Formation and utilization of methionine by rat liver cells in culture

Summary The enzymeN ⁵-methyltetrahydrofolate: homocysteine methyltransferase (methionine synthetase) catalyzes the synthesis of methionine from homocysteine. Methylcobalamin is a cofactor for the reaction. The effects of methionine deprivation and methylcobalamin supplementation on the growth of normal and transformed rat liver epithelial cell lines were determined using growth constants to quantitate cell proliferation. No marked specific requirement by the transformed cell lines for methionine relative to leucine was observed. A sigmoidal relationship, however, was found to exist between growth constants and the logarithms of the amino acid concentrations for both normal and transformed cells. Methylcobalamin stimulated the growth rates of the normal and transformed liver cells in methionine-deficient, homocysteine-containing medium. Growth on methionine was not increased by the addition of methylcobalamin. The growth constants for two normal, two spontaneously transformed, one chemically transformed, and one tumor cell line grown in medium in which methionine was replaced by homocysteine were found to be proportional to the level of methionine synthetase. The results demonstrate the utility of growth quantitation to study the methionine dependency of transformed cells. Presented in part at the Conference on Differentiation and Carcinogenesis in Liver Cell Cultures sponsored by the New York Academy of Sciences, October 11, 1979 (see reference 1).     

Reversion to methionine independence by malignant rat and SV40-transformed human fibroblasts.

Although many lines of malignant and transformed cells are unable to grow in folate- and cobalamin-supplemented medium in which methionine is replaced by homocysteine its immediate metabolic precursor, rare cells from these lines regained the normal ability to grow under these conditions. Six revertant lines, one from Walker-256 rat breast carcinoma cells and five from SV40-transformed human fibroblasts, have been characterized with regard to growth and three measures of methionine biosynthetic capacity: methionine synthetase and methylenetetrahydrofolate reductase activities in cell extracts, and uptake of label from [5-¹⁴C]methyltetrahydrofolate by intact cells. When all three measures of methionine biosynthetic capacity were considered, two revertants isolated from SV40-transformed cells had regained the ability to grow like normal cells in homocysteine medium without substantial changes in these measures. Increased methionine biosynthesis thus is not a prerequisite to reversion of the methionine auxotrophy present in the transformed parental lines.     

An increased requirement for methionine by transformed rat liver epithelial cells in vitro

The growth of two normal and four transformed rat liver epithelial cell lines in a methionine-containing medium and a methionine-deficient medium supplemented with homocysteine was examined. The growth rates of the normal cells on the homocysteine-supplemented medium were approximately one-half the growth rates shown by the same cells in the methionine-containing medium. In contrast, three of the four transformed cell lines studied showed virtually no growth on the homocysteine-supplemented medium, although they grew quite rapidly on the methionine-containing medium. The fourth, transformed by N-methyl-N-nitrosourea, was able to grow on the homocysteine-supplemented medium at about one-third the rate as on the methionine-containing medium. Thus, transformed rat liver epithelial cells resemble other malignant cells in their reduced capacity to grow on homocysteine in the absence of methionine.     

S-adenosylmethionine synthetase in cultured normal and oncogenically-transformed human and rat cells

We have investigated the enzymatic formation of S-adenosylmethionine in extracts of a variety of normal and oncogenically-transformed human and rat cell lines which differ in their ability to grow in medium in which methionine is replaced by its immediate precursor homocysteine. We have localized the bulk of the S-adenosylmethionine synthetase activity to the post-mitochondrial supernatant. We show that in all cell lines a single kinetic species exists in a dialyzed extract with a Km for methionine of about 3-12 microM. In selected lines we have demonstrated a requirement for Mg2+ in addition to that needed to form the Mg X ATP complex for enzyme activity and have shown that the enzyme can be regulated by product feedback inhibition. Because we detect no differences in the enzymatic ability of these cell extracts to utilize methionine for S-adenosylmethionine formation in vitro, we suggest that the failure of oncogenically-transformed cell lines to grow in homocysteine medium may result from the decreased methionine pools in these cells or from the loss of ability of these cells to properly metabolize homocysteine, adenosine, or their cellular product S-adenosylhomocysteine.     

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.     

S-adenosylmethionine synthetase in cultured normal and oncogenically-transformed human and rat cells

We have investigated the enzymatic formation of S-adenosylmethionine in extracts of a variety of normal and oncogenically-transformed human and rat cell lines which differ in their ability to grow in medium in which methionine is replaced by its immediate precursor homocysteine. We have localized the bulk of the S-adenosylmethionine synthetase activity to the post-mitochondrial supernatant. We show that in all cell lines a single kinetic species exists in a dialyzed extract with a K_m for methionine of about 3–12 μM. In selected lines we have demonstrated a requirement for Mg²⁺ in addition to that needed to form the Mg·ATP complex for enzyme activity and have shown that the enzyme can be regulated by product feedback inhibition. Because we detect no differences in the enzymatic ability of these cell extracts to utilize methionine for S-adenosylmethionine formation in vitro, we suggest that the failure of oncogenically-transformed cell lines to grow in homocysteine medium may result from the decreased methionine pools in these cells or from the loss of ability of these cells to properly metabolize homocysteine, adenosine, or their cellular product S-adenosylhomocysteine.     

Expression and amplification of glutamine synthetase gene endows HepG2 cells with ammonia-metabolizing activity for bioartificial liver support system

To establish the ammonia-metabolizing cell lines for a bioartificial liver support system, CHO-K1 and HepG2 were transformed with pBK-CMV-GS vector that contains glutamine synthetase (gs) gene. The recombinant cell lines were selected under the various concentrations of glutamine synthetase inhibitor, methionine sulfoximine (MSX). The host CHO-K1 and HepG2 cell lines produces ammonia, but the both MSX tolerable CHO (GS-CHO) and HepG2 (GS-HepG2) cell lines endowed with the high GS activity could metabolize the ammonium from medium. The ammonia-metabolizing activity of CHO and HepG2 cell was about one-fourth of that of primary hepatocyte.     

Methionine metabolism defect in cells transfected with an activated HRAS1 oncogene

Methionine dependence is a metabolic defect characterized by the inability of eukaryotic cells in culture to proliferate in a medium where methionine has been replaced by its immediate metabolic precursor, homocysteine. This defect has been reported to be a specific property of diverse tumour-derived and transformed cell lines; normal cell strains grow well under the above culture conditions. The basis of methionine requirement in such cells is not known. We asked whether this defect might be controlled by activated oncogenes and in particular by the mutated (activated) HRAS1 oncogene derived from the EJ/T24 human carcinoma line. We report that this oncogene induces methionine requirement after transfection in non-transformed immortalized rat cells.     

Constitutive behavior of methionyl-tRNA synthetase compared to repressible behavior of methionine adenosyltransferase in mammalian cells

Methionine adenosyltransferase, one of the two major enzymes utilizing methionine, is regulated by the levels of methionine in the growth medium (Jacobsen, S.J., Hoffman, R.M. and Erbe, R.W. (1980) J. Natl. Cancer Inst. 65, 1237–1244, and Caboche, M. and Mulsant, P. (1978) Somatic Cell Genet. 4, 407–421). We report here that methionyl-tRNA synthetase, unlike methionine adenosyltransferase, behaves in a constitutive manner with respect to the concentration of methionine in the culture medium. This behavior is seen in Chinese hamster ovary cells and in normal diploid and SV 40-transformed human fibroblasts. Although the kinetics of regulation of methionine adenosyltransferase and methionyl-tRNA synthetase by exogenous methionine are clearly different, the levels of the two enzymes in the human cell lines are similar.     

Agarose-selected variants of two human tumor cell lines exhibit altered methionine auxotrophy

Our aim was to determine if the selection of human tumor cells with enhanced anchorage-independent growth capacity was associated with alterations in methionine auxotrophy. Cells with an increased ability to form colonies on soft agarose were selected from human melanoma (MeWo) and neuroepithelioma (SK-N-MC) cell lines. In contrast to their respective parental lines, a high proportion of the agarose-selected variants were completely unable to proliferate in methionine-free medium containing its immediate precursor homocysteine. The variants exhibited no significant change in their total DNA 5-methylcytosine content and showed no stimulation of either RNA or DNA synthesis upon the addition of homocysteine when the cells were cultured in methionine-free medium. These variants were unable to synthesize [3H]S-adenosylmethionine from [3H]adenine and homocysteine. The failure to detect the accumulation of [3H]S-adenosylmethionine in these variant lines was not likely due to the enhanced turnover of S-adenosylmethionine but rather to a reduced ability to synthesize methionine from homocysteine and 5-methyltetrahydrofolic acid. These results support our hypothesis that alterations in the metabolism of methionine and/or intracellular transmethylating activities may contribute to, or be associated with, the autonomous growth of malignant human tumor cells.     

Participation of cob(I) alamin in the reaction catalyzed by methionine synthase from Escherichia coli: a steady-state and rapid reaction kinetic analysis

The kinetic mechanism of the reaction catalyzed by cobalamin-dependent methionine synthase from Escherichia coli K12 has been investigated by both steady-state and pre-steady-state kinetic analyses. The reaction catalyzed by methionine synthase involves the transfer of a methyl group from methyltetrahydrofolate to homocysteine to generate tetrahydrofolate and methionine. The postulated reaction mechanism invokes an initial transfer of the methyl group to the enzyme to generate enzyme-bound methylcobalamin and tetrahydrofolate. Enzyme-bound methylcobalamin then donates its methyl group to homocysteine to generate methionine and cob(I)alamin. The key questions that were addressed in this study were the following: (1) Does the reaction involve a sequential or ping-pong mechanism? (2) Is enzyme-bound cob(I)alamin a kinetically competent intermediate? (3) If the reaction does involve a sequential mechanism, what is the nature of the "free" enzyme to which the substrates bind; i.e., is the prosthetic group in the cob(I)alamin or methylcobalamin state? Both the steady-state and rapid reaction studies were conducted at 25 degrees C under anaerobic conditions. Initial velocity analysis under steady-state conditions revealed a family of parallel lines suggesting either a ping-pong mechanism or an ordered sequential mechanism. Steady-state product inhibition studies provided evidence for an ordered sequential mechanism in which the first substrate to bind is methyltetrahydrofolate and the last product to be released is tetrahydrofolate. Pre-steady-state kinetic studies were then conducted to determine the rate constants for the various reactions. Enzyme-bound cob(I)alamin was shown to react very rapidly with methyltetrahydrofolate (with an observed rate constant of 250 s-1 versus a turnover number under maximal velocity conditions of 19 s-1).(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Form of Vitamin B(12) and Its Role in a Methanol-Utilizing Bacterium Protaminobacter ruber

A methanol-utilizing bacterium, Protaminobacter ruber, produced a large amount of vitamin B(12). The compounds were isolated from the cells and identified as methylcobalamin (methyl-B(12)) and adenosylcobalamin (adenosyl-B(12)) by various tests. The variation in the form of B(12) during cultivation was examined by bioautography with cellulose acetate membrane electrophoresis. Methyl-B(12) and adenosyl-B(12) were the two main B(12) compounds produced in the various phases of bacterial growth. The ratio of the amount of methyl-B(12) to total B(12) compounds was higher during the earlier phases of growth. After the logarithmic phase, adenosyl-B(12) was the predominant form. The existence of N-methyltetrahydrofolate:homocysteine transmethylase and methyl-B(12):homocysteine transmethylase was demonstrated in cell-free extracts of Protaminobacter ruber. Methyl-B(12) in P. ruber seems to function mainly in the B(12)-dependent methionine synthetase system.     

Effect of cobalamin derivatives on in vitro enzymatic DNA methylation: methylcobalamin can act as a methyl donor

5-Methylcytosine synthesis in DNA involves the transfer of methyl groups from S-adenosyl-methionine to the 5'-position of cytosine through the action of DNA (cytosine-5)-methyltransferase. The rate of this reaction has been found to be enhanced by cobalt ions. We therefore analyzed the influence of vitamin B12 and related compounds containing cobalt on DNA methylation. Vitamin B12, methylcobalamin, and coenzyme B12 were found to enhance significantly the de novo DNA methylation in the presence of S-adenosylmethionine for concentrations up to 1 microM, but at higher concentrations these compounds were found to inhibit DNA methylation. Methylcobalamin behaves as a competitive inhibitor of the enzymatic methylation reaction (Ki = 15 microM), the Km for S-adenosylmethionine being 8 microM. In addition, the use of radioactive methylcobalamin shows that it can be used as a methyl donor in the de novo and maintenance DNA methylation reactions. Thus, two DNA methylation pathways could exist: one involving methylation from S-adenosylmethionine and a second one involving methylation from methylcobalamin.     

Photosynthesis of Euglena gracilis under Cobalamin-Sufficient and -Limited Growing Conditions

Cobalamin is essential for growth of Euglena gracilis and photosynthesis. Methylcobalamin in Euglena chloroplasts (Y Isegawa, Y Nakano, S Kitaoka, 1984 Plant Physiol 76: 814-818) functions as a coenzyme of methionine synthetase. The requirement of cobalamin for photosynthesis appeared remarkably high in Euglena grown under the dark-precultured condition. The required amount of cobalamin for normal photosynthetic activity was 7.4 × 10⁻¹¹ molar, while 7.4 × 10⁻¹⁰ molar cobalamin was required for normal growth. The lowered photosynthetic activity in cobalamin-limited cells was restored 20 hours after feeding cyanocobalamin or methionine to cobalamin-limited cells. Lowering of photosynthetic activity was due to loss of photosystem I activity. This photosynthetic activity was recovered after supplementation by methionine or cobalamin. The results suggest that methionine serves for the stabilization of photosystem I. This paper is the first report of the physiological function of cobalamin in chloroplasts of photosynthetic eukaryotes.     

Altered methionine metabolism occurs in all members of a set of diverse human tumor cell lines

Methionine dependence is a metabolic defect found thus far only in transformed and malignant cells. The defect is manifested as the inability of cells to grow in media in which methionine (Met) is replaced by its immediate precursor homocysteine (Hcy). We have termed this Met ^? Hcy ⁺ media. We demonstrate here that methionine-dependent cells derived from human tumors, compared to normal methionine-independent cells, have low levels of free Met, low levels of S-adenosylmethionine (AdoMet) and elevated levels of S-adenosylhomocysteine (AdoHcy) when incubated in Met ^? Hcy ⁺ medium. Methionine-independent human tumor cells also have very low levels of free Met compared to normal cells but generally have levels of AdoMet and AdoHcy comparable to normal cells in Met ^? Hcy⁺ medium. All tumor cell types incorporate amounts of Met into protein similar to normal methionine-pindependent human fibroblasts when incubated in Met ^? Hcy⁺ medium, thereby indicating apparently normal levels of Met synthesis in the tumor cells. The methionine-independent tumor cell lines in Met ^? Hcy⁺ medium seem able to regulate their AdoMet/AdoHcy ratios normally despite this defect in having very low levels of free Met. Thus, in a diverse set of human tumor cell lines, all are defective in at least one aspect of Met metabolism, giving rise to the possibility of a general metabolic defect in cancer.     

Changes in cobalamin metabolism are associated with the altered methionine auxotrophy of highly growth autonomous human melanoma cells.

Our aim was to identify the biochemical defect responsible for the inability of highly growth autonomous human tumor cells to proliferate in culture medium devoid of methionine, but containing homocysteine and 5-methyletrahydrofolic acid. We have adopted the terms "homocysteine-responsive" and "homocysteine-nonresponsive" to describe cells which can or cannot proliferate in methionine-free homocysteine-supplemented medium. Using a panel of genetically related homocysteine-responsive and -nonresponsive human melanoma cell lines, the results from a number of experiments indicate that acquisition of the "homocysteine-nonresponsive phenotype" is associated with the reduced intracellular accumulation of methyl-cobalamin, a critical cofactor of the methionine synthase enzyme. When in vitro methionine synthase assays were performed in the presence of exogenously added methyl-cobalamin, specific methionine synthase activity in extracts obtained from homocysteine-responsive cells was only twofold greater than that observed with extracts prepared from homocysteine-nonresponsive cells. However, when exogenous methyl-cobalamin was omitted from the enzyme assays, methionine synthase activity in extracts derived from homocysteine-nonresponsive cells was dramatically reduced, compared with the small decrease observed with homocysteine-responsive cell extracts. Compared with their homocysteine-responsive counterparts, homocysteine-nonresponsive cells exhibited increased levels of cobalamin efflux and decreased intracellular accumulation of methyl-cobalamin. There was a clear relationship between the abilities of these related melanoma cell lines to proliferate in methionine-free homocysteine-supplemented medium, and the extent of cobalamin loss and capacity of exogenously added methyl-cobalamin to stimulate in vitro methionine synthase activity. These results indicate a link between alterations in the intracellular trafficking and/or metabolism of cobalamin and the increased growth autonomy of human melanoma cells.     

Methionine dependence in cancer cells — A review

Summary Methionine dependence is a defect found in many cancer cell lines that inhibits their growth in culture when methionine is replaced by its immediate precursor, homocysteine, in the culture medium. Normal cultured cells do not have this defect. This report lists the diverse and large number of animal and human cancer lines that are methionine-dependent, and critically reviews the cell biology and methionine biochemistry of the phenomenon. This work was supported by Grant CA27564 from the National Institutes of Health; The Council for Tobacco Research-USA, Inc.; The United Cancer Council, Inc.; The Cancer Research Coordinating Committee of the University of California; Grants from the Academic Senate, University of California, San Diego; and a Special Fellowship to R. M. H. from the Leukemia Society of America. An erratum to this article is available at .     

Proofreading in vivo: editing of homocysteine by methionyl-tRNA synthetase in the yeast Saccharomyces cerevisiae.

Homocysteine thiolactone is a product of an error-editing reaction, catalyzed by Escherichia coli methionyl-tRNA synthetase, which prevents incorporation of homocysteine into tRNA and protein, both in vitro and in vivo. Here, the thiolactone is also shown to occur in cultures of the yeast Saccharomyces cerevisiae. In yeast, the thiolactone is made from homocysteine in a reaction catalyzed by methionyl-tRNA synthetase. One molecule of homocysteine is edited as thiolactone per 500 molecules of methionine incorporated into protein. Homocysteine, added exogenously to the medium or overproduced by some yeast mutants, is detrimental to cell growth. The cost of homocysteine editing in yeast is minimized by the presence of a pathway leading from homocysteine to cysteine, which keeps intracellular homocysteine at low levels. These results not only directly demonstrate that editing of errors in amino acid selection by methionyl-tRNA synthetase operates in vivo in yeast but also establish the importance of proofreading mechanisms in a eukaryotic organism.     

Heterogeneity in cblG: differential retention of cobalamin on methionine synthase.

Cultured fibroblasts from patients with functional methionine synthase deficiency have been shown to belong to two complementation classes, cblE and cblG. Both are associated with decreased intracellular levels of methylcobalamin (MeCbl) and decreased incorporation of label from 5-methyltetrahydrofolate into macromolecules. Methionine synthase specific activity is normal or near normal in cell extracts from cblE patients under standard reducing conditions, whereas specific activity is low in cblG extracts. Seven of 10 cblG cell lines accumulated [57Co]CN-Cbl equivalent to control cells and showed similar proportions of label associated with the two intracellular cobalamin binders, methionine synthase and methylmalonyl-CoA mutase. The remaining three cblG lines showed reduced accumulation of labeled Cbl and virtually none associated with methionine synthase. The specific activity of methionine synthase was decreased in cell extracts from both cblG subgroups, being almost undetectable in extracts from the latter three lines. Incorporation of label from [14C]MeTHF into either macromolecules or into methionine was decreased in both cblG groups, but was paradoxically higher in the three lines with very low in vitro methionine synthase activity. These results demonstrate further heterogeneity within cblG and suggest that the defect in the three variant lines affects the ability of methionine synthase to retain Cbl.