Studies on Transglycosidation to Vitamin B6 by Microorganisms

Some properties of pyridoxine glucoside-synthesizing enzyme were studied using the partially and highly purified enzyme preparations from Micrococcus sp. No. 431.

The enzyme was stable at pH 7.0 and between 0°C and 30°C. The maximal activity was obtained at pH 8.0 and 37°C. Besides sucrose, phenyl-α-d-glucoside and maltose served as glucosyl donor. Of vitamin B₆ compounds tested, only pyridoxine served as glucosyl acceptor. The enzyme activity was inhibited by PCMB and heavy metal ions, and the inhibition was prevented by 2-mercaptoethanol, indicating the enzyme would be a sulfhydryl enzyme. The activity was not affected by chelating agents and not activated by metal ions.     

Moisture Sorption Isotherms of Various Tobaccos

The equilibrium moisture contents of sun-cured (Kroumougrad), flue-cured (Bright Yellow—4) and air-cured (Burley-21 and Matsukawa) tobaccos were measured over a relative humidity range from 5 to 80% at 20°C. The moisture sorption isotherms of tobaccos were of sigmoid type, and classified into two groups. In a lower humidity range below ca. 40% RH, the A group (Kroumougrad and BY-4) had a smaller moisture sorption capacity than B group (Burley-21 and Matsukawa), while in a higher humidity range above ca. 50% RH the former had a larger moisture sorption capacity than the latter. By extracting with water, the moisture content of BY-4 was increased in the lower humidity range, while it decreased in the higher humidity range. However, the moisture content of Matsukawa was scarecely changed by extracting it with water. These results suggest that the differences in equilibrium moisture content with the type of curing were due to the differences in contents of water soluble com- ponents. To control the hygroscopic properties of a tobacco, therefore, the influences of the addition of sucrose and glycerol on the equilibrium moisture content were quantitatively analysed. The moisture sorption capacity of tobacco was greatly different from its nitrogen sorption capacity. The specific surface area of tobacco calculated from moisture sorption isotherm was ca. 110 times larger than the specific surface area calculated from the nitrogen sorption isotherm. Both the nitrogen and moisture sorption data should be necessary for better understanding of the complicated sorption-desorption phenomena in tobaccos.     

Studies on Vitamin B6 Metabolism in Microorganisms

Escherichia freundii alkaline phosphatase was found in a membrane fraction and was purified by procedures involving spheroplast formation with lysozyme and EDTA, and DEAE-cellulose and Sephadex G-150 column chromatographies. Then this enzyme along with other phosphatases was investigated on the ability to transfer the phosphoryl group from p-nitrophenyl phosphate to pyridoxine. It was found that the ability of the transphosphorylation varied with these phosphatases. The transphosphorylation to hydroxy compounds such as alcohols, sugars and nucleosides was also compared. Escherichia freundii acid phosphatase showed the highest activity of transphosphorylation among phosphatases tested. The mechanism of transphosphorylation was discussed.

An enzyme, pyridoxamine 5′-phosphate transaminase, was purified from the cell-free extract of Clostridium kainantoi. The purification procedures involved ammonium sulfate fractionation, protamine sulfate treatment and, DEAE-cellulose, hydroxylapatite, DEAE-Sephadex and Sephadex G-200 column chromatographies. The purified enzyme, which had approximately 2700-fold higher specific activity over the original extract, showed a single schlieren pattern in the ultracentrifuge. From the spectral analysis, it seemed that pyridoxamine 5′-phosphate transaminase did not contain pyridoxal 5′-phosphate as a prosthetic group. It was recognized that the transamination was accelerated by the addition of amino acid and was inhibited by diisopropyl phosphofluoride. Glutamic acid formed in the reaction was identified to be a D-isomer. A study on the substrate specificity showed that the enzyme might be possible to be specific for pyridoxamine 5′-phosphate.

The extracellular formation of vitamin B₆ was searched in marine and terrestrial microorganisms. Two bacterial strains were selected and were identified as Vibrio and Flavobacterium, respectively. Marine microorganisms showed the considerable formation of vitamin B₆ and the presence of vitamin B₆ in sea water was also recognized. The cultural and reaction conditions for vitamin B₆ formation by these strains were investigated. Glycerol was commonly the most effective compound on vitamin B₆ formation among the compounds tested. It was suggested that both bacteria did not have the control system on vitamin B₆ biosynthesis by the amount of possible end products.     

Studies on the Metabolism of Pantothenic Acid in Microorganisms

The ability of the formation of coenzyme A from pantothenic acid and cysteine in the presence of AMP or ATP was searched in yeasts and bacteria. The result of screening showed that the activity was found in several yeasts and the bacteria belonging to the genera Sarcina, Corynebacterium and Brevibacterium. Particularly, Brevibacterium ammoniagenes IFO 12071 (ATCC 6871) accumulated a large amount of coenzyme A.

Isolation of the reaction products, which were synthesized by Brevibacterium ammoniagenes IFO 12071, were carried out. The isolates were identified as coenzyme A, dephosphocoenzyme A and phosphopantothenic acid.

The possibility for the formation of coenzyme A in a larger amount from pantothenic acid and cysteine was investigated with baker’s yeast under the condition coupled with ATP-generating system.

Effect of various factors affecting the accumulation of coenzyme A was investigated. Among them, glucose concentration and inorganic phosphorus concentration were the most important factors for its accumulation. Coenzyme A was not accumulated without the phosphorylation of AMP to ATP. Several cationic surfactants stimulated the accumulation of coenzyme A.

The amount of coenzyme A accumulated reached about 200 μg per ml of the reaction mixture under the suitable reaction conditions employed.     

Distribution of 7-Keto-8-aminopelargonic Acid Synthetase in Bacteria and the Control Mechanism of the Enzyme Activity

The 7-keto-8-aminopelargonic acid (KAPA) synthetase activities of cell-free extracts from various bacteria were investigated. The experiments on the substrate specificity of KAPA synthetase, using crude cell-free extracts from bacteria having high enzyme activity, showed that l-serine and pyruvic acid could replace l-alanine, but that, when the enzyme was partially purified, these compounds were not effective. Many kinds of amino acids such as l-cysteine, l-serine, d-alanine, glycine, d-histidine, and l-histidine, inhibited the enzyme activity. This inhibition was found to be competitive with l-alanine. Pyridoxal 5′-phosphate, which is a cofactor of the enzyme, also inhibited the enzyme activity at high concentrations. The repression of KAPA synthetase by biotin occurred in Bacillus subtilis and B. sphaericus but not in Micrococcus roseus and Pseudomonas fluorescens, even at a concentration of 1000 mµg per ml of biotin.     

Sedimentation Analysis of the Interacting Mixture of Dextran Sulfate and Low Density Lipoprotein

The reversible interaction between dextran sulfate (D) and the low density lipoprotein of human serum (P) was investigated by sedimentation velocity. Analysis of the velocity patterns of dextran sulfate—lipoprotein mixtures revealed that the maximum number of binding sites on dextran sulfate molecule is approximately 6. It was also shown that the species of the complex formed is affected by the mixing ratio of the two constituents: at the molar ratio (P/D) 0.69, the complex exists in average as DP_1.6 and at 0.98 as DP_2.2. The linear increment of sedimentation coefficient of the complex due to the binding of one lipoprotein molecule was 7.8S. Finally, the mechanism of precipitation of the complexes was discussed.     

Fatty Acid Metabolism in Microorganisms

The production of pimelic acid from azelaic acid by microorganisms was studied. About 100 strains of bacteria which were able to utilize azelaic acid as a sole carbon source were isolated from soil and other natural materials. Among these bacteria, several strains produced a large quantity of an organic acid (pimelic acid) from azelaic acid in their culture fluids during the cultivation. The acid was isolated from the culture fluid of strain A133 in crystalline form. The crystal was identified as pimelic acid by physicochemical and biological methods.

From the results of investigations on the morphological and physiological characters, the bacterial strain A133 was assumed to be Micrococcus sp.     

Distribution and Properties of NAD Phosphorylating Reaction

Distribution of NAD phosphorylating reactions, phosphorylation through NAD kinase and phosphotransferase, was investigated. NAD kinase activity was distributed rather widely in bacteria, whereas phosphotransferase activity with p-NPP and NAD was limited to a few genera. Proteus mirabilis showed strong activity of phosphotransferase besides NAD kinase activity.

Partial purification of the phosphotransferase was attempted. The enzyme preparation possessed phosphatase activity as well as phosphotransferase activity. Phosphorylation of NAD proceeded maximally under the conditions below pH 4.0. Cu²⁺ showed stimulating effect on the activity. Besides p-NPP and phenylphosphate, various nucleotides, especially 2′ (or 3′) isomers, served as excellent phosphoryl donors, and various kinds of nucleosides and nucleotides were phosphorylated to form nucleoside monophosphates and nucleoside diphosphates.     

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.