The S-Methylmethionine Cycle in Lemna paucicostata

The metabolism of S-methylmethionine has been studied in cultures of plants of Lemna paucicostata and of cells of carrot (Daucus carota) and soybean (Glycine max). In each system, radiolabeled S-methylmethionine was rapidly formed from labeled l-methionine, consistent with the action of S-adenosyl-l-methionine:methionine S-methyltransferase, an enzyme which was demonstrated during these studies in Lemna homogenates. In Lemna plants and carrot cells radiolabel disappeared rapidly from S-methylmethionine during chase incubations in nonradioactive media. The results of pulse-chase experiments with Lemna strongly suggest that administered radiolabeled S-methylmethionine is metabolized initially to soluble methionine, then to the variety of compounds formed from soluble methionine. An enzyme catalyzing the transfer of a methyl group from S-methylmethionine to homocysteine to form methionine was demonstrated in homogenates of Lemna. The net result of these reactions, together with the hydrolysis of S-adenosylhomocysteine to homocysteine and adenosine, is to convert S-adenosylmethionine to methionine and adenosine. A physiological advantage is postulated for this sequence in that it provides the plant with a means of sustaining the pool of soluble methionine even when overshoot occurs in the conversion of soluble methionine to S-adenosylmethionine. The facts that the pool of soluble methionine is normally very small relative to the flux into S-adenosylmethionine and that the demand for the latter compound may change very markedly under different growth conditions make it plausible that such overshoot may occur unless the rate of synthesis of S-adenosylmethionine is regulated with exquisite precision. The metabolic cost of this apparent safeguard is the consumption of ATP. This S-methylmethionine cycle may well function in plants other than Lemna, but further substantiating evidence is neeeded.     

Over-expression of cystathionine γ-synthase in Arabidopsis thaliana leads to increased levels of methionine and S-methylmethionine

Cystathionine γ-synthase (CGS, EC 4.2.99.9), the first committed enzyme in methionine biosynthesis, was over-expressed in Arabidopsis thaliana by introducing in the genome of this plant the coding sequence of the Arabidopsis enzyme under the control of the cauliflower mosaic virus 35S promoter. In order to target the recombinant protein to the chloroplast, the transgene included the sequence encoding the N-terminal transit peptide of Arabidopsis CGS. CGS activity and polypeptide were increased several fold in these plants. There was a markedly increased level of soluble methionine in the leaves of the transformed plants, up to 15-fold, indicating that CGS is a rate-limiting enzyme in this metabolic pathway. In addition, the transformed plants strongly over-accumulated S-methylmethionine, but not S-adenosylmethionine, in agreement with the view that S-methylmethionine corresponds to a storage form of labile methyl groups in plants and/or plays a role in preventing S-adenosylmethionine accumulation. The same strategy was used to increase the level of cystathionine β-lyase (CBL, EC 4.4.1.8), the second committed enzyme in methionine biosynthesis, in transformed A. thaliana. Despite an increase in both CBL activity and polypeptide in transformed Arabidopsis plants over-expressing Arabidopsis CBL, there was very little change in the contents of soluble methionine and S-methylmethionine, suggesting strongly that CBL is not rate limiting in the methionine biosynthetic pathway.     

Induction and Repression in the S-Adenosylmethionine and Methionine Biosynthetic Systems of Saccharomyces cerevisiae

Two methionine biosynthetic enzymes and the methionine adenosyltransferase are repressed in Saccharomyces cerevisiae when grown under conditions where the intracellular levels of S-adenosylmethionine are high. The nature of the co-repressor molecule of this repression was investigated by following the intracellular levels of methionine, S-adenosylmethionine, and S-adenosylhomocysteine, as well as enzyme activities, after growth under various conditions. Under all of the conditions found to repress these enzymes, there is an accompanying induction of the S-adenosylmethionine-homocysteine methyltransferase which suggests that this enzyme may play a key role in the regulation of S-adenosylmethionine and methionine balance and synthesis. S-methylmethionine also induces the methyltransferase, but unlike S-adenosylmethionine, it does not repress the methionine adenosyltransferase or other methionine biosynthetic enzymes tested.     

Assay for S-adenosylmethionine: methionine methyltransferase

A quantitative assay for S-adenosylmethionine: methionine methyltransferase in phosphate buffer extracts has been developed. This enzyme catalyzes the biosynthesis of S-methylmethionine from methionine and S-adenosylmethionine. The radioactively labeled product, S-methylmethionine, is first separated from the radioactively labeled substrate, l-methionine, by means of ion-exchange chromatography. Once separated thusly, the amount present can then be directly determined by the use of a liquid scintillation spectrometer.     

Biosynthesis of adenosyl-d-methionine and adenosyl-2-methylmethionine by Candida utilis

Supplementation of the culture medium of Candida utilis with d-methionine or 2-methyl-dl-methionine leads to intracellular synthesis of S-adenosyl-d-methionine and S-adenosyl-2-methylmethionine. The identity of the sulfonium compounds was established by tracer technique, chromatography, acid hydrolysis, and examination of the released methionine and 2-methylmethionine. In addition to the expected sulfur amino acid component, both adenosine sulfonium fractions contained S-adenosyl-l-methionine. This is explained by transmethylation of S-adenosyl-d-methionine and of S-adenosyl-2-methyl-methionine with endogenous l-homocysteine; the resulting l-methionine reacts with ATP to form S-adenosyl-l-methionine. Experiments with purified cell-free preparations of S-adenosylmethionine synthetase (EC 2.5.1.6) from C. utilis confirmed the reaction of ATP with d-methionine or 2-methyl-dl-methionine.     

Methionine metabolism and ethylene biosynthesis in senescing petals of Tradescantia

The endogenous content of methionine in isolated petals of Tradescantia was found to increase during petal senescence while the levels of S-methylmethionine and protein were found to decline. The increase in free methionine was, at least in part, the result of protein degradation. Methionine and homocysteine were shown to be intermediates in ethylene biosynthesis while S-methylmethionine was not involved. Application of 1-aminocyclopropane-1-carboxylic acid (ACC) to all floral tissues resulted in large stimulations of ethylene production. ACC was shown to be an endogenous amino acid the internal levels of which correlated positively with the rate of ethylene production. Application of l-methionine-[U-¹⁴C] led to a rapid appearance of radioactivity in both ethylene and ACC. The specific radioactivity of C-2 and C-3 of ACC and that of ethylene were found to be nearly identical which indicated that ACC was the immediate precursor of ethylene in senescing petals of Tradescantia.     

Methionine Biosynthesis is Essential for Infection in the Rice Blast Fungus Magnaporthe oryzae

Methionine is a sulfur amino acid standing at the crossroads of several biosynthetic pathways. In fungi, the last step of methionine biosynthesis is catalyzed by a cobalamine-independent methionine synthase (Met6, EC 2.1.1.14). In the present work, we studied the role of Met6 in the infection process of the rice blast fungus, Magnaporthe oryzae. To this end MET6 null mutants were obtained by targeted gene replacement. On minimum medium, MET6 null mutants were auxotrophic for methionine. Even when grown in presence of excess methionine, these mutants displayed developmental defects, such as reduced mycelium pigmentation, aerial hypha formation and sporulation. They also displayed characteristic metabolic signatures such as increased levels of cysteine, cystathionine, homocysteine, S-adenosylmethionine, S-adenosylhomocysteine while methionine and glutathione levels remained unchanged. These metabolic perturbations were associated with the over-expression of MgCBS1 involved in the reversed transsulfuration pathway that metabolizes homocysteine into cysteine and MgSAM1 and MgSAHH1 involved in the methyl cycle. This suggests a physiological adaptation of M. oryzae to metabolic defects induced by the loss of Met6, in particular an increase in homocysteine levels. Pathogenicity assays showed that MET6 null mutants were non-pathogenic on both barley and rice leaves. These mutants were defective in appressorium-mediated penetration and invasive infectious growth. These pathogenicity defects were rescued by addition of exogenous methionine and S-methylmethionine. These results show that M. oryzae cannot assimilate sufficient methionine from plant tissues and must synthesize this amino acid de novo to fulfill its sulfur amino acid requirement during infection.     

Methionine biosynthesis in isolated Pisum sativum mitochondria

Homocysteine-dependent transmethylases utilizing 5-methyltetrahydropteroylglutamic acid and S-adenosylmethionine as methyl donors have been examined using ammonium sulphate fractions prepared from isolated mitochondria of pea cotyledons. Substantial levels of a 5-rnethyltetrahydropteroylglutamate transmethylase were detected, the catalytic properties of this enzyme being found similar to those of a previously reported enzyme present in cotyledon extracts. The mitochondrial 5-CH₃-H₄PteGlu transmethylase had an apparent K_m of 25 μM for the methyl donor, was saturated with homocysteine at 1 mM and was inhibited 50% by l-methionine at 2.5 mM. At similar concentrations of methyl donor the mitochondrial S-adenosylmethionine methyltransferase was not saturated. Mitochondrial preparations were found capable of synthesizing substantial amounts of S-adenosylmethionine but lacked ability to form S-methylmethionine. Significant levels of β-cystathionase, cystathionine-γ-synthase, l-homoserine transacetylase and l-homoserine transsuccinylase were detected in the isolated mitochondria. The activity of the enzymes of homocysteine biosynthesis was not affected by l-methionine in vitro. It is concluded that pea mitochondria have ability to catalyze the synthesis of methionine de novo.     

Changes in the levels of major sulfur metabolites and free amino acids in pea cotyledons recovering from sulfur deficiency

Changes in levels of sulfur metabolites and free amino acids were followed in cotyledons of sulfur-deficient, developing pea seeds (Pisum sativum L.) for 24 hours after resupply of sulfate, during which time the legumin mRNA levels returned almost to normal. Two recovery situations were studied: cultured seeds, with sulfate added to the medium, and seeds attached to the intact plant, with sulfate added to the roots. In both situations the levels of cysteine, glutathione, and methionine rose rapidly, glutathione exhibiting an initial lag. In attached but not cultured seeds methionine markedly overshot the level normally found in sulfur-sufficient seeds. In the cultured seed S-adenosylmethionine (AdoMet), but not S-methylmethionine, showed a sustained rise; in the attached seed the changes were slight. The composition of the free amino acid pool did not change substantially in either recovery situation. In the cultured seed the large rise in AdoMet level occurred equally in nonrecovering seeds. It was accompanied by 6-fold and 10-fold increases in γ-aminobutyrate and alanine, respectively. These effects are attributed to wounding resulting from excision of the seed. ³⁵S-labeling experiments showed that there was no significant accumulation of label in unidentified sulfur-containing amino compounds in either recovery situation. It was concluded from these results and those of other workers that, at the present level of knowledge, the most probable candidate for a `signal' compound, eliciting recovery of legumin mRNA level in response to sulfur-feeding, is cysteine.     

Synthesis of methylated ethanolamine moieties: regulation by choline in soybean and carrot

The results of experiments in which intact plants of Lemna paucicostata were labeled with either l-[³H₃C]methionine, l-[¹⁴CH₃]methionine, or [1,2-¹⁴C]ethanolamine support the conclusion that growth in concentrations of choline of 3.0 micromolar or above brings about marked decreases in the rate of biosynthesis of methylated forms of ethanolamine (normally present chiefly as phosphatidylcholine, with lesser amounts of choline and phosphocholine). The in vivo locus of the block is at the committing step in the biosynthetic sequence at which phosphoethanolamine is methylated by S-adenosylmethionine to form phosphomethylethanolamine. The block is highly specific: flow of methyl groups originating in methionine continues into S-adenosylmethionine, S-methylmethionine, the methyl moieties of pectin methyl ester, and other methylated metabolites. When choline uptake is less than the total that would be synthesized by control plants, phosphoethanolamine methylation is down-regulated to balance the uptake; total plant content of choline and its derivatives remains essentially constant. At maximum down-regulation, phosphoethanolamine methylation continues at 5 to 10% of normal. A specific decrease in the total available activity of AdoMet: phosphoethanolamine N-methyltransferase, as well as feedback inhibition of this enzyme by phosphocholine, and prevention of accumulation of phosphoethanolamine by down-regulation of ethanolamine synthesis may each contribute to effective control of phosphoethanolamine methylation. This down-regulation may necessitate major changes in S-adenosylmethionine metabolism. Such changes are discussed.     

Stereospecific oxidation of calmodulin by methionine sulfoxide reductase A

Methionine sulfoxide reductase A has long been known to reduce S-methionine sulfoxide, both as a free amino acid and within proteins. Recently the enzyme was shown to be bidirectional, capable of oxidizing free methionine and methionine in proteins to S-methionine sulfoxide. A feasible mechanism for controlling the directionality has been proposed, raising the possibility that reversible oxidation and reduction of methionine residues within proteins is a redox-based mechanism for cellular regulation. We undertook studies aimed at identifying proteins that are subject to site-specific, stereospecific oxidation and reduction of methionine residues. We found that calmodulin, which has nine methionine residues, is such a substrate for methionine sulfoxide reductase A. When calmodulin is in its calcium-bound form, Met77 is oxidized to S-methionine sulfoxide by methionine sulfoxide reductase A. When methionine sulfoxide reductase A operates in the reducing direction, the oxidized calmodulin is fully reduced back to its native form. We conclude that reversible covalent modification of Met77 may regulate the interaction of calmodulin with one or more of its many targets.     

The activity of adenosyl-d-methionine and adenosyl-2-methylmethionine in transmethylations

The d-methionine- and 2-methyl-dl-methionine analogs of the enzymatic methyl donor, (?)S-adenosyl-l-methionine, were synthesized by methylation of S-adenosyl-d-homocysteine and S-adenosyl-2-methyl-dl-homocysteine with methyl iodide. By chromatographic purification, S-adenosyl-d-methionine and S-adenosyl-2-methyl-dl-methionine were obtained. The structure of the latter was ascertained by hydrolysis to 2-methylmethionine in strong acid, and to 5′-methylthioadenosine and 2-methylhomoserine at pH 4. Reference material of the latter compound was obtained by alkaline hydrolysis of 2-methylmethionine methylsulfonium iodide. The sulfonium compounds were tested as methyl donors with N-acetylserotonin O-methyltransferase, l-homocysteine S-methyltransferase, histamine N-methyltransferase, and guanidinoacetate N-methyltransferase. In most instances, methyl donor activity was observed.     

Methyladeninylcobamide functions as the cofactor of methionine synthase in a Cyanobacterium, Spirulina platensis NIES-39

To clarify the physiological function of pseudovitamin B₁₂ (or adeninylcobamide; AdeCba) in Spirulina platensis NIES-39, cobalamin-dependent methionine synthase (MS) was characterized. We cloned the full-length Spirulina MS. The clone contained an open reading frame encoding a protein of 1183 amino acids with a molecular mass of 132 kDa. Deduced amino acid sequences of the Spirulina MS contained critical residues identical to cobalamin-, zinc-, S-adenosylmethionine-, and homocysteine-binding motifs. The recombinant Spirulina enzyme showed higher affinity for methyladeninylcobamide than methylcobalamin as a cofactor. These results indicate that Spirulina cells can utilize AdeCba synthesized as the cofactor for MS.     

Amino acids and low-molecular-weight carbohydrates of some marine red algae

Amino acids and low-MW carbohydrates of 18 red algae have been analyzed. Several non-protein amino acids have been identified, including pyrrolidine-2,5-dicarboxylic acid (3c) and N-methylmethionine sulfoxide (5), new natural products, and 13 known compounds, citrulline, β-alanine, γ-aminobutyric acid, baikiain (1), pipecolic acid (2), domoic acid (3a), kainic acid (3b), azetidine-2-carboxylic acid (4), methionine sulfoxide taurine, N-methyltaurine, N,N-dimethyltaurine and N,N,N-trimethyltaurine. Sugars present were mainly floridoside, isofloridoside and mannoglyceric acid. Details of the structural elucidation of new compounds are also given.     

The expression level of threonine synthase and cystathionine-γ-synthase is influenced by the level of both threonine and methionine in <Emphasis Type="Italic">Arabidopsis</Emphasis> plants

The biosynthesis pathways of the essential amino acids methionine and threonine diverge from O-phosphohomoserine, an intermediate metabolite in the aspartate family of amino acids. Thus, the enzymes cystathionine-γ-synthase (CGS) in the methionine pathway and threonine synthase (TS), the last enzyme in the threonine pathway, compete for this common substrate. To study this branching point, we overexpressed TS in sense and antisense orientation in Arabidopsis plants with the aim to study its effect on the level of threonine but more importantly on the methionine content. Positive correlation was found not only between TS expression level and threonine content, but also between TS/threonine and CGS expression level. Plants expressing the sense orientation of TS showed a higher level of threonine, increased expression level of CGS, and a significantly higher level of S-methylmethionine, the transport form of methionine. By contrast, plants expressing the antisense form of TS showed lower levels of threonine and of CGS expression level. In these antisense plants, the methionine level increased up to 47-fold compared to wild-type plants. To study further the effect of threonine on CGS expression level, wild-type plants were irrigated with threonine and control plants were irrigated with methionine or water. While threonine increased the expression level of CGS but reduced that of TS, methionine reduced the expression level of CGS but increased that of TS. This data demonstrate that both methionine and threonine affect the two enzymes at the branching point, thus controlling not only their own level, but also the level of each other. This mechanism probably aids in keeping the levels of these two essential amino acids sufficiently high to support plant growth.     

Methionine and vitamin B 12 repression and precursor induction in the regulation of homocysteine methylation in Salmonella typhimurium

Summary 5-methyltetrahydrofolate, the product of a reaction catalysed by 5-methyltetrahydrofolate: FAD oxidoreductase (metF), is the methyl donor in the transmethylation of homocysteine in Salmonella typhimurium either via a vitamin B₁₂ dependent (metH) or independent (metE) pathway. Both the metF and H enzymes were shown to be repressible by methionine.B₁₂ was found to repress synthesis of the metF enzyme in some metH mutants but not in others although all lacked B₁₂-dependent 5-methyltetrahydrofolate homocysteine transmethylase. This suggested a dual enzymatic and regulatory role for the metH gene but no complementation was detected between any metH mutants.The levels of metF and H enzymes were elevated in mutants blocked at early stages in methionine synthesis. Also the metH enzyme level in a metF mutant was increased by the addition to the medium of known precursors unable to support its growth, suggesting precursor induction of the enzymes. This increase did not occur in the presence of chloramphenicol.The different regulatory systems involved in the methylation of homocysteine could reflect the importance of this step in the inter-relationship of different metabolic pathways.     

The action of cyanogen bromide on horse-heart cytochrome c and horse-heart myoglobin

1. The effects of cyanogen bromide on horse-heart cytochrome c and horse-heart myoglobin have been investigated. Cytochrome c yielded four fragments, of which two were haemopeptides. The two colourless peptides had amino acid compositions corresponding to those that are expected, on the basis of the sequence proposed for horse-heart cytochrome c by Margoliash, Smith, Kreil & Tuppy (1961), from cleavage at both methionine residues. Of the two haemopeptides, one was isolated and shown to be that derived from cleavage at only one methionine residue, that nearer to the C-terminus of the peptide chain. 2. Myoglobin also gave four peptides, three of which accounted for the total amino acid content of the intact protein. The fourth fragment arose by cleavage at a single methionine residue, that nearer the C-terminus. Characterization of this fourth fragment made it possible to deduce the order of arrangement of the fragments in the intact molecule.