SILAR-10 C as a Liquid Phase for Gas-liquid Chromatography of Alditol Acetates

It is known that amino acid esters added in a protein hydrolysate are covalently incorporated during the plastein reaction. As its modification, a novel simplified process was developed which permitted incorporation of l-methionine directly into soy protein during treatment with papain. This process is characterized by its requirement for a very high substrate (protein) concentration and an alkaline pH condition. Racemic dl-methionine ethyl ester could be used to incorporate the l-isomer only. The amount of l-methionine incorporated varied depending on the amount of formulation of l-methionine ethyl ester; it was easily feasible to obtain final products with almost expected methionine contents. From an economic point of view, defatted soy flour was used as starting material, with a satisfactory result that the methionine level was enhanced in a large measure.     

Salt Effects on Plastein Formation by α-Chymotrypsin

The plastein formation by α-chymotrypsin from an ovalbumin hydrolysate was affected in an order of valency of salts when the concentration of each salt was 1 m. Monovalent cations were rather effective at this concentration and enhanced the plastein yield by 10%. In the presence of NaCl, the plastein formation showed two distinct maximal rates at its concentrations of 0.1 m and 0.8 m. The first maximum was considered to be resulted from an increase in enzyme activity, since chymotryptic hydrolysis of both N-acetyl-l-tyrosine ethyl ester and benzyloxycarbonyl-l-phenylalanine p-nitrophenyl ester was activated at an NaCl concentration of 0.1 ~ 0.2 m. The second maximum was ascribed to the salting-out of the product due to the higher concentration of NaCl. A salt-tolerant protease was also used to confirm the above conclusions. It was observed that this enzyme was much effective in producing a plastein at a high NaCl concentration. This may be due to the fact that both the enzyme activation effect and the product salting-out effect participate co-operatively.     

Phyllostine,a New Phytotoxic Compound Produced by Phyllosticta sp.

Ethionine-resistant mutants derived from Corynebacterium glutamicum KY 9276 (Thr^?) were found to accumulate l-methionine in culture media. One of the mutants, ER-107-4, which produced 250 μg/ml of l-methionine was subjected to further mutagenesis to obtain better l-methionine producers. l-Methionine production increased stepwise by successive endowing such markers as selenomethionine, 1,2,4-triazole, trifluoromethionine and methionine hydroxamate resistance. Thus, a mutant multi-resistant to ethionine, selenomethionine and methionine hydroxamate, ESLMR-724, produced 2 mg/ml of l-methionine in a medium containing 10% glucose.

Increase of l-methionine production was accompanied by increased levels and reduced repressibility of methionine-forming enzymes. The levels of methionine enzymes in ESLMR-724 increased to 2.5~4.2 fold of those in KY9276, In addition, homoserine-O-trans-acetylase and cystathionine γ-synthase which were strongly repressed by l-methionine in KY 9276 were stimulated by exogenous l-methionine in ESLMR-724. Implications of these results were discussed in relation to the productivity of l-methionine and the regulation of l-methionine biosynthesis.     

The Chlorinolysis of Methionine Derivatives

The chlorinolysis of l-methionine methyl ester hydrochloride with molecular chlorine was carried out under various conditions, resulting in methyl l-2-amino-4,4,4-trichlorobutanoate and methyl l-2-amino-3,4,4,4-tetrachlorobutanoate which were isolated as N-benzoyl and N-carbobenzoxy derivatives. The chlorinolysis of N-acylmethionine ester and methionine sulfoxide ester proceeded also without cleavage of the N-protecting group to give the same products as above. However, the reaction of methionine sulfone derivative with chlorine did not proceed in the same conditions.

It was proved that the resulting polychloroamino acid derivatives are optically pure. The possible chlorinolysis mechanism was also proposed.     

Further Studies on the Effect of Amino Acid Supplementation on the Urinary Nitrogen Compounds in Rats Fed a Low-casein Diet

When 8% casein basal diet was supplemented with 0.3% dl-methionine or 0.3% dl-methionine plus 0.36% dl- or 0.18% l-threonine, the changes in urinary excretions of urea and allantoin were examined in weanling male rats of Wistar strain with the observations on the body weight gain and % nitrogen retention. Carbohydrate sources used were sucrose or an equimolar mixture of glucose and fructose (G-F) in place of pregelatinized starch used in the previous experiments.

In contrast to the previous results, differences in nitrogen utilization, expressed in term of growth rate or % nitrogen retention, became significant by the addition of 0.3% methionine to the basal diet and it was further increased by the simultaneous supplementation with 0.36% dl- or 0.18% l-threonine.

Urea excretion was the main variable in total urinary nitrogen output to cause the significant difference in % nitrogen retention between the groups. As postulated in the previous paper, thus, the use of sucrose or G-F mixture considerably exaggerated these group-differences in such various indices as body weight gain and % nitrogen retention, and this trend became more distinct in the urea and allantoin excretions.

Liver arginase activity inversely changed with urea excretion, but proportionately to the qualitative improvement of dietary protein by the addition of methionine or methionine plus threonine. Changes in liver glutamic dehydrogenase activity were also parallel with the improvement of dietary protein quality.     

Inhibition of Yeast Growth by Methionine

The accumulation of S-adenosylmethionine in adenine-requiring yeast cells grown in a culture medium containing dl-, l-, or d-methionine was much larger than that in cells grown in a methionine-free medium. The accumulation of S-adenosyl-d-methionine in the cells was significantly lower than that of S-adenosyl-l-methionine. When yeast cells containing a large amount of S-adenosyl-l-methionine were incubated in an adenine-free medium, adenosylmethionine was degraded, but poor and insignificant growth was observed indicating the meager nature of this compound as an adenine source. No degradation of accumulated S-adenosyl-d-methionine was detected. Isotopic experiment revealed that S-adenosyl-l-methionine in the yeast cells turned over at a considerable rate when the medium contained both adenine and l-methionine. Most of the l-methionine assimilated appears to be metabolized via S-adenosyl-l-methionine.     

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.     

Microbial Production of l-Threonine

l-Threonine production by strain BB-69, which was derived from Brevibacterium flavum No. 2247 as a α-amino-β-hydroxyvaleric acid resistant mutant and produced about 12 g/liter of l-threonine, was reduced by the addition of l-lysine or l-methionine in the culture medium. Many of lysine auxotrophs but not methionine auxotrophs derived from strain B–2, which produced about 7 g/liter of l-threonine, produced more l-threonine than the parental strain. Except only one methionine auxotroph (BBM–21), none of lysine and methionine auxotrophs derived from BB–69 produced more l-threonine than the parental strain. Homoserine dehydrogenase of crude extract from strain B–2 was inhibited by l-threonine more strongly than that from BB–69. Strain BBM–21, a methionine auxotroph derived from BB–69, produced about 18 g/liter of l-threonine, 50% more than BB–69, while accumulation of homoserine decreased remarkably as compared with BB–69. l-Threonine production by BBM–21 was increased by the addition of l-homoserine, a precursor of l-threonine, while that by BB–69 was not. No difference was found among BBM–21, BB–69 and No. 2247 in the degree of inhibition of homoserine kinase by l-threonine. l-Threonine production by revertants of BBM–21, that is, mutants which could grow without methionine, were all lower than that of BBM–21. Correlation between l-threonine production and methionine or lysine auxotrophy was discussed.     

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.     

Amino Acid Metabolism in Microorganisms

Certain Streptomyces strains were found to accumulate an unknown substance in culture broth when the microorganisms were grown in the medium containing dl-methionine. The substance was isolated from the culture broth as hydrochloride and was identified as 3-methylthiopropylamine (MTPA), decarboxylated product of methionine, from its melting point, chemical composition, infrared spectrum, and other properties. Cultural conditions for MTPA formation in Streptomyces sp. K 37 were investigated. The yield of MTPA from l-methionine reached about 90% with a culture medium containing corn steep liquor. Namely, 6.47 mg of MTPA per millilitre of culture broth was produced from 10 mg of l-methionine per millilitre of the growth medium. The transforming activity was found in the cells of the early culture period. MTPA-producing activity was induced by l- methionine in the medium. d-Methionine was not utilized as a substrate of the reaction with intact cells. Optimum pH for the reaction appeared to be 6.0~8.0.     

Isolation and Characterization of S-Adenosylmethionine-requiring Mutants and Role of S-Adenosylmethionine in the Regulation of Methionine Biosynthesis in Corynebacterium glutamicum

Using a minimal medium containing a methionine analog together with a small amount of S-adenosylmethionine (SAM), many SAM requiring mutants which responded only to SAM and not to methionine, S-adenosylhomocysteine, or homocysteine were efficiently isolated from Corynebacterium glutamicum TLD-140 after mutagenesis. Among them, SAM-14 and SAM-19 selected from selenomethionine resistant mutants were subjected to further investigation. Both mutants were unable to grow in a minimal medium and had no detectable activity of SAM synthetase. Both mutants acquired higher resistance to methionine hydroxamate and ethionine as well as to selenomethionine than TLD-140 and produced l-methionine in a medium.

Homoserine-O-transacetylase in SAM-19 was subject to full repression by the addition of excess SAM to the growth medium and was not repressed under SAM limitation, whereas addition of excess l-methionine under SAM limitation caused a partial repression of the enzyme. SAM synthetase as well as l-methionine biosynthetic enzymes in a methionine auxotroph of C. glutamicum was repressed by the addition of l-methionine to the growth medium.

These results suggest that SAM is implicated in the repression of l-methionine synthesizing enzymes in C. glutamicum.     

Studies on the Synthesis of l-Amino Acids

l-Homoserine was prepared by the reduction of l-aspartic acid β-methyl ester with sodium borohydride in water solution without any racemization. The yield of l-homoserine was about 25% of the theoretical amount, and no product other than l-homoserine, l-aspartic acid and l-aspartic acid β-methyl ester was present in the reaction mixture. The low yield of l-homoserine was ascribed to the hydrolysis of the ester.

l-Azetidine-2-carboxylic acid could not be detected in the reaction mixture. In contrast with the reduction of l-glutamic acid γ-esters, the reduction of l-aspartic acid β-ester was not accompanied by the cyclization.     

Microbial Production of l-Threonine

l-Threonine producing α-amino-β-hydroxyvaleric acid resistant mutants were derived from E. coli K-12 with 3 x 10^-5 frequency. One of mutants, strain β-101, accummulated maximum amount of l-threonine (1. 9 g/liter) in medium. Among isoleucine, methionine and lysine auxotrophs derived from E. coli K-12, only methionine auxotrophs produced l-threonine. In contrast, among isoleucine, methionine and lysine auxotrophs derived from β-101, l-threonine accumulation was generally enhanced in isoleucine auxotrophs. One of isoleucine auxotrophs, strain βI-67, produced maximum amount of l-threonine (4. 7 g/liter). Methionine auxotroph, βM-7, derived from β-101 produced 3.8 g/liter, and βIM-4, methionine auxotroph derived from β1-67, produced 6.1 g/liter, when it was cultured in 3% glucose medium supplemented with 100 μg/ml of l-isoleucine and l-methionine, respectively. These l-threonine productivities of E. coli mutants were discussed with respect to the regulatory mechanisms of threonine biosynthesis. A favourable fermentation medium for l-threonine production by E. coli mutants was established by using strain βM-4.     

Accumulation of S-Adenosylmethionine by Molds

Aspergillus tamani accumulated about 20 μmoles of S-adenosylmethionine (SAM) in 1 g of dry cells when cultured secondarily in a medium containing more than 10 mm of l- methionine. The accumulation was not so high when l-methionine was replaced by d- methionine. Addition of nucleic acid-related substances was not effective for the accumulation. Addition of d, l-ethionine in place of methionine caused accumulation of S-adenosylethionine (SAE) in place of SAM. Among 100 strains of molds tested, a number of strains belonging to the genera Penicillium, Aspergillus, Rhizopus and Mucor could accumulate SAM in their mycelia. Especially Mucor jansseni had the highest ability; it accumulated 45 μmoles of SAM in 1 g of dry cells.     

Studies on the Formation of the Cheese-like Flavor

Solution containing l-leucine and l-methionine cultured by Aspergillus flavus were found to develop cheese-like flavor.

α-Keto-isocaproic acid was isolated and identified from the culture of l-leucine and α-keto-β-methylmercaptobutyric acid from that of l-methionine. The flavor was also developed from the mixture of the synthetic sample of α-ketoisocaproic acid and α-keto-β-methylmercaptobutyric acid.     

A Novel One-step Process for Enzymatic Incorporation of Amino Acids into Proteins : Papain-catalyzed Polymerization of l-Methionine Ethyl Ester and Its Regulation by Adding a Protein Substrate

To enhance a methionine level of soy protein the plastein reaction was replaced by a simplified one-step process which had been newly developed as described in the preceding paper. It was found that during the process l-methionine ethyl ester (H · Met · OEt) underwent papain-catalyzed polymerization when the enzymatic incubation was carried out in the absence or inadequacy of soy protein. There was a critical point with regard to the ratio of the concentration of H·Met·OEt·HCl ([M]) and that of the soy protein ([S]). A sufficiently low [M]/[S] prevented H · Met · OEt from forming its polymer, permitting efficient incorporation of methionine into soy protein. A high possibility was suggested that in such a case H·Met·OEt acted as a nucleophile amine to be incorporated in the mode of papain-catalyzed aminolysis of protein.     

Enzymatic Conversion of Dethiobiotin to Biotin in Cell-free Extracts of a Bacillus sphaericus bioB Transformant

The activity of biotin synthase, responsible for biotin synthesis from dethiobiotin, was demonstrated in a completely defined reaction mixture with cell-free extracts of a Bacillus sphaericus bioB transformant. Among the sulfur compounds tested, only S-adenosyl-l-methionine was active, while l-methionine and l-cysteine had no significant effect. Protein concentrations higher than 15mg/ml in the reaction mixture were needed to detect biotin synthase activity. When dialyzed cell-free extracts were used for the reaction, NADH, NADPH, or FAD among the well-known cofactors tested enhanced the activity, and Fe²⁺, Mn²⁺, and Ca²⁺ among the metal ions tested also had some effects.     

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.     

Production of l-allose and d-talose from l-psicose and d-tagatose by l-ribose isomerase

l-ribose isomerase (L-RI) from Cellulomonas parahominis MB426 can convert l-psicose and d-tagatose to l-allose and d-talose, respectively. Partially purified recombinant L-RI from Escherichia coli JM109 was immobilized on DIAION HPA25L resin and then utilized to produce l-allose and d-talose. Conversion reaction was performed with the reaction mixture containing 10% l-psicose or d-tagatose and immobilized L-RI at 40 °C. At equilibrium state, the yield of l-allose and d-talose was 35.0% and 13.0%, respectively. Immobilized enzyme could convert l-psicose to l-allose without remarkable decrease in the enzyme activity over 7 times use and d-tagatose to d-talose over 37 times use. After separation and concentration, the mixture solution of l-allose and d-talose was concentrated up to 70% and crystallized by keeping at 4 °C. l-Allose and d-talose crystals were collected from the syrup by filtration. The final yield was 23.0% l-allose and 7.30% d-talose that were obtained from l-psicose and d-tagatose, respectively.     

Inhibition by Hadacidin,Duazomycin A,and Other Amino Acid Derivatives of de novo Starch Synthesis

Two amino acid derivative antibiotics, hadacidin and duazomycin A, were isolated as inhibitors of de novo starch synthesis in excised leaf segments from culture filtrates of Penicillium No. 467 and Streptomyces No. 317, respectively. In addition, azaserine, 6-diazo-5-oxo-l-norleucine (DON), and trifluoro-dl-methionine were found to be potent inhibitors among about 70 kinds of commercial amino acid derivatives. These amino acid derivatives inhibited de novo starch synthesis at concentrations ranging from 1 to 10ppm but did not inhibit photosynthetic oxygen evolution at a concentration of 100ppm. The inhibition caused by these diazo compounds was reversed by a supplement of l-glutamine. With hadacidin and trifluoro-dl-methionine, however, the reversal was not observed upon the addition of l-aspartic acid or l-methionine, respectively. Among these active compounds, hadacidin was herbicidal against lettuce and barnyard millet by foliar treatment at a concentration of more than 1000 ppm.