Two novel pyrrolooxazole pigments formed by the Maillard reaction between glucose and threonine or serine

Pyrrolothiazolate formed by the Maillard reaction between l-cysteine and d-glucose has a pyrrolothiazole skeleton as a chromophore. We searched for a Maillard pigment having a pyrrolooxazole skeleton formed from l-threonine or l-serine instead of l-cysteine in the presence of d-glucose. As a result, two novel yellow pigments, named pyrrolooxazolates A and B, were isolated from model solutions of the Maillard reaction containing l-threonine and d-glucose, and l-serine and d-glucose, respectively, and identified as (2R,3S,7aS)-2,3,7,7a-tetrahydro-6-hydroxy-2,5,7a-trimethyl-7-oxo-pyrrolo[2,1-b]oxazole-3-calboxylic acid and (3S,7aS)-2,3,7,7a-tetrahydro-6-hydroxy-5,7a-dimethyl-7-oxo-pyrrolo[2,1-b]oxazole-3-calboxylic acid by instrumental analyses. These compounds were pyrrolooxazole derivatives carrying a carboxy group, and showed the absorption maxima at 300–360 nm under acidic and neutral conditions and at 320–390 nm under alkaline conditions.     

Synthesis of l-Tryptophan from Pyruvate,Ammonia and Indole

The tryptophanase activity which synthesizes l-tryptophan from pyruvate, ammonia and indole, was found to be widely distributed in cells of bacteria belonging to Enterobacteriaceae, such genera as Escherichia, Kluyvera, Enterobacter, Erwinia and Proteus. With the cells of Proteus rettgeri, equilibrium of the elimination reaction of l-tryptophan in the presence of high concentration of ammonia was studied. It was found that the equilibrium inclines toward the synthetic state.

When 5-hydroxy- and 5-methyl-indole were substituted for indole, 5-hydroxy- and 5-methyl-l-tryptophan, respectively, were synthesized. The synthesis of l-tryptophan was also observed with indole and various amino acids, S-methyl-l-cysteine, S-ethyl-l-cysteine, l-cysteine, 5-fluoro-dl-tryptophan, or oxalacetic acid.     

Purification,Crystallization and Properties of Tryptophanase from Proteus rettgeri

An inducible tryptophanase was crystallized from the cell extract of Proteus rettgeri grown in a medium containing l-tryptophan. The purification procedure included ammonium sulfate fractionation, heat treatment, DEAE-Sephadex and hydroxylapatite column chromatographies. Crystals were obtained from solutions of the purified enzyme by the addition of ammonium sulfate.

The crystalline enzyme preparation was homogeneous by the criteria of ultracentrifugation and zone electrophoresis. The molecular weight was determined to be approximately 210,000.

The crystalline enzyme catalyzed the degradation of l-tryptophan into indole, pyruvate and ammonia in the presence of added pyridoxal phosphate. The enzyme also catalyzed pyruvate formation from 5-hydroxy-l-tryptophan, 5-methyl-l-tryptophan, S-methyl-l-cysteine and l- cysteine. l-, d-Alanine, l-phenylalanine and indole inhibited pyruvate formation from these substrates.     

Properties of Tyrosinase from Pseudomonas melanogenum

The properties of the tyrosinase from Pseudomonas melanogenum was investigated with the crude enzyme preparation. Optimum temperature and pH of the enzyme were 23°C and 6.8, respectively. l-Tyrosine, d-tyrosine, m-tyrosine, N-acetyl-l-tyrosine and l-DOPA were utilized as a substrate by the enzyme. The value for Km obtained were as follows: l-tyrosine 6.90 × 10^?4 m, d-tyrosine 1.43 ×10^?3 m and l-DOPA 9.90 × 10^?4 m. The enzyme was inhibited by chelating agents of Cu²⁺ l-cysteine, l-homocysteine, thiourea and diethyl-dithiocarbamate and the inhibition was completely reversed by the addition of excess Cu²⁺ From these results it is concluded that the enzyme is a copper-containing oxidase.     

Elimination,Replacement and Isomerization Reactions by Intact Cells Containing Tyrosine Phenol Lyase

Tyrosine phenol lyase catalyzes a series of α,β-elimination, β-replacement and racemization reactions. These reactions were studied with intact cells of Erwinia herbicola ATCC 21434 containing tyrosine phenol lyase.

Various aromatic amino acids were synthesized from l-serine and phenol, pyrocatechol, resorcinol or pyrogallol by the replacement reaction using the intact cells. l(d)-Tyrosine, 3,4-dihydroxyphenyl-l(d)-alanine (l(d)-dopa), l(d)-serine, l-cysteine, l-cystine and S-methyl-l-cysteine were degraded to pyruvate and ammonia by the elimination reaction. These amino acids could be used as substrate, together with phenol or pyrocatechol, to synthesize l-tyrosine or l-dopa via the replacement reaction by intact cells. l-Serine and d-serine were the best amino acid substrates for the synthesis of l-tyrosine or l-dopa. l-Tyrosine and l-dopa synthesized from d-serine and phenol or pyrocatechol were confirmed to be entirely l-form after isolation and identification of these products. The isomerization of d-tyrosine to l-tyrosine was also catalyzed by intact cells.

Thus, l-tyrosine or l-dopa could be synthesized from dl-serine and phenol or pyrocatechol by intact cells of Erwinia herbicola containing tyrosine phenol lyase.     

Purification,Crystallization and Properties of Tyrosine Phenol Lyase from Erwinia herbicola

Crystalline tyrosine phenol lyase was prepared from the cell extract of Erwinia herbicola grown in a medium supplemented with l-tyrosine. The crystalline enzyme was homogeneous by the criteria of ultracentrifugation and acrylamide gel electrophoresis. The molecular weight was determined to be approximately 259,000. The crystalline enzyme catalyzed the conversion of l-tyrosine into phenol, pyruvate and ammonia, in the presence of added pyridoxal phosphate. The enzyme also catalyzed pyruvate formation from d-tyrosine, S-methyl-l-cysteine, 3, 4-dihydroxyphenyl-l-alanine, l- and d-serine, and l- and d-cysteine, but at lower rates than from l-tyrosine. l-Phenyl-alanine, l-alanine, phenol and pyrocatechol inhibited pyruvate formation from l-tyrosine.

Crystalline tyrosine phenol lyase from Erwinia herbicola is inactive in the absence of added pyridoxal phosphate. Binding of pyridoxal phosphate to the apoenzyme is accompanied by pronounced increase in absorbance at 340 and 425 mμ. The amount of pyridoxal phosphate bound to the apoenzyme was determined by equilibrium dialysis to be 2 moles per mole of enzyme. Addition of the substrate, l-tyrosine, or the competitive inhibitors, l-alanine and l-phenyl-alanine, to the holoenzyme causes appearance of a new absorption peak near 500 mμ which disappears as the substrate is decomposed but remains unchanged in the presence of the inhibitor.     

Synthesis of an Isoglutathione Derivative by Proteases and Its α→γ Transpeptidation

Benzyloxycarbonyl-l-cysteine and glycine benzhydrylamide were condensed by papain in a yield of 39.5%. After elimination of the N-protecting group, l-cysteinylglycine benzhydrylamide was condensed with benzyloxycarbonyl-l-glutamic acid by acid protease from Irpex lacteus Fr. in a yield of 21.0%. From the isoglutathione derivative thus obtained, a γ-linkage between glutamic acid and cysteine was formed by α → γ transpeptidation in alkaline conditions after esterification of γ-carboxylic acid.     

Biosynthetic Threonine Deaminase from Proteus morganii

Biosynthetic threonine deaminase was purified to an apparent homogeneous state from the cell extract of Proteus morganii, with an overall yield of 7.5%. The enzyme had a s⁰_20,w of 10.0 S, and the molecular weight was calculated to be approximately, 228,000. The molecular weight of a subunit of the enzyme was estimated to be 58,000 by sodium dodecyl sulfate gel electrophoresis. The enzyme seemed to have a tetrameric structure consisting of identical subunits. The enzyme had a marked yellow color with an absorption maximum at 415 nm and contained 2 mol of pyridoxal 5′-phosphate per mol. The threonine deaminase catalyzed the deamination of l-threonine, l-serine, l-cysteine and β-chloro-l-alanine. Km values for l-threonine and l-serine were 3.2 and 7.1 mm, respectively. The enzyme was not activated by AMP, ADP and ATP, but was inhibited by l-isoleucine. The Ki for l-isoleucine was 1.17 mm, and the inhibition was not recovered by l-valine. Treatment with mercuric chloride effectively protected the enzyme from inhibition by l-isoleucine.     

Effect of l-Cysteine on Browning of Egg Albumen

Browning of egg albumen heated at 105~1110°C was retarded by the addition of l-cysteine. A level of 5% l-cysteine was shown as a necessary amount for the effective retardation of browning. It was found that this retarding effect of l-cysteine on browning of egg albumen was caused by the elimination of carbohydrates in egg albumen which were necessary to browning reaction of proteins with the formation of 2-polyhydroxyalkyl thiazolidine 4-carboxylic acids. The depletion of carbohydrates by adding cysteine may be applicable to prevent the browning which occurs during spray drying of egg albumen and whole egg.     

Synthesis of γ-Glutamylpeptides by γ-Glutamylcysteine Synthetase from Proteus mirabilis

Syntheses of various γ-glutamylpeptides were examined taking use of the highly purified γ-glutamylcysteine synthetase from Proteus mirabilis. The accumulation of each peptide was measured after long time incubation, and good formation was observed in the synthesis of peptides of following amino acids, l-cysteine, l-α-aminobutyrate, l-serine, l-homoserine, glycine, l-alanine, l-norvaline, l-lysine, l-threonine, taurine and l-valine. Peptide syntheses were confirmed by analyses of the component amino acids, after hydrolysis of the peptides.

The structure of the glutamylpeptides, especially the peptide-linkage at the γ-carbonyl residue of l-glutamate, was determined by mass spectrometry of the N-trifluoroacetyl methylester derivatives of the glutamylpeptides. Enzymatic synthesis of γ-glutamyl-l-α-aminobutyrate was also confirmed by PMR spectrometry in the comparison with chemically synthesized compound.     

Production of O-Acetyl-l-homoserme by Methionine Analogresistant Mutants and. Regulation of Homosenne-O-transacetylase in Gorynebacterium glutamicum

A large amount of O-acetyl-l-homoserine (OAH) was found to be produced by trifluo-romethionine-resistant mutants derived from Corynebacterium glutamicum ESLR–146 (Thr?,ethionine^R, selenomethionine^R) and ET_zR–606(Thr?,ethionine^R, 1,2,4-triazole^R) by mutational treatment with ethyl methanesulfonate. Some cultural conditions for OAH production were examined with one of the mutants, ESLFR-736, which was derived from ESLR–146. Addition of l-methionine or l-serine decreased OAH production. Optimal level of l-threo- nine, a growth factor in ESLFR–736, for OAH production was about 200 μg/ml, and further addition of excess l-threonine repressed OAH production. Corn steep liquor (CSL) and yeast extract added simultaneously enhanced OAH production to a great extent. Thus, the amount of OAH production reached to a level of 10.5 mg/ml with a medium containing 10% glucose and 0.01 % of both CSL and yeast extract after 2 days incubation.

Cell-free extract of C. glutamicum catalyzed the formation of OAH from acetyl CoA and l-homoserine, while a corresponding reaction with succinyl CoA was hardly detected. These observations indicate that OAH but not O-succinyl-l-homoserine is an intermediate of l-methionine biosynthesis in C. glutamicum.

The regulation of homoserine-O-transacetylase was examined in a methionine requiring mutant of C. glutamicum. The enzyme activity was not inhibited by l-methionine, S-adenosyl-methionine and S-adenosylhomocysteine, separately or in combination. The synthesis of homoserine-O-transacetylase was strongly repressed by l-methionine. The enzyme level in an OAH producer, ESLFR–736, increased to about 2-fold of that in ESLR–146, the parental strain.     

Inhibition of l-Alanine Adding Enzyme by Glycine

l-Alanine adding enzymes from Bacillus subtilis and Bacillus cereus which catalyzed l-alanine incorporation into UDPMurNAc were partially purified and the properties of the enzymes were examined. The enzyme from B. subtilis was markedly stimulated by reducing agents including 2-mercaptoethanol, dithiothreitol, glutathione and cysteine. Mn²⁺ and Mg²⁺ activated l-alanine adding activity and their optimal concentrations were 2 to 5 mm and 10 mm, respectively. The optimum pH was 9.5 and the Km for l-alanine was 1.8×10^?4m. l-Alanine adding reaction was strongly inhibited by p-chloromercuribenzoate and N-ethyl-maleimide. Among glycine, l- and d-amino acids and glycine derivatives, glycine was the most effective inhibitor of the l-alanine adding reaction. The enzyme from B. cereus was more resistant to glycine than that from B. subtilis. Glycine was incorporated into UDPMurNAc in place of l-alanine, and the Ki for glycine was 4.2×l0^?3m with the enzyme from B. subtilis. From these data, the growth inhibition of bacteria by glycine is discussed.     

Cloning,Expression, and Identification of Genes Involved in the Conversion of DL-2-Amino-Δ2-thiazoline-4-carboxylic Acid to L-Cysteine via S-Carbamyl-L-cysteine Pathway in Pseudomonas sp. TS1138

Two novel genes (tsB, tsC) involved in the conversion of DL-2-amino-Δ²-thiazoline-4-carboxylic acid (DL-ATC) to L-cysteine through S-carbamyl-L-cysteine (L-SCC) pathway were cloned from the genomic DNA library of Pseudomonas sp. TS1138. The recombinant proteins of these two genes were expressed in Escherichia coli BL21, and their enzymatic activity assays were performed in vitro. It was found that the tsB gene encoded an L-ATC hydrolase, which catalyzed the conversion of L-ATC to L-SCC, while the tsC gene encoded an L-SCC amidohydrolase, which showed the catalytic ability to convert L-SCC to L-cysteine. These results suggest that tsB and tsC play important roles in the L-SCC pathway and L-cysteine biosynthesis in Pseudomonas sp. TS1138, and that they have potential applications in the industrial production of L-cysteine.     

Regulatory Properties of Chorismate Mutase from Corynebacterium glutamicum

Regulatory properties of chorismate mutase from Corynebacterium glutamicum were studied using the dialyzed cell-free extract. The enzyme activity was strongly feedback inhibited by l-phenylalanine (90% inhibition at 0.1~1 mm) and almost completely by a pair of l-tyrosine and l-phenylalanine (each at 0.1~1 mm). The enzyme from phenylalanine auxotrophs was scarcely inhibited by l-tyrosine alone but the enzyme from a wild-type strain or a tyrosine auxotroph was weakly inhibited by l-tyrosine alone (40~50% inhibition, l-tyrosine at 1 mm). The enzyme activity was stimulated by l-tryptophan and the inhibition by l-phenylalanine alone or in the simultaneous presence of l-tyrosine was reversed by l-tryptophan. The Km value of the reaction for chorismate was 2.9 } 10^?3 m. Formation of chorismate mutase was repressed by l-phenylalanine. A phenylalanine auxotrophic l-tyrosine producer, C. glutamicum 98–Tx–71, which is resistant to 3-amino-tyrosine, p-aminophenylanaine, p-fluorophenylalanine and tyrosine hydroxamate had chorismate mutase derepressed to two-fold level of the parent KY 10233. The enzyme in C. glutamicum seems to have two physiological roles; one is the control of the metabolic flow to l-phenylalanine and l-tyrosine biosynthesis and the other is the balanced partition of chorismate between l-phenylalanine-l-tyrosine biosynthesis and l-tryptophan biosynthesis.     

Regulatory Properties of Prephenate Dehydrogenase and Prephenate Dehydratase from Corynebacterium glutamicum

Regulatory properties of the enzymes in l-tyrosine and l-phenyalanine terminal pathway in Corynebacterium glutamicum were investigated. Prephenate dehydrogenase was partially feedback inhibited by l-tyrosine. Prephenate dehydratase was strongly inhibited by l-phenylalanine and l-tryptophan and 100% inhibition was attained at the concentrations of 5 × 10^?2mm and 10^?1mm, respectively. l-Tyrosine stimulated prephenate dehydratase activity (6-fold stimulation at 1 mm) and restored the enzyme activity inhibited by l-phenylalanine or l-tryptophan. These regulations seem to give the balanced synthesis of l-tyrosine and l-phenyl-alanine. Prephenate dehydratase from C. glutamicum was stimulated by l-methionine and l-leucine similarly to the enzyme in Bacillus subtilis and moreover by l-isoleucine and l-histidine. C. glutamicum mutant No. 66, an l-phenylalanine producer resistant to p-fluorophenyl-alanine, had a prephenate dehydratase completely resistant to the inhibition by l-phenylalanine and l-tryptophan.     

γ-Glutamylcysteine Synthetase from Proteus mirabilis

The distribution of γ-glutamylcysteine synthetase (l-glutamate: L-cysteine γ-ligase, EC 6.3.2.2) was investigated in bacteria, and the enzyme was purified from Proteus mirabilis approximately 9,000-fold with an over-all yield of 10%. The purification procedure included ammonium sulfate fractionation, protamine treatment, DEAE-cellulose and hydroxylapatite column chromatographies and Sephadex gel filtrations. The purified enzyme was homogeneous by the criteria of ultracentrifugation. It showed multiple bands on disc-polyacrylamide gel electrophoresis and on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. One band with a molecular weight of 62,000 was obtained on SDS-polyacrylamide gel electrophoresis after cross-linking of the enzyme with dimethylsuberimidate. The molecular weight was determined from the sedimentation and diffusion coefficients to be 64,000 and by Sephadex G-150 gel filtration to be 62,000. The purified enzyme catalyzed the stoichiometric formation of γ-glutamylcysteine and the reaction showed a sigmoidal dependence upon l-cysteine concentration. The enzyme also catalyzed γ-glutamyl amino acid formation from l-α-aminobutyrate, l-homoserine, glycine, l-serine, dl-norvaline or dl-homocysteine, but at lower rates than from l-cysteine. The γ-glutamyl-α-aminobutyrate formation by the enzyme did not show a sigmoidal but a hyperbolic dependence upon l-α-aminobutyrate concentration.     

Purification and Crystallization of d-Arabinose (l-Fucose) Isomerase from Aerobacter aerogenes by Polyethylene Glycol

d-Arabinose(l-fucose) isomerase (d-arabinose ketol-isomerase, EC 5.3.1.3) was purified from the extracts of d-arabinose-grown cells of Aerobacter aerogenes, strain M-7 by the procedure of repeated fractional precipitation with polyethylene glycol 6000 and isolating the crystalline state. The crystalline enzyme was homogeneous in ultracentrifugal analysis and polyacrylamide gel electrophoresis. Sedimentation constant obtained was 15.4s and the molecular weight was estimated as being approximately 2.5 × 10⁵ by gel filtration on Sephadex G-200.

Optimum pH for isomerization of d-arabinose and of l-fucose was identical at pH 9.3, and the Michaelis constants were 51 mm for l-fucose and 160 mm for d-arabinose. Both of these activities decreased at the same rate with thermal inactivation at 45 and 50°C. All four pentitols inhibited two pentose isomerase activities competitively with same Ki values: 1.3–1.5 mm for d-arabitol, 2.2–2.7 mm for ribitol, 2.9–3.2 mm for l-arabitol, and 10–10.5 mm for xylitol. It is confirmed that the single enzyme is responsible for the isomerization of d-arabinose and l-fucose.     

Sensitive and Simple Methods for Determination of l-Lysine with l-Lysine α-Oxidase

l-Lysine could be determined satisfactorily with a new fungal enzyme, l-Iysine α-oxidase (EC 1.4.3). The method consists of the oxidative deamination of l-Iysine with l-lysine α-oxidase and the spectrophotometric determination of one of the reaction products: α-keto-ε-aminocaproate, its intramolecular dehydrated form, Δ¹-piperideine-2-carboxylate or hydrogen peroxide. The method on the basis of the color reaction of hydrogen peroxide formed from l-lysine with 4-aminoantipyrine and phenol in the presence of peroxidase was most sensitive and simple. The method could be used for the direct assay of l-lysine levels in serums from several animals without pretreatments.     

Distribution of 7-Keto-8-aminopelargonic Acid Synthetase in Bacteria and the Control Mechanism of the Enzyme Activity

The 7-keto-8-aminopelargonic acid (KAPA) synthetase activities of cell-free extracts from various bacteria were investigated. The experiments on the substrate specificity of KAPA synthetase, using crude cell-free extracts from bacteria having high enzyme activity, showed that l-serine and pyruvic acid could replace l-alanine, but that, when the enzyme was partially purified, these compounds were not effective. Many kinds of amino acids such as l-cysteine, l-serine, d-alanine, glycine, d-histidine, and l-histidine, inhibited the enzyme activity. This inhibition was found to be competitive with l-alanine. Pyridoxal 5′-phosphate, which is a cofactor of the enzyme, also inhibited the enzyme activity at high concentrations. The repression of KAPA synthetase by biotin occurred in Bacillus subtilis and B. sphaericus but not in Micrococcus roseus and Pseudomonas fluorescens, even at a concentration of 1000 mµg per ml of biotin.     

Pyrolysis of Sulfur-containing Amino Acids

Sulfur-containing amino acids (l-cysteine, l-cystine and dl-methionine) were pyrolyzed. From pyrolyzed cysteine and cystine were identified 7~8 volatile compounds including 2-methylthiazolidine which is considered to be the product of the reaction of acetaldehyde with mercaptethylamine, and from pyrolyzed methionine were identified 11 volatiles. At the same time, besides these volatile compounds, alanine, cystine and isoleucine, and alanine, isoleucine and methionine were detected in the pyrolyzed products of cysteine and cystine, respectively, but no amino acid was detected from that of methionine. The mixture of seven identified volatiles generated from l-cystine developed a pop-corn like aroma with a roasted sesame like one, and methylmercaptane seemed to be the main contributor to the pickled radish like odor produced from pyrolysis of dl-methionine. Degradation schemes of cystine and methionine were proposed.