Uptake ofd-Glucosamine bySaccharomyces cerevisiae

d-glucosamine does not serve as a metabolic substrate inSaccharomyces cerevisiae although it stimulates by 15% endogenous respiration. It is taken up by a system or systems shared withd-glucose,d-fructose andd-xylose but apparently not fully with 2-deoxy-d-glucose. Its half-saturation constant is 38±14 mmol/L, in agreement with its inhibitor constant versusd-glucose andd-xylose uptake. Its maximum rate is 69±17 μmol per g dry mass per min. The transport is thermodynamically passive butd-glucosamine distribution follows the membrane potential, reaching ratios of 80∶1 at pH 7.5 and about 1∶1 at pH 4.0. These rations decrease with increasingd-glucosamine concentration as well as with increasing suspension density, and are affected by metabolic inhibitors.     

Characterization of seven basic endochitinases isolated from cell cultures of Citrus sinensis (L.)

Seven endochitinases (EC 3.2.1.14) (relative molecular masses 23000–28000 and isoelectric points 10.3–10.4) were purified from nonembryogenic Citrus sinensis L. Osbeck cv. Valencia callus tissue. The basic chitinase/lysozyme from this tissue (BCLVC) exhibited lysozyme, chitinase and chitosanase activities and was determined to be a class III chitinase. While BCLVC acted as a lysozyme at pH 4.5 and low ionic strength (0.03) it acted as a chitinase/chitosanase at high ionic strengths (0.2) with a pH optimum of ca. 5. The lysozyme activity of BCLVC was inhibited by histamine, imidazole, histidine and the N-acetyl-d-glucosamine oligosaccharide (GlcNAc)₃. The basic chitinase from cv. Valencia callus, BCVC-2, had an N-terminal amino acid sequence similar to tomato and tobacco AP24 proteins. The sequences of the other five chitinases were N-terminal blocked. Whereas BCLVC was capable of hydrolyzing 13.8–100% acetylated chitosans and (GlcNAc)_4–6 oligosaccharides, BCVC-2 hydrolyzed only 100% acetylated chitosan, and the remaining enzymes expressed varying degrees of hydrolytic capabilities. Experiments with (GlcNAc)_2–6 suggest that BCLVC hydrolysis occurs in largely tetrasaccharide units whereas hydrolysis by the other chitinases occurs in disaccharide units. Cross-reactivities of the purified proteins with antibodies for a potato leaf chitinase (Ab_PLC), BCLVC, BCVC-3, and tomato AP24 indicate that these are separate and distinct proteins.Mention of a trademark, warranty, propriety, or vendor does not constitute a guarantee by the U.S. Department of Agriculture and does not imply its approval to the exclusion of other products or vendors that may also be suitable.Abbreviations Ab antibody - BCLVC basic chitinase/lysozyme cv. Valencia callus - BCVC basic chitinase cv. Valencia callus - CE capillary electrophoresis - CM-chitin-RBV carboxymethyl-chitin-remazol brilliant violet - GlcNAc N-acetyl-d-glucosamine - HEWL hen egg-white lysozyme - M_r relativemolecular mass - pI isoelectric point - PLC potato leaf chitinase - PR pathogenesis-related - SEC size exclusion chromatography We thank Mr. M. Burkhart, Ms. T.-T. Ho, and Ms. M. Doherty for their valuable technical assistance. A portion of the funding for this work was made available from the Citrus Production Research Marketing Order by the Division of Marketing and Development, Florida Department of Agriculture and Consumer Services, Bob Crawford, Commissioner.     

Characterization of a recombinant cellobiose 2-epimerase from <Emphasis Type="BoldItalic">Caldicellulosiruptor saccharolyticus</Emphasis> and its application in the production of mannose from glucose

A putative N-acyl-d-glucosamine 2-epimerase from Caldicellulosiruptor saccharolyticus was cloned and expressed in Escherichia coli. The recombinant enzyme was identified as a cellobiose 2-epimerase by the analysis of the activity for substrates, acid-hydrolyzed products, and amino acid sequence. The cellobiose 2-epimerase was purified with a specific activity of 35 nmol min^–1 mg^–1 for d-glucose with a 47-kDa monomer. The epimerization activity for d-glucose was maximal at pH 7.5 and 75°C. The half-lives of the enzyme at 60°C, 65°C, 70°C, 75°C, and 80°C were 142, 71, 35, 18, and 4.6 h, respectively. The enzyme catalyzed the epimerization reactions of the aldoses harboring hydroxyl groups oriented in the right-hand configuration at the C2 position and the left-hand configuration at the C3 position, such as d-glucose, d-xylose, l-altrose, l-idose, and l-arabinose, to their C2 epimers, such as d-mannose, d-lyxose, l-allose, l-gulose, and l-ribose, respectively. The enzyme catalyzed also the isomerization reactions. The enzyme exhibited the highest activity for mannose among monosaccharides. Thus, mannose at 75 g l^–1 and fructose at 47.5 g l^–1 were produced from 500 g l^–1 glucose at pH 7.5 and 75°C over 3 h by the enzyme.     

An efficient method for N-acetyl-d-neuraminic acid production using coupled bacterial cells with a safe temperature-induced system

N-Acetyl-d-neuraminic acid (Neu5Ac) is a precursor for producing many pharmaceutical drugs such as zanamivir which have been used in clinical trials to treat and prevent the infection with influenza virus, such as the avian influenza virus H5N1 and the current 2009 H1N1. Two recombinant Escherichia coli strains capable of expressing N-acetyl-d-glucosamine 2-epimerase and N-acetyl-d-neuraminic acid aldolase were constructed based on a highly efficient temperature-responsive expression system which is safe compared to chemical-induced systems and coupled in Neu5Ac production. Carbon sources were optimized for Neu5Ac production, and the concentration effects of carbon sources on the production were investigated. With 2,200 mM pyruvate as carbon source and substrate, 61.9 mM (19.1 g l⁻¹) Neu5Ac was produced from 200 mM N-acetyl-d-glucosamine (GlcNAc) in 36 h by the coupled cells. Our Neu5Ac biosynthetic process is favorable compared with natural product extraction, chemical synthesis, or even many other biocatalysis processes.     

Automated screen of a preliminary lead-drug for chitosanase drug design

Chitosan is a naturally occurring component of certain bacterial and fungal cell walls. If some groups of medically and agriculturally significant fungi contain chitosan, chitosan metabolism represents attractive drug targets specific to those fungal systems. Recently, structure-based drug design emerges as a powerful technique in drug screening. The process initially requires three dimensional structure of a target molecule. Because the bacterialStreptomyces lividans N174 chitosanase is only one chitosanase whose X-ray structure has been solved, we begin the process of structure-based drug design with the bacterial enzyme but it should be extended to a fungal one. In order to initiate the process, a preliminary lead-drug was screened by automated computer search from chemical databases. The 5-nitro-isatin showed an inhibitory effect by 50% at 1.5 mM on theStreptomyces lividans N174 chitosanase.     

Production of Pseudomonas Cells Having a High Fumarate Hydratase Activity

An extracellular 45 kDa endochitosanase was purified and characterized from the culture supernatant of Bacillus sp. P16. The purified enzyme showed an optimum pH of 5.5 and optimum temperature of 60°C, and was stable between pH 4.5-10.0 and under 50°C. The K _m and V _max were measured with a chitosan of a D.A. of 20.2% as 0.52 mg/ml and 7.71×10^?6 mol/sec/mg protein, respectively. The enzyme did not degrade chitin, cellulose, or starch. The chitosanase digested partially N-acetylated chitosans, with maximum activity for 15-30% and lesser activity for 0-15% acetylated chitosan. The chitosanase rapidly reduced the viscosity of chitosan solutions at a very early stage of reaction, suggesting the endotype of cleavage in polymeric chitosan chains. The chitosanase hydrolyzed (GlcN)₇ in an endo-splitting manner producing a mixture of (GlcN)_2-5. Time course studies showed a decrease in the rate of substrate degradation from (GlcN)₇ to (GlcN)₆ to (GlcN)₅, as indicated by the apparent first order rate constants, k ₁ values, of 4.98×10^?4, 2.3×10^?4, and 9.3×10^?6 sec^?1, respectively. The enzyme hardly catalyzed degradation of chitooligomers smaller than the pentamer.     

Effect of chitin sources on production of chitinase and chitosanase byStreptomyces griseus HUT 6037

The advantage of usingStreptomyces griseus HUT 6037 in the production of chitinase or chitosanase is that the organism is capable of hydrolyzing amorphous or crystal-line chitin and chitosan according to the type of the substrate used. We investigated the effects of the enzyme induction time and chitin sources, CM-chitosan and deacetylated chitosan (degree of deacetylation 75–99%), on production of chitosanase. We found that this strain accumulated chitosanase when cells were grown in the culture medium containing chitosanaceous substrates instead of chitinaceous substrates. The highest chitosanase activity was obtained at 4 days of cultivation with 99% deacetylated chitosan. Soluble chitosan (53% deacetylated chitosan) was found to induce chitinase as well as chitosanase. The specific activities of chitinase and chitosanase were 0.91 and 1.33 U/mg protein at 3 and 5 days, respectively. From the study of the enzymatic digestibility of various degrees of deacetylated chitosan, it was found that (GlcN)₃, (GlcN)₄ and (GlcN)₅ were produced during the enzymatic hydrolysis reaction. The results of this study suggested that the sugar composition of (GlcN)₃ was homogeneous and those of (GlcN)₄ and (GlcN)₅ were heterogeneous.     

Isolation of a crustaceann-acetyl-d-glucosamine-1-phosphate transferase and its activation by phospholipids

Summary Then-acetyl-d-glucosamine-1-phosphate: dolichol phosphate transferase fromArtemia has been partially purified and characterized. The enzyme is solubilized from crude microsomes using Triton X-100, and after detergent removal appears to be associated with phospholipids. Using dolichol phosphate and UDP-n-acetyl-d-glucosamine as substrates, the enzyme catalyzes the formation of dolichol-pyrophosphate-n-acetyl-d-glucosamine. the product identity has been verified by TLC and paper chromatography following mild acid hydrolysis. Under the incubation conditions used only one product is made, i.e., Dol-p-p-GlcNAc. The formation of product is linear with increasing amounts of added protein and with time of incubation. The enzyme requires magnesium ions for activity. Activity of the enzyme is stimulated 6-fold by exogenous dolichol phosphate and is also stimulated by added phospholipids, with optimal activity being obtained in the presence of mixtures of phosphatidylcholine and phosphatidylglycerol. Enzymatic activity is not increased upon addition of GDP-mannose or dolichol phosphate mannose. The enzyme is rapidly inactivated by exposure to several detergents, including Triton X-100 and deoxycholate. The activity is inhibited by tunicamycin and by the purified B₂ homologue of this antibiotic. Other antibiotic inhibitors such as diumycin and polyoxin D have little effect on the enzyme. Both the microsomal and solubilized enzyme preparations are inactivated by 70% upon treatment with phospholipase A₂; activity may be restored by addition of phospholipids. Following hydrophobic interaction chromatography on Phenyl Sepharose, gel filtration chromatography on Sepharose CL-4B indicated that the enzyme, purified 81-fold, contained phophatidylcholine and phosphatidyl-ethanolamine.Abbreviations SDS sodium dodecyl sulfate - PMSF phenyl methanesulfonylfluoride - HEPES 4-(2-hydroxyethyl)-1-piperazineethane sulfonic acid - GlcNAc N-acetyl-d-glucosamine - Dol-PP-GlcNAc dolichol pyrophosphate N-acetyl-d-glucosamine - Dol-P-man dolichol-phosphate-mannose - Dol-PP- (GlcNAc)₂ dolichol-pyrophosphate-di-N- acetylchitobiose - DMSO dimethylsulfoxide - C:M (2:1) chloroform:methanol (2:1) - C:M:W (10:10:3) chloroform:methanol:water (10:10:3) - GlcNAc-1-P N-acetyl-d-glucosamine-1-phosphate - Dol-P dolichol phosphate - EGTA ethylene glycol bis (b-aminoethyl ether)-NNNN tetraacetic acid     

Cloning and expression inStreptomyces lividans of a chitosanase-encoding gene from the actinomyceteKitasatosporia N174 isolated from soil

Summary The chitosanase gene from a new soil isolate, the actinomyceteKitasatosporia N174, was cloned inStreptomyces lividans TK24. The enzyme expressed from the cloned gene had a molecular weight of approximately 29,500; an isoelectric point of 7.5 and was indistinguishable from the purified N174 chitosanase.Abbreviations CHS chitosanase - chs chitosanase-encoding gene - kb kilobases - PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulfate     

Properties of Chitosanase from Bacillus cereus S1

Chitosanase from Bacillus cereus S1 was purified, and the enzymatic properties were investigated. The molecular weight was estimated to 45,000 on SDS-PAGE. Optimum pH was about 6, and stable pH in the incubation at 40°C for 60 min was 6–11. This chitosanase was stable in alkaline side. Optimum temperature was around 60°C, and enzyme activity was relatively stable below 60°C. The degradations of colloidal chitosan and carboxymethyl cellulose (CMC) were about 30 and 20% relative to the value of soluble chitosan, respectively, but colloidal chitin and crystalline cellulose were not almost hydrolyzed. On the other hand, S1 chitosanase adsorbed on colloidal chitin completely and by about 50% also on crystalline cellulose, in contrast to colloidal chitosan, which it did not adsorb. S1 chitosanase finally hydrolyzed 100% N-deacetylated chitosan (soluble state) to chitobiose (27.2%), chitotriose (40.6%), and chitotetraose (32.2%). In the hydrolysis of various chitooligosaccharides, chitobiose and chitotriose were not hydrolyzed, and chitotetraose was hydrolyzed to chitobiose. Chitobiose and chitotriose were released from chitopentaose and chitohexaose. From this specificity, it was hypothesized that the active site of S1 chitosanase recognized more than two glucosamine residues posited in both sides against splitting point for glucosamine polymer. Received: 8 June 1999 / Accepted: 20 July 1999     

Immobilization of 5‐Fluorouridine on Chitosan

The 2′,3′‐O‐levulinic acid derivative 2b of the cancerostatic 5‐fluorouridine as well as its N(3)‐farnesylated nucleolipid 2d were synthesized and coupled to H₂O‐soluble chitosanes of different molecular weight and at various pH values (3.5–5.5) leading to 6 and 7 . In addition, the coumarine fluorophore ATTO‐488 N(9)‐butanoate was bound to the biopolymer by a sequential‐coupling technique to afford 9 and 10 . Moreover, chitosan foils were prepared, to which 2b was coupled. Their degradation by chitosanase (from Streptomyces sp. N174) was studied UV‐spectrophotometrically in a Franz diffusion cell.     

来自拟青霉属真菌的壳聚糖酶的分离纯化、理化性质及降解产物的分析(英文)

从来自拟青霉属真菌Paecilomyces sp.CS-Z的发酵液中获得一种壳聚糖酶,该酶被纯化了9.4倍,产率为48.2%。经SDS-PAGE分析确定为单一条带,分子量为29kDa,其最适pH为6.0–6.5,最适温度为55℃,在80℃处理60min后,能保持较好的热稳定性,Hg2+完全抑制了酶活,对脱乙酰度85%–95%的壳聚糖具有较高的水解活性,而对几丁质和羧甲基纤维素无活性。薄层层析和质谱分析表明该酶是一种内切酶,其水解产物为聚合度大于6的壳寡糖,其理化性质与至今报道的壳聚糖酶有所不同,为壳聚糖酶的开发提供了重要的实验依据。     

Screening of chitin deacetylase from Mucoralean strains (Zygomycetes) and its relationship to cell growth rate

Chitin deacetylase (CDA) is an enzyme that catalyzes the hydrolysis of acetamine groups of N-acetyl-d-glucosamine in chitin, converting it to chitosan in fungal cell walls. In the present study, the activity in batch culture of CDA from six Mucoralean strains, two of them wild type, isolated from dung of herbivores of Northeast Brazil, was screened. Among the strains tested, Cunninghamella bertholletiae IFM 46114 showed a high intracellular enzyme activity of 0.075 U/mg protein after 5 days of culture, and a wild-type strain of Mucor circinelloides showed a high intracellular enzyme activity of 0.060 U/mg protein, with only 2 days of culture, using N-acetylchitopentaose as substrate. This enzyme showed optimal activity at pH 4.5 in 25 mM glutamate-sodium buffer at 50°C, and was stable over 1 h preincubation at the same temperature. The kinetic parameters of CDA did not follow Michaelis-Menten kinetics, but rather Hill affinity distribution, showing probable allosteric behavior. The apparent K_HILL and V_max of CDA were 288±34 nmol/l and 0.08±0.01 U mg protein^–1 min^–1, respectively, using N-acetylchitopentaose as substrate at pH 4.5 at 50°C.     

Amino acid racemase with broad substrate specificity,its properties and use in phenylalanine racemization

Summary Broad substrate specificity amino acid racemase (EC 5.1.1.10) was purified from a crude extract of Pseudomonas putida SCRC-744 to near homogeneity. The enzyme has an isoelectric point of 7.6 and a molecular weight of 62,000–65,000. The enzyme showed a broad substrate specificity toward amino acids, utilizing d-glutamine as the best substrate. d-Phenylalanine acted as a substrate to 1% the velocity for d-glutamine. Maximal reaction velocities were observed at 50°–60°C and around pH 8. The apparent K_m values for d-glutamine and d-phenylalanine were 7.8 mM and 25.7 mM, respectively. Both enantiomers of phenylalanine were efficiently racemized by acetone-dried cells of P. putida SCRC-744.     

Purification and characterization of an extracellular chitosanase produced by Amycolatopsis sp. CsO-2

Extracellular chitosanase produced by Amycolatopsis sp. CsO-2 was purified to homogeneity by precipitation with ammonium sulfate followed by cation exchange chromatography. The molecular weight of the chitosanase was estimated to be about 27,000 using SDS-polyacrylamide gel electrophoresis and gel filtration. The maximum velocity of chitosan degradation by the enzyme was attained at 55°C when the pH was maintained at 5.3. The enzyme was stable over a temperature range of 0–50°C and a pH range of 4.5–6.0. About 50% of the initial activity remained after heating at 100°C for 10 min, indicating a thermostable nature of the enzyme. The isoelectric point of the enzyme was about 8.8. The enzyme degraded chitosan with a range of deacetylation degree from 70% to 100%, but not chitin or CM-cellulose. The most susceptible substrate was 100% deacetylated chitosan. The enzyme degraded glucosamine tetramer to dimer, and pentamer to dimer and trimer, but did not hydrolyze glucosamine dimer and trimer.     

Site-directed mutagenesis of possible catalytic residues of cellobiose 2-epimerase from Ruminococcusalbus

The cellobiose 2-epimerase from Ruminococcus albus (RaCE) catalyzes the epimerization of cellobiose and lactose to 4-O-β-d-glucopyranosyl-d-mannose and 4-O-β-d-galactopyranosyl-d-mannose (epilactose). Based on the sequence alignment with N-acetyl-d-glucosamine 2-epimerases of known structure and on a homology-modeled structure of RaCE, we performed site-directed mutagenesis of possible catalytic residues in the enzyme, and the mutants were expressed in Escherichia coli cells. We found that R52, H243, E246, W249, W304, E308, and H374 were absolutely required for the activity of RaCE. F114 and W303 also contributed to catalysis. These residues protruded into the active-site cleft in the model (α/α)₆ core barrel structure.     

Increased <Emphasis Type="SmallCaps">d</Emphasis>-allose production by the R132E mutant of ribose-5-phosphate isomerase from <Emphasis Type="Italic">Clostridium thermocellum</Emphasis>

Ribose-5-phosphate isomerase from Clostridium thermocellum converted d-psicose to d-allose, which may be useful as a pharmaceutical compound, with no by-product. The 12 active-site residues, which were obtained by molecular modeling on the basis of the solved three-dimensional structure of the enzyme, were substituted individually with Ala. Among the 12 Ala-substituted mutants, only the R132A mutant exhibited an increase in d-psicose isomerization activity. The R132E mutant showed the highest activity when the residue at position 132 was substituted with Ala, Gln, Ile, Lys, Glu, or Asp. The maximal activity of the wild-type and R132E mutant enzymes for d-psicose was observed at pH 7.5 and 80°C. The half-lives of the wild-type enzyme at 60°C, 65°C, 70°C, 75°C, and 80°C were 11, 7.0, 4.2, 1.5, and 0.6 h, respectively, whereas those of the R132E mutant enzymes were 13, 8.2, 5.1, 3.1, and 0.9 h, respectively. The specific activity and catalytic efficiency (k _cat/K _m) of the R132E mutant for d-psicose were 1.4- and 1.5-fold higher than those of the wild-type enzyme, respectively. When the same amount of enzyme was used, the conversion yield of d-psicose to d-allose was 32% for the R132E mutant enzyme and 25% for the wild-type enzyme after 80 min.     

Recombinant expression of a chitosanase and its application in chitosan oligosaccharide production

Recently, considerable attention has been focused on chitosan oligosaccharides (COSs) due to their various biological activities. COSs can be prepared by enzymatic degradation of chitosan, which is the deacetylation product of chitin, one of the most abundant biopolymers in nature. In the current study, we recombinantly expressed a chitosanase and used it for COS preparation. A bacillus-derived GH8 family chitosanase with a 6×His tag fused at its N-terminal was expressed in the Escherichia coli strain BL21(DE3) as a soluble and active form. Its expression level could be as high as 500 mg/L. Enzymatic activity could reach approximately 140,000 U/L under our assay conditions. The recombinant chitosanase could be purified essentially to homogeneity by immobilized metal-ion affinity chromatography. The enzyme could efficiently convert chitosan into monomer-free COS: 1 g of enzyme could hydrolyze about 100 kg of chitosan. Our present work has provided a cheap chitosanase for large-scale COS production in industry.     

Properties of recombinant <Emphasis Type="Italic">Strep</Emphasis>-tagged and untagged hyperthermophilic D-arabitol dehydrogenase from <Emphasis Type="Italic">Thermotoga maritima</Emphasis>

The first hyperthermophilic d-arabitol dehydrogenase from Thermotoga maritima was heterologously purified from Escherichia coli. The protein was purified with and without a Strep-tag. The enzyme exclusively catalyzed the NAD(H)-dependent oxidoreduction of d-arabitol, d-xylitol, d-ribulose, or d-xylulose. A twofold increase of catalytic rates was observed upon addition of Mg²⁺ or K⁺. Interestingly, only the tag-less protein was thermostable, retaining 90% of its activity after 90 min at 85 °C. However, the tag-less form of d-arabitol dehydrogenase had similar kinetic parameters compared to the tagged enzyme, demonstrating that the Strep-tag was not deleterious to protein function but decreased protein stability. A single band at 27.6 kDa was observed on SDS-PAGE and native PAGE revealed that the protein formed a homohexamer and a homododecamer. The enzyme catalyzed oxidation of d-arabitol to d-ribulose and therefore belongs to the class of d-arabitol 2-dehydrogenases, which are typically observed in yeast and not bacteria. The product d-ribulose is a rare ketopentose sugar that has numerous industrially applications. Given its thermostability and specificity, d-arabitol 2-dehydrogenase is a desirable biocatalyst for the production of rare sugar precursors.     

Characterization of salt-tolerant glutaminase from Stenotrophomonas maltophilia NYW-81 and its application in Japanese soy sauce fermentation

Glutaminase from Stenotrophomonas maltophilia NYW-81 was purified to homogeneity with a final specific activity of 325 U/mg. The molecular mass of the native enzyme was estimated to be 41 kDa by gel filtration. A subunit molecular mass of 36 kDa was measured with SDS-PAGE, thus indicating that the native enzyme is a monomer. The N-terminal amino acid sequence of the enzyme was determined to be KEAETQQKLANVVILATGGTIA. Besides l-glutamine, which was hydrolyzed with the highest specific activity (100%), l-asparagine (74%), d-glutamine (75%), and d-asparagine (67%) were also hydrolyzed. The pH and temperature optima were 9.0 and approximately 60°C, respectively. The enzyme was most stable at pH 8.0 and was highly stable (relative activities from 60 to 80%) over a wide pH range (5.0–10.0). About 70 and 50% of enzyme activity was retained even after treatment at 60 and 70°C, respectively, for 10 min. The enzyme showed high activity (86% of the original activity) in the presence of 16% NaCl. These results indicate that this enzyme has a higher salt tolerance and thermal stability than bacterial glutaminases that have been reported so far. In a model reaction of Japanese soy sauce fermentation, glutaminase from S. maltophilia exhibited high ability in the production of glutamic acid compared with glutaminases from Aspergillus oryzae, Escherichia coli, Pseudomonas citronellolis, and Micrococcus luteus, indicating that this enzyme is suitable for application in Japanese soy sauce fermentation.