Methionine metabolism in mammals. Regulation of homocysteine methyltransferases in rat tissue

Betaine:homocysteine methyltransferase--a new assay for the liver enzyme and its absence from human skin fibroblasts and peripheral blood lymphocytes

Chronic elevation of plasma homocysteine is associated with increased atherogenesis and thrombosis, and can be lowered by betaine (N,N,N-trimethylglycine) treatment which is thought to stimulate activity of the enzyme betaine:homocysteine methyltransferase. We have developed a new assay for this enzyme, in which the products of the enzyme-catalysed reaction between betaine and homocysteine are oxidised by performic acid before being separated and quantified by amino acid analysis. This assay confirmed that human liver contains abundant betaine:homocysteine methyltransferase (33.4 nmol/h/mg protein at 37 degrees C, pH 7.4). Chicken and lamb livers also contain the enzyme, with respective activities of 50.4 and 6.2 nmol/h/mg protein. However, phytohaemagglutinin-stimulated human peripheral blood lymphocytes and cultured human skin fibroblasts contained no detectable betaine:homocysteine methyltransferase (less than 1.4 nmol/h/mg protein), even after cells were pre-cultured in media designed to stimulate production of the enzyme. The results emphasize the importance of the liver in mediating the lowering of elevated circulating homocysteine by betaine.

A nonradioactive assay for N5-methyltetrahydrofolate-homocysteine methyltransferase (methionine synthase) based on o-phthaldialdehyde derivatization of methionine and fluorescence detection

The enzyme N5-methyltetrahydrofolate-homocysteine methyltransferase (methionine synthase, EC 2.1.1.13) catalyzes the conversion of homocysteine to methionine in the presence of a reducing system. N5-Methyltetrahydrofolate serves as a methyl donor in this reaction. An assay for the enzyme is described, which is based on methionine quantitation by o-phthaldialdehyde (OPA) derivatization and reversed-phase liquid chromatography. The enzymatic reaction is linear for at least 120 min under reducing conditions (125 mM 2-mercaptoethanol) and running the assay below an oil layer. This reducing system does not interfere with formation of the methionine-OPA adduct, which is separated from interfering compounds and an internal standard (norvaline) by a mobile phase adjusted to pH 5.0. The inclusion of internal standard increases the precision of the assay and corrects for the variable fluorescence yield due to occasional inaccurate pH adjustment before the derivatization step. Norvaline was suitable for this purpose because it elutes close to methionine and is not a natural amino acid present in biological extracts. This nonradioactive assay for methionine synthase was evaluated by comparison with a conventional method based on isolation of radioactive methionine by anion-exchange chromatography and by determination of enzyme activity in extract from cultured cells and liver.

Homocysteine export from cells cultured in the presence of physiological or superfluous levels of methionine: methionine loading of non-transformed, transformed, proliferating, and quiescent cells in culture

Determination of the transient increase in plasma homocysteine following administration of excess methionine is an established procedure for the diagnosis of defects in homocysteine metabolism in patients. This so-called methionine loading test has been used for 25 years, but the knowledge of the response of various cell types to excess methionine is limited. In the present paper we investigated homocysteine export from various cell types cultured in the presence of increasing concentrations (15-1,000 microM) of methionine. For comparison of homocysteine export, the export rates per million cells were plotted versus cell density for proliferating cells, and versus time for quiescent cells. The homocysteine export from growing cells was greatest during early to mid-exponential growth phase, and then decreased as a function of cell density. The export rate was higher from phytohemagglutinin-stimulated than non-stimulated lymphocytes, and higher from proliferating than from quiescent fibroblasts. The hepatocytes showed highest export rate among the cell types investigated. The enhancement of homocysteine export by excess methionine ranged from no stimulation to marked enhancement, depending on cell type investigated, and three different response patterns could be distinguished: 1) quiescent fibroblasts and growing murine lymphoma cell showed no significant increase in homocysteine export following methionine loading; export from human lymphocytes was only slightly enhanced in the presence of excess methionine; 2) the homocysteine export from proliferating hepatoma cells and benign and transformed fibroblasts was stimulated three to eightfold by increasing the methionine concentration in the medium from 15 to 1,000 microM; and 3) the response to methionine loading was particularly increased (about 15-fold) in non-transformed primary hepatocytes in stationary culture. The results outline a potentially useful procedure for the comparison of homocysteine export during cell growth in the presence of various concentrations of methionine. The results are discussed in relation to the special feature of homocysteine metabolism in various cell types and tissues including liver, and to the possible source of plasma homocysteine following methionine loading in vivo.

Effects of inhibition of cystathionase activity on glutathione and metallothionein levels in the adult rat

The effects of alterations in sulfur metabolism on hepatic and renal metallothionein and glutathione metabolism were studied in the adult rat using inhibition of two enzymes of these pathways, hepatic cystathionase and renal gamma-glutamyl transpeptidase. Rats were fed a diet containing both methionine (0.66%) and cystine (0.20%) for 1 week before receiving three consecutive daily intraperitoneal injections of propargylglycine, a selective cystathionase inhibitor, at various doses (2.5-375 mumol/kg). When hepatic cystathionase was inhibited greater than 90% (greater than or equal to 50 mumol propargylglycine/kg), renal and hepatic metallothionein and hepatic glutathione were unaltered except at the highest dose. On the other hand, renal glutathione was increased two-fold with a concomitant decrease in renal gamma-glutamyl transpeptidase activity (50% of control). In another experiment, when renal gamma-glutamyl transpeptidase was inhibited greater than 90% with three consecutive daily injections of acivicin, a selective gamma-glutamyl transpeptidase inhibitor (10 mg/kg IP), renal glutathione content was unaltered while hepatic glutathione was decreased. Renal and hepatic metallothionein were not changed. Thus, the cysteine pools for metallothionein and glutathione appear unrelated under the present experimental conditions. In addition, following either proparglyglycine or acivicin injections, renal and hepatic glutathione pools appear to be altered differently. These results suggest that renal glutathione may be preferentially maintained even when hepatic glutathione is decreased.

Changes in body-weight, composition and hepatic enzyme activities in response to dietary methionine, betaine and choline levels in growing chicks

The experiments described here were set up (a) to investigate the effect of age and (b) to investigate the effect of giving five diets which varied in methionine and choline or betaine contents on some of the enzymes that metabolize these nutrients in chick liver. Growth and carcass composition of the chicks fed on the different diets were also examined. There was no obvious relationship between age and enzyme activity in young chicks. Only a diet low in methionine (but not one low in choline) showed a significant decrease in growth and a change in carcass composition. The effects of diet on enzyme activity were complex. Choline oxidase (EC 1.1.3.17) activity was affected by the level of choline in the diet, being high when choline was present at high levels, especially when methionine was limiting. 5-Methyltetrahydrofolate homocysteine methyltransferase (EC 2.1.1.3) had a high activity in the livers of chicks fed on a conventional diet compared with those given semi-purified diets. Other enzymes showed minor changes in response to the diet. The diet low in methionine showed a lower activity of cystathionine beta-synthase (EC 4.2.1.22) and slightly higher activities of methionine adenosyltransferase (EC 2.5.1.6) and betaine-homocysteine methyltransferase (EC 2.1.1.5; compared with other diets), suggesting that this diet encouraged re-methylation of homocysteine at the expense of trans-sulphuration to cystathionine. The findings obtained in these studies form a useful basis for further investigation of the metabolic interrelationships between methionine and related nutrients.

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.

Determination of plasma homocysteine by high-performance liquid chromatography with fluorescence detection

Severe homocystinemia is frequently associated with vascular disease while the pathological consequences of moderate or slightly elevated plasma homocysteine are unknown. Cobalamin and folate deficiencies may result in an elevation of plasma homocysteine. A sensitive and reproducible assay for total plasma homocysteine has been developed. The essential steps in the assay include (i) conversion of homocysteine disulfides to free homocysteine with borohydride reduction; (ii) conjugation of homocysteine with monobromobimane; (iii) separation of homocysteine-bimane from other plasma thiol-bimane adducts by reverse-phase high-performance liquid chromatography; and (iv) detection and quantitation of homocysteine-bimane by fluorometry. The method has a sensitivity of 4.4 pmol of homocysteine and is highly reproducible (intra- and interassay coefficients of variation = 4.97 and 4.53%, respectively). The mean concentration of total plasma homocysteine in nonfasting adult males (n = 12) and females (n = 12) was 15.8 (range, 7.0-23.7) and 16.5 nmol/ml (range, 8.6-20.7), respectively. Markedly elevated levels of homocysteine were found in patients with cobalamin and folate deficiency. Total plasma homocysteine represents approximately 4% of borohydride-generated thiol reactivity in the plasma of normal individuals.

Source of methyl groups in brain and nerve tissue in the rat

Previous studies that demonstrated that mouse brain accumulated significantly more radioactivity from subcutaneously administered 5-methyltetrahydrofolate labelled in the methyl group compared to the label in the folate moiety are open to two interpretations. The methyl group could have been transferred to another compound (probably methionine) prior to its transport into the brain. Alternatively, if plasma 5-methyltetrahydrofolate per se is significantly involved in the provision of methyl groups to brain and nerve tissue it would be expected that the folate moiety would be returned to the plasma to complete the cycle and thus would appear not to have been taken up. In this article, using competition experiments that exploit the differences in the mechanism of transport of methionine and 5-methyltetrahydrofolate into brain and nerve, evidence is presented that in the rat the methyl group of 5-methyltetrahydrofolate is transported after its conversion to methionine.

Betaine metabolism in human neonates and developing rats

Proton nuclear magnetic resonance spectroscopy has been used to demonstrate the presence of high concentrations of betaine (up to 0.75 mol/mol creatinine) in the urine of normal healthy human neonates. Betaine is not normally excreted in adults. Excretion of betaine from birth to 7 days old was monitored. The excretion of betaine in rats from 21 days after birth to 40-45 days old was also monitored. A peak in excretion in the rats of 1.5-3 mol/mol creatinine occurred between days 30-35. The presence of a high concentration of betaine in the urine is unlikely to be caused by a relative lack of betaine homocysteine methyl transferase activity compared with adults but may relate to the disposal of dietary choline during development.

Cystathionine metabolism in neuroblastoma

Cystathioninuria is a frequent and highly specific marker of neuroblastoma, but the etiology of this abnormality has not been well studied. To investigate this phenomenon, we analyzed 27 human neuroblastoma tissue specimens for the presence of cystathionine synthase and cystathionase. Levels of cystathionine synthase varied from undetectable to 622 pmol/mg protein, but no specimen had cystathionase measurable by rocket radioimmunoassay or catalytic assay. In addition, we assayed neuroblastoma cell lines exposed to a variety of differentiating agents: butyric acid, dimethyl sulfoxide, serum-free medium, or sodium citrate to induce differentiation. In each case we were unable to demonstrate cystathionase induction. These data are consistent with the hypothesis that neuroblastomas have a biochemical block in the transsulfuration enzymes at the level of cystathionase and that expression of cystathionine synthase in the absence of cystathionase may account for the presence of cystathioninuria in patients with neuroblastoma.

Impaired formylation and uptake of tetrahydrofolate by rat small gut following cobalamin inactivation

The effect of inactivation of cobalamin by N2O on the intestinal absorption of folate was studied using rat everted gut sacs. Further, in view of uncertainties about the presence of methionine synthetase in gut [1], this enzyme was measured. Everted gut sacs were incubated with [2-14C]tetrahydrofolate, and the subsequent appearance of labelled formyl- and methyl [14C] tetrahydrofolate in everted segments of small intestine of rats was studied. Considerable methionine synthetase activity was present in washed everted gut sacs but not in gut segments in the absence of such treatment. Methionine synthetase activity declined after exposure to N2O, which oxidizes and inactivates cob(I)alamin. Folate uptake by gut sacs was not affected by 24 h exposure of the animals to N2O but fell significantly after 7 days exposure. There was a significant fall in the amount of formyltetrahydrofolate formed after cobalamin inactivation and this was reversed by supplying either methionine, methylthioadenosine or sodium formate. Serine had no effect. The data support the hypothesis that methionine and methylthioadenosine act by supplying single carbon units at the formate level of oxidation.

Methyl group metabolism in sheep

1. Sheep have a very low intake of methyl nutrients in the post-ruminant state, due to the almost complete degradation of dietary choline by rumen microorganisms, the lack of dietary creatine and the relatively low content of methionine in microbial proteins. 2. Methylneogenesis provides a major source of labile methyl groups in post-ruminant sheep and impairment of the methylneogenesis leads to a marked reduction of the labile methyl pool. 3. S-Adenosylmethionine (AdoMet) metabolism via transmethylation is most active in sheep liver and pancreas and is regulated by the availability of methionine and intracellular ratios of AdoMet to S-adenosylhomocysteine (AdoHcy). 4. Adaptive mechanisms which arise as a consequence of the poor methyl nutrition in post-ruminant sheep are a marked reduction of labile methyl catabolism and an increase in the capacity of methylneogenesis.

Age- and tumour-related changes in methionine biosynthesis in mice

Two routes for the methylation of homocysteine to methionine, depending either on betaine or folate cofactor as methyl donor, were studied in liver and kidneys of normal and Ehrlich ascites carcinoma-bearing mice at various stages of their postnatal development. Distinct age-dependence in the activities of betaine methyltransferase, methylenetetrahydrofolate reductase and methionine synthase were found both in normal and tumour-bearing mice. Independent of the levels of enzyme activity in healthy mice, the tumour activated one route of methionine formation only, namely that utilizing methyltetrahydrofolate as the methyl donor. This effect was observed in host liver exclusively. No host age-related changes were found in Ehrlich ascites carcinoma growth.

Prevention of strychnine-induced seizures and death by the N-methylated glycine derivatives betaine, dimethylglycine and sarcosine

Betaine (N,N,N-trimethylglycine) and N,N-dimethylglycine have been reported to have anticonvulsant properties in animals. The purpose of the present study was to determine whether these compounds can antagonize strychnine-induced seizures when administered intraperitoneally and to compare their effects with those of sarcosine (N-methylglycine) and glycine. Betaine, N,N-dimethylglycine and sarcosine were equipotent in decreasing the incidence of seizures and death, causing a 38 to 72 percent decrease in the incidence of seizures and death at a dosage of 5 mmole/kg. Glycine had no effect. Thus anticonvulsant activity is conferred to glycine by a single N-methylation.

Effects of betaine on seizures in the rat

The ability of betaine to block homocysteine, pentylenetetrazol, and electroshock induced seizures in mice has previously been observed. In this study, betaine administered IP and intraventricularly to rats blocked pentylenetetrazol-induced seizures, but IP betaine did not block audiogenic seizures. Intraventricular betaine was about 1000-fold more potent than IP betaine in blocking PTZ-induced seizures. Glycine, a component of the betaine molecule, was ineffective. It is concluded that betaine has an appreciable but selective effect in controlling experimental seizures in rats. This effect is mediated directly by the brain, and is not due to metabolism of betaine to glycine.

Inactivation of betaine-homocysteine methyltransferase by adenosylmethionine and adenosylethionine

Preincubation of betaine-homocysteine methyltransferase, prepared from rat liver, with either S-adenosylmethionine or S-adenosylethionine results in a marked loss of enzyme activity. Gel filtration did not restore activity. However both S-adenosylhomocysteine and L-homocysteine, when added to the preincubation medium, inhibited the inactivation of betaine-homocysteine methyltransferase.

Methotrexate hepatotoxicity

An inhibitor of folate metabolism, amethopterin (methotrexate) has been successfully used in the treatment of psoriasis and neoplastic disease. This drug produces several dangerous side effects of both an acute and chronic nature which have widely curtailed its use. A serious chronic side effect of the drug is its hepatotoxicity, which may culminate in hepatic cirrhosis and death. To date the underlying mechanism of methotrexate in producing liver damage is unknown. Results of three studies conducted in this laboratory on the nutritional effects of methotrexate offer some evidence that the hepatotoxicity may possibly be incurred through the effect of the drug on methionine biosynthesis and methylation processes. This thesis is discussed in the light of methylating agents vital to the synthesis of methionine.

Effects of nitrous oxide-induced inactivation of cobalamin on methionine and S-adenosylmethionine metabolism in the rat

Inhalation of nitrous oxidises cobalamin and, in turn, inactivates methionine synthetase which forms methionine from homocysteine and which requires cob[I]alamin as a co-factor. This study was planned to determine the effect of virtual cessation of methionine synthesis via a cobalamin-dependent pathway, on tissue levels of methionine, S-adenosylmethionine and on related enzymes. The level of methionine in liver fell initially after exposure to N2O but was restored to pre-N2O levels after 6 days despite continuing N2O exposure. Brain methionine fell within 12 h of N2O exposure but the fall was not significant. The restoration of methionine levels is accompanied by an increase in activity of betaine homocysteine methyltransferase in liver but this enzyme was not detected in brain. The activity of methionine synthetase remained very low in both liver and brain as long as N2O inhalation was continued. There was an initial rise in liver S-adenosylmethionine levels followed by a steady fall to 40% of its initial level after 11 days of N2O exposure. However, there was no change in the level of S-adenosylmethionine in brain during this period. The data indicate that either brain meets its requirement by increased methionine uptake from plasma or that there are alternate pathways in brain for methionine synthesis other than those requiring a cobalamin coenzyme.

Betaine, metabolic by-product or vital methylating agent?

The possible physiological role of betaine, the oxidative product of choline, is considered. It is proposed that betaine, instead of merely being a metabolic by-product of choline oxidation, may serve as an important methylating agent when normal methylating pathways are impaired by ethanol ingestion, drugs or nutritional imbalances. Furthermore, betaine may prove to have therapeutic application in cases of altered folate, vitamin B12 or methionine metabolism.

The role of methionine in the intracellular accumulation and function of folates

It is suggested that mammalian cells have evolved to respond to methionine deficiency since in such circumstances vital methylation reactions are put at risk, due to decreased levels of S-adenosyl-methionine. Enzymatic changes occurring as a result of decreased methionine, S-adenosylmethionine and S-adenosylhomocysteine, optimize the remethylation of homocysteine to methionine by decreasing homocysteine catabolism and channelling cellular folates into 5-methyltetrahydropteroylglutamate (5-CH3-H4 PteGlu). The latter, in addition to optimising the remethylation cycle, directs the folate cofactors away from purine and pyrimidine biosynthesis and decreases the rate of proliferation of rapidly dividing cells thus reducing competition for methionine incorporation into proteins. Decreased cellular homocysteine, as a result of decreased methionine, would also restrict cell division by decreased conversion of plasma 5-CH3-H4PteGlu into intracellular polyglutamates. Cobalamin deficiency, either nutritional or due to exposure to the Co (I) cobalamin inactivating agent nitrous oxide, prevents the demethylation of 5-CH3-H4PteGlu, which even in the presence of adequate amounts of homocysteine and methionine prevents rapidly proliferating cells from converting enough of the plasma 5-CH3-H4 PteGlu into folylpolyglutamate forms to permit normal DNA biosynthesis and cell replication. This, together with the trapping of the cellular folate cofactors in the 5-CH3-H4PteGlu form, results in megaloblastic changes occurring in tissues such as the marrow. The vital role of the methylation reactions was demonstrated by exposing monkeys to nitrous oxide which inactivated their methionine synthetase. The resultant ataxia and severe demyelination was prevented and diminished by methionine supplementation. When methionine synthetase was similarly inactivated in mice it was shown that while 5-CH3-H4PteGlu enters mammalian cells, it is not converted into a polyglutamyl form and subsequently leaves the cell unmetabolised. In similar experiments in rats methionine was found to have only a small effect in restoring folylpolyglutamate biosynthesis, contrary to previous reports using nutritionally cobalamin deficient animals. It was found that a decrease in the deoxythymidine salvage pathway by methionine, under the experimental conditions used, has led others to the mistaken conclusion that methionine has an 'anti-folate' effect in bone marrow, i.e. that it decreases folate availability for thymidylate synthetase.

The effect of local application of homocysteine on neuronal activity in the central nervous system of the rat

Homocysteine, a monocarboxylic, sulfur-containing amino acid, produces convulsions in rats and mice when administered systemically. Convulsions and high serum concentrations of homocysteine are among the symptoms that characterize patients with homocystinuria, a hereditary disorder of amino acid metabolism. In order to evaluate the effects of homocysteine on the central nervous system directly, extracellular recordings were made from neurons in rat cerebral cortex, cerebellum and midbrain during local application of homocysteine by pressure ejection or iontophoresis. Both methods of drug delivery produced dose-dependent increases in the activity of neurons in every area tested. Activity was increased by D,L-homocysteine and L-glutamate in 67 percent of cells tested with both drugs. The doses required to produce equivalent excitations in this group of cells were similar, suggesting that homocysteine is at least as potent as glutamate. The excitatory effects of both homocysteine and glutamate were antagonized by local application of betaine, a biological methyl donor which blocks convulsions produced by systemic administration of pentylenetetrazol and electroshock as well as homocysteine. The effects of local application of homocysteine were also blocked by local application of the glutamate antagonist glutamate diethylester (GDEE). In 6 of 7 cells tested, GDEE appeared to preferentially affect homocysteine-induced excitations. These data indicate that homocysteine has an excitatory action on neurons, a finding which may account for some of the symptoms associated with certain disorders of amino acid metabolism.

The effects of S-adenosylhomocysteine and S-adenosylmethionine on some purine- and pyrimidine-metabolizing systems

The effects of S-adenosylhomocysteine and S-adenosylmethionine on some purine- and pyrimidine-metabolizing systems have been examined. Both compounds were capable of acting as relatively good inhibitors of adenosine deaminase, nucleoside phosphorylase, and adenylate deaminase activities but as relatively poor inhibitors of myokinase and nucleoside monophosphate kinase. The inhibitory effects were freely reversible. 5'-Nucleotidase, orotidine 5'- phosphate, and phosphodiesterase were unaffected. Nucleoside phosphorylase was competitively inhibited by both compounds, whereas mixed inhibitory effects occurred with adenosine deaminase.

The effects of nitrous oxide on cobalamins, folates, and on related events

The anaesthetic gas nitrous oxide (N2O), when inhaled for longer than 6 hr, produces megaloblastic anemia in man. Longer term inhalation, as in addicts, produces a syndrome similar to that due to B12 neuropathy, and long term exposure to low concentrations results in an increased abortion rate and neuropathy, particularly in dental personnel. N2O acts by oxidizing vitamin B12 from the active reduced cob[I]alamin form to the inactive cob[III]alamin form. In turn, this inactivates the enzyme methionine synthetase which requires both B12 and folate as cofactors. In the rat, hepatic methionine synthetase is completely inactivated after 3 hr exposure to a mixture of equal parts of N2O/O2. There is an impared uptake of folate analogues by the liver so that the plasma folate level rises and thereafter there is a considerable loss of folate into the urine. Hepatic folate concentration falls to 25% within 10 days of N2O exposure. There is a failure to synthesize folate polyglutamate (the active folate coenzyme) from all other than formyltetrahydrofolate. As oxidization of the methyl of methionine is an important source of formyl, the failure of methionine synthesis in turn appears to lead to the failure in supply of formate and, hence, a lack of the formylfolate substrate.

Characterization of the enzymic capacity for cysteine desulphhydration in liver and kidney of the rat

The contribution of cystathionine gamma-lyase, cystathionine beta-synthase and cysteine aminotransferase coupled to 3-mercaptopyruvate sulphurtransferase to cysteine desulphhydration in rat liver and kidney was assessed with four different assay systems. Cystathionine gamma-lyase and cystathionine beta-synthase were active when homogenates were incubated with 280 mM-L-cysteine and 3 mM-pyridoxal 5'-phosphate at pH 7.8. Cysteine aminotransferase in combination with 3-mercaptopyruvate sulphurtransferase catalysed essentially all of the H2S production from cysteine at pH 9.7 with 160 mM-L-cysteine, 2 mM-pyridoxal 5'-phosphate, 3 mM-2-oxoglutarate and 3 mM-dithiothreitol. At more-physiological concentrations of cysteine (2 mM) cystathionine gamma-lyase and cystathionine beta-synthase both appeared to be active in cysteine desulphhydration, whereas the aminotransferase pathway did not. The effect of inhibition of cystathionine gamma-lyase by a suicide inactivator, propargylglycine, in the intact rat was also investigated; there was no significant effect of propargylglycine administration on the urinary excretion of total 35S, 35SO4(2-) or [35S]taurine formed from labelled dietary cysteine.

Development and regional distribution of methionine synthetase in rabbit brain

The development and regional distribution of methionine synthetase (EC 2.1.1.13) in rabbit brain was determined. In adult rabbits, the specific activity (units per milligram protein) of methionine synthetase in cortex, cerebellum, brain stem, and corpus striatum was comparable to the specific activity in whole brain (0.5 units/mg). In the first few weeks of life, the specific activity of methionine synthetase in whole rabbit brain declined from a value of 1.1 units/mg at 1 day of age to 0.5 units/mg at 6-10 weeks. Two-year-old rabbits had 0.6 units/mg in whole brain. These results show that: (a) methionine synthetase is distributed widely in mammalian brain and (b) methionine synthetase activity in brain declines relatively little with development.

Induction of betaine: homocysteine methyltransferase in some murine cells cultured in vitro

Betaine when present in the culture medium could induce the activity of betaine: homocysteine methyltransferase (EC 2.1.1.5) in mouse L-cells, and leukemic L1210 cells, as well as in mouse embryo fibroblasts grown in vitro. We found this process to be time- and concentration-dependent. A persisting contact of the cells with betaine was indispensible for expressing and maintaining the enzyme activity. The treatment of cells with cycloheximide or actinomycin D abolished the process of induction. Methionine as well as homocysteine, when present either in the culture medium or in the reaction mixture, strongly depressed the activity of this enzyme. The L-cells with the induced betaine:homocysteine methyltransferase survived but did not multiply in the methionine-deficient medium, therefore, they did not become prototrophs with respect to methionine.

Methionine recycling in brain: a role for folates and vitamin B-12

The recycling of methionine via homocysteine was measured in vivo in brain. After constant intravenous infusions (5 h) of both [3H-methyl]methionine and [35S]methionine into rats, the ratios of [3H-methyl]methionine to [35S]methionine in liver, brain, and plasma were determined. Similar experiments were performed in rabbits, except that the [3H-methyl]- and [35S]methionine were injected intraventricularly. If the methyl group of methionine was removed with the formation of homocysteine and then replaced by another (unlabeled) methyl group, the specific activity of the [3H-methyl]methionine would decrease more than that of [35S]methionine; i.e., the ratio of [3H-methyl]- to [35S]methionine in the tissue would decline. The results showed that the ratios of [3H-methyl]- to [35S]methionine in liver and brain were less than the same ratio in plasma in the rats. The comparable ratios in the brain and CSF of rabbits were less than the ratio in the injectate. Since brain contains only one enzyme capable of remethylating homocysteine to methionine, the vitamin B-12-dependent methyltetrahydrofolate-homocysteine methyltransferase (EC 2.1.1.13), our results for methionine recycling via homocysteine in brain strongly support the activity of this enzyme in brain in vivo.

Anticonvulsant properties of betaine

It has been shown previously that convulsions induced by homocysteine are blocked by betaine. In the present study, betaine was found to block the induction of convulsions by electroconvulsive shock and by pentylenetetrazol at least at effectively as it blocked convulsions induced by homocysteine. Thus, betaine has a general anticonvulsant action, the reason for which is unknown.

Lipid composition and metabolism in liver and brain of vitamin B12-deficient rat sucklings

1. Rat sucklings (18-d-old) bred from vitamin B12-deprived dams were compared with vitamin B12-supplemented dams' offspring, which were considered normal rat sucklings. 2. The vitamin B12-deficient rat sucklings had lower body-weight, liver weight and brain weight. 3. Vitamin B12 deficiency was also evident from the tenfold lower concentrations of vitamin B12 in liver and cerebellum. 4. The concentration of liver lipid was markedly increased in vitamin B12-deficient rats; triacylglycerol accounted for most of the increase. In brain the lipid concentration was slightly decreased (less than 0.05). 5. The methylation of ethanolamine phosphoglyceride to choline phosphoglyceride was reduced in both liver and brain in vitamin B12-deficient rats, as measured after the administration of [14C]ethanolamine. A slight decrease in choline phosphoglyceride concentration could be a consequence of this finding. The composition of phospholipids was otherwise normal. 6. Odd-chain fatty acids (pentadecanoate and heptadecanoate) accumulated in both liver and brain of the vitamin B12-deficient rat sucklings and constituted approximately 1% of total fatty acid. 7. The biosynthesis of fatty acid and cholesterol from intraperitoneally-injected 3H2O and [14C]propionate was unchanged in vitamin B12 deficiency.

Effect of vitamin B12 deficiency on phosphatidylethanolamine methylation in rat liver

1. In vitamin B12 deficiency the activity of tetrahydropteroylglutamate methyltransferase (EC 2.1.1.13) is depressed and the synthesis of methionine is reduced. Because the methyl group of methionine is largely utilized for the methylation of phosphatidylethanolamine, we investigated the effects of vitamin B12 deficiency on phosphatidylcholine synthesis. 2. The incorporation of injected [14C]formaldehyde into liver phosphatidylcholine was reduced by approximately 50% in vitamin B12-deficient rats. Also the corresponding incorporation of 5-[14C]methyltetrahydrofolic acid tended to decrease. The findings are consistent with a lower conversion of these precursors to methionine. 3. The effect of the deficient methyl-group supply on phosphatidylcholine synthesis was also investigated by the injection of [14C]ethanolamine. The amount (%) of lipid-14C recovered in phosphatidylcholine was significantly reduced in vitamin B12 deficiency. 4. Chemical analysis of liver phospholipids showed that the vitamin B12-deficient rats had a higher proportion of phosphatidylethanolamine and a lower proportion of phosphatidylcholine, indicating that the impaired synthesis of phosphatidylcholine by methylation leads to changes in membrane phospholipid composition.