Salts and glycine increase reversibility and decrease aggregation during thermal unfolding of ribonuclease-A

Ribonuclease-A (RNase-A) has been a model for studying protein folding and unfolding. However, we show here that its unfolding at neutral pH is complicated by aggregation. Circular dichroism thermal scans showed that reversibility of RNase-A after heating is only about 63%. In accordance with this observation, native-polyacrylamide gel electrophoresis of the sample heated at 75 degrees C showed formation of soluble oligomers. Ammonium sulfate at 0.4 M caused about a 3 degrees C higher melting temperature and nearly complete reversibility, while glycine and NaCl at 0.4 M significantly increased reversibility and decreased aggregation without affecting melting temperature. These results demonstrate that aggregation makes thermal unfolding of RNase-A at least partially irreversible and salts and glycine increase reversibility and decrease aggregation.     

Thermal Inactivation and Product Inhibition of Aspergillus terreus CECT 2663 α-L-Rhamnosidase and Their Role on Hydrolysis of Naringin Solutions

The kinetics of thermal inactivation of A. terreus α-rhamnosidase was studied using the substrate p-nitrophenyl α-L-rhamnoside between 50°C and 70°C. Up to 60°C the inactivation of the purified enzyme was completely reversible, but samples of crude or partially purified enzyme showed partial reversibility. The presence of the product rhamnose, the substrate naringin, and other additives reduced the reversible inactivation, maintaining in some cases full enzyme activity at 60°C. A mechanism for the inactivation process, which permitted the reproduction of experimental results, was proposed. The products rhamnose (inhibition constant, 2.1 mM) and prunin (2.6 mM) competitively inhibited the enzyme reaction. The maximum hydrolysis of supersaturated naringin solution, without enzyme inactivation, was observed at 60°C. Hydrolysis of naringin reached 99% with 1% naringin solution, although the hydrolysis degree of naringin was only 40% due to products inhibition when the initial concentration of flavonoid was 10%. The experimental results fitted an equation based on the integrated Michaelis-Menten's, including competitive inhibition by products satisfactorily.     

NADP-Specific Glutamate Dehydrogenase from Alkaliphilic Bacillus sp. KSM-635: Purification and Enzymatic Properties

An NADP-specific glutamate dehydrogenase [L-glutamate: NADP⁺ oxidoreductase (deaminating), EC 1.4.1.4] from alkaliphilic Bacillus sp. KSM-635 was purified 5840-fold to homogeneity by a several-step procedure involving Red-Toyopearl affinity chromatography. The native protein, with an isoelectric point of pH 4.87, had a molecular mass of approximately 315 kDa consisting of six identical summits each with a molecular mass of 52 kDa. The pH optima for the aminating and deaminating reactions were 7.5 and 8.5, respectively. The optimum temperature was around 60°C for both. The purified enzyme had a specific activity of 416units/mg protein for the aminating reaction, being over 20-fold greater than that for deaminating reaction, at the respective pH optima and at 30°C. The enzyme was specific for NADPH (K_m 44 μM), 2-oxoglutarate (K_m 3.13 mM), NADP⁺ (K_m 29 μM), and L-glutamate (K_m 6.06 mM). The K_m for NH₄Cl was 5.96 mM. The enzyme could be stored without appreciable loss of enzyme activity at 5°C for half a year in phosphate buffer (pH 7.0) containing 2 mM 2-mercaptoethanol, although the enzyme activity was abolished within 20 h by freezing at ?20°C.     

Identification of the Blue Pigment Formed in a D-Glucose-Glycine Reaction System

D-Glucose (0.7 M), glycine (0.3 M), and sodium hydrogencarbonate (0.1 M) were dissolved in aqueous 30% ethanol at pH 8.0 and left at 50 °C for 4 d in a dark room under nitrogen displacement. The resulting blue pigment was isolated and purified from the blue solution by anionic exchange and gel filtration chromatography. This blue pigment, which is designated Blue-G1, was identified as 5-[1,4-bis-carboxymethyl-5-(2,3,4-trihydroxybutyl)-1,4-dihydropyrrolo[3,2-b]pyrrol-2-ylmethylene]-1,4-bis-carboxymethyl-2-(2,3,4-trihydroxybutyl)-4,5-dihydropyrrolo[3,2-b]pyrrol-1-ium. Blue-G1 had two symmetrical pyrrolopyrrole structures with a trihydroxybutyl group. Blue-G1 had a polymerizing activity, suggesting it to be an important Maillard reaction intermediate through the formation of melanoidins.     

Isolation and Characterization of Thermotolerant Gluconobacter Strains Catalyzing Oxidative Fermentation at Higher Temperatures

Thermotolerant acetic acid bacteria belonging to the genus Gluconobacter were isolated from various kinds of fruits and flowers from Thailand and Japan. The screening strategy was built up to exclude Acetobacter strains by adding gluconic acid to a culture medium in the presence of 1% D-sorbitol or 1% D-mannitol. Eight strains of thermotolerant Gluconobacter were isolated and screened for D-fructose and L-sorbose production. They grew at wide range of temperatures from 10°C to 37°C and had average optimum growth temperature between 30-33°C. All strains were able to produce L-sorbose and D-fructose at higher temperatures such as 37°C. The 16S rRNA sequences analysis showed that the isolated strains were almost identical to G. frateurii with scores of 99.36-99.79%. Among these eight strains, especially strains CHM16 and CHM54 had high oxidase activity for D-mannitol and D-sorbitol, converting it to D-fructose and L-sorbose at 37°C, respectively. Sugar alcohols oxidation proceeded without a lag time, but Gluconobacter frateurii IFO 3264^T was unable to do such fermentation at 37°C. Fermentation efficiency and fermentation rate of the strains CHM16 and CHM54 were quite high and they rapidly oxidized D-mannitol and D-sorbitol to D-fructose and L-sorbose at almost 100% within 24 h at 30°C. Even oxidative fermentation of D-fructose done at 37°C, the strain CHM16 still accumulated D-fructose at 80% within 24 h. The efficiency of L-sorbose fermentation by the strain CHM54 at 37°C was superior to that observed at 30°C. Thus, the eight strains were finally classified as thermotolerant members of G. frateurii.     

Synthesis of β-D-Fructopyranosyl-(2→6)-D-glucopyranose from D-Glucose and D-Fructose by a Thermal Treatment

The synthesis is reported of β-D-fructopyranosyl-(2→6)-D-glucopyranose that had previously been isolated from a fermented plant extract as a new saccharide. A disaccharide was predominately formed from an equal amount of D-glucose and D-fructose under melting conditions at 140 °C for 60 to 90 min. This saccharide was isolated from the reaction mixture by carbon-Celite column chromatography and preparative HPLC, and was confirmed to be β-D-fructopyranosyl-(2→6)-D-glucopyranose by TOF-MS and NMR analyses.     

Mutual Binding Inhibition of Tetrodotoxin and Saxitoxin to Their Binding Protein from the Plasma of the Puffer Fish,Fugu pardalis

The mutual binding inhibition of tetrodotoxin and saxitoxin to their binding protein from the plasma of Fugu pardalis was investigated by HPLC. The values for the half inhibitory concentration of tetrodotoxin (1.6 μM) binding to this protein (1.2 μM) for saxitoxin, and of saxitoxin (0.47 μM) binding to that (0.30 μM) for tetrodotoxin were 0.35±0.057 μM and 81±16 μM (n=2), respectively.     

On the Fermenting Ability of Sand Cultures of Acetone-Butanol Organisms Stored for Long Years

β-N-Acetyl-D-hexosaminidase was isolated from the mid-gut gland of Patinopecten yessoensis. The enzyme was purifted by making an acetone-dried preparation of the mid-gut gland, extracting with 50 mM citrate-phosphate buffer (pH 4.0) (about 13% of the extracted proteins was β-N-acetyl-D-hexosaminidase), ammonium sulfate fractionation, and column chromatographies on CM-Sepharose and DEAE-Sepharose. The purifted β-N-acetyl-D-hexosaminidase was homogeneous on SDS–PAGE, and sufficiently free from other exo-type glycosidases. The molecular weight was 56,000 by SDS–PAGE. The enzyme hydrolyzed both p-nitrophenyl β-N-acetyl-D-glucosaminide and p-nitrophenyl β-N-acetyl-D-galactosaminide. For p-nitrophenyl β-N-acetyl-D-glucosaminide, the pH optimum was 3.7, the optimum temperature was 45°C, and the K_m was 0.24 mM. For p-nitrophenyl β-N-acetyl-D-galactosaminide, these were pH 3.4, 45°C, and 0.15 mM, respectively. The enzyme liberated non-reducing terminal β-Iinked N-acetyl-D-glucosamine or N-acetyl-D-galactosamine from various 2-aminopyridyl derivatives of oligosaccharides of N-glycan or glycolipid type except of G_M2-tetrasaccharide. As the enzyme was stable around pH 3.5–5.5, it may be useful for long time reactions around the optimum pH.     

Purification and Crystallization of d-Arabinose (l-Fucose) Isomerase from Aerobacter aerogenes by Polyethylene Glycol

d-Arabinose(l-fucose) isomerase (d-arabinose ketol-isomerase, EC 5.3.1.3) was purified from the extracts of d-arabinose-grown cells of Aerobacter aerogenes, strain M-7 by the procedure of repeated fractional precipitation with polyethylene glycol 6000 and isolating the crystalline state. The crystalline enzyme was homogeneous in ultracentrifugal analysis and polyacrylamide gel electrophoresis. Sedimentation constant obtained was 15.4s and the molecular weight was estimated as being approximately 2.5 × 10⁵ by gel filtration on Sephadex G-200.

Optimum pH for isomerization of d-arabinose and of l-fucose was identical at pH 9.3, and the Michaelis constants were 51 mm for l-fucose and 160 mm for d-arabinose. Both of these activities decreased at the same rate with thermal inactivation at 45 and 50°C. All four pentitols inhibited two pentose isomerase activities competitively with same Ki values: 1.3–1.5 mm for d-arabitol, 2.2–2.7 mm for ribitol, 2.9–3.2 mm for l-arabitol, and 10–10.5 mm for xylitol. It is confirmed that the single enzyme is responsible for the isomerization of d-arabinose and l-fucose.     

An Aminopeptidase of Aspergillus sojae

An aminopeptidase was purified from Aspergillus sojae X–816. The molecular weight of the enzyme was estimated to be 220,000. The isoelectric point was at pH 5.3. The optimum pH for l-leucylglycylglycine was 7.5. The enzyme was stable up to 37°C against temperature treatment for 15 min. Some chelating agents inhibited the enzyme activity. The Km value for l-leucylglycylglycine at pH 7.5 and 37°C was 45 mm. The Km value for l-leucyl-β-naphthylamide at pH 7.0 and 37°C was 2.2 mm.     

Inhibition of l-Alanine Adding Enzyme by Glycine

l-Alanine adding enzymes from Bacillus subtilis and Bacillus cereus which catalyzed l-alanine incorporation into UDPMurNAc were partially purified and the properties of the enzymes were examined. The enzyme from B. subtilis was markedly stimulated by reducing agents including 2-mercaptoethanol, dithiothreitol, glutathione and cysteine. Mn²⁺ and Mg²⁺ activated l-alanine adding activity and their optimal concentrations were 2 to 5 mm and 10 mm, respectively. The optimum pH was 9.5 and the Km for l-alanine was 1.8×10^?4m. l-Alanine adding reaction was strongly inhibited by p-chloromercuribenzoate and N-ethyl-maleimide. Among glycine, l- and d-amino acids and glycine derivatives, glycine was the most effective inhibitor of the l-alanine adding reaction. The enzyme from B. cereus was more resistant to glycine than that from B. subtilis. Glycine was incorporated into UDPMurNAc in place of l-alanine, and the Ki for glycine was 4.2×l0^?3m with the enzyme from B. subtilis. From these data, the growth inhibition of bacteria by glycine is discussed.     

Mechanisms of Browning Degradation of d-Fructose in Special Comparison with d-Glucose-Glycine Reaction

Degradation mechanisms of d-fructose by the interaction with amino acids or organic acids in aqueous solution at initial pH 5.5 heated at 100°C were investigated and a substantial difference in mechanisms between fructose degradation and glucose-glycine reaction was presented. d-Fructose browned more intensely than did d-glucose in lower concentration of glycine and/or in earier stage of reaction period. By catalytic action of carboxylate anions without any condensation with amino groups, d-fructose was decomposed to 3-deoxy-d-erythrohexosulose, 5-(hydroxymelhyl)-2-furaldehyde, and a less amount of pyruval-dehyde through caramelization. It was considered that the main path of fructose degradation was 1,2-enolization but 2,3-enolization would also occur to a little extent.     

Studies on Glucose-Isomerizing Enzyme of Bacteria

d-Glucose-isomerizing enzyme from Escherichia intermedia HN-500, which converts d-glucose to d-fructose in the presence of arsenate, was purified by treating with manganous sulfate, rivanol, and DEAE-Sephadex column chromatography. About 180-fold purified enzyme preparation was obtained by the above procedures. The purified preparation was free from the activities of d-glucose-, d-galactose-, glucose-6-phosphate-, mannitol-, and sorbitol-dehydrogenases and was homogeneous on polyacrylamide gel in zone electrophoresis. Optima of pH and temperature for the enzyme were found to be pH 7.0 and 50°C, respectively. The enzyme was completely inactivated by heating at 60°C for ten minutes and stable in the pH range of 7.0~9.0 at 30°C. Activation energy for the isomerizing enzyme was calculated to be 15,300 calories per mole degree from Arrhenius' equation. Either in the absence or presecne of arsenate, d-mannose, d-xylose, d-mannitol and d-sorbitol could not be isomerized by the purified enzyme at all, but the present enzyme isomerized exclusively glucose-6-phosphate and fructose-6-phosphate in the absence of arsenate.     

Production,Purification, and Characterization of D-Aminoacylase from Alcaligenes xylosoxydans subsp. xylosoxydans A-6

The best inducers for D-aminoacylase from Alcaligenes xylosoxydans subsp. xylosoxydans A-6 (Alcaligenes A-6) were a poor substrate, N-acetyl-;-methyl-D-leucine, and an inhibitor, N-acetyl-D-alloisoleucine. The enzyme has been homogeneously purified. The molecular weight of the native enzyme was estimated to be 58,000 by gel filtration. A subunit molecular weight of 52,000 was measured by SD8–PAGE, indicating that the native protein is a monomer. The isoelectric point was 5.2. The enzyme was specific to the D-isomer and hydrolyzed N-acetyl derivatives of D-leucine, D-phenylalanine, D-norleucine, D-methionine, and D-valine, and also N-formyl, N-butyryl, and N-propionyl derivatives of D-leucine. The K_m for N-acetyl-D-leucine was 9.8mM. The optimum pH and temperature were 7.0 and 50°C, respectively. The stabilities of pH and temperature were 8.1 and 40°C. D-Aminoacylases from three species of the genus Alcaligenes differ in inducer and substrate specificities, but are similar with respect to molecular weight and N-terminal amino acid sequence.     

Production of l-allose and d-talose from l-psicose and d-tagatose by l-ribose isomerase

l-ribose isomerase (L-RI) from Cellulomonas parahominis MB426 can convert l-psicose and d-tagatose to l-allose and d-talose, respectively. Partially purified recombinant L-RI from Escherichia coli JM109 was immobilized on DIAION HPA25L resin and then utilized to produce l-allose and d-talose. Conversion reaction was performed with the reaction mixture containing 10% l-psicose or d-tagatose and immobilized L-RI at 40 °C. At equilibrium state, the yield of l-allose and d-talose was 35.0% and 13.0%, respectively. Immobilized enzyme could convert l-psicose to l-allose without remarkable decrease in the enzyme activity over 7 times use and d-tagatose to d-talose over 37 times use. After separation and concentration, the mixture solution of l-allose and d-talose was concentrated up to 70% and crystallized by keeping at 4 °C. l-Allose and d-talose crystals were collected from the syrup by filtration. The final yield was 23.0% l-allose and 7.30% d-talose that were obtained from l-psicose and d-tagatose, respectively.     

Purification and Characterization of Novel N-Acyl-D-aspartate Amidohydrolase from Alcaligenes xylosoxydans subsp. xylosoxydans A-6

Alcaligenes xylosoxydans subsp. xylosoxydans A-6 (Alcaligenes A-6) produced N-acyl-D-aspartate amidohydrolase (D-AAase) in the presence of N-acetyl-D-aspartate as an inducer. The enzyme was purified to homogeneity. The enzyme had a molecular mass of 56 kDa and was shown by sodium dodecyl sulfate (SDS)–polyacrylamide gel electrophoresis (PAGE) to be a monomer. The isoelectric point was 4.8. The enzyme had maximal activity at pH 7.5 to 8.0 and 50°C, and was stable at pH 8.0 and up to 45°C. N-Formyl (K_m=12.5 mM), N-acetyl (K_m=2.52 mM), N-propionyl (K_m=0.194 mM), N-butyryl (K_m=0.033 mM), and N-glycyl (K_m =1.11 mM) derivatives of D-aspartate were hydrolyzed, but N-carbobenzoyl-D-aspartate, N-acetyl-L-aspartate, and N-acetyl-D-glutamate were not substrates. The enzyme was inhibited by both divalent cations (Hg²⁺, Ni²⁺, Cu²⁺) and thiol reagents (N-ethylmaleimide, iodoacetic acid, dithiothreitol, and p-chloromercuribenzoic acid). The N-terminal amino acid sequence and amino acid composition were analyzed.     

N-Carbamyl-L-Amino Acid Amidohydrolase of Pseudomonas sp. Strain NS671: Purification and Some Properties of the Enzyme Expressed in Escherichia coli

An N-carbamyl-L-amino acid amidohydrolase was purified from cells of Escherichia coli in which the gene for N-carbamyl-L-amino acid amidohydrolase of Pseudomonas sp. strain NS671 was expressed. The purified enzyme was homogeneous by the criterion of SDS–polyacrvlamide gel electrophoresis. The results of gel filtration chromatography and SDS–polyacrylamide gel electrophoresis suggested that the enzyme was a dimeric protein with 45-kDa identical subunits. The enzyme required Mn²⁺ ion (above 1 mM) for the activity. The optimal pH and temperature were 7.5 and around 40°C, respectively, with N-carbamyl-L-methionine as the substrate. The enzyme activity was inhibited by ATP and was iost completely with p-chloromercuribenzoate (1 mM). The enzyme was strictly L-specific and showed a broad substrate specificity for N-carbamyl-L-α-amino acids.     

Structure of Rugulovasine A,B and their Derivatives

Culture conditions for the preparation of cells containing high tyrosine phenol lyase activity were studied with Erwinia herbicola ATCC 21434. Adding pyridoxine to the medium enhanced enzyme formation, suggesting that it was utilized as a precursor of the coenzyme, pyridoxal phosphate. Glycerol plus succinic acid; amino acids, such as, DL-methionine, DL-alanine and glycine; and metallic ion, ferrous ion promoted enzyme formation as well as cell growth. Adding L-tyrosine, as inducer, to the culture medium was essential for enzyme formation. However, when large amounts of L-tyrosine were added, the enzyme formation was repressed by the phenol liberated from L-tyrosine. In fact, formation of the enzyme was enhanced by removing phenol during cultivation. L(D)-Phenylalanine or phenylpyruvic acid had a synergistic effect on the induction of enzyme by L-tyrosine.

Cells with high enzyme activity were prepared by growing cells at 28°C for 28 hr in a medium containing 0.2% L-tyrosine, 0.2% KH₂PO₄, 0.1% MgSO₄7H₂O, 0.001% FeSO_4·7H₂O, 0.01% pyridoxine-HC1, 0.6% glycerol, 0.5% succinic acid, 0.1% DL-methionine, 0.2% DL-alanine, 0.05% glycine, 0.1% L-phenylalanine and 120 ml/liter hydrolyzed soybean protein in tap water with the pH controlled at 7.5 throughout cultivation.     

DAHP Synthetase and Its Control in Corynebacterium glutamicum

Properties of 3-deoxy-D-arabinoheptulosonate-7-phosphate (DAHP) synthetase from Corynebacterium glutamicum were examined using the cell free extract. The optimum pH for the reaction was broad ranging from 5.5 to 7.0 and the optimum temperature was 37°C. Co²⁺ inhibited the enzyme activity at 20°C, whereas Co²⁺ apparently stimulated the enzyme activity at 37°C because the ion protected the enzyme from inactivation at 37°C. Co²⁺ reversed the inhibition of the enzyme activity by EDTA. The activity of DAHP synthetase was feedback inhibited only weakly by l-phenylalanine, l-tyrosine or l-tryptophan alone, but was strongly inhibited synergistically by l-phenylalanine and l-tyrosine. l-Tryptophan enhanced the inhibition by the pair of l-tyrosine and l-phenylalanine. Maximal inhibition was near 90 % in the simultaneous presence of the three amino acids. Sensitivity of the enzyme to the inhibitors was lost during the purification process of the enzyme or during the reaction at 37°C. Especially sensitivity to l-tryptophan was easily lost. Co²⁺ protected the enzyme from the desensitization. Mutants resistant to p-fluorophenylalanine plus l-tyrosine (or 3-aminotyrosine) had DAHP synthetase which was released from the feedback inhibition by the three amino acids. The formation of the enzyme was not affected by aromatic amino acids.     

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.