-glutathione by rat and human hepatocytes for the quantification of xenobiotic reactive intermediates

The quantification and identification of xenobiotic reactive intermediates is difficult in the absence of highly radiolabeled drug. We have developed a method for identifying these intermediates by measuring the formation of adducts to intracellularly generated radiolabeled glutathione (GSH). Freshly isolated adherent rat and human hepatocytes were incubated overnight in methionine and cystine-free ('thio-free') medium. They were then exposed to 100 microM methionine and 10 microCi 35S-labeled methionine in otherwise thio-free medium to replete cellular GSH pools with intracellularly generated 35S-labeled GSH. After 3 h, acetaminophen was added as a test compound and the cells were incubated for an additional 24 h. Intracellular GSH and its specific activity were quantified after reaction with monobromobimane followed by HPLC analysis with fluorescence and radiochemical detection. Radiolabeled GSH was detectable at 3 h and maintained high specific activity and physiological concentrations for up to 24 h. Incubation medium from acetaminophen treated and nontreated hepatocytes were analyzed for radiolabeled peaks by HPLC using radiochemical detection. Radiolabeled peaks not present in nontreated hepatocytes were identified as acetaminophen GSH adducts by LC-MS. Formation of acetaminophen 35S-GSH adducts by rat hepatocytes containing endogenously synthesized 35S-GSH was increased with acetaminophen concentrations ranging from 500 to 2 mM.     

Turnover and functions of glutathione studied with isolated hepatic and renal cells

Suspensions of freshly isolated rat hepatocytes and renal tubular cells contain high levels of reduced glutathione (GSH), which exhibits half-lives of 3-5 and 0.7-1 h, respectively. In both cells types the availability of intracellular cysteine is rate limiting for GSH biosynthesis. In hepatocytes, methionine is actively converted to cysteine via the cystathionine pathway, and hepatic glutathione biosynthesis is stimulated by the presence of methionine in the medium. In contrast, extracellular cystine can support renal glutathione synthesis; several disulfides, including cystine, are rapidly taken up by renal cells (but not by hepatocytes) and are reduced to the corresponding thiols via a GSH-linked reaction sequence catalyzed by thiol transferase and glutathione reductase (NAD(P)H). During incubation, hepatocytes release both GSH and glutathione disulfide (GSSG) into the medium; the rate of GSSG efflux is markedly enhanced during hydroperoxide metabolism by glutathione peroxidase. This may lead to GSH depletion and cell injury; the latter seems to be initiated by a perturbation of cellular calcium homeostasis occurring in the glutathione-depleted state. In contrast to hepatocytes, renal cells metabolize extracellular glutathione and glutathione S-conjugates formed during drug biotransformation to the component amino acids and N-acetyl-cysteine S-conjugates, respectively. In addition, renal cells contain a thiol oxidase acting on extracellular GSH and several other thiols. In conclusion, our findings with isolated cells mimic the physiological situation characterized by hepatic synthesis and renal degradation of plasma glutathione and glutathione S-conjugates, and elucidate some of the underlying biochemical mechanisms.     

Biosynthesis of 3-dimethylsulfoniopropionate in Wollastonia biflora (L.) DC. Evidence that S-methylmethionine is an intermediate.

The compatible solute 3-dimethylsulfoniopropionate (DMSP) is accumulated by certain salt-tolerant flowering plants and marine algae. It is the major biogenic precursor of dimethylsulfide, an important sulfur-containing trace gas in the atmosphere. DMSP biosynthesis was investigated in Wollastonia biflora (L.) DC. [= Wedelia biflora (L.) DC., Melanthera biflora (L.) Wild, Asteraceae]. After characterizing DMSP and glycine betaine accumulation in three diverse genotypes, a glycine betaine-free genotype was chosen for radiotracer and stable isotope-labeling studies. In discs from young leaves, label from [U-14C]methionine was readily incorporated into the dimethylsulfide and acrylate moieties of DMSP. This establishes that DMSP is derived from methionine by deamination, decarboxylation, oxidation, and methylation steps, without indicating their order. Five lines of evidence indicated that methylation is the first step in the sequence, not the last. (a) In pulse-chase experiments with [14C]methionine, S-methylmethionine (SMM) had the labeling pattern expected of a pathway intermediate, whereas 3-methylthiopropionate (MTP) did not. (b) [14C]SMM was efficiently converted to DMSP but [14C]MTP was not. (c) The addition of unlabeled SMM, but not of MTP, reduced the synthesis of [14C]DMSP from [14C]methionine. (d) The dimethylsulfide group of [13CH3,C2H3]SMM was incorporated as a unit into DMSP. (e) When [C2H3,C2H3]SMM was given together with [13CH3]methionine, the main product was [C2H3,C2H3]DMSP, not [13CH3,C2H3]DMSP or [13CH3,13CH3]DMSP. The stable isotope labeling results also show that the SMM cycle does not operate at a high level in W. biflora leaves.     

Inhibition of sulfate-forming activity in rat liver mitochondria by (aminooxy)acetate

Summary The effect of (aminooxy)acetate, an inhibitor of aminotransferases, on the sulfate formation froml-cysteine andl-cysteinesulfinate in rat liver mitochondria was studied. Incubation of 10 mMl-cysteine with rat liver mitochondria at 37°C in the presence of 10 mM 2-oxoglutarate and 10 mM glutathione resulted in the formation of 4.60 and 1.52µmol of sulfate and thiosulfate, respectively, per 60 min per mitochondria obtained from 1 g of liver. Under the same conditions sulfate formation froml-cysteinesulfinate was 24.96µmol, but thiosulfate was not formed. The addition of (aminooxy)acetate at 2 mM or more completely inhibited the sulfate and thiosulfate formation froml-cysteine and the sulfate formation froml-cysteinesulfinate. These findings support our previous conclusion that cysteine transamination and 3-mercaptopyruvate pathway (MP pathway) are involved in the sulfate formation froml-cysteine in rat liver mitochondria (Ubuka et al., 1992).     

Methionine metabolism by rat muscle and other tissues. Occurrence of a new carnitine intermediate.

Perfused rat hindquarter preparations were shown to incorporate radioactivity from [U-14C]methionine into citrate-cycle intermediates, lactate, alanine, glutamate, glutamine and CO2. During perfusion, large amounts of methionine were also oxidized to methionine sulphoxide. The capacity for transamination of methionine or its oxo analogue, 4-methylthio-2-oxobutyrate, by muscle extracts was demonstrated. Rat skeletal muscle, heart, liver and kidney mitochondria, when incubated with the latter plus radiolabelled carnitine, formed a newly identified carnitine derivative, 3-methylthiopropionylcarnitine. It is concluded that the capacity for oxidation of methionine by a trans-sulphuration-independent pathway occurs in several mammalian tissues. The extent of inter-organ handling of intermediates in this pathway(s) is discussed.     

Aminooxyacetate inhibits gluconeogenesis by isolated chicken hepatocytes

Although the pathway for glucose synthesis from lactate in avian liver is not thought to involve transamination steps, inhibitors of transamination (aminooxyacetate and L-2-amino-4-methoxy-trans-3-butenoic acid) block lactate gluconeogenesis by isolated chicken hepatocytes. Inhibition of glucose synthesis from lactate by aminooxyacetate is accompanied by a large increase in the lactate-to-pyruvate ratio. Oleate largely relieves inhibition by aminooxyacetate and lowers the lactate-to-pyruvate ratio. In parallel studies with rat hepatocytes, oleate did not overcome aminooxyacetate inhibition of glucose synthesis. The ratios of lactate used to glucose formed were greater than 2 with both rat and chicken hepatocytes, were increased by aminooxyacetate, and were restored toward 2 by oleate. Thus, in the absence of oleate, lactate is oxidized to provide the energy needed to meet the metabolic demand of chicken hepatocytes. Excess cytosolic reducing equivalents generated by the oxidation of lactate to pyruvate are transferred from the cytosol to the mitosol by the malate-aspartate shuttle. Aminooxyacetate inhibits the shuttle and, consequently, glucose synthesis for want of pyruvate.     

Heart mitochondria metabolize 3-methylthiopropionate to CO2 and methanethiol

3-Methylthiopropionate (MTP) stimulates respiration of substrate-depleted heart mitochondria. This is blocked by uncouplers and by malonate. With the use of methyl-14C- and uniformly 14C-labeled MTP, it was found that methanethiol and CO2 are reaction products. The methyl carbon was not significantly oxidized. This study, together with a recent report [P. W. D. Scislowski et al. (1987) Biochem. J. 247, 35-40], demonstrates the existence of a transsulfuration independent pathway of methionine metabolism by muscle, and that the complete pathway following the initial transamination is a mitochondrial process. The data suggest that MTP is oxidized via acetyl-CoA.     

Metabolism and cytotoxicity of eugenol in isolated rat hepatocytes

The metabolism and toxic effects of eugenol (4-allyl-2-methoxyphenol) were studies in isolated rat hepatocytes. Incubation of hepatocytes with eugenol resulted in the formation of conjugates with sulfate, glucuronic acid and glutathione. The major metabolite formed was the glucuronic acid conjugate. Covalent binding to cellular protein was observed using [3H]eugenol. Loss of intracellular glutathione and cell death were also observed in these incubations. Concentrations of 1 mM eugenol caused a loss of over 90% of intracellular glutathione and resulted in approximately 85% cell death over a 5-h incubation period. The loss of the majority of glutathione occurred prior to the onset of cell death (2 h). The effects of eugenol were concentration dependent. The addition of 1 mM N-acetylcysteine to incubations containing 1 mM eugenol was able to completely prevent glutathione loss and cell death as well as inhibit the covalent binding of eugenol metabolites to protein. Conversely, pretreatment of hepatocytes with diethylmaleate to deplete intracellular glutathione increased the cytotoxic effects of eugenol. These results demonstrate that eugenol is actively metabolized in hepatocytes and suggest that the cytotoxic effects of eugenol are due to the formation of a reactive intermediate, possibly a quinone methide.     

Formation of dimethylsulfide and methanethiol from methoxylated aromatic compounds and inorganic sulfide by newly isolated anaerobic bacteria

Formation of gas and of methylated sulfur compounds was observed in anaerobic enrichment cultures with methoxylated aromatic compounds as substrates. Via direct dilution of mud samples in defined reduced media supplemented with trimethoxybenzoate or syringate two new strains of anaerobic homoacetogenic bacteria (strain TMBS4 and strain SA2) were obtained in pure culture. Both strains produced dimethylsulfide and methanethiol during growth on methoxylated aromatic compounds. Growth tests and determination of stoichiometries demonstrated that the volatile sulfur compounds were formed from the methyl group at the aromatic ring and the sulfide added as reducing agent to the medium (R = aromatic residue): 2 R - O - CH₃ + H₂ S 2 R - OH + (CH₃)₂SDimethylsulfide was the major organic sulfur compound formed, whereas methanethiol appeared only as intermediate in small quantities. The isolates grew also with trihydroxybenzenes such as gallate, phloroglucinol, or pyrogallol without formation of methylated sulfur compounds. The aromatic compounds were degraded to acetate. The freshwater strain TMBS4 also fermented pyruvate. Other aliphatic or aromatic compounds were not utilized. External electron acceptors (sulfate, nitrate, fumarate) were not reduced. Both strains were mesophilic and formed rod-shaped, non-motile, Gram-negative cells. Spore formation was not observed. Tentatively, both isolates can be affiliated to the genus Pelobacter.Abbreviations TMB 3,4,5-trimethoxybenzoate - MT methanethiol - DMS dimethylsulfide     

Methionine catabolism in Saccharomyces cerevisiae

The catabolism of methionine to methionol and methanethiol in Saccharomyces cerevisiae was studied using (13)C NMR spectroscopy, GC-MS, enzyme assays and a number of mutants. Methionine is first transaminated to alpha-keto-gamma-(methylthio)butyrate. Methionol is formed by a decarboxylation reaction, which yields methional, followed by reduction. The decarboxylation is effected specifically by Ydr380wp. Methanethiol is formed from both methionine and alpha-keto-gamma-(methylthio)butyrate by a demethiolase activity. In all except one strain examined, demethiolase was induced by the presence of methionine in the growth medium. This pathway results in the production of alpha-ketobutyrate, a carbon skeleton, which can be re-utilized. Hence, methionine catabolism is more complex and economical than the other amino acid catabolic pathways in yeast, which use the Ehrlich pathway and result solely in the formation of a fusel alcohol.     

Glutamine affects glutamate metabolism in isolated rat kidney cortex mitochondria.

The active state respiration of isolated rat kidney cortex mitochondria with 10 mM glutamate as single substrate is substantially increased by the addition of 10 mM glutamine. This increase in respiration was accompanied by a higher transamination rate and was found to be insensitive to the selective inhibition of either the transamination or the desamination pathway of glutamate oxidation. These data can be explained by an approximately 2-fold elevated intramitochondrial glutamate concentration observed in the additional presence of glutamine.     

Anaerobic oxidation of dimethylsulfide and methanethiol in mangrove sediments is dominated by sulfate-reducing bacteria

The oxidation of dimethylsulfide and methanethiol by sulfate-reducing bacteria (SRB) was investigated in Tanzanian mangrove sediments. The rate of dimethylsulfide and methanethiol accumulation in nonamended sediment slurry (control) incubations was very low while in the presence of the inhibitors tungstate and bromoethanesulfonic acid (BES), the accumulation rates ranged from 0.02–0.34 to 0.2–0.4 nmol g FW sediment⁻¹ h⁻¹, respectively. Degradation rates of methanethiol and dimethylsulfide added were 2–10-fold higher. These results point to a balance of production and degradation. Degradation was inhibited much stronger by tungstate than by BES, which implied that SRB were more important. In addition, a new species of SRB, designated strain SD1, was isolated. The isolate was a short rod able to utilize a narrow range of substrates including dimethylsulfide, methanethiol, pyruvate and butyrate. Strain SD1 oxidized dimethylsulfide and methanethiol to carbon dioxide and hydrogen sulfide with sulfate as the electron acceptor and exhibited a low specific growth rate of 0.010 ± 0.002 h⁻¹, but a high affinity for its substrates. The isolated microorganism could be placed in the genus Desulfosarcina (the most closely related cultured species was Desulfosarcina variabilis , 97% identity). Strain SD1 represents a member of the dimethylsulfide/methanethiol-consuming SRB population in mangrove sediments.     

Proteolytic conversion of proinsulin into insulin. Identification of a Ca2+-dependent acidic endopeptidase in isolated insulin-secretory granules.

The metabolism of cysteine and cysteinesulphinate was studied in freshly isolated rat hepatocytes. Over 80% of the 14CO2 formed from [1-14C]cysteinesulphinate could be accounted for by production of hypotaurine plus taurine in incubations of rat hepatocytes with either 1 mM- or 25 mM-cysteinesulphinate. In similar incubations with 1 mM- or 25 mM-cysteine, less than 10% of 14CO2 evolution from [1-14C]cysteine could be accounted for by production of hypotaurine plus taurine. In incubations with cysteine, but not with cysteinesulphinate, the production of urea and ammonia was substantially increased above that observed in incubations without substrate. Addition of unlabelled cysteinesulphinate did not affect 14CO2 production from [1-14C]cysteine. Addition of 2-oxoglutarate resulted in a marked increase in cysteinesulphinate catabolism via the transamination pathway, but addition of neither 2-oxoglutarate nor pyruvate to the incubation system had any effect on cysteine catabolism. Inhibition of cystathionase with propargylglycine decreased 14CO2 production from [1-14C]cysteine about 50% and markedly decreased production of ammonia plus urea N; cysteinesulphinate catabolism by cysteinesulphinate-independent pathways in the rat hepatocyte and, furthermore, that cleavage of cyst(e)ine by cystathionase may be an important physiological pathway for cysteine catabolism in rat liver.     

The effect of methionine on methotrexate metabolism in rat hepatocytes in monolayer culture

The effect of methyl donors on the metabolism of methotrexate has been investigated in rat hepatocytes in monolayer culture. Pulse exposure to low concentrations of methotrexate (1 microM, 3h) in the absence of methionine results in the facile formation of the di- to pentaglutamates with the di- and triglutamate predominating. Further incubation after the removal of methotrexate (MTX) results in a shift to the tetra- and pentaglutamate at the expense of the shorter chain length derivatives. The same measurement in the presence of 1 mM methionine causes approx. an 80% inhibition in the formation of polyglutamates. This effect can be partially achieved when methionine is replaced by choline or betaine. No alteration in the formation of 7-hydroxymethotrexate could be detected by similar changes in methionine concentrations in the medium. The activity of the enzymes which synthesize and degrade methotrexate polyglutamates, folylpolyglutamate synthetase and gamma-glutamyl hydrolase, respectively, were the same in extracts of cells grown in the absence and in the presence of 1 mM methionine. Incubation of the hepatocytes with methionine causes a significant increase in 5,6,7,8-tetrahydrofolate (H4folate), 5,10-methylenehydrofolate and 10-formyltetrahydrofolate and a decrease in 5-methyltetrahydrofolate. These results suggest that the inhibition of glutamylation of methotrexate could be due in part to an elevation in reduced folates which can more effectively compete with methotrexate as a substrate for folylpolyglutamate synthetase. Inhibition in methotrexate glutamylation by methionine, betaine and choline in hepatocytes may contribute to the alleviation of hepatic toxicity by methyl donors.