Studies on Biosynthesis on Biotin by Microorganisms

The accumulation of biotin-vitamers in the culture media of a large number of microorganisms (about 700 strains) was studied. The contents of the biotin-vitamers were quantitatively determined by microbiological assays with Lactobacillus arabinosus and Saccharomyces cerevisiae.

It was found that large amounts of biotin-vitamers were accumulated by various microorganisms such as Streptomyces, molds and bacteria, and that the yield of biotin-vitamers was enhanced by the addition of pimelic acid or azelaic acid to the media. It was also found that the main portion of the vitamers accumulated by many microorganisms did not support the growth of Lactobacillus arabinosus, while it did support that of Saccharomyces cerevisiae. The small amounts of true biotin were observed in the culture media of various Streptomyces and molds, but hardly in the culture media of bacteria.

The identification of biotin-vitamers accumulated by various microorganisms is described, and the distribution of the vitamers in microorganisms is also described.

The results presented in this paper show that the main component of the vitamers accumulated by many microorganisms is identified as desthiobiotin by anion exchange column chromatography, paper chromatography and chemical analysis. Small amounts of fraction B (unidentified vitamers) and Fraction D (biotin) were also detected in the culture media of various molds and Streptomyces. However, these fractions were not observed in the culture media of any bacteria tested.

It was also found that large amounts of an unknown biotin-vitamer was accumulated by various bacteria. The vitamer was avidin-uncombinable, and, from the paper electrophoretic studies, it was assumed that the vitamer might be an analogue of pelargonic acid.     

Biosynthesis of Biotin-vitamers from Pelargonie Acid by Pseudomonas sp. Strain 393

The biosynthesis of biotin-vitamers from pelargonic acid by Pseudomonas sp. strain 393 was investigated. The main product of biotin-vitamers from pelargonic acid was desthiobiotin. The addition of streptomycin or l-alanine enhanced accumulation of desthiobiotin in culture fluid. Propionic, pimelic and azelaic acids were identified as main metabolites from pelargonic acid. When propionic acid was incubated with resting cells, pelargonic and azelaic acids were formed. The biosynthetic pathway of pelargonic acid to pimelic acid was also studied.     

The Controlling Action of Actithiazic Acid on the Biosynthesis of Biotin-vitamers by Various Microorganisms

By the addition of actithiazic acid, or acidomycin (ACM), to culture media, the accumulation of desthiobiotin by various microorganisms was enhanced from two-fold to about seventyfold, while that of biotin was markedly reduced. Especially, Bacillus sphaericus accumulated 350 μg per ml of biotin-vitamers assayed with Saccharomyces cerevisiae. ACM was not incorporated into the desthiobiotin molecule by resting cells of B. sphaericus. The amount of biotin-vitamers assayed with S. cerevisiae which was synthesized from pimelic acid by the resting cells grown with ACM was twice as great as that synthesized by the cells grown without ACM. From these results, the mechanism of the controlling action of ACM on biotin biosynthesis was discussed.     

Formation of Desthiobiotin from Oleic Acid by Brevibacterium sp.

Microbial formation of biotin-vitamers from oleic acid was investigated. Many strains of bacteria which were able to utilize oleic acid as a sole carbon source were isolated from soils and other natural materials. Among these bacteria, some strains formed a biotin-vitamer from oleic acid in the culture broth during the cultivation. The vitamer was purified from the culture broth of strain No. 23, and identified as desthiobiotin by chromatographical and biological methods.

From the results of investigation on the taxonomical characteristics, the bacterial strain No. 23 was assumed to be Brevibacterium sp.     

Biosynthesis of Biotin-vitamers from Glutaric Acid,a New Biotin Precursor

Biotin-vitamers were synthesized from glutaric acid by resting cells of certain strains of Agrobacterium. Pimelic acid, which has been known as a biotin precursor in many microorganisms, was not effective at all to this species. Optimum conditions for the biosynthesis of the vitamers by resting cells of Agrobacterium radiobacter IAM 1526 were investigated. L-Lysine was also effective, but the rate of the biosynthesis of biotin-vitamers from L-lysine was one-half that from glutaric acid. The vitamer synthesized was bioautographically identified as desthiobiotin. It was confirmed that ¹⁴C-labelled glutaric acid was incorporated into the desthiobiotin molecule.     

Studies on Biosynthesis of Biotin by Microorganisms

A biotinless mutant (K-681-UV-134) accumulated a large amount of desthiobiotin and an unknown biotin-vitamer in the culture medium.

The parent strain (K-681) of this mutant isolated from soil was identified as Bacillus cereus.

The unknown vitamer was accumulated at the early stage of the incubation in comparison with desthiobiotin.

The unknown vitamer was purified by the paper- and column-chromatographic methods from the culture filtrate. The purified vitamer gave a single spot when spraying with the ninhydrin reagent after paper chromatographing and its R_F values in several solvent systems were identical with those of authentic 7-keto-8-aminopelargonic acid.     

An early intermediate in the biosynthesis of biotin: Incorporation studies with [1,7-C(2)]pimelic acid

1. An unknown biotin vitamer was obtained in high yields in culture filtrates of Penicillium chrysogenum. 2. Production of this vitamer and desthiobiotin is controlled by the biotin concentration in the medium. 3. The unknown vitamer becomes labelled when the organism is grown in the presence of radioactive pimelic acid. 4. Chromatographic procedures were developed for the purification of the radioactive vitamer. 5. The vitamer is extremely stable in concentrated acid but gives rise to new vitamers under certain conditions. 6. The intermediate role of this vitamer in the synthesis of biotin is discussed.     

Studies on Production of Biotin by Microorganisms

The utilization of hydrocarbons by microorganisms was studied in many fields, but the production of biotin vitamers by hydrocarbon-utilizing bacteria has never been reported.

We have screened many hydrocarbon-utilizing bacteria which produce biotin vitamers in the culture broth. The effects of cultural conditions on biotin vitamers production by strain 5–2, tentatively assigned to the genus Pseudomonas, were studied.

More than 98% of biotin vitamers produced from hydrocarbons by strain 5–2 was chromatographically determined as desthiobiotin. As nitrogen source, natural nutrients were more effective than inorganic nitrogen sources. The production of biotin vitamers was increased under the condition of good aeration. Exogenous pimelic or azelaic acid enhanced biotin vitamers production by strain 5–2.

The production of biotin vitamers from n-alkanes, n-alkenes or glucose by an isolated bacterium, strain 5-2, tentatively assigned to the genus Pseudomonas, was investigated. Among these carbon sources, n-undecane was the most excellent for biotin vitamers production.

The biosynthetic pathway of biotin vitamers, especially desthiobiotin, from n-undecane was also studied. It was found by thin-layer and gas-liquid chromatographical methods that pimelic and azelaic acids were the main acid components in n-undecane culture.

This result, together with previously reported enhancement of biotin vitamers production by these acids, suggests that pimelic and azelaic acids may be the intermediates of biotin vitamers biosynthesis from n-undecane.     

Studies on Biosynthesis of Biotin by Microorganisms

Conversion of desthiobiotin to biotin by various kinds of microorganisms such as molds, Streptomyces, bacteria and yeasts was studied. The results described in the present paper showed that various kinds of microorganisms converted desthiobiotin to biotin during the cultivation of these microorganisms.

The conversion product from desthiobiotin by these microorganisms was chromatographically identified as biotin. The relationship between the producibilities of desthiobiotin and biotin from pimelic acid, and biotin synthesis from desthiobiotin was also presented.     

The biosynthesis of biotin in growing yeast cells: The formation of biotin from an early intermediate

1. Yeast cells grown in the presence of an unknown radioactive biotin vitamer produced by Penicillium chrysogenum incorporated the vitamer into the newly synthesized biotin. 2. The biotin was isolated as the avidin–biotin complex and after hydrolysis the biological activity and radioactivity were shown to be coincidental. 3. The specific activity of the biotin was identical with that of the pimelic acid used in a previous investigation to label the unknown vitamer. 4. The role of the unknown biotin vitamer as an intermediate in biotin biosynthesis is discussed.     

Synthesis of Desthiobiotin from 7,8-Diaminopel-argonic Acid in Biotin Auxotrophs of Escherichia coli K-12

The synthesis of desthiobiotin from 7,8-diaminopelargonic acid (DAP) was demonstrated in resting cell suspensions of Escherichia coli K-12 bioA mutants under conditions in which the biotin locus was derepressed. The biosynthetically formed desthiobiotin was identified by chromatography, electrophoresis, and by its ability to support the growth of yeast and those E. coli biotin auxotrophs that are blocked earlier in the biotin pathway. Optimal conditions for desthiobiotin synthesis were determined. Desthiobiotin synthetase activity was repressed 67% when partially derepressed resting cells were incubated in the presence of 3 ng of biotin per ml. Serine, bicarbonate, and glucose stimulated desthiobiotin synthesis apparently by acting as sources of CO(2). The results of this study are consistent with an earlier postulated pathway for biotin biosynthesis in E. coli: pimelic acid --> 7-oxo-8-aminopelargonic acid --> DAP --> desthiobiotin --> biotin.     

Biosynthesis of Biotin in Microorganisms VI. Further Evidence for Desthiobiotin as a Precursor in Escherichia coli

Biotin auxotrophs were isolated from Escherichia coli K-12. One of the mutants was unable to grow on desthiobiotin and accumulated a large amount of a vitamer in medium when growing on an optimal concentration of biotin. The production of the vitamer was inhibited in the presence of an excess amount of biotin. The vitamer was identified as desthiobiotin on the basis of biological activities, avidin combinability, and chromatographic characteristics. The mutant lacked the ability to convert desthiobiotin to biotin. These results further support the hypothesis that desthiobiotin is a normal intermediate in the biosynthesis of biotin in E. coli.     

Biosynthesis of Desthiobiotin in Cell-free Extracts of Escherichia coli

Cell-free extracts of Escherichia coli were active in catalyzing the synthesis of a biotin vitamer from 7,8-diaminopelargonic acid. The vitamer was identified as desthiobiotin on the basis of its chromatographic and electrophoretic characteristics and its biotin activities for a variety of microorganisms. The reaction was stimulated five-fold by bicarbonate, suggesting that an "active CO(2)" was incorporated into the carbonyl carbon of desthiobiotin. The enzyme was demonstrable in a wild-type (K-12) and in all biotin mutants of E. coli that were tested, with the exception of a strain which was able to grow on desthiobiotin but not on diaminopelargonic acid. Furthermore, the enzyme was repressible by biotin in all of the strains tested. These results are consistent with the hypothesis that the biosynthesis of desthiobiotin from 7,8-diaminopelargonic acid is an obligatory step in the biosynthetic pathway of biotin in E. coli.     

Biosynthesis of biotin: synthesis of 7,8-diaminopelargonic acid in cell-free extracts of Escherichia coli

Cell-free extracts prepared from a biotin auxotroph of Escherichia coli were active in catalyzing the synthesis of 7,8-diaminopelargonic acid, an intermediate of the biotin pathway, from 7-oxo-8-aminopelargonic acid. The product was identified on the basis of its chromatographic characteristics and its biotin activities for biotin auxotrophs of E. coli. Enzyme activity was determined in a reaction coupled with the desthiobiotin synthetase system, which is required for the conversion of 7,8-diaminopelargonic acid to desthiobiotin, and by measuring the amount of desthiobiotin formed by microbiological assay. The reaction was stimulated by l-methionine and pyridoxal-5'-phosphate. l-Methionine could not be replaced by any other amino acids tested. Pyridoxamine and pyridoxamine-5'-phosphate were as active as pyridoxal phosphate. The enzyme, presumably an aminotransferase, was demonstrable in the parent strain of E. coli and all mutant strains tested with the exception of a strain which is able to grow on diaminopelargonic acid but not on 7-oxo-8-aminopelargonic acid. Furthermore, the enzyme was repressible by biotin. The results were consistent with the hypothesis that the biosynthesis of 7,8-diaminopelargonic acid from 7-oxo-8-aminopelargonic acid is an obligatory step in the biosynthetic pathway of biotin in E. coli.     

Studies on Degradation of d-Biotin by Microorganisms

During the course of our investigations on the metabolism of d-biotin by microorganism, it has been found that some strains of fungi belonging to the genera Rhodotorula, Penicillium and Endomycopsis, are able to degrade d-biotin oxidatively into various biotin vitamers. The present work was undertaken to characterize these vitamers. The vitamers formed were separated by the ion exchange column chromatography, into Fraction A (d-biotin sulfoxide), Fraction B (unknown vitamer II), Fraction C (d-biotin) and Fraction D (unknown vitamer I). Rf values of vitamer I and vitamer II were found to be different from those of the known biotin vitamers. The vitamers I and II did not support the growth of Lactobacillus arabinosus and Saccharomyces cerevisiae, but did support that of Bacillus subtilis. This degradation reaction occurred rather favorably in high aerobic condition.     

Synthesis of 7-oxo-8-aminopelargonic acid, a biotin vitamer, in cell-free extracts of Escherichia coli biotin auxotrophs

The enzymatic synthesis of 7-oxo-8-aminopelargonic acid (7-KAP) from pimelyl-coenzyme A and l-alanine was demonstrated in cell-free extracts of a biotin mutant of Escherichia coli K-12 which excretes only 7-KAP into the growth medium. This biotin vitamer was identified by its chromatographic and electrophoretic properties. The enzyme (7-KAP synthetase) was repressed when the organism was grown in biotin concentrations greater than 0.2 ng/ml. The parent strain and members of other mutant groups that excrete 7-KAP, in addition to other vitamers, also exhibited synthetase activity. A mutant group that failed to excrete 7-KAP was further sub-divided into three groups, one of which lacked synthetase activity. These results are discussed in relation to a previously proposed scheme for biotin biosynthesis in which the formation of 7-KAP is considered the point of entry for pimelic acid into the biotin pathway.     

Biotin-vitamer Formation from Salicylic Acid by Pseudomonas sp.

Biotin-vitamer formation from salicylic acid was investigated. Strains of Pseudomonas sp., No. 102 and No. 362, isolated from soil samples utilized well salicylic acid as a sole source of carbon, and formed biotin-vitamers in culture broth. The metabolites were partially purified by the methods of active carbon adsorption and anion-exchange column chromatography, and clarified as desthiobiotin, bisnordesthiobiotin and 7-keto-8-aminopelargonic acid.     

Studies on Utilization of Hydrocarbons by Yeasts

The production of microbial cell substances from hydrocarbons has been attracting attention of people for many years. Production of bacterial cell from hydrocarbons is disadvantageous because of the difficulty in separating cell from the broth.

We have tested hydrocarbon-utilizing yeasts isolated from garden soil for cell production. The effect of medium composition on yeast growth and the utilization of individual hydrocarbon by yeast, strain Y-3, were investigated.

As a nitrogen source, urea was more effective than ammonium nitrate. When a very smal! amount of corn steep liquor was added, yeast growth was very improved. Aliphatic series of hydrocarbon lower than C₉ were not or very slightly assimilated by this yeast.

Generally speaking, series of even-number hydrocarbons were more effective than those of odd-number hydrocarbons.

We found that the yeast Y-3 strain reported in the previous paper¹⁾ has a diterminal oxidation system of hydrocarbon.

This yeast capable of growing in mineral-salts solution with hydrocarbons as sole source of carbon produced a series of dioic acid from n-undecane. These acids are 1,11-undecane dioic acid, 1,9-nonane dioic acid (azelaic acid), 1,7-heptane dioic acid (pimelic acid) and 1,5-pentane dioic acid (glutaric acid). 1,10-Decane dioic acid (sebacic acid) was also isolated from n-decane cultures.

Azelaic acid was partially transformed into pimelic acid and glutaric acid by treating it with resting cells of this yeast.

1,11-Undecane dioic was also transformed into azelaic acid pimelic acid, and glutaric acid by the same treatment as described above.     

Effect of water soluble vitamins and their analogues on the growth of candida albicans. I. Biotin,pyridoxamine, pyridoxine and fluorinated pyrimidines

Summary C. albicans showed an absolute dependency for biotin in shaker cultures in a basal mineral synthetic medium free of vitamin-precursors and vitamin-sparing amino acids. Diminished growth activity was observed with biotin sulfone and biotin diamine sulfate, but not with biocytin, N-biotinyl--alanine, N-biotinyl-L-aspartic ethyl ester, D-desthiobiotin or biotin-D-sulfoxide. The ability of the organism to utilize desthiobiotin indicates that its block in biosynthesis of biotin occurs at a step prior to desthiobiotin biosynthesis. Pyridoxamine and pyridoxine were both highly growth stimulatory at 1000 and 2056 µg/ml but not in the vitamin range at 1 to 10 µg/ml. Since desoxypyridoxine compounds failed to inhibit growth in the absence of B₆, it was concluded thatC. albicans has no dependency for vitamin B₆, although it actively metabolizes it. Pyridoxamine shortened the lag phase of the organism and reversed the toxicity of 5-fluorouracil and 5-fluoro-2-deoxyuridine, pointing to a new role of vitamin B₆ in nucleic acid metabolism of the organism. Inhibition indices for pyridoxamine and pyridoxine versus FU and FUDR were inconstant, indicating that the antagonism with the fluoropyrimidines was non-competitive in nature and the B₆ competes with these compounds at more than one site on the cell.     

Studies on the biosynthesis of biotin. Production of biotin and biotin-like compounds by a pseudomonad

1. Filtrates from cultures of a strain of Pseudomonas aeruginosa, grown in a basal glucose-ammonium chloride-vitamins-salts medium, possessed biotin activity as detected by microbiological assays. Exponential-phase culture filtrates contained biotin and desthiobiotin in the approximate ratio 1:3, with smaller amounts of biotin sulphoxide and three unidentified compounds with biotin activity. 2. The addition of malonate, adipate or pimelate to the basal medium stimulated the production of compounds with biotin activity; this effect was enhanced when these compounds were included in the medium as the major carbon source. Succinate, glutarate, suberate, fumarate or oxaloacetate did not stimulate the production of compounds with biotin activity. The ratio of biotin to desthiobiotin in filtrates from cultures grown in medium containing malonate as the carbon source was about 1:1. Experiments in which mixtures of malonate and pimelate were included in the medium as the carbon sources showed that these acids probably make a similar contribution in biotin biosynthesis. 3. A number of heterocyclic compounds, including several containing the ureido group (-NH-CO-NH-), were included in the basal medium but none of them stimulated the production of compounds with biotin activity to any marked degree. 4. Several amino acids, particularly cysteine (or cystine) and lysine, when added individually as supplements to the basal medium, stimulated the production of compounds with biotin activity. Filtrates from cultures grown in medium supplemented with cysteine contained approximately equal proportions of biotin and desthiobiotin. A much greater stimulation in the production of compounds with biotin activity was obtained when certain amino acids were included in the medium as the major source of nitrogen or carbon and nitrogen; ornithine, citrulline and argininosuccinate had the most marked effect. The ratio of biotin to desthiobiotin in filtrates from these cultures was usually greater than in filtrates from cultures grown in basal medium. 5-Aminovalerate also caused some stimulation when used as the nitrogen source, but urea was inactive. The effect of binary mixtures of certain amino acids was also examined. 5. The results are discussed in relation to the possible role of the stimulatory compounds during biotin biosynthesis.