Inhibition of glycine N-methyltransferase activity by folate derivatives: implications for regulation of methyl group metabolism

Glycine N-methyltransferase, an enzyme that uses S-adenosylmethionine to methylate glycine with the production of sarcosine, was recently shown to be identical with a major folate binding protein of rat liver (Cook, R.J. and Wagner, C. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 3631-3634). We now present evidence that 5-methyltetrahydropteroylpentaglutamate (5-CH3-H4PteGlu5) is bound with high specificity, and is a powerful inhibitor of the enzyme. It is proposed that this information may be used to modify the "methyl trap" hypothesis which describes how the availability of one-carbon units is regulated by folate, vitamin B12 and methionine.     

Effects of nitrous oxide inactivation of vitamin B12 and of methionine on folate coenzyme metabolism in rat liver, kidney, brain, small intestine and bone marrow

The effects of nitrous oxide inactivation of the vitamin B12-dependent enzyme, methionine synthetase (EC 2.1.1.13), and of methionine on folate coenzyme metabolism were determined in rat liver, kidney, brain, small intestine and bone marrow cells. Nitrous oxide exposure led to an increase in the proportion of 5-methyltetrahydrofolate at the expense of other reduced folates in all tissues examined. Administration of methionine at levels up to 400 mg/kg resulted in the normalization of folate coenzyme patterns in liver as a result of the increased levels of S-adenosylmethionine. In other tissues examined, methionine had no effect on the levels of S-adenosylmethionine or S-adenosylhomocysteine, or on the distribution of folate coenzymes. These results are consistent with the methyl trap hypothesis as the explanation of the relationship between vitamin B12 and folate metabolism, and provide direct evidence that the sparing effect of methionine on folate metabolism is a phenomenon restricted to the liver.     

Examination of the role of methylenetetrahydrofolate reductase in incorporation of methyltetrahydrofolate into cellular metabolism

Most mammalian cells receive exogenous folate from the bloodstream in the form of 5-methyltetrahydropteroylmonoglutamate (CH3-H4PteGlu1). Because this folate derivative is a very poor substrate for folylpolyglutamate synthetase, the enzyme that adds glutamyl residues to intracellular folates, CH3-H4PteGlu1 must first be converted to tetrahydropteroylmonoglutamate (H4PteGlu1), 10-formyltetrahydropteroylmonoglutamate (CHO-H4PteGlu1), or dihydrofolate (H2folate), which are excellent substrates for folylpolyglutamate synthetase. Polyglutamylation is required both for retention of intracellular folates and for efficacy of folates as substrates for most folate-dependent enzymes. Two enzymes are known that will react with CH3-H4PteGlu1 in vitro, methylenetetrahydrofolate reductase and methyltetrahydrofolate-homocysteine methyltransferase (cobalamin-dependent methionine synthase). These studies were performed to assess the possibility that methylenetetrahydrofolate reductase might catalyze the conversion of CH3-H4PteGlu1 to CH2-H4PteGlu1. CH2-H4PteGlu1 is readily converted to CHO-H4PteGlu1 by the action of methylenetetrahydrofolate dehydrogenase/methenyltetrahydrofolate cyclohydrolase, and these enzyme activities show very little preference for folypolyglutamate substrates as compared with folylmonoglutamates. We conclude from in vitro studies of the enzyme that methylenetetrahydrofolate reductase cannot convert CH3-H4PteGlu1 to CH2-H4PteGlu1 under physiological conditions and that uptake and retention of folate will be dependent on methionine synthase activity.     

Specific vitamin requirements of insect cell lines (P. Americana) according to their tissue origin and in vitro conditions

Summary AllP. americana cell lines, whatever tissue of origin, manifest similar vitamin requirements, except for ascorbic acid and vitamin B12. Investigations with chemically defined culture media reveal specific needs for purine and pyrimidine precursors and specific interactions between cyanocobalamin, folate, and methionine. Deficiency of one of these vitamins is always more drastic than deficiencies of both. Lethal effects can be prevented by increasing the concentration of methionine. Furthermore, the degree to which vitamin B12 or folate are needed depends on the extracellular concentration of nutrients. These nutrients include the mentioned vitamins and metabolites whose synthesis is vitamin dependent.     

Folic acid metabolism in vitamin B12-deficient sheep. Effects of injected methionine on liver constituents associated with folate metabolism

1. The effects of injected l-methionine (2g every second day for 28 days) on liver folates and other constituents of liver associated with folate metabolism were studied in vitamin B(12)-deficient ewes and their pair-fed controls receiving vitamin B(12). The dose rate of methionine used was sufficient to restore almost to normal the elevated excretion in the urine of formiminoglutamate in the deficient animals. 2. Liver folates active for Lactobacillus casei, Streptococcus faecalis R and Pediococcus cerevisiae were severely depressed in deficient livers and were partly restored by methionine. Analysis of the folates after ion-exchange chromatography showed that the major effect of methionine was to increase the concentrations of tetrahydrofolates and formyltetrahydrofolates. Methyltetrahydrofolates were also increased, but there was no effect of methionine on the small amounts of incompletely reduced folates present in deficient livers. The folates present were predominantly penta-, hexa- and hepta-glutamates whether or not animals received vitamin B(12) or methionine. 3. Concentrations of ATP, NAD(+), NADH and NADPH were lower in freeze-clamped liver from vitamin B(12)-deficient sheep than in liver from pair-fed, vitamin B(12)-treated sheep. These changes were not affected by methionine which was also without effect on the elevated K(+)/Na(+) ratios found in deficient livers. 4. The livers of vitamin B(12)-deficient animals contained lower concentrations of choline and higher concentrations of lipid than their pair-fed controls. These effects were reversed by methionine.     

Folate (vitamin B9) and vitamin B12 and their function in the maintenance of nuclear and mitochondrial genome integrity

Folate plays a critical role in the prevention of uracil incorporation into DNA and hypomethylation of DNA. This activity is compromised when vitamin B12 concentration is low because methionine synthase activity is reduced, lowering the concentration of S-adenosyl methionine (SAM) which in turn may diminish DNA methylation and cause folate to become unavailable for the conversion of dUMP to dTMP. The most plausible explanation for the chromosome-breaking effect of low folate is excessive uracil misincorporation into DNA, a mutagenic lesion that leads to strand breaks in DNA during repair. Both in vitro and in vivo studies with human cells clearly show that folate deficiency causes expression of chromosomal fragile sites, chromosome breaks, excessive uracil in DNA, micronucleus formation, DNA hypomethylation and mitochondrial DNA deletions. In vivo studies show that folate and/or vitamin B12 deficiency and elevated plasma homocysteine (a metabolic indicator of folate deficiency) are significantly correlated with increased micronucleus formation and reduced telomere length respectively. In vitro experiments indicate that genomic instability in human cells is minimised when folic acid concentration in culture medium is greater than 100nmol/L. Intervention studies in humans show (a) that DNA hypomethylation, chromosome breaks, uracil incorporation and micronucleus formation are minimised when red cell folate concentration is greater than 700nmol/L and (b) micronucleus formation is minimised when plasma concentration of vitamin B12 is greater than 300pmol/L and plasma homocysteine is less than 7.5μmol/L. These concentrations are achievable at intake levels at or above current recommended dietary intakes of folate (i.e. >400μg/day) and vitamin B12 (i.e. >2μg/day) depending on an individual's capacity to absorb and metabolise these vitamins which may vary due to genetic and epigenetic differences.     

The metabolism of 5-methyltetrahydropteroyl-L-glutamic acid and its oxidation products in the rat.

Folate metabolism in the rat was investigated using radiolabelled 5-methyltetrahydropteroylglutamate (5-CH3-H4PteGlu) and its oxidation products. 5-CH3-H4PteGlu is absorbed completely from the intestine, although in some preparations it is an equimolecular mixture of C-6 epimers, only one of which is naturally present in biological systems. The methyl group is incorporated into non-folate compounds, including methionine and creatine. No evidence was observed for the oxidation of the methyl group of 5-CH3-H4PteGlu to form other folate types. The tetrahydrofolate moiety of 5-CH3-H4PteGlu is metabolized in a similar manner to folic acid, forming formyl folates and tissue polyglutamates, and is catabolized by scission. The triazine oxidation product of 5-CH3-H4PteGlu is not metabolized by the rat or its gut microflora. 5-Methyl-5,6-dihydropteroylglutamate, however, is assimilated into the folate pool, but is substantially broken down by passage through the gut. The possible implication of this in scorbutic diets is discussed.     

Transport and metabolism of folates by bacteria.

Transport of labeled folic acid (PteGlu), pteroylpolyglutamates (PteGlu3-5), 5-methyl-tetrahydrofolate (5-methyl-H4PteGlu), and methotrexate in late-log phase cells of Lactobacillus casei was active, and subject to inhibition by unlabeled pteroylmonoglutamates, pteroylpolyglutamates, and iodoacetate, but not glutamate or glutamate dipeptides. Pteroylpolyglutamates were transported without prior hydrolysis and shared a common uptake system with pteroylmonoglutamates. The affinity and maximum velocity of PteGlun uptake decreased with increasing glutamate chin length (Km:PteGlu1, 0.03 mum; PteGlu3, 0.32 mum; PteGlu4, 1.9 mum; PteGlu5, 3.7 mum) and comparisons with growth response curves suggested that polyglutamates were more effectively utilized by L. casei, once transported, than monoglutamate. No concentration of 5-methyl-H4PteGlu3-8 inside the cells was observed. The major folate metabolites found in L. casei preloaded with high levels of [3H]PteGlu (0.5 mum) were 10-formyl-H4PteGlu2 and 10-formyl-PteGlu. Both compounds were released, the monoglutamate more rapidly. Pteroyltriglutamate formation appeared to be a rate-limiting step in intracellular metabolism. No 10-formyl-Pte-Glu was found in iodoacetate-treated cells and efflux was inhibited. Cells preloaded with low levels of [3H]PteGlu (7 nm) metabolized the vitamin to polyglutamate forms, the major derivatives being H4PteGlun. First order exit rates of labeled folate from preloaded L. casei indicated an inhibition of PteGlu uptake with time. Exit rates dropped from 0.05 min-1 to greater than 0.002 min-1 as intracellular folate was metabolized from monoglutamate to polyglutamate derivatives (n larger than or equal to 3). In the latter case, materials lost by efflux were breakdown products and no folate of glutamate chain length greater than two was released. Pediococcus cerevisiae actively transported 5-methyl-H4PteGlu but did not take up to 5-methyl-H4PTeGlu3-8. No active accumulation of 5-methyl-H4PteGlu was observed in Streptococcus faecalis.     

High-pressure liquid chromatography separation and determination of rat liver folates

The endogenous levels of the various folate compounds in rat liver were determined using high-pressure liquid chromatography for the rapid separation of folate monoglutamate forms with specific quantitation of the folates by microbiological analysis of eluted fractions. The eight folate derivatives that were assayable were tetrahydrofolic acid (H₄PteGlu), 5-methyl-H₄PteGlu, 10-formyl-H₄PteGlu, 5-formyl-H₄PteGlu, 5,10-methenyl-H₄PteGlu, 5,10-methylene-H₄PteGlu, H₂PteGlu, and PteGlu. New techniques for the preparation of tissues were developed in order to reduce the degradation of the folates. Tissue folates were converted to the monoglutamate form by a partially purified hog kidney polyglutamate hydrolase preparation and incubations were carried out at pH 6.0. This minimized folate degradation but still allowed for maximal polyglutamate hydrolase activity. Rapid removal of tissues was compared with freeze-clamping techniques. The major folates in rat liver were H₄PteGlu and 5-methyl-H₄PteGlu, comprising 42 and 39%, respectively, of the total liver folate pool of 27.30 nmol/g liver (about 13 μg/g liver). In addition, 10-formyl-H₄PteGlu and 5-formyl-H₄PteGlu each comprised 10% of the total folate pool. No endogenous PteGlu, H₂PteGlu, or 5,10-methylene-H₄PteGlu was detected in rat liver samples under our conditions. Distribution of ¹⁴C derived from a previous [¹⁴C]folic acid injection paralleled the distribution of folate as determined microbiologically after high-pressure liquid chromatography separation. The importance of these methods for the direct determination and estimation of flux of H₄PteGlu, 5-methyl-H₄PteGlu, and 10-formyl-H₄PteGlu in studies dealing with the folate system was emphasized.     

Biosynthesis of methionine in mouse cells cultured in vitro

In the mouse cell-lines cultured in vitro, viz. L-cells and mouse embryo fibroblasts, the methylation of homocysteine to methionine is carried out by vitamin B12-dependent 5-methyltetrahydrofolate:L-homocysteine methyltransferase only. In these cells grown in the standard Eagle medium, the activity of another methyltransferase, which utilizes betaine as the methyl donor, was not detected. The high activity of the vitamin B12-dependent methionine synthetase is typical for mouse cells from the logarithmic phase of growth. In L-cells 60%, and in the mouse fibroblasts 30% of the enzyme exist in the holo-form; the ratio between the holo- and apoenzyme activity remains stable in cells from logarithmic and stationary cultures. The level of the activity of methionine synthetase strongly depends on the presence of vitamin B12, folate and methionine in the culture medium and is greater after prolonged contact of the cells with these agents.     

Characteristics of thymidylate synthase purified from a human colon adenocarcinoma

Thymidylate synthase has been purified greater than 4000-fold from a human colon adenocarcinoma maintained as a xenograft in immune-deprived mice. In this disease, the enzyme is an important target for the cytotoxic action of 5-fluorouracil, which is influenced by the reduced folate substrate CH2-H4PteGlu. Due to the importance of this interaction, and the existence in cells of folate species as polyglutamyl forms, the interaction of folylpolyglutamates with thymidylate synthase was examined. Polyglutamates of PteGlu were used as inhibitors, and the interaction of CH2-H4PteGlu polyglutamates as substrates or in an inhibitory ternary complex were also examined. Using PteGlu1-7, Ki values were determined. A maximal 125-fold decrease in Ki was observed between PteGlu1 and PteGlu4; further addition of up to three glutamyl residues did not result in an additional decrease in Ki. Despite the increased binding affinity of folypolyglutamates for this enzyme, no change in the Km values for either dUMP (3.6 microM) or CH2-H4PteGlu (4.3 microM) were detected when polyglutamates of [6R]CH2-H4PteGlu were used as substrates. Product inhibition studies demonstrated competitive inhibition between dTMP and dUMP in the presence of CH2-H4PteGlu5. In addition, CH2-H4PteGlu4 stabilized an inhibitory ternary complex formed between FdUMP, thymidylate synthase, and CH2-H4PteGlu4. Thus the data do not support a change in the order of substrate binding and product release upon polyglutamylation of CH2-H4PteGlu reported for non-human mammalian enzyme. This is the first study to characterize kinetically thymidylate synthase from a human colon adenocarcinoma.     

Human placental microvilli contain high-affinity binding sites for folate.

Uptake of [3H]pteroylglutamic acid [( 3H]PteGlu) was studied in microvilli isolated from the syncytiotrophoblast of the human term placenta. The effect of changes in medium osmolality on the equilibrium uptake of [3H]PteGlu was negligible, which suggested that the observed uptake represented binding to proteins on or within the microvilli rather than translocation of the vitamin from the incubation medium to a free state in the intravesicular fluid. Equilibrium uptake experiments performed over a wide range of [3H]PteGlu concentrations disclosed a class of binding sites with an association constant of 0.3 nM-1 as well as a second class of sites with high capacity and low affinity. Binding of [3H]PteGlu at the high-affinity sites was inhibited by tetrahydrofolate and N5-methyltetrahydrofolate, but not by several other structural analogues. It is likely that the high-affinity binding sites are receptors for maternal plasma folate; however, their role in placental transport or storage of the vitamin was not delineated in these studies.     

Folate and homocysteine metabolism in copper-deficient rats.

To investigate the effect of copper deficiency on folate and homocysteine metabolism, we measured plasma, red-cell and hepatic folate, plasma homocysteine and vitamin B-12 concentrations, and hepatic methionine synthase activities in rats. Two groups of male Sprague-Dawley rats were fed semi-purified diets containing either 0. 1 mg (copper-deficient group) or 9.2 mg (control group) of copper per kg. After 6 weeks of dietary treatment, copper deficiency was established as evidenced by markedly decreased plasma and hepatic copper concentrations in rats fed the low-copper diet. Plasma, red-cell, hepatic folate, and plasma vitamin B-12 concentrations were similar in both groups, whereas plasma homocysteine concentrations in the copper-deficient group were significantly higher than in the control group (P<0.05). Copper deficiency resulted in a 21% reduction in hepatic methionine synthase activity as compared to the control group (P<0.01). This change most likely caused the increased hepatic 5-methyltetrahydrofolate and plasma homocysteine concentrations in the copper-deficient group. Our results indicate that hepatic methionine synthase may be a cuproenzyme, and plasma homocysteine concentrations are influenced by copper nutriture in rats. These data support the concept that copper deficiency can be a risk factor for cardiovascular disease.     

Concentration-dependent processivity of multiple glutamate ligations catalyzed by folylpoly-gamma-glutamate synthetase

Folylpoly-gamma-glutamate synthetase (FPGS, EC 6.3.2.17) is an ATP-dependent ligase that catalyzes formation of poly-gamma-glutamate derivatives of reduced folates and antifolates such as methotrexate and 5,10-dideaza-5,6,7,8-tetrahydrofolate (DDAH 4PteGlu 1). While the chemical mechanism of the reaction catalyzed by FPGS is known, it is unknown whether single or multiple glutamate residues are added following each folate binding event. A very sensitive high-performance liquid chromatography method has been used to analyze the multiple ligation reactions onto radiolabeled DDAH 4PteGlu 1 catalyzed by FPGS to distinguish between distributive or processive mechanisms of catalysis. Reaction time courses, substrate trapping, and pulse-chase experiments were used to assess folate release during multiple glutamate additions. Together, the results of these experiments indicate that hFPGS can catalyze the processive addition of approximately four glutamate residues to DDAH 4PteGlu 1. The degree of processivity was determined to be dependent on the concentration of the folate substrate, thus suggesting a mechanism for the regulation of folate polyglutamate synthesis in cells.     

Nitric oxide inhibits methionine synthase activity in vivo and disrupts carbon flow through the folate pathway

Many of nitric oxide's biological effects are mediated via NO binding to the iron in heme-containing proteins. Cobalamin (vitamin B(12)) is structurally similar to heme and is a cofactor for methionine synthase, a key enzyme in folate metabolism. NO inhibits methionine synthase activity in vitro, but data concerning NO binding to cobalamin are controversial. We now show spectroscopically that NO reacts with all three valency states of cobalamin and that NO's inhibition of methionine synthase activity most likely involves its reaction with monovalent cobalamin. By following incorporation of the methyl moiety of [(14)C]methyltetrahydrofolic acid into protein, we show that NO inhibits methionine synthase activity in vivo, in cultured mammalian cells. The inhibition of methionine synthase activity disrupted carbon flow through the folate pathway as measured by decreased incorporation of [(14)C]formate into methionine, serine, and purine nucleotides. Homocysteine, but not cysteine, attenuated NO's inhibition of purine synthesis, providing further evidence that NO was acting through methionine synthase inhibition. NO's effect was observed both when NO donors were added to cells and when NO was produced physiologically in co-culture experiments. Treating cells with an NO synthase inhibitor increased formate incorporation into methionine, serine, and purines and methyl-tetrahydrofolate incorporation into protein. Thus, physiological concentrations of NO appear to regulate carbon flow through the folate pathway.     

Folic acid and the methylation of homocysteine by Bacillus subtilis

1. Cell-free extracts of Bacillus subtilis synthesize methionine from serine and homocysteine without added folate. The endogenous folate may be replaced by tetrahydropteroyltriglutamate or an extract of heated Escherichia coli for the overall C₁ transfer, but tetrahydropteroylmonoglutamate is relatively inactive. 2. Extracts of B. subtilis contain serine transhydroxymethylase and 5,10-methylenetetrahydrofolate reductase, which are non-specific with respect to the glutamate content of the folate substrates. Methyl transfer to homocysteine requires a polyglutamate folate as methyl donor. These properties are not affected by growth of the organism with added vitamin B₁₂. 3. The synthesis of methionine from 5-methyltetrahydropteroyltriglutamate and homocysteine has the characteristics of the cobalamin-independent reaction of E. coli. No evidence for a cobalamin-dependent transmethylation was obtained. 4. S-Adenosylmethionine was not a significant precursor of the methyl group of methionine with cell-free extracts, neither was S-adenosylmethionine generated by methylation of S-adenosylhomocysteine by 5-methyltetrahydrofolate. 5. A procedure for the isolation and analysis of folic acid derivatives from natural sources is described. 6. The folates isolated from lysozyme extracts of B. subtilis are sensitive to folic acid conjugase. One has been identified as 5-formyltetrahydropteroyltriglutamate; the other is possibly a diglutamate folate. 7. A sequence is proposed for methionine biosynthesis in B. subtilis in which methyl groups are generated from serine and transferred to homocysteine by means of a cobalamin-independent pathway mediated by conjugated folate coenzymes.     

Endogenous folate of normal fibroblasts using high-performance liquid chromatography and modified extraction procedure

The endogenous levels of the various folate monoglutamate compounds in cultured human fibroblasts were determined using high-performance liquid chromatography for the separation of folate monoglutamate. Endogenous folates were converted to monoglutamate forms using conjugase enzyme present in rat serum and incubation was carried out at pH 6.5. This minimized folate coenzyme interconversion during processing. Using methanol for precipitation of protein instead of heat minimized degradation of labile folates. Recovery of all folates except 10-formyltetrahydrofolic acid (10-CHO H4PteGlu) using this procedure was more than 90%. Disruption of cells by boiling appeared to cause less postextraction changes of cell folates than did freezing and thawing or sonication. When heat to release endogenous folate, conjugase treatment with rat serum at pH 6.5, and precipitation of protein with methanol were used, more than half of the intracellular folate of normal fibroblasts in confluent growth was 5-methyltetrahydrofolic acid (5-CH3 H4PteGlu), and 10-CHO H4PteGlu and tetrahydrofolic acid (H4PteGlu) comprised 29 and 6%, respectively.     

Folic acid compounds in romaine lettuce.

The composition of folate coenzymes in romaine lettuce was studied. Lettuce extract was purified on QAE-Sephadex A-25 and folate compounds were separated into a monoglutamate fraction and a polyglutamate fraction by chromatography on Sephadex G-15. Both the mono- and poly-glutamate fractions were resolved on DEAE-cellulose. Positive identification of DEAE peaks was made by further cochromatography with high specific activity radioactive marker folate compounds and with differential microbiological assay. The distribution of folate compounds in lettuce is as follows: 32% 5-CH3-H4PteGlu; 1% 5-CHO-H4PteGlu; 3% 5-CHO-H4PteGlu4; 9% 5-CH3-H4PteGlu4; 13% 5-CHO-H4PteGlu5; and 31% 5-CH3-H4PteGlu5.