l-Glutamic Acid Fermentation

Structure of a sugar lipid produced by an oleic acid-requiring mutant of Brevibacterium thiogenitalis was studied and established as (I).

Relation between biotin and oleic acid was studied using a biotin-requiring organism accumulating l-glutamic acid and its blocked mutants lacking the biosynthetic system of biotin or/and oleic acid. The results support the following considerations. Biotin is not formed from oleic acid and does not substantially affect the growth of l-glutamic acid-accumulating bacteria and their productivity of l-glutamic acid.

Consequently, biotin serves only for the synthesis of fatty acids in the present organisms. The essential factor for their growth and metabolism is an unsaturated fatty acid like oleic acid and not biotin. And also, saturated fatty acids have substantially no relation with their growth and metabolism like accumulation of l-glutamic acid.     

Biochemical Effects of Fatty Acid and its Derivatives on l-Glutamic Acid Fermentation

In the preceding paper on the interrelation between sucrose ester of fatty acid and biotin, the fatty acid being a mixture of C₁₀ to C₁₈ acid, it was described that carbon chain length of fatty acid has a great influence on the accumulation of l-glutamic acid. Fatty acids with C₁₂ to C₁₈ chain length, particularly myristic, palmitic and margaric acids were effective on the accumulation of l-glutamic acid in the culture medium containing sufficient biotin, whereas lower and higher length acids were ineffective. In the form of polyoxyethylene sorbitan or polyethylene glycol ester, C₁₆ and C₁₈ acids were remarkably effective. However, the ester of C₁₂ acid and polyoxyethylene ethers of C₁₂ to C₁₈ alcohols had little or no effect.     

Biochemical Effects of Fatty Acid and its Derivatives on l-Glutamic Acid Fermentation

Brev. lactofermentum rapidly took up biotin from culture medium and stored it in the cells. The saturation level of the stored biotin (3.8 × 10⁴ molecules/cell) exceeded the level required for the maximum growth by ten times, and the minimum level (1.3 × 10³ molecules/cell) was the most adequate to the accumulation of l-glutamic acid. The stored cellular biotin over the minimum level was metabolically available in the subsequent culture lacking in supplemented biotin. The cellular biotin was gradually reduced to the minimum level with the multiplication of the cells, and them the accumulation of l-glutamic acid was observed. This relation between the level of cellular biotin and the accumulation of l-glutamic acid was impaired by the addition of Tween 60 or some saturated fatty acid. In the presence of biotin and Tween 60 the biotin-saturated cells turned into cells capable of accumulating l-glutamic acid keeping the maximum level; and in the same medium the cells having the minimum amount of biotin took up biotin and then were saturated with it, and yet the cells preserved the acid-accumulating property. It was confirmed with the use of bioautographic technique and avidin test that the biotin released from the cells by acid hydrolysis was identical with authentic d-biotin.     

Biochemical Effects of Fatty Acid and its Derivatives on l-Glutamic Acid Fermentation

Tween 60 (polyoxyethylene sorbitan monostearate) has been found to be the most effective derivative of fatty acid in accumulating l-glutamic acid in biotin-sufficient medium. The effect was exceedingly subject to the influence of the addition time of the ester, and this was observed also on the growth curve of Brev. lactofermentum. Changes of the growth curve caused by the varied addition time of the ester corresponded to those by the concentration of biotin in the medium that did not contain Tween 60. The patterns of fermentation course in the two corresponding conditions, such as biotin 3 μg/l and biotin 20 μg/l-Tween 60 mg/ml, agreed closely with each other. It seemed that identical cells were grown on the conditions. The only difference between the cells was observed as to the contents of intracellular biotin. Although l-glutamic acid was not accumulated by biotin-sufficient cells, cells with sufficient biotin and capable of accumulating l-glutamic acid were obtained in the presence of Tween 60, in which case the ester neither prevented the cells from taking up biotin nor controlled the level of intracellular biotin.     

l-Glutamic Acid Fermentation

It is well known that biotin has a marked effect on l-glutamic acid fermentation.

The authors have intended to find strains which are independent of the amounts of biotin in the culture medium. As a result, oleic acid-requiring mutants were obtained from a strain of Brevibacterium thiogenitalis which is an auxotroph for biotin. The growth of the mutant was remarkably stimulated by Tween 20, 40, 60, Ca ions and a small amount of corn steep liquor. And also, the mutant was found to have lost its requirement for biotin and showed growth response only to oleic acid or unsaturated fatty acids.

The effect of biotin, oleic acid and other unsaturated fatty acids on the production of l-glutamic acid was investigated by using an oleic acid-requiring mutant of Brevibacterium thiogenitalis No. 653. The results described in the present paper showed that the oleic acid-requiring mutant D-248 produced a large amount of l-glutamic acid in the excess biotin-contaming media, and that oleic acid seemed to be completely replaced by other unsaturated fatty acids such as palmitoleic acid and linoleic acid.     

l-Glutamic Acid Fermentation with Molasses

An l-glutamic acid (l-GA)-forming bacterium. Microbacterium ammoniaphium was cultured in the molasses medium with or without poiyoxyethylene fatty acid esters to obtain l-GA-accumulating cells or non-accumulating cells, respectively.

Then protoplast-like bodies (PLB) were prepared from each group of cells by reacting them with egg white lysozyme.

l-GA-accumulating reaction by the PLB was carried out under high and low osmotic pressures.

From the results of the experiment, it was shown that the difference in the ability of l-GA accumulation between l-GA-accumulating cells and non-accumulating cells was attributed mainly to the difference in the nature of the cell membrane.

Further, the relationship between the molar ratio of saturated fatty acids/unsaturated fatty acids which was reported previously and the nature of the membrane was discussed.

The lipid composition of the cell membrane from Microbacterium ammoniaphilum was determined by thin-layer and column chromatographies to make clear the relation between the extracellular accumulation of l-glutamic acid and the lipid in the cell membrane. When polyoxyethylene fatty acid ester was added to the beet medium and a large amount of l-glutamic acid was accumulated, the increase of the saturated fatty acid (C₁₆, C₁₈) in the neutural lipid fraction and the decreases of the phospholipid fraction and the unsaturated fatty acid $({\text{C}}_{18}^{1=})$ in the neutral lipid fraction were recognized.     

l-Glutamic Acid Fermentation with Molasses

When an l-Glutamic acid (l-GA)-forming bacterium, Microbacterium ammoniaphilum, was cultured in the molasses medium with the addition of penicillin to accumulate large quantity of l-GA extracellularly, no significant differences were observed in the phospholipid quantity and the fatty acid composition which were found between the l-GA-accumulating cells grown either in the molasses medium with addition of polyoxyethylene fatty acid ester (POEFE) or in the glucose medium with the addition of biotin.

Moreover, it was shown that, in the molasses-POEFE system, the amount of l-GA accumulated was nearly constant, independent of the extracellular osmotic pressure caused by the presence of NaNO₃ or β-alanine, while, in the molasses-penicillin system, the amount varied inversely to the osmotic pressure.

From these results, it is assumed that either chemical or mechanical process can eliminate the permeability barrier in the cell membrane, thus allowing the extracellular accumulation by l-GA-forming bacteria.     

Induction of Antibiotic Formation in Streptomyces sp. No. 362 by the Change of Cellular Fatty Acid Spectrum

Microorganisms which require oleic acid for the formation of antibiotics were screened. Streptomyces sp. No. 362, one of the selected organisms, produced antimicrobial substances only when oleic acid, palmitic acid or the high concentration of l-glutamic acid (or l-glutamine) was supplemented to the medium. The cellular fatty acid composition was changed by the supplement of these fatty acids, but not by l-glutamic acid (or l-glutamine). Antibiotic-producing cells had about 4 to 10 times larger amino acid pools, especially l-glutamic acid pool, and hexosamine pools. The ability for l-glutamate uptake of cells grown in the oleic or palmitic acid supplemented medium was markedly enhanced and the efflux of the accumulated l-glutamate was reduced. The antibiotic produced by this strain was identified as one of the streptothricin-group antibiotics and the role of these additives in the antibiotic formation is discussed.     

Change in Permeability to l-Glutamic Acid in the Glycerol Auxotroph GL-21

In this study, the mechanism of the extracellular accumulation of l-glutamic acid by the glycerol auxotroph was partially clarified. Whenever Corynebacterium alkanolyticum GL–21 (glycerol auxotroph) accumulated a large amount of l-glutamic acid in the fermentation broth, the content of its cellular phospholipids was not more than 50% of that of C. alkanolyticum No. 314 (prototroph).

Moreover, biotin, oleic acid or thiamine had no influence on the cellular phospholipid content of the auxotroph.

Under limited supply of glycerol, the efflux of l-glutamic acid in the auxotroph was extremely enhanced, but its enzyme activities participating in l-glutamic acid biosynthesis remained at the same level as those of the prototroph.

From the results, it is considered that the regulation of phospholipid content gave rise to the destruction of the permeability barrier to l-glutamic acid in the cell membrane.     

Studies on the Polymorphism of l-Glutamic Acid

The effects on the polymorphic crystallization of l-glutamic acid were examined of many substances including amino acids, inorganic salts, surface active agents, and sodium salt or hydrochloride of l-glutamic acid, when contained in the mother liquor.

The co-existence of amino acids, especially of l-aspartic acid, l-phenylalanine, l-tyrosine, l-lcucine and l-cystine contributed to the crystallization of l-glutamic acid in α-form, and these amino acid showed an inhibitory action on the transition of α-crystals as the solid phase in the aqueous solution, to β-crystals.

In the presence of a large amount of l-glutamate or the hydrochloride at the time of nucleation of l-glutamic acid, mostly β-crystals appeared even in the presence of the amino acids named above.     

Studies on Oxidation-Reduction Potentials (ORP) of Microbial Cultures

At maximum production of l-glutamic acid, the oxidation-reduction potential of the culture broth in l-glutamic acid fermentation showed a stable value of 9.0 to 9.6 as rH value. When biotin concentration in the medium was high (40γ/liter), the production of l-glutamic acid decreased, and the rH was 8.0 and it was out of accordance with that of the control (biotin-poor; 2γ/liter). Under “less-aerobic” conditions, its rH rose to 10.4.

From these results, it was concluded that the rH during maximum production of l-glutamic acid showed a stable value affected actively by the redox system, l-glutamic acid/α-ketoglutaric acid and      

Studies on Metabolism of Pyrrolidone Carboxylic Acid in Bacteria

The present investigation is concerned with l-glutamic acid production in the presence of pyrrolidone carboxylic acid and glucose in Bacillus megaterium st. 6126. This strain does not grow on dl-pyrrolidone carboxylic acid (dl-PCA)¹⁾ as the sole source of carbon and nitrogen. The optimal concentration of yeast extract required for the maximal production of l-glutamic acid was 0.005% under the conditions used. As the yeast extract concentration was increased, growth increased proportionally; but the l-glutamic acid production did not exceed the control’s to which glucose and ammonium chloride had been added. l-Glutamic acid produced by both growing cultures and resting cells was derived from glucose and ammonium salt of dl-PCA. Isotope experiments suggested that the l-glutamic acid produced was partially derived from ammonium salt of dl-PCA in the growing culture which had been supplemented with d-glucose-U-¹⁴C or dl-PCA-1-¹⁴C and that ammonium salt of dl-PCA was consumed as the source of nitrogen and carbon for l-glutamic acid.     

Studies on the Metabolism of d-Amino Acid in Microorganisms

It is confirmed by a new method for the determination of d-glutamic acid, that Aerobacter strain A rapidly metabolizes d-glutamic acid, while it only shows feeble metabolic activity towards l-glutamic acid when it is grown on a dl-glutamate-K₂HPO₄ medium. A specific d-glutamic oxidase is demonstrated in the cell-free extracts of Aerobacter strain A. This enzyme seems to be different from d-glutamic-aspartic oxidase obtained from Aspergillus ustus by the authors, since the former has no activity towards d-aspartic acid.     

l-Glutamic Acid Fermentation with Molasses

The relation between oleate and biotin to the extracellular accumulation of l-glutamate in Microbacterium ammoniaphilum was studied. And it was suggested that oleate was the essential constituent for the bacterial cell structure, and, at the same time, it participated in the cellular permeability of l-glutamate. On the other hand, biotin was recognized to play a role on the synthesis of cellular fatty acid, mainly oleate and palmitate. Through the discussion above mentioned, the reason was made clear that biotin was not necessary for the bacterial growth or the extracellular accumulation of l-glutamate, if oleate had been added.     

Isolation and Identification of O-Acetyl and 12-Hydroxyradiclonic Acids

An N-acetylglutamate-acetylornithine acetyltransferase-deficient arginine-requiring mutant AA–1, was derived from an l-arginine producer of Corynebacterium glutamicum. It accumulated a large amount (30 mg per ml) of l-glutamic acid and a small amount (1.2 mg per ml) of N^α-acetylornithine, an intermediate of arginine biosynthesis, in the culture medium.

The production of N^α-acetylornithine by AA–1 was not affected by the concentration of l-arginine in the medium, whereas that of l-glutamic acid was inhibited by a high concentration of l-arginine in the medium containing excess biotin.     

Polyethylene Glycol–Modified Papain Catalyzed Oligopeptide Synthesis from the Esters of l-Aspartic and l-Glutamic Acids in Benzene

Comparative studies were made of the polymerization of l-aspartic and l-glutamic acid dialkyl esters using polyethylene glycol–modified papain as a catalyst in phosphate buffer (pH 7.5) and in benzene. Changes in the substrate specificity of papain and in the composition of oligomerized products were observed. In the buffer, the diethyl and di-n-propyl esters of l-glutamic acid were sufficiently converted to high molecular weight oligomers with the accumulation of dimer and trimer, but l-aspartic acid esters were very poor substrates. In benzene, l-aspartic acid esters became more reactive than L-glutamic acid esters. In particular, from l-aspartic acid dimethyl ester the product, which was mainly composed of heptamer to decamer, was obtained in a 90% yield. The reaction in benzene required desalted substrates and a small amount of water to proceed extensively.     

Studies on the Low Temperature Fermentation

An attempt has been made to isolate the bacteria capable of accumulating amino acids during the growth at low temperature from various natural sources. A psychrophilic strain P 145 forming glutamic acid at 5°C was obtained and identified as a Brevibacterium sp. The bacterium grew in the range of 0° to 37°C and exhibited the optimum growth at 15°C. The bacterium was defined as a facultative psychrophile.

The strain strictly required methionine only at above 28°C; below this temperature it grew normally without the amino acid. When methionine was added thiamine and biotin stimulated the growth of this strain at 28°C.

With the Brevibacterium sp. P 145 isolated from soil, the effect of incubation temperature on the extracellular amino acid accumulation has been examined from cultural and enzymological points of view. The strain was found to accumulate l-glutamic acid up to 5.88 mg/ml and l-alanine 0.38 mg/ml at 5°C, whereas it formed 0.21 mg/ml of l-glutamic acid and 2.54 mg/ml of l-alanine at 28°C.

The accumulation of l-alanine in the medium at 28°C seemed to be related to the thiamine requirement of the strain. In the case of thiamine deficiency, l-alanine was the main product in the culture at 28°C. When the incubation temperature was abruptly shifted from 28° to 5°C or from 5° to 28°C, the amino acid accumulation was also changed to that of the final temperature. l-Alanine dehydrogenase existed even in the cells grown at 5°C but was not active at this low temperature. These results were in accord with the informations obtained from cultural experiments.     

Culture Conditions for the Production of l-Glutamic Acid from n-Paraffins by Glycerol Auxotroph GL-21

A novel process for the microbial production of l-glutamic acid on an industrial scale was successfully established by using a glycerol auxotroph.

The most suitable carbon source for producing L-glutamic acid was n-paraffins (C₁₃–C₁₅). The production of L-glutamic acid was not affected by a large amount of biotin or oleic acid in the absence of penicillin, and occurred maximally at the glycerol concentration of 0.02% at pH 6.6. The most effective temperature was 28°C.

Under optimal conditions in a 200 liter fermentor, the mutant produced 72 g/liter of L-glutamic acid. On the other hand, the parent produced 53 g/liter of L-glutamic acid in the presence of penicillin.

It is believed that the low productivity of L-glutamic acid by the parent strain was mainly due to the occurrence of the marked decrease in the viable cell counts at the later phase of the fermentation caused by the action of penicillin added.     

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.     

Studies on Metabolism of Pyrrolidone Carboxylic Acid in Bacteria

l-Glutamic acid was formed from d-, l-, and dl-PCA with cell-free extract of Pseudomonas alcaligenes ATCC-12815 grown in the medium containing dl-PCA as a sole source of carbon and nitrogen. The enzyme(s) involved in this conversion reaction was distributed in the soluble fraction within the cell and in 0.5 saturated fraction at the fractionation procedure with the saturation of ammonium sulfate. Optimum pH of this enzyme(s) lied at pH 8.5 and optimum temperature was 30°C. Cu (5 × 10^?3 m) inhibited the reaction considerably while Ca or Fe accelerated it. PALP (1×10^?3 m) also gave an enhanced activity to some extent. The enzyme preparation converted dextro-rotatory enan-thiomorph of PCA to its laevo-rotatory one which in turn was not converted to the opposite rotation direction by this enzyme. Furthermore, the preparation did not, if any, show d-glutamic acid racemase activity. Isotopic experiments with using dl-PCA-1-¹⁴C revealed that l-glutamic acid-1-¹⁴C was formed by the cleavage of –CO–NH– bond of pyrrolidone ring of PCA. It was concluded that dl-PCA when assimilated by the present bacterium is at first transformed to l-PCA by the optically isomerizing enzyme and subsequently is cleaved to l-glutamic acid probably by the PCA hydrolysing enzyme.