Production of l-Tryptophan by Azaserine-resistant Mutants of Brevibacterium flavum

Azaserine-resistant mutants derived from a 5-fluorotryptophan-resistant, l-tryptophan-producing mutant of Brevibacterium flavum, accumulated 10.3 g/liter of l-tryptophan at maximum. The production increased to 11.4 g/liter when l-serine was added. In the mutant, only anthranilate synthase among enzymes of the tryptophan-specific bio synthetic pathway increased in activity to a 2-fold higher level than that in the parent strain, No. 187. Sensitivity of anthranilate synthase to the feedback inhibition was not altered by the mutation. Activity of 3-deoxy-d-arabino-heptulosonate 7-phosphate synthase, the first common enzyme for aromatic amino acid biosynthesis, also increased 2.7-fold and was less sensitive to the feedback inhibition by phenylalanine and tyrosine. Tryptophan transport activity in strain A-100 was similar as that in the parent. Azaserine inhibited anthranilate synthase activity by 50% at 0.075 mm. The inhibition was of a mixed type with respect to both the two substrates. Anthranilate synthase of strain A-100 was inhibited in a similar manner to that of the parent.     

Tryptophan Synthase and Production of l-Tryptophan in Regulatory Mutants

A 5-fluorotryptophan-resistant mutant of Brevibacterium flavum, No. 187, accumulated 2.6 g of indole 3-glycerol (InG) in addition to 8.0 g of l-tryptophan per liter in the culture medium. The addition of l-serine to the medium decreased the accumulation of InG and increased that of l-tryptophan up to a concentration of 10.3 g/liter, while the addition of l-tryptophan increased the InG accumulation, suggesting that InG was formed by hydrolysis of indole 3-glycerol phosphate (InGP), the substrate of tryptophan synthase (TS) which catalyzed the final step reaction of tryptophan biosynthesis. Then, in order to examine the mechanism of the InG accumulation, TS was purified from tryptophan auxotroph, TA-60. The reaction mechanism of TS was Ordered Bi Bi with Km’s of 0.63 and 0.038 mm for serine and InGP, respectively. Tryptophan, a product of the TS reaction, inhibited TS competitively with respect to serine and the Ki for tryptophan was estimated to be 2.0 mm. On the other hand, anthranilate synthase (AS), the first enzyme in the tryptophan biosynthetic pathway, was much less sensitive to the feedback inhibition by tryptophan in strain No. 187 than in the wild strain. The tryptophan concentration giving 50% inhibition of AS in strain No. 187 was estimated to be 2.4 mm, almost comparable to that of TS, 7.7 mm. From these results, it was concluded that the accumulation of InG in strain No. 187 would result from the product inhibition of TS by the tryptophan accumulated.     

l-Tryptophan Production by Achromobacter liquidum

The heat resistance and growth possibilities of various members of the Micrococcaceae in egg yolk and egg yolk with added salt were determined. Egg yolk alone protected members of the Micrococcaceae considerably against heat. Whereas in water Staphylococcus aureus S6 had a decimal reduction time (D) value of 66 s at 55 degrees C, its D value in egg yolk at the same temperature was 246 s. In salted egg yolk (water activity, 0.95), S. aureus S6 had a D value of 180 s at 66 degrees C and was largely inactivated during the pasteurization processes currently applied. Micrococcus saprophyticus and S. epidermidis (D value of each under the same conditions, 390 s) could survive such treatments to a certain extent and can thus spoil commercial egg yolk.     

L-Tyrosine Production by Analog-resistant Prototrophic Mutants of Glutamic Acid Producing Bacteria

p-Fluorophenylalanine (PFP) and m-fluorophenylalanine were the most effective inhibitors on the growth of Corynebacterium glutamicum ATCC 13032 among the analogs of phenylalanine and tyrosine tested. Their inhibitory effects were released by L-phenylalanine, and slightly by L-tyrosine and L-tryptophan. 3-Aminotyrosine (3AT), p-aminophenylalanine, o-fluorophenylalanine, and β-2-thienylalanine were weak inhibitors.

Resistant mutants of C. glutamicum isolated on the medium containing both PFP and 3AT or PFP and L-tyrosine were found to accumulate both L-tyrosine and L-phenylalanine, while resistant mutants isolated on the medium containing only PFP were found to produce only L-phenylalanine. Resistant mutants from other glutamic acid producing bacteria isolated on the medium containing both PFP and 3AT or both PFP and L-tyrosine were found to accumulate L-tyrosine and L-phenylalanine.     

Enzymatic Production of l-Tryptophan from l- and dl-5-Indolyl-methylhydantoin by Newly Isolated Bacterium

Bacteria which can hydrolyze dl-5-indolylmethylhydantoin to l-tryptophan were isolated from various soils. The dl-5-indolylmethylhydantoin-hydrolyzing enzymes were found to be inducible and intracellular. With intact cells, 50 mg/ml as wet base, of newly isolated bacterial strain T-523, 10 mg/ml of dl-5-indolylmethylhydantoin dissapeared and 7.4 mg/ml of l-tryptophan in a molar yield of 82% was produced after 35 hr incubation. Tryptophan produced was confirmed to be l-form regardless of the stereoisomer of the substrates used. A mechanism of asymmetric hydrolysis of dl -5-indolyImethylhydantoin was discussed.     

Fermentative Production of l-Glutamine by Sulfaguanidine Resistant Mutants Derived from l-Glutamate Producing Bacteria

Excellent l-glutamine producers were screened for among sulfaguanidine resistant mutants derived from the wild type l-glutamic acid-producing bacteria, Brevibacterium flavum, Brevibacterium lac to fermentum, Corynebacterium glutamicum and Microbacterium ammoniaphilum.

The best strain, No. 1~60, was a sulfaguanidine resistant mutant derived from B. flavum 2247 by mutation. Strain No. 1~60 accumulated 41.0 mg/ml of l-glutamine after 48 hr of cultivation from 10% glucose as a carbon source. This yield was the highest among those so far reported.

The addition of Mn^{2 +} (2 ppm) to the standard medium for B. flavum 2247 decreased the l- glutamine production and increased the l-glutamic acid excretion markedly. On the contrary, strain 1 —60 was not affected the Mn²⁺ (2 ppm) addition at all.

Glutamate kinase activity and the intracellular content of ATP in sulfaguanidine resistant mutant No. 1~60 were higher than those in the parent strain, B. flavum 2247.

It was confirmed that the increase in glutamate kinase and the increase in internal ATP, which were important for the l-glutamine synthesis, were very effective for the improvement of l-glutamine-producing mutants.     

Excretion of l-Tryptophan by Analogue-resistant Mutants of Pseudomonas hydrogenothermophila TH-1 in Autotrophic Cultures

Cells of a thermophilic hydrogen bacterium, Pseudomonas hydrogenothermophila TH-1 were treated with N-methyl-N′-nitro-N-nitrosoguanidine and resulting mutants resistant to tryptophan analogues were selected under autotrophic culture conditions (energy source, H₂; carbon source, CO₂). A mutant strain, 7922, which was resistant to 2000 µg/ml of 5-methyltryptophan and 200–500 µg/ml of 5-fluorotryptophan, was obtained by two step mutations. This mutant excreted 38–70 µg/ml of tryptophan into flask culture broth and a maximum of 200 µg/ml into jar fermentor broth.     

Production of L-Tryptophan by 5-Fluorotryptophan Resistant Mutants of Bacillus subtilis

The growth of Bacillus subtilis TR–44, a prototrophic transductant from one of inosine producers, was completely inhibited by 200 µg/ml of 5-fiuorotryptophan, a tryptophan analogue, and the inhibition was reversed by the addition of L-tryptophan.

Several mutants resistant to 5FT* produced L-tryptophan in the growing cultures. The best producer, strain FT–39, which was selected on a medium containing 1500 µg/ml of 5FT, produced 2 g/liter of L-tryptophan, when cultured in a medium containing 8% of glucose but without any tryptophan precursors. In this mutant, anthranilate synthetase, a key enzyme of the tryptophan biosynthesis, had increased over 280-fold, presumably owing to a genetic derepression. From FT–39, mutants resistant to 7000 µg/ml of 5FT were derived. Among them, strain FF–25 produced 4 g/liter of L-tryptophan, twice as much as did the parental strain. Since this strain produced large amount of L-phenylalanine as well as L-tryptophan, the genetic alteration seemed to be involved in some metabolic regulation of common part of the aromatic amino acid biosynthetic pathway.

Further, some auxotrophs derived from these 5FT resistant mutants produced more L-tryptophan than did the parental strains.

Relationships between the accumulation of L-tryptophan and the regulation mechanisms of the L-tryptophan biosynthesis were discussed.     

Production of l-Valine by 2-Thiazolealanine Resistant Mutants Derived from Glutamic Acid Producing Bacteria

Potent l-valine producers were screened among 2-thiazolealanine resistant mutants derived from three typical l-glutamic acid producing bacteria: Brevibacterium lactofermentum, Corynebacterium acetoacidophilum, Arthrobacter citreus. By strain No. 487, the best producer derived from Brevibacterium, 31 mg/ml of l-valine was produced after 72 hr when 10% glucose was supplied as a carbon source, thus giving the yield of 31% from glucose. Accumulation of the other amino acids was negligible. The addition of l-isoleucine and l-leucine in the culture medium did not reduce the l-valine production, indicating that the l-valine biosynthesis is insensitive to these end products in the l-valine producer.     

Production of L-Tryptophan by Sulfonamide-resistant Mutants

Sulfaguanidine-resistant mutant S-225, derived from a tryptophan-producing 5-fluoro-tryptophan-resistant mutant of Brevibacterium flavum, accumulated 19 g/liter of L-tryptophan at maximum when cultured for 72 hr in a medium containing 13% glucose as carbon source, 1.8-fold higher than did the parent. Strain S-225 accumulated 17 g/liter of L-tryptophan in a medium containing 10% sucrose as carbon source (17% yield based on the sugar). It also accumulated 450 mg/liter of chorismate, an intermediate common to the biosyntheses of tryptophan and p-aminobenzoate. The accumulation was 1.7-fold higher than that by the parent, suggesting that the intracellular concentration of chorismate was increased through acquisition of the sulfaguanidine resistance. Sulfaguanidine-resistant mutants were also derived from a tryptophan-producing mutant of Corynebacterium glutamicum. The mutants showed 2.2-fold higher maximum tryptophan production than did the parent.     

Production of l-Threonine by Analog-resistant Mutants

Mutants resistant to α-amino-β-hydroxyvaleri0c acid (AHV) were derived from various bacteria which belong to Corynebacterium, Brevibacterium, Arthrobacter, Microbacterium, or Bacillus by mutational treatment with N-methyl-N′-nitro-N-nitrosoguanidine(NTG), and screened for their ability to produce l-threonine. A number of l-threonine producers were obtained from each group of bacteria. Among them, the mutants derived from C. glutamicum KY9159(Met^?) were further mutagenized with NTG to derive thialysine(S-Lys)-resistant mutants. An AHV-resistant mutant, KY10484 was proved to be much more sensitive to the growth inhibition by thialysine than the parent strain, KY9159. From KY10484, a number of AHV- and thialysine-resistant mutants were derived. Approximately a half of these mutants were found to produce more l-threonine than KY10484. Among these mutants, KY10440 (Met^?, AHV^R, s-Lys^R) was used to investigate the cultural conditions for l-threonine production. The growth of KY10440 decreased largely with addition of l-homoserine, a threonine precursor. l-Asparagine, l-cystine, l-glutamine or l-arginine partially reversed the inhibitory effect of l-homoserine. Addition of these amino acids at low level led to increase l-threonine production. The amount of l-threonine accumulation reached to a level of 14mg/ml with a medium containing 10% glucose and to a level of 10 mg/ml with a medium containing 5% molasses (as glucose).

Another AHV- and thialysine-resistant mutant, KY10251 which was also derived from KY9159 was found to produce both 9 mg/ml of l-threonine and 5.5 mg/ml of l-lysine in a culture broth.     

Competitive Exclusion of Epiphytic Bacteria by IcePseudomonas syringae Mutants

The growth of ice nucleation-active and near-isogenic ice nucleation-deficient (Ice) Pseudomonas syringae strains coexisting on leaf surfaces was examined to determine whether competition was sufficient to account for antagonism of phylloplane bacteria. The ice nucleation frequency spectra of 46 IceP. syringae mutants, obtained after mutagenesis with ethyl methanesulfonate, differed both quantitatively and qualitatively, but the mutants could be grouped into four distinct phenotypic classes. The numbers of ice nucleation-active bacteria and ice nuclei active at -5 degrees C were reduced on plants colonized with IceP. syringae mutant strains before challenge inoculations with an IceP. syringae wild-type strain. Frost injury to plants pretreated with IceP. syringae strains was also reduced significantly compared with that to control plants and was correlated with the population size of the IceP. syringae strain and with the numbers of ice nuclei active at -5 degrees C. An IceP. syringae strain colonized leaves, flowers, and young fruit of pears in field experiments and significantly reduced the colonization of these tissues by IceP. syringae strains and Erwinia amylovora as compared with untreated trees.     

Acetate Production by Methanogenic Bacteria

Methanosarcina barkeri MS and 227 and Methanosarcina mazei S-6 produced acetate when grown on H₂-CO₂, methanol, or trimethylamine. Marked differences in acetate production by the two bacterial species were found, even though methane and cell yields were nearly the same. M. barkeri produced 30 to 75 μmol of acetate per mmol of CH₄ formed, but M. mazei produced only 8 to 9 μmol of acetate per mmol of CH₄.     

Production of l-DOPA by Mutants of Pseudomonas melanogenum

Several kinds of mutants of Pseudomonas melanogenum were derived by mutational treatment with N-methyl-N’-nitro-N-nitrosoguanidine, and selected for 3,4-dihydroxyphenyl-l-alanine (l-DOPA) production by newly devised screening method which was carried out on agar plates based on violet-black colour formation by the reaction of l-DOPA with iron ion. Mutants tested were; glucose-insensitive mutant, cysteine-insensitive mutant, 3-amino-tyrosine-resistant mutant and p-fluorophenylalanine-resistant mutant. Some colonies isolated by monocolony procedure without mutagenic treatment were also tested. Among the 3-aminotyrosine-resistant mutants many good l-DOPA producers were found.

An 3-aminotyrosine-resistant mutant, strain ATN–36, produced 14 to 15 mg/ml of l-DOPA from 26 mg/ml of l-tyrosine (68 % in molar conversion ratio). When the cell concentration in reaction mixture was increased to 4-times the concentration of culture broth, l-DOPA production reached to 21 mg/ml from 52 mg/ml of tyrosine. An enzymatic basis of the high l-DOPA productivity of the improved mutants was found to be due to the increased tyrosinase activity (150 to 160% of the parental strain) of the mutants.     

Antibiotic Production by Anaerobic Bacteria

Soils from aerobic and anaerobic sources were investigated for the possible presence of bacteria which produce antibiotics under anaerobic conditions of growth. The screening techniques devised for this study yielded 157 soil bacteria which, during anaerobic growth, produced antibiotic activity against aerobic test bacteria.

Studies on choice of media, presence of oxygen, and changes in antibiotic activity during growth indicated that representative strains of these bacteria produced mixtures of antibiotics. The activity was heat labile.

     

L-Asparaginase Production by Various Bacteria

Of 123 species of bacteria surveyed for L-asparaginase synthesis, Erwinia aroideae NRRL B-138 provided the highest yields.