Relation between Fatty Acid Composition of Cellular Phospholipids and the Excretion of L-Glutamic Acid by a Glycerol Auxotroph of Corynebacterium alkanolyticum

Relation between fatty acid composition of cellular phospholipids and the excretion of L-glutamic acid was investigated using Corynebacterium alkanolyticum GL–21 (a glycerol auxotroph).

When grown on n-hexadecane, the proportion of unsaturated fatty acids was higher in L-glutamic acid-accumulating cells than in L-glutamic acid-nonaccumulating cells. When grown on fructose or acetic acid, the reverse relation was observed. Moreover, cells containing no oleic acid produced L-glutamic acid from n-pentadecane.

These results suggest that the membrane permeability to L-glutamic acid is not always controlled by the cellular content of unsaturated fatty acids.     

Extracellular Accumulation of Phospholipids,UDP-N-Acetylhexosamine Derivatives and L-Glutamic Acid by Penicillin-treated Corynebacterium alkanolyticum

The addition of penicillin to cells of Corynebacterium alkanolyticum No. 314 growing on n-paraffins medium caused the simultaneous excretion of phospholipids, UDP-N-acetylhexosamine derivatives and L-glutamic acid.

Among many antibiotics which inhibit cell wall synthesis, only the inhibitors of peptideglycan transpeptidase such as penicillin G and cephaloridine were effective for inducing the excretion of phospholipids, UDP-N-acetylhexosamine derivatives and L-glutamic acid, while the others promoted only the excretion of UDP-N-acetylhexosamine derivatives.

From the close relationship between the excretion of L-glutamic acid and the excretion of phospholipids, it was suggested that the action of penicillins and cephalosporins on the cell membrane resulted in the excretion of L-glutamic acid.     

Binding of Pepsin Inhibitor (S-PI) and Pepsin

Relation between cellular phospholipids and L-glutamic acid excretion was investigated using Corynebacterium alkanolyticum GL–21 (a glycerol auxotroph).

When strain GL–21 was cultured in glycerol-limited medium which contained n-hexadecane, acetic acid or fructose as carbon source, there occurred the limitation of cellular phospholipid content and the over-accumulation of L-glutamic acid in the broth. Two-dimensional thin-layer chromatograms provided evidence that both the parent and the mutant strains contained the same phospholipids such as cardiolipin, phosphatidylethanolamine, phosphadityl-glycerol, phosphatidylinositol and phosphatidic acid. Limited supply of glycerol to the mutant did not greatly alter the proportions of the individual phospholipids.     

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.     

Microbial Production of l-Glutamic Acid by Glycerol Auxotrophs

To establish a novel process for the production of l-glutamic acid from n-paraffins, a glycerol auxotroph GL-21, a new type mutant, was successfully obtained from Corynebacterium alkanolyticum No. 314 by treatment with N-methyl-N′-nitro-N-nitrosoguanidine. This auxotroph required glycerol for its growth regardless of the carbon source used.

At 72 hr, this mutant GL-21 produced about 40 mg/ml of l-glutamic acid from n-paraffins in the culture broth at 0.01 per cent addition of glycerol in the absence of penicillin.

A thiamine auxotroph, a biotin auxotroph and an oleic acid auxotroph were also obtained by a similar technique, but these auxotrophs were found to be inapplicable for the production of l-glutamic acid from n-paraffins.     

Relation between the Extracellular Accumulation of L-Glutamic Acid and the Excretion of Phospholipids by Penicillin-treated Corynebacterium alkanolyticum

The addition of penicillin (50 u/ml) to the cells of Corynebacterium alkanolyticum No. 314 growing on n-paraffins medium at the logarithmic growth phase was the most suitable for the extracellular accumulation of L-glutamic acid and the excretion of phospholipids.

The relation between the extracellular accumulation L-glutamic acid and the excretion of phospholipids in the presence of penicillin was very close and specific. The kinds of phospholipids excreted and their fatty acid components were the same as those of intracellular phospholipids.     

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      

Production of L-Isoleucine by AHV Resistant Mutants of Brevibacterium flavum

The growth of Brevibacterium flavum No. 2247A was inhibited by α-amino-β-hydroxy-valeric acid (AHV), and the inhibition was partially reversed by L-isoleucine.

AHV resistant strain ARI-129, which was isolated on a medium supplemented with 2 mg/ml of AHV, produced 11 g/liter of L-isoleucine.

No difference was observed in threonine dehydratase between No. 2247A and ARI–129. Homoserine dehydrogenase from ARI–129 was insensitive to the feedback inhibition by L-isoleucine and L-threonine.

O-Methyl-L-threonine resistant mutant, strain AORI–126, which was derived from ARI–129, produced 14.5 g/liter of L-isoleucine. Specific activity of threonine dehydratase from AORI–126 increased about two-fold higher than those from No. 2247A and ARI–129, whereas degree of inhibition of the enzyme by L-isoleucine was the same among three strains.

Among auxotrophic mutants derived from ARI–129, adenine and lysine auxotrophs produced more L-isoleucine than the parent did.

In the adenine auxotroph, L-isoleucine production was markedly reduced by the addition of excess adenine.     

Structure of Rugulovasine A,B and their Derivatives

Culture conditions for the preparation of cells containing high tyrosine phenol lyase activity were studied with Erwinia herbicola ATCC 21434. Adding pyridoxine to the medium enhanced enzyme formation, suggesting that it was utilized as a precursor of the coenzyme, pyridoxal phosphate. Glycerol plus succinic acid; amino acids, such as, DL-methionine, DL-alanine and glycine; and metallic ion, ferrous ion promoted enzyme formation as well as cell growth. Adding L-tyrosine, as inducer, to the culture medium was essential for enzyme formation. However, when large amounts of L-tyrosine were added, the enzyme formation was repressed by the phenol liberated from L-tyrosine. In fact, formation of the enzyme was enhanced by removing phenol during cultivation. L(D)-Phenylalanine or phenylpyruvic acid had a synergistic effect on the induction of enzyme by L-tyrosine.

Cells with high enzyme activity were prepared by growing cells at 28°C for 28 hr in a medium containing 0.2% L-tyrosine, 0.2% KH₂PO₄, 0.1% MgSO₄7H₂O, 0.001% FeSO_4·7H₂O, 0.01% pyridoxine-HC1, 0.6% glycerol, 0.5% succinic acid, 0.1% DL-methionine, 0.2% DL-alanine, 0.05% glycine, 0.1% L-phenylalanine and 120 ml/liter hydrolyzed soybean protein in tap water with the pH controlled at 7.5 throughout cultivation.     

Structure of the Hydrolyzed Product (F-2) Released from γ-Polyglutamic Acid by γ-Glutamyl Hydrolase YwtD of Bacillus subtilis

The structure of the hydrolyzed product (F-2) with a molecular mass of about 2 kDa released from γ-polyglutamic acid by the γ-glutamyl hydrolase YwtD of Bacillus subtilis was analyzed. The results showed that F-2 is an optically heterogeneous polymer consisting of D- and L-glutamic acid in an 80:20 ratio with D-glutamic acid on both the N- and C-terminal sides, suggesting that YwtD is an enzyme that cleaves the γ-glutamyl bond between D- and D-glutamic acid recognizing adjacent L-glutamic acid toward the N-terminal region.     

Bacterial Degradation of N-Lauroyl-L-valine

Studies were conducted on the degradation of N-lauroyl-L-valine by type cultured bacteria. Many strains could utilize sodium N-lauroyl-L-valinate as carbon and nitrogen sources for their growth. Metabolism of N-lauroyl-L-valine was investigated in detail using Ps. aeruginosa AJ2116. Laurie acid was identified by gas chromatography suggesting cleavage of N-acyl linkage in N-lauroyl-L-valine.

Laurie acid might be metabolized to capric acid (C₁₀) and caprylic acid (C₈) becuase the accumulated substances gave nearly identical peaks with those of authentic fatty acids on gas chromatograms. The experiment using N-lauroyl-L-valine (¹⁴C) indicated that ¹⁴CO₂ was produced as a final product. Valine was not detected because it might be metabolized very rapidly immediately after its release.

It was supposed that the enzymes or enzyme systems degrading N-lauroyl-L-valine might be constitutive from the experiment using two kinds of cells grown in the medium containing N-lauroyl-L-valine or nutrient broth.     

Production of l-Glutamic Acid from Hydrocarbon by Penicillin-resistant Mutants of Corynebacterium hydrocarboclastus

Penicillin-resistant mutants were derived from Corynebacterium hydrocarboclastus R-7. One of them produced 84 g/liter of l-glutamic acid from hydrocarbon, though its parent strain produced 26 g/liter.

The penicillin-resistant mutant had stronger activities of substrate consumption and oxygen absorption than the parent strain, and this was one of the reasons for the accumulation of a larger quantity of l-glutamic acid.

The interacellular content of phosphatidyl inositol mannoside (P.I.M) was related to the glutamate productivity, and the higher glutamate productivity of the penicillin-resistant mutant was supposed to be related to the remarkable diminution in the content of P.I.M.     

New Resolving Agents

Seven optical active 2-benzylamino alcohols were synthesized by reduction of N-benzoyl derivatives of L-alanine, L-valine, L-leucine, L-phenylalanine, L-aspartic acid, L-glutamic acid and L-lysine and applied for the resolution of (±)-trans-chrysanthemic acid. d-trans-Chrys-anthemic acid was obtained by resolution via the salts of 2-benzylamino alcohols derived from L-valine and L-leucine, while (?)-trans-chrysanthemic acid was prepared through the salts of the amino alcohols derived from L-alanine and L-phenylalanine.     

Accumulation of l-Glutamic Acid from Dibasic Carboxylic Acids by a Hydrocarbon Utilizing Bacterium

In order to know the substrate specificity in a hydrocarbon utilizing bacterium, the following materials were examined: n-alkanes, n-alkenes, monohydric alcohols, aldehydes, monobasic carboxylic acids, dihydric alcohols and dibasic carboxylic acids.

It was found that dibasic carboxylic acids were well utilized, and a great deal of l-glutamic acid was accumulated from them. Then suberic acid, which is C₈ dibasic carboxylic acid, was compared with n-dodecane in the effects of thiamine, penicillin, C/N ratio and substrate concentration on l-glutamic acid accumulation and cell growth.     

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.     

Cultural Conditions for l-Leucine Production by Strain No. 218, a Mutant of Brevibacterium lactofermentum 2256

The excellent l-leucine producing mutant No. 218, derived from a biotin requiring glutamic acid producing strain, is methionine and isoleucine auxotrophic. A suboptimum growth condition made by adding a limiting amount of isoleucine was necessary for the maximum production of l-leucine. On the other hand, methionine was indifferent to the productivity if sufficiently supplied for growth.

Biotin of more than 50 μg/liter caused the accumulation of l-leucine; less than 50 μg/liter, however, gave a drastic change in accumulation pattern from l-leucine to l-glutamic acid. Strain No. 218 produced 28 mg/ml of l-leucine after 72 hr cultivation when 13 % glucose was supplied as a carbon source, thus giving the yield of 21.6%.

Effects on l-leucine production of concentrations of inorganic salts, pH, temperature and aeration were also investigated.     

l-Glutamate Formation from Hydrocarbons by Microorganisms

Large quantities of l-glutamic acid from liquid paraffins by microorganisms were produced with an addition of penicillin to the growing culture, and the action of penicillin to the glutamate production was studied. One of main effects of penicillin seems to exist in the cellular permeability of l-glutamic acid.     

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 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.     

Production of L-Threonine by Mutants Resistant to Both α-Amino-β-hydroxyvaleric Acid and S-(2-Aminoethyl)-L-cysteine Derived from Brevibacterium flavum

Growth of Brevibacterium flavum FA-1-30 and FA-3-115, L-lysine producers derived from Br. flavum No. 2247 as S-(2-aminoethyl)-L-cysteine (AEC) resistant mutants, was inhibited by α-amino-β-hydroxyvaleric acid (AHV), and this inhibition was reversed by L-threonine. All the tested AHV resistant mutants derived from FA-1-30 accumulated more than 4 g/liter of L-threonine in media containing 10% glucose, and the best producer, FAB-44, selected on a medium containing 5 mg/ml of AHV produced about 15 g/liter of L-threonine. Many of AHV resistant mutants selected on a medium containing 2 mg/ml of AHV accumulated L-lysine as well as L-threonine, AHV resistant mutants derived from FA-3-115 produced 10.7 g/liter of L-threonine maximally. AEC resistant mutants derived from strains BB–82 and BB–69, which were L-threonine producers derived from Br. flavum No. 2247 as AHV resistant mutants, did not produce L-threonine more than the parental strains, and moreover, many of them did not accumulate L-threonine but L-lysine. Homoserine dehydrogenases of crude extracts from L-threonine producing AHV resistant mutants derived from FA–1–30 and FA–3–115 were insensitive to the inhibition by L-threonine, and those of L-threonine and L-lysine producing AHV resistant mutants from FA–1–30 were partially sensitive.

Correlation between L-threonine or L-lysine production and regulations of enzymatic activities of the mutants was discussed.