Sugar Specificity in the Induction and on the Activity of Streptomyces α-d-Galactosidases

The α-d-galactosidases of six Streptomyces strains were examined on their inducer susceptibility, substate specificity, and inhibitor susceptibility. In all strains examined, α-d-galactosidase was induced by d-galactose, but neither by d-fucose nor by l-arabinose. α-d-Fucosidase activity was always induced accompanying with α-d-galactosedase activity. β-l-Arabinosidase activity, however, was never observed. These α-d-galactosidases were purified to electrophoretically pure degree by successive ammonium sulfate and ethanol precipitation, and ion exchange and gel filtration chromatography. The purified preparations from six strains were different from each other in their chromatographic behaviors and in some physical properties, but they all showed strong α-d-fucosidase activity as well. The α-d-galactosidase activities were strongly inhibited by d-galactose and l-arabinose, but scarcely by d-fucose. On the other hand, their α-d-fucosidase activities were inhibited by d-fucose as well as by d-galactose and l-arabinose.     

Isolation and Identification of Ubiquinone 10 from Cultured Cells of Tobacco

Callus tissues were induced from stem and root segments of Rauwolfia serpentina. Growth and alkaloid production of the callus tissues were examined under various culture conditions. The growth was strikingly promoted in the presence of 2,4-D (0.5~1 ppm), kinetin (0.2~0.5 ppm) and yeast extract (0.1~0.2%). At favourable conditions, the growth value in 4 weeks’ culture was ca. 40 (F.W.), and ca. 25 (D.W.) for stem callus tissues, and ca. 15 (F.W.), and ca. 8 (D.W.) for root callus tissues. Stem and root callus tissues produced ajmaline and some other unidentified Rauwolfia alkaloids. The ajmaline content in root callus tissues was 10~20mg % and in stem callus tissues was 1~10mg %. The ajmaline production was strikingly reduced when 2,4-D concentration increased, or kinetin was omitted in the culture medium. Phytosterols including stigmasterol, β-sitosterol or cholesterol were also produced.     

Studies on Molecular Properties of αs1-κ-Casein Complex by the Hydrodynamical Methods

Some molecular properties of α_s1-κ-casein complex, α_s1- and κ-casein polymers were examined by gel filtration, ultracentrifugation, and viscometry at pH 7.1. The Stoke’s radii of α_s1-κ-casein complex, α_s1- and κ-casein polymers were 99, 44 and 108 Å, respectively. The molecular weight of the above proteins were approximately 45 × 10⁴, 10 × 10⁴ and 80 × 10⁴, respectively. The stokes radius of α_s1-κ casein complex reduced compared with that of κ-casein polymer and the molecular weight of the complex was about half that of κ-casein polymer. These results suggest that κ-casein polymer dissociates into 4 smaller particles when α_s1-κ-casein complex is formed. The frictional coefficient and Scheraga-Mandelkern constants for each protein suggest that the molecular shape of α_s1-casein polymer is globular and that of α_s1-κ-casein complex and κ-casein polymer is rod-like.     

Similarity between γ-Casein and a Product of β-Casein Hydrolysis by Milk Protease

A γ-casein-like fraction (FIV) was isolated from the β-casein A hydrolyzate by milk protease and compared with γ-casein. The mobility in polyacrylamide gel electrophoresis, sedimentation coefficient, molecular weight, amino acid composition and terminal amino acids of FIV were almost coincided with those of γ-casein. It is suggested that γ-casein is possibly a product of β-casein hydrolysis by milk protease.     

Properties of Glycomacropeptide and Para-K-casein Derived from Human K-Casein and Comparison of Human and Bovine K-Caseins as to Susceptibility to Chymosin and Pepsin

The nutritional efficiency of quinolinic acid as a substitute for nicotinic acid was investigated using weanling rats Of the Sprague Dawley strain (3-weeks old) fed a nicotinic acid-free, tryptophan-limited diet containing various amounts of nicotinic acid or quinolinic acid. Judging from the growth response, food efficiency ratio, levels of NAD activity in the blood, liver, brain and upper small intestine, and urinary excretion of niacin we have concluded that exogenous quinolinic acid is approximately 1/9 as active as nicotinic acid. As many foods contain quinolinic acid, dietary quinolinic acid cannot be ignored from the standpoint of tryptophan and nicotinic acid replacement.     

Fluorescence Polarization of αs1, κ-Caseins and αs1-κ-Casein Complex

Conjugates of α^s1-,κ-caseins and α^s1-,κ-casein complex were prepared with dimethylaminonaphthalenesulfonate and pyrenebutyrate. Their fluorescence lifetimes and the rotational relaxation times were measured by single photon counting technique and fluorescence depolarization technique, respectively. Both dimethylaminonaphthalenesulfonate and pyrenebutyrate conjugates had more than two lifetimes and the longer lifetime of pyrenebutyrate conjugates was near 140 nsec.

The rotational relaxation time of pyrenebutyrate α^s1-,κ-casein complex was smaller than that of pyrenebutyrate κ-casein polymer, which suggested that the complex formation of α^s1- and κ-casein polymers led to dissociation of the κ-casein polymer.

Changes of the rotational relaxation time as a function of weight ratio of α^s1- and κ-casein polymers (α^s1/κ) showed the specific variation and it was suggested that 4 moles of α^s1-κ-casein complex were formed from one mole of κ-casein polymer.     

Essential Regulation of Lung Surfactant Homeostasis by the Orphan G Protein-Coupled Receptor GPR116

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The role of cullin 5-containing ubiquitin ligases

The suppressor of cytokine signaling (SOCS) box consists of the BC box and the cullin 5 (Cul5) box, which interact with Elongin BC and Cul5, respectively. SOCS box-containing proteins have ubiquitin ligase activity mediated by the formation of a complex with the scaffold protein Cul5 and the RING domain protein Rbx2, and are thereby members of the cullin RING ligase superfamily. Cul5-type ubiquitin ligases have a variety of substrates that are targeted for polyubiquitination and proteasomal degradation. Here, we review the current knowledge on the identification of Cul5 and the regulation of its expression, as well as the signaling pathways regulated by Cul5 and how viruses highjack the Cul5 system to overcome antiviral responses.