Chicken IL-6 is a heat-shock gene

The febrile response is elicited by pyrogenic cytokines including IL-6 in response to microorganism infections and diseases in vertebrates. Mammalian HSF1, which senses elevations in temperature, negatively regulates the response by suppressing pyrogenic cytokine expression. We here showed that HSF3, an avian ortholog of mammalian HSF1, directly binds to and activates IL-6 during heat shock in chicken cells. Other components of the febrile response mechanism, such as IL-1β and ATF3, were also differently regulated in mammalian and chicken cells. These results suggest that the febrile response is exacerbated by a feed-forward circuit composed of the HSF3-IL-6 pathway in birds.     

Purification of 7-Keto-8-aminopelargonic Acid-7,8-Diaminopelargonic Acid Aminotransferase,an Enzym Involved in Biotin Biosynthesis,from Brevibacterium divaricatum

Vitamin B₆ is synthesized by green Cytisus scoparius callus and green Phellodendron amurense callus cultured on Linsmaier and Skoog Agar-medium with 10^?5m of ±-naphthaleneacetic acid (NAA) and 10^?6 m of 6-benzyladenine (BA). Even when thiamine and inositol were omitted from this medium, the growth and vitamin B₆ content of Cytisus scoparius callus did not change. Vitamin B₆ contents of clones of the calluses varied and were unstable during long-term subculture. Clonal selection was repeated to obtain stable strains with high vitamin B₆ content, and the vitamin B₆ content of one strain of green Cytisus scoparius callus became 4-times higher than that of the green leaves.     

Metabolisms of Nucleosides in Bacteria

In this study, the authors developed a simplified method for the separation and the quantitative determination of nucleosides and bases, using paper electraophoretic technique. By this method, nucleosides and bases were well separated and determined in a fairly short time. Thus, this method was expected to be as accurate as the published methods and was believed to be a better method for both quantitative determination and detection of the nucleosides and bases in a large number of samples.     

Studies on Microbial Metabolisms of Sugar Nucleotides

Effects of various factors including incubation time, water content of airdried cells, concentration and pH of KH₂PO₄–K₂HPO₄ mixture, d-glucose concentration, MgSO₄ concentration, GMP concentration, cell concentration, aeration and various kinds of carbohydrates on the fermentative production of GDP-mannose, GDP and GTP from 5′-GMP by air-dried cells of baker’s yeast were investigated. The water content of air-dried cells was the most important factor in the fermentation. When the air-dried cells of baker’s yeast (100 mg/ml) were incubated with 5′-GMP (20 μmoles/ml), d-glucose (800 μmoles/ml), potassium phosphate buffer (360 μmoles/ml, pH 7.0), and MgSO₄ (20 μmoles/ml), 2-hr incubation gave GDP in 20% yield and GTP in 61.1% yield, GDP-mannose being produced in 45% yield after 8-hr incubation. The phosphorylation of 5′-AMP, 5′-dAMP, 5′-dGMP 5′-CMP and 5′-UMP was also observed in high yields under the same conditions.     

Microbial Formation of D-Pantothenic Acid-α-glucoside

The formation of D-pantothenic acid-α-glucoside (PaA-α-G) was found from D-pantothenic acid (PaA) and maltose in incubation mixtures of microorganisms, especially Saccharomyces yeasts and Sporobolomyces coralliformis IFO 1032. The reaction conditions were investigated for formation of PaA-α-G by resting cells of Spor. coralliformis. The formation of the compound increased with PaA concentration (3~20 mg/ml). The yield was maximum at 5~10 mg/ml of PaA. Cetyl trimethyl ammonium bromide (0.1 %) promoted the formation of PaA-α-G. Sucrose was the optimal α-glucosyl donor. When 30 mg/ml of sucrose was fed to the reaction mixture (initial sucrose, 100 mg/ml; and PaA, 10 mg/ml) at 12-hr intervals, 5.74 mg/ml (3.30 mg/ml as PaA) of PaA-α-G was formed in 48-hr incubation at 28°C with shaking. PaA-α-G was also formed by yeast α-glucosidase, mold maltase and the cell-free extract of Spor. coralliformis. The compound showed approximately 9~10% and 0.1~0.3% (molar ratio) of activity of PaA for Saccharomyces carlsbergensis ATCC 9080 and Lactobacillus plantarum ATCC 8014, respectively. The compound had the same microbiological activity as authentic 4′-O-(α-D-glucopyranosyl)-D-pantothenic acid.     

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.     

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.     

Ionophorous Properties of SY-1 (20-Deoxysalinomycin) in Rat Liver Mitochondri

SY-1 (20-deoxysalinomycin), a monocarboxylic polyether antibiotic closely related to salinomycin, caused a rapid release of previously accumulated alkali metal cations by valinomycin or monazomycin in rat liver mitochondria, and simultaneously reversed swelling of mitochondria.

With a strict specificity for substrate and cation, SY-1 exhibited a property of inhibiting mitochondrial functions such as substrate oxidation, oxidative phosphorylation and ATP hydrolysis induced by valinomycin or monazomycin, In comparative study with salinomycin, SY-1 was found to be more effective on the mitochondrial functions than salinomycin.

On the basis of the results so far obtained, the inhibitory effect of SY-1 on mitochondria is interpreted as a result of interaction with essential cations, especially with K⁺, in mitochondria.