Location of penicilloyl groups on CNBr fragments of the albumin from penicillin-treated patients

Two fixation sites for penicilloyl groups on human albumin were demonstrated. Using CNBr cleavage the first site was located between methionine 123 and methionine 297 and the second one between methionine 297 and the C-terminal residue. In both cases, penicilloyl groups were unmasked by pronase degradation or disulfide bond reduction.     

Quorum sensing in Vibrio fischeri: evidence that S-adenosylmethionine is the amino acid substrate for autoinducer synthesis.

Synthesis of the autoinducer signal involved in the cell density-dependent activation of Vibrio fischeri luminescence is directed by luxI. The autoinducer is N-(3-oxohexanoyl)homoserine lactone, and little is known about its synthesis. We have measured autoinducer synthesis by amino acid auxotrophs of Escherichia coli that contained luxI on a high-copy-number plasmid. Experiments with cell suspensions starved for methionine or homoserine show that either methionine or S-adenosylmethionine but not homoserine or homoserine lactone is required for autoinducer synthesis. The S-adenosylmethionine synthesis inhibitor cycloleucine blocks methionine-dependent autoinducer synthesis. Thus, it appears that S-adenosylmethionine rather than methionine is the molecule required for autoinducer synthesis. The amount of 15N-labeled methionine incorporated into the autoinducer by growing cultures of a homoserine and a methionine auxotroph was measured by mass spectrometry. The labeling studies show that even in the presence of homoserine, almost all of the autoinducer produced contains the 15N label from methionine. Thus, it appears that S-adenosylmethionine serves as the amino acid substrate in the luxI-dependent synthesis of the V. fischeri autoinducer.     

Regulation of aspartate-derived amino acid biosynthesis in the yeastSaccharomyces cerevisiae

The activity of three enzymes, aspartokinase, homoserine dehydrogenase, and homoserine kinase, has been studied in the industrial strainSaccharomyces cerevisiae IFI256 and in the mutants derived from it that are able to overproduce methionine and/or threonine. Most of the mutants showed alteration of the kinetic properties of the enzymes aspartokinase, which was less inhibited by threonine and increased its affinity for aspartate, and homoserine dehydrogenase and homoserine kinase, which both lost affinity for homoserine. Furthermore, they showed in vitro specific activities for aspartokinase and homoserine kinase that were higher than those of the wild type, resulting in accumulation of aspartate, homoserine, threonine, and/or methionine/S-adenosyl-methionine (Ado-Met). Together with an increase in the specific activity of both aspartokinase and homoserine kinase, there was a considerable and parallel increase in methionine and threonine concentration in the mutants. Those which produced the maximal concentration of these amino acids underwent minimal aspartokinase inhibition by threonine. This supports previous data that identify aspartokinase as the main agent in the regulation of the biosynthetic pathway of these amino acids. The homoserine kinase in the mutants showed inhibition by methionine together with a lack or a reduction of the inhibition by threonine that the wild type undergoes, which finding suggests an important role for this enzyme in methionine and threonine regulation. Finally, homoserine dehydrogenase displayed very similar specific activity in the mutants and the wild type in spite of the changes observed in amino acid concentrations; this points to a minor role for this enzyme in amino acid regulation.     

Failure of selenomethionine residues in albumin and immunoglobulin G to protect against peroxynitrite.

Selenomethionine has been suggested to protect against peroxynitrite by quenching it in vivo. Selenomethionine is distributed randomly in the methionine pool. Albumin and IgG were purified from plasma of a human being before and after 28 days of supplementation with 400 microg selenium/day as selenomethionine. The albumin contained 1 selenium atom, presumably as selenomethionine, per 8000 methionine residues before supplementation and 1 per 2800 after supplementation. Although this ratio suggested that selenomethionine would not have as great an effect in quenching peroxynitrite as would methionine, direct testing of the albumin and IgG fractions was carried out to assess the ability of these proteins to prevent peroxynitrite oxidation of dihydrorhodamine 123 to rhodamine 123. The ability of the albumin preparations to resist nitration of tyrosine residues was also assessed. The high-selenomethionine preparations of the proteins had no greater effect in quenching the peroxynitrite than did the normal-selenomethionine preparations. These results do not support the proposal that selenomethionine in proteins contributes to in vivo protection against peroxynitrite.     

Methionine metabolism in apple tissue in relation to ethylene biosynthesis

A comparison of the rate of ethylene production by apple fruit to the methionine content of the tissue suggests that the sulfur of methionine has to be recycled during its continuous synthesis of ethylene. The metabolism of the sulfur of methionine in apple tissue in relation to ethylene biosynthesis was investigated. The results showed that in the conversion of methionine to ethylene the CH₃S-group of methionine is first incorporated as a unit into S-methylcysteine. By demethylation, S-methylcysteine is metabolized to cysteine. Cysteine then donates its sulfur to form methionine, presumably through cystathionine and homocysteine. This view is consistent with the observation that cysteine, homoserine and homocysteine were all converted to methionine, in an order of efficiency from least to greatest. For the conversion to ethylene, methionine was the most efficient precursor, followed by homocysteine and homoserine. Based on these results, a methionine-sulfur cycle in relation to ethylene biosynthesis is presented.     

Threonine production by ethionine-resistant mutants of Serratia marcescens.

Ethionine reduced both the growth rate and the final growth level of Serratia marcescens Sr41. Growth inhibition was completely reversed by methionine. Strain D-315, defective in homoserine dehydrogenase I, was more sensitive to ethionine-mediated growth inhibition than was the wild-type strain. Ethionine-resistant mutants were isolated from cultures of strain D-316, which was derived from strain D-315 as a threonine deaminase-deficient mutant. Of 60 resistant colonies, 7 excreted threonine on minimal agar plates. One threonine-excreting strain, ETr17, was highly resistant to ethionine and, moreover, insensitive to methionine-mediated growth inhibition, whereas the parent strain was sensitive. When cultured in minimal medium with or without excess methionine, strain ETr17 had a higher homoserine dehydrogenase level than did strain D-316. The homoserine dehydrogenase activity was not inhibited by threonine or methionine. Transductional analysis revealed that the ethionine-resistant (etr-1) mutation carried by strain ETr17 was located in the metBM-argE region and caused the derepressed synthesis of homoserine dehydrogenase II. Strain ETr17 had a higher aspartokinase level than did the parent strain. By transductional cross with the argE+ marker, the etr-1 mutation was transferred into strain D-562 which was derived from D-505, a strain defective in aspartokinases I and III. The constructed strain had a higher aspartokinase level than did strain D-505 in medium with or without excess methionine, indicating that the etr-1 mutation led to the derepressed synthesis of aspartokinase II. Strain ETr17 produced about 8 mg of threonine per ml of medium containing sucrose and urea.     

The methionine biosynthetic pathway from homoserine in Pseudomonas putida involves the metW, metX, metZ, metH and metE gene products

Biosynthesis of methionine from homoserine in Pseudomonas putida takes place in three steps. The first step is the acylation of homoserine to yield an acyl-L-homoserine. This reaction is catalyzed by the products of the metXW genes and is equivalent to the first step in enterobacteria, gram-positive bacteria and fungi, except that in these microorganisms the reaction is catalyzed by a single polypeptide (the product of the metA gene in Escherichia coli and the met5 gene product in Neurospora crassa). In Pseudomonas putida, as in gram-positive bacteria and certain fungi, the second and third steps are a direct sulfhydrylation that converts the O-acyl-L-homoserine into homocysteine and further methylation to yield methionine. The latter reaction can be mediated by either of the two methionine synthetases present in the cells.     

Effect of dimethyl sulfoxide on lysine production by a mutant ofBacillus subtilis with low homoserine dehydrogenase activity

SomeBacillus subtilis mutants with different levels of homoserine dehydrogenase were described. Strains that do not accumulate methionine have a high homoserine dehydrogenase activity. Low activity was detected in mutants where cell growth was completely inhibited by 0.7 mmol/L methionine. A low concentration of dimethyl sulfoxide had a stimulatory effect on lysine production by the methionine-sensitive mutant ofBacillus subtilis.     

Aspartate kinase and homoserine dehydrogenase ofCandida utilis

Aspartate kinase and homoserine dehydrogenase activity were assayed in a dialyzed cell-free extract ofCandida utilis. Aspartate kinase was partly inhibited by ATP-Mg and by Mg²⁺ alone. There appear to be two isoenzymes of aspartate kinase in the yeast, one heatlabile, the other relatively heat-stable. The first is subject to feedback inhibition by threonine, the other is threonine-resistant. Neither aspartate kinase nor homoserine dehydrogenase is the rate-limiting enzyme in methionine biosynthesis. Homoserine dehydrogenase measured in the forward direction showed an activity five times higher than aspartate kinase. No regulatory interaction could be demonstrated for this enzyme. No repression of aspartate kinase and homoserine dehydrogenase synthesis by threonine, methionine or both amino acids was observed.     

Methionine-lysine-threonine-isoleucine interrelationships in the amino acid nutrition of rice callus tissue

Growth of rice callus tissue is discouraged when methionineis excluded from CMAA medium. While determining the methionineelimination effect, the amino acid interrelationships amongmethionine, lysine, threonine and isoleucine in the nutritionof the callus tissue were found. Poor growth, found in cultureson methionine deficient media was seen only when the media containedboth threonine and lysine, simultaneously. The substitutionof homoserine for methionine was also observed. Determination of free amino acid composition in tissues revealedthat free methionine was barely detectable in tissues grownwith sufficient amounts of threonine and lysine. When the concentrationof either threonine or lysine was reduced, the free methioninecontent of the tissue increased. When the methionine deficientmedium was supplemented with homoserine, the free methioninein the tissue increased, although the tissue retained a considerableamount of free threonine and lysine. Cultivation of tissue onan isoleucine deficient medium resulted in a significant decreasein free threonine content. These experimental results suggest that the biosynthetic pathwayto methionine is cooperatively inhibited by threonine and lysine,and that threonine decomposition is inhibited by its end productisoleucine. (Received February 19, 1970; )     

Effect of technical threonine sources on homoserine biosynthesis by mutant Brevibacteruim flavum 2T

The effect of threonine technical sources on the homoserine biosynthesis by the threonine auxotroph Brevibacterium flavum 2T when cultivated on sucrose and acetic acid containing media was investigated. Various threonine sources (corn extract and fodder yeast, microbial biomass and soybean meal hydrolyzates) prepared by means of different hydrolyzing agents (acids, enzymes, autolysis) were used. The most effective substrate was protein--vitamin concentrate hydrolyzate, particularly combined with corn extract in the ratio 1: 0,25-0.5 (with respect to the dry weight of the initial material). The homoserine yield was 16.2 g/l on the sucrose containing medium and 18.4 g/l on the acetic acid containing medium which was in agreement with controls. The medium containing pure threonine was used as a control. With other threonine sources (corn extract, protein-vitamin concentrate autolyzate and enzymolyzate, fodder yeast and soybean meal hydrolyzates), the homoserine production was significantly lower, i.e. 40-70% of the control. The content of amino acids (threonine, isoleucine, methionine) in the initial material and their suitability for the homoserine biosynthesis were found to be correlated. The substrates with a high content of threonine (over 3.5%) and a low content of methionine (below 0.5%) proved most effective. The use of the material in which the ratio threonine: methionine was less than 6.0 caused the homoserine biosynthesis to be partially replaced with that of lysine.     

Homoserine kinase and threonine synthase in methionine-overproducing soybean tissue cultures

To gain understanding of the regulation of methionine level in plants, we assayed homoserine kinase and threonine synthase in extracts of wild type and several methionine-overproducing soybean [Glycine max (L.) Merr.] callus lines. The specific activity of homoserine kinase was depressed by 45–73%, and that of threonine synthase by 26–43% in the high methionine lines. Cysteine inhibited threonine synthase in wild type and variant lines. Threonine synthase in two variant lines showed significantly less inhibition by cysteine and in one line was inhibited by threonine. Depressed threonine synthase activity may increase the availability of homoserine phosphate to the competing methionine biosynthetic pathway.Abreviations MOPS morpholinopropane-sulfonate - EDTA ethylenediamine-tetraacetate - DTE dithioerythritol - AdoMet S-adenosylmethionine     

Enzyme-catalyzed acylation of homoserine: mechanistic characterization of the Haemophilus influenzae met2-encoded homoserine transacetylase

The first unique step in bacterial and plant methionine biosynthesis involves the acylation of the gamma-hydroxyl of homoserine. In Haemophilus influenzae, acylation is accomplished via an acetyl-CoA-dependent acetylation catalyzed by homoserine transacetylase. The activity of this enzyme regulates flux of homoserine into multiple biosynthetic pathways and, therefore, represents a critical control point for cell growth and viability. We have cloned homoserine transacetylase from H. influenzae and present the first detailed enzymatic study of this enzyme. Steady-state kinetic experiments demonstrate that the enzyme utilizes a ping-pong kinetic mechanism in which the acetyl group of acetyl-CoA is initially transferred to an enzyme nucleophile before subsequent transfer to homoserine to form the final product, O-acetylhomoserine. The maximal velocity and V/K(homoserine) were independent of pH over the range of values tested, while V/K(acetyl)(-)(CoA) was dependent upon the ionization state of a single group exhibiting a pK value of 8.6, which was required to be protonated. Solvent kinetic isotope effect studies yielded inverse effects of 0.75 on V and 0.74 on V/K(CoA) on the reverse reaction and effects of 1.2 on V and 1.7 on V/K(homoserine) on the forward reaction. Direct evidence for the formation of an acetyl-enzyme intermediate was obtained using rapid-quench labeling studies. On the basis of these observations, we propose a chemical mechanism for this important member of the acyltransferase family and contrast its mechanism with that of homoserine transsuccinylase.     

The decarboxylation of S-adenosylmethionine by detergent-treated extracts of rat liver

1. The production of (14)CO(2) from S-adenosyl[carboxyl-(14)C]methionine by rat liver extracts was investigated. It was found that, in addition to the well-known cytosolic putrescine-activated S-adenosylmethionine decarboxylase, an activity carrying out the production of (14)CO(2) could be extracted from a latent, particulate or membrane-bound form by treatment with buffer containing 1% (v/v) Triton X-100 [confirming the report of Sturman (1976) Biochim. Biophys. Acta428, 56-69]. 2. The formation of (14)CO(2) by such detergent-solubilized extracts differed from that by cytosolic S-adenosylmethionine decarboxylase in a number of ways. The reaction by the solubilized extracts did not require putrescine and was not directly proportional to time of incubation or the amount of protein added. Instead, activity a showed a distinct lag period and was much greater when high concentrations of the extracts were used. The cytosolic S-adenosylmethionine decarboxylase was activated by putrescine, showed strict proportionality to protein added and the reaction proceeded at a constant rate. Cytosolic activity was not inhibited by homoserine or by S-adenosylhomocysteine, whereas the Triton-solubilized activity was strongly inhibited. 3. By using an acetone precipitate of Triton-treated homogenates as a source of the activity, it was found that decarboxylated S-adenosylmethionine was not present among the products of the reaction, although 5'-methylthioadenosine and 5-methylthioribose were found. Such extracts were able to produce (14)CO(2) when incubated with [U-(14)C]-homoserine, and (14)CO(2) production was greater when S-adenosyl[carboxyl-(14)C]methionine that had been degraded by heating at pH6 at 100 degrees C for 30min (a procedure known to produce mainly 5'-methylthioadenosine and homoserine lactone) was used as a substrate than when S-adenosyl[carboxyl-(14)C]methionine was used. 4. These results indicate that the Triton-solubilized activity is not a real S-adenosylmethionine decarboxylase, but that (14)CO(2) is produced via a series of reactions involving degradation of the S-adenosyl-[carboxyl-(14)C]methionine. It is probable that this degradation can occur via several pathways. Our results would suggest that part of the reaction occurs via the production of S-adenosylhomocysteine, which can then be converted into 2-oxobutyrate via the transsulphuration pathway, and that part occurs via the production of homoserine by an enzyme converting S-adenosylmethionine into 5'-methylthioadenosine and homoserine lactone.     

The mechanism of antifungal action of (S)-2-amino-4-oxo-5-hydroxypentanoic acid, RI-331: the inhibition of homoserine dehydrogenase in Saccharomyces cerevisiae

We have explored the mechanism by which an antifungal antibiotic, (S)-2-amino-4-oxo-5-hydroxypentanoic acid, RI-331, preferentially inhibits protein biosynthesis in Saccharomyces cerevisiae, by inhibiting the biosynthesis of the aspartate family of amino acids, methionine, isoleucine and threonine. This inhibition was effected by inhibiting the biosynthesis of their common intermediate precursor homoserine. The target enzyme of RI-331 was homoserine dehydrogenase (EC.1.1.1.3) which is involved in converting aspartate semialdehyde to homoserine in the pathway from aspartate to homoserine. The enzyme is lacking in animals. So the antibiotic is selectively toxic to prototrophic fungi.     

Effects of deregulation of methionine biosynthesis on methionine excretion in Escherichia coli

Several regulators of methionine biosynthesis have been reported in Escherichia coli, which might represent barriers to the production of excess l-methionine (Met). In order to examine the effects of these factors on Met biosynthesis and metabolism, deletion mutations of the methionine repressor (metJ) and threonine biosynthetic (thrBC) genes were introduced into the W3110 wild-type strain of E. coli. Mutations of the metK gene encoding S-adenosylmethionine synthetase, which is involved in Met metabolism, were detected in 12 norleucine-resistant mutants. Three of the mutations in the metK structural gene were then introduced into metJ and thrBC double-mutant strains; one of the resultant strains was found to accumulate 0.13 g/liter Met. Mutations of the metA gene encoding homoserine succinyltransferase were detected in alpha-methylmethionine-resistant mutants, and these mutations were found to encode feedback-resistant enzymes in a 14C-labeled homoserine assay. Three metA mutations were introduced, using expression plasmids, into an E. coli strain that was shown to accumulate 0.24 g/liter Met. Combining mutations that affect the deregulation of Met biosynthesis and metabolism is therefore an effective approach for the production of Met-excreting strains.     

A diagonal electrophoretic method for selective purification of methionine peptides

1. A method is described that selectively purifies methionine peptides from enzymic digests of a protein. The peptides, after paper electrophoresis, are treated on paper with iodoacetamide at acid pH. This specifically converts methionine residues into their sulphonium salts. When the paper is submitted to electrophoresis at right angles to the original direction, the carbamoylmethylmethionine peptides emerge from an undifferentiated diagonal. 2. Heating at neutral pH converts carbamoylmethylmethionine into homoserine and thereby specifically cleaves the peptides. 3. The effect of the modifications on amino acid composition and sequence analyses of the peptides was studied. 4. When the method was applied to a tryptic digest of S-aminoethyl-chymotrypsinogen A, two peptides were selectively purified that had the expected amino acid sequence.     

Regulation of enzymes of lysine biosynthesis in Corynebacterium glutamicum

The regulation of the six enzymes responsible for the conversion of aspartate to lysine, together with homoserine dehydrogenase, was studied in Corynebacterium glutamicum. In addition to aspartate kinase activity, the synthesis of diaminopimelate decarboxylase was also found to be regulated. The specific activity of this enzyme was reduced to one-third in extracts of cells grown in the presence of lysine. Aspartate-semialdehyde dehydrogenase, dihydrodipicolinate synthase, dihydrodipicolinate reductase, and diaminopimelate dehydrogenase were neither influenced in their specific activity, nor inhibited, by any of the aspartate family of amino acids. Homoserine dehydrogenase was repressed by methionine (to 15% of its original activity) and inhibited by threonine (4% remaining activity). Inclusion of leucine in the growth medium resulted in a twofold increase of homoserine dehydrogenase specific activity. The flow of aspartate semialdehyde to either lysine or homoserine was influenced by the activity of homoserine dehydrogenase or dihydrodipicolinate synthase. Thus, the twofold increase in homoserine dehydrogenase activity resulted in a decrease in lysine formation accompanied by the formation of isoleucine. In contrast, repression of homoserine dehydrogenase resulted in increased lysine formation. A similar increase of the flow of aspartate semialdehyde to lysine was found in strains with increased dihydrodipicolinate synthase activity, constructed by introducing the dapA gene of Escherichia coli (coding for the synthase) into C. glutamicum.     

Quantification of S-adenosyl Methionine in Microbial Cell Extracts

A sensitive method for quantification of S-adenosyl methionine (SAM) in microbial cell extracts was developed and applied to Corynebacterium glutamicum. The method is based on SAM being completely hydrolyzed into ¹⁸O-homoserine when extracted in boiling H₂¹⁸O and thus can be clearly distinguished by GC-MS analysis from naturally labeled homoserine present in the cell extract. Additional quantification of the total homoserine pool, representing both SAM and homoserine, via HPLC allows separate determination of both metabolites. Received 23 August 2005; Revisions requested 30 August 2005; Revisions received 26 September 2005; Accepted 31 October 2005     

Methionine transport in Yersinia pestis.

Yersinia pestis TJW, an avirulent wild-type strain, requires phenylalanine and methionine for growth. It was of interest to examine and define the methionine transport system because of this requirement. The methionine system showed saturation kinetics with a Km for transport of approximately 9 times 10(-7) M. After 8 s of methionine transport, essentially all of the methionine label appeared in S-adenosyl-L-methionine (SAM) as detected in ethanol extracts. Small amounts of free methionine was detected intracellularly after 1 min of transport. Addition of glucose increased significantly the amount of intracellular methionine at 1 min. A series of SAM metabolic products was detected after 90 s to 5 min of transport including: 5'-thiomethyladenosine, homoserine lactone, S-adenosyl homoserine, and a fluorescent methyl receptor compound. Results from assays for SAM synthetase in spheroplast fractions showed a small (16%) but significant portion of synthetase associated with the membrane. However, most of the enzyme activity was associated with the cytoplasmic fraction. Methionine transport was characterized by a high degree of stereospecificity. No competition occurred from structurally unrelated amino acids. Although uptake was inhibited by uncoupling and sulfhydryl reagents, no efflux was observed. Results using energy inhibitors on unstarved and starved cells showed that respiratory inhibitors such as potassium cyanide (KCN) and amytal were most effective, and that arsenate was least effective. KCN plus arsenate completely blocked utilization of energy derived from glucose, and KCN completely blocked utilization of energy deived from D-lactate. The data indicate that methionine transport in Y. pestis is linked to the trapping of methionine in SAM. The results further suggest that this transport system can be classified as a permease-bound system where transport is coupled to an energized membrane state and to respiration.