Purification and Characterization of Three Chitosanase Activities from Bacillus megaterium P1

Bacillus megaterium P1, a bacterial strain capable of hydrolyzing chitosan, was isolated from soil samples. Chitosan-degrading activity was induced by chitosan but not by its constituent d-glucosamine. Extracellular secretion of chitosanase reached levels corresponding to 1 U/ml under optimal conditions. Three chitosan-degrading proteins (chitosanases A, B, and C) were purified to homogeneity. Chitosanase A (43 kilodaltons) was highly specific for chitosan and represented the major chitosan-hydrolyzing species. Chitosanases B (39.5 kilodaltons) and C (22 kilodaltons) corresponded to minor activities and possessed comparable specific activities toward chitosan, chitin, and cellulose. Chitosanase A was active from pH 4.5 to 6.5 and was stable on the basis of activity up to 45 degrees C. The optimum temperature for enzymatic chitosan hydrolysis was 50 degrees C. Kinetic studies on chitosanase A suggest that the enzyme is substrate inhibited. The apparent K(m) and V(max) determined at 22 degrees C and pH 5.6 were 0.8 mg/ml and 280 U/mg, respectively. End products of chitosan hydrolysis by each of the three chitosanases were identified as glucosamine oligomers, similar to those obtained for previously reported chitosanase digestions.     

Extracellular Enzyme From Myxobacter AL-1 That Exhibits Both β-1,4-Glucanase and Chitosanase Activities

An enzyme that has both beta-1,4-glucanase and chitosanase activities is characterized. Evidence for homogeneity was obtained from electrophoresis and sedimentation velocity studies; only one N-terminal amino acid, valine, was found. Results of denaturation studies showed that beta-1,4-glucanase and chitosanase activities decreased at equal rates. With carboxymethylcellulose as the substrate, a K(m) of 1.68 g of carboxymethylcellulose per liter of solution and a V(max) of 2.20 x 10(-9) mol/min were found. With chitosan (the beta-1,4-polymer of glucosamine) as the substrate, a K(m) of 0.30 g of chitosan per liter of solution and a V(max) of 0.75 x 10(-9) mol/min were found. A pH optimum of 5.0 was found for beta-1,4-glucanase activity, and pH optima of 5.0 and 6.8 were found for chitosanase activity. beta-1,4-Glucanase activity had a temperature optimum of 38 C, and chitosanase activity had a temperature optimum of 70 C. Chitosan stabilized both enzyme activities at 70 C. Cellotriose was the smallest polymer capable of hydrolysis. Glucosamine was released by action of the enzyme upon cell wall preparations of several fungi.     

Fermentation conditions and properties of a chitosanase from Acinetobacter sp. C-17

A species of bacterium with high chitosanase activity was isolated from soil samples in Haiyan City, China, and identified as an Acinetobacter species. This strain, named Acinetobacter sp. strain C-17, produced a chitosanase that was inducible and secreted into the medium. The optimal conditions for enzyme production were cells used to inoculate a medium containing 1% chitosan (pH 7.0) followed by culture at 30 degrees C. The chitosanase activity reached 1.7 U/ml when strain C-17 was incubated in a 250-ml flask under the optimal conditions for 24 h, and reached 2.8 U/ml when cells were incubated in a 3-l fermentor. The optimal pH and temperature for hydrolysis of chitosanase were 7.0 and 36 degrees C, respectively. The chitosanase activity was stable in the pH range of 5-8 and temperature range of 30-40 degrees C. The chitosanase of the strain was extracted by zinc acetate and ammonium sulfate precipitation. The molecular mass was estimated to be 35.4 kDa by SDS-PAGE.     

Biochemical and molecular characterization of a thermostable chitosanase produced by the strain Paenibacillus sp. 1794 newly isolated from compost

Chitosan raises a great interest among biotechnologists due to its potential for applications in biomedical or environmental fields. Enzymatic hydrolysis of chitosan is a recognized method allowing control of its molecular size, making possible its optimization for a given application. During the industrial hydrolysis process of chitosan, viscosity is a major problem; which can be circumvented by raising the temperature of the chitosan solution. A thermostable chitosanase is compatible with enzymatic hydrolysis at higher temperatures thus allowing chitosan to be dissolved at higher concentrations. Following an extensive micro-plate screening of microbial isolates from various batches of shrimp shells compost, the strain 1794 was characterized and shown to produce a thermostable chitosanase. The isolate was identified as a novel member of the genus Paenibacillus, based on partial 16S rDNA and rpoB gene sequences. Using the chitosanase (Csn1794) produced by this strain, a linear time course of chitosan hydrolysis has been observed for at least 6 h at 70 °C. Csn1794 was purified and its molecular weight was estimated at 40 kDa by SDS-PAGE. Optimum pH was about 4.8, the apparent K _m and the catalytic constant k_cat were 0.042 mg/ml and 7,588 min^?1, respectively. The half-life of Csn1794 at 70 °C in the presence of chitosan substrate was >20 h. The activity of chitosanase 1794 varied little with the degree of N-acetylation of chitosan. The enzyme also hydrolyzed carboxymethylcellulose but not chitin. Chitosan or cellulose-derived hexasaccharides were cleaved preferentially in a symmetrical way (“3?+?3”) but hydrolysis rate was much faster for (GlcN)₆ than (Glc)₆. Gene cloning and sequencing revealed that Csn1794 belongs to family 8 of glycoside hydrolases. The enzyme should be useful in biotechnological applications of chitosan hydrolysis, dealing with concentrated chitosan solutions at high temperatures.     

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。     

Characterization and kinetics of 45 kDa chitosanase from Bacillus sp. P16

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 degrees C, and was stable between pH 4.5-10.0 and under 50 degrees C. The Km and Vmax were measured with a chitosan of a D.A. of 20.2% as 0.52 mg/ml and 7.71 x 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, k1 values, of 4.98 x 10(-4), 2.3 x 10(-4), and 9.3 x 10(-6) sec(-1), respectively. The enzyme hardly catalyzed degradation of chitooligomers smaller than the pentamer.     

Synthesis of exo-β-glucosaminidase BY FUNGUS <Emphasis Type="Italic">Penicillium</Emphasis> sp. IB-37-2

A new strain Penicillium sp. IB-37-2, which actively hydrolyzes chitosan (SD ～80–85%) but possesses low activity against colloidal chitin, was isolated. The fungus was observed to have a high level chitosanase biosynthesis (1.5–3.0 U/mL) during submerged cultivation at 28°C, with a pH of 3.5–7.0 and 220 rpm in nutrient media containing chitosan or chitin from shells of crabs. Purification of the chitosanase enzyme complex from Penicillium sp. IB-37-2 by ultrafiltration and hydrophobic chromatography, followed by denaturing electrophoresis, revealed two predominant proteins with molecular weights of 89 and 41 kDa. The purified enzyme complex demonstrated maximal activity (maximal rate of hydrolysis of dissolved chitosan) and stability at 50–55°C and a pH of 3.5–4.0. The enzyme preparation also hydrolyzed laminarin, β-(1,3)-(1,4)-glycan, and colloidal chitin. Exohydrolysis of chitosan by the preparation isolated from Penicillium sp. IB-37-2 resulted in the formation of single product, D-glucosamine.     

Purification and characterization of chitosanase and Exo-beta-D-glucosaminidase from a Koji mold, Aspergillus oryzae IAM2660

Chitosan-degrading activity was detected in the culture fluid of Aspergillus oryzae, A. sojae, and A. flavus among various fungal strains belonging to the genus Aspergillus. One of the strong producers, A. oryzae IAM2660 had a higher level of chitosanolytic activity when N-acetylglucosamine (GlcNAc) was used as a carbon source. Two chitosanolytic enzymes, 40 kDa and 135 kDa in molecular masses, were purified from the culture fluid of A. oryzae IAM2660. Viscosimetric assay and an analysis of reaction products by thin-layer chromatography clearly indicated the endo- and exo-type cleavage manner for the 40-kDa and 135-kDa enzymes, respectively. The 40-kDa enzyme, designated chitosanase, catalyzed a hydrolysis of glucosamine (GlcN) oligomers larger than pentamer, glycol chitosan, and chitosan with a low degree of acetylation (0-30%). The 135-kDa exo-beta-D-glucosaminidase,enzyme,named released a single GlcN residue from the GlcN oligomers and chitosan, but did not release GlcNAc residues from either GlcNAc oligomer or colloidal chitin.     

A new spectrophotometric method of assay for chitosanase based on calcofluor white dye binding

A new spectrophotometric method for the assay of chitosanase based on complex formation of the substrate chitosan with Calcofluor white dye is described. The absorption maximum for the chitosan-Calcofluor complex is determined to be 406 nm. The apparent minimum size of chitosan for complex formation is 5–7 kDa. Therefore, those enzymes that do not generate glucosamine or reducing groups as products of hydrolysis at levels not measurable by the available methods of assay can be assayed by the present method. In the standardized procedure 200 μg of chitosan in acetate buffer pH 4.5 with the enzyme in a reaction volume of 1.5ml is incubated at 45°C for 1 h, after which 1.5 ml of Calcofluor white (0.05%) is added, kept for 1h and absorbance at 406 nm measured by a spectrophotometer. The chitosanase unit is arbitrarily defined as the reduction in absorbance by 0.01/min.     

Two glutamic acids in chitosanase A from Matsuebacter chitosanotabidus 3001 are the catalytically important residues.

Chitosanase is the glycolytic enzyme that hydrolyzes the glucosamine GlcN-GlcN bonds of chitosan. To determine the catalytically important residues of chitosanase A (ChoA) from Matsuebacter chitosanotabidus 3001, we performed both site-directed and random mutagenesis of choA, obtaining 31 mutants. These mutations indicated that Glu-121 and Glu-141 were catalytically important residues, as mutation at these sites to Ala or Asp drastically decreased the enzymatic activity to 0.1-0.3% of that of the wild type enzyme. Glu-141 mutations remarkably decreased kinetic constant k(cat) for hydrolysis of chitosan, meanwhile Glu-121 mutations decreased the activities to undeterminable levels, precluding parameter analysis. No hydrolysis of (GlcN)(6) was observed with the purified Glu-121 mutant and extremely slow hydrolysis with the Glu-141 mutant. We also found that Asp-139, Asp-148, Arg-150, Gly-151, Asp-164, and Gly-280 were important residues for enzymatic activities, although they are not directly involved in catalysis. In addition, mutation of any of the six cysteine residues of ChoA abrogated the enzymatic activity, and Cys-136 and Cys-231 were found to form a disulfide bond. In support of the significance of the disulfide bond of ChoA, chitosanase activity was impaired on incubation with a reducing agent. Thus, ChoA from M. chitosanotabidus 3001 uses two glutamic acid residues as putative catalytic residues and has at least one disulfide bond.     

High yield production of monomer-free chitosan oligosaccharides by pepsin catalyzed hydrolysis of a high deacetylation degree chitosan

The high molecular weight of chitosan, which results in a poor solubility at neutral pH values and high viscosity aqueous solutions, limits its potential uses in the fields of food, health and agriculture. However, most of these limitations are overcome by chitosan oligosaccharides obtained by enzymatic hydrolysis of the polymer. Several commercial enzymes with different original specificities were assayed for their ability to hydrolyze a 93% deacetylation degree chitosan and compared with a chitosanase. According to the patterns of viscosity decrease and reducing end formation, three enzymes--cellulase, pepsin and lipase A--were found to be particularly suitable for hydrolyzing chitosan at a level comparable to that achieved by chitosanase. Unlike the appreciable levels of both 2-amino-2-deoxy-D-glucose and 2-acetamido-2-deoxy-D-glucose monomers released from chitosan by the other enzymes after a 20h-hydrolysis (4.6-9.1% of the total product weight), no monomer could be detected following pepsin cleavage. As a result, pepsin produced a higher yield of chitosan oligosaccharides than the other enzymes: 52% versus as much as 46%, respectively. Low molecular weight chitosans accounted for the remaining 48% of hydrolysis products. The calculated average polymerization degree of the products released by pepsin was around 16 units after 20h of hydrolysis. This product pattern and yield are proposed to be related to the bond cleavage specificity of pepsin and the high deacetylation degree of chitosan used as substrate. The optimal reaction conditions for hydrolysis of chitosan by pepsin were 40 degrees C and pH 4.5, and an enzyme/substrate ratio of 1:100 (w/w) for reactions longer than 1h.     

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     

A smart bioconjugate of alginate and pectinase with unusual biological activity toward chitosan

The commercial preparation of pectinase (Pectinex Ultra SP-L) was conjugated to alginate by noncovalent interactions by employing 1% alginate during the conjugation protocol. The optimum "immobilization efficiency" was 0.76. The pH optimum and the thermal stability of the enzyme remained unchanged upon conjugation with alginate. The soluble bioconjugate showed a 3-fold increase in V(max)/K(m) as compared to the free enzyme when the smart biocatalyst was used for chitosan hydrolysis. Time course hydrolysis of chitosan thus showed higher conversion of chitosan into reducing oligosaccharides/sugars. The smart bioconjugate could be reused five times without any detectable loss of chitosanase activity.     

Isolation and characterisation of chitosanase from Bacillus sp. 739 strain

The specific nature of the chitosanase activity of the strain Bacillus sp. 739 has been determined. Maximum enzyme activity was observed in a medium containing the biomass of the fruiting bodies of the fungus Macrolepiota procera. The chitosanase was purified to homogeneity using chromatography on DEAE-Sephadex A-50 and Toyopearl HW-50. The molecular weight of the enzyme, assessed by electrophoresis (the Laemmli procedure) approximated 46 kDa. Temperature and pH optima of the purified chitosanase were in the ranges 45-55 degrees C and 6.0-6.5, respectively. Time to half-maximum inactivation of the enzyme at 50 degrees C was equal to 1 h. With colloidal chitosan as the substrate, the value of K(M) of the purified chitosanase was equal to 25 mg/ml. The enzyme also exhibited a weak ability to hydrolyze colloidal chitin.     

Purification and some enzymatic properties of the chitosanase from Bacillus R-4 which lyses Rhizopus cell walls.

A strain of Bacillus sp (Bacillus R-4) produces a protease and a carbohydrolase both of which have the ability to lyse Rhizopus cell walls. Of the enzymes, the carbohydrolase has been purified to an ultracentrifugally and electrophoretically homogeneous state, and identified as a chitosanase. The enzyme was active on glycol chitosan as well as chitosan. Molecular weight of the purified enzyme was estimated as 31 000 and isoelectric point as pH 8.30. The enzyme was most active at pH 5.6 and at 40 degrees C with either Rhizopus cell wall or glycol chitosan as substrate, and was stable over a range of pH 4.5 to 7.5 at 40 degrees C for 3 h. The activity was lost by sulfhydryl reagents and restored by either reduced glutathione of L-cysteine. An abrupt decrease in viscosity of the reaction mixture suggested an endowise cleavage of chitosan by this enzyme.     

Metal complexes of crosslinked chitosans Part II. An investigation of their hydrolysis to chitooligosaccharides using chitosanase

This paper investigates the behavior of crosslinked chitosans and metal-complexed crosslinked chitosans under similar hydrolytic conditions. Crosslinked chitosans with trimellitic anhydride, diisocyanatohexane, and dibromodecane as crosslinking agents under heterogenous reaction conditions were used as metal complexing agents by equilibrating them with metal salts such as ZnCl₂, MnSO₄, CuSO₄, CdSO₄, Pb(NO₃)₂, and HgCl₂. Crosslinked chitosan without metal complexation had the same hydrolytic behavior as uncrosslinked chitosan. However, when the crosslinked chitosans were complexed with metals, their rates of hydrolysis and extent of hydrolysis were significantly reduced. Thus, while for chitosan about 840 μg/ml reducing sugar was produced in 4 h time, and 780 μg/ml was produced for diisocyanatohexane crosslinked chitosan, only 400 μg/ml and 320 μg/ml reducing sugars were produced for cadmium sulfate with crosslinked chitosan and diisocyanatohexane crosslinked chitosan, respectively. Similar results are obtained for other crosslinking agents. Studies on preincubation of the metal with the enzyme show that of the metals studied, Mn has no effect on preincubatioin with the enzyme, Hg, Cd, Pb, and Cu completely deactivates the enzyme, while Zn reduces the enzyme activity by about 43.3%. Preincubation of the metal salts with the chitosan shows that Hg and Cu completely deactivate the molecule from enzyme hydrolysis, Cd and Zn inactivate it to the extent of 56.8% and 43.3%, respectively, while Mn has no effect. Availability of the amino functions seems to be a key feature for the chitosanase to hydrolyze the chitosan polymer. This was also proved by the significant increase in the extent of hydrolysis for chitosan samples with 88% (final value 1120 μg/ml reducing sugar) and 85% deacetylation (final value 840 μg/ml reducing sugar). HPIC studies of the products show that a variety of oligomers are produced in the chitosanase enzyme hydrolytic reaction.     

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.     

Cloning of an endoglycanase gene from Paenibacillus cookii and characterization of the recombinant enzyme

An endoglycanase gene of Paenibacillus cookii SS-24 was cloned and sequenced. This Pgl8A gene had an open reading frame of 1,230 bp that encoded a putative signal sequence (31 amino acids) and mature enzyme (378 amino acids: 41,835 Da). The enzyme was most homologous to a β-1,3-1,4-glucanase of Bacillus circulans WL-12 with 84% identity. The recombinant enzyme hydrolyzed carboxymethyl cellulose, swollen celluloses, chitosan and lichenan but not Avicel, chitin powder or xylan. With chitosan as the substrate, the optimum temperature and hydrolysis products of the recombinant enzyme varied at pH 4.0 and 8.0. This is the first report that characterizes chitosanase activity under different pH conditions.     

Production, purification, and characterization of an extracellular chitosanase from Streptomyces.

The synthesis by Streptomyces sp. no. 6 of an extracellular chitosanase was induced by glucosamine. The enzyme was purified to homogeneity by Sephadex G-100, carboxymethyl-cellulose, and diethylaminoethyl-cellulose chromatography. The purified enzyme hydrolyzed chitosan (the beta-1,4-linked polymer of glucosamine) but not chitin nor carboxymethyl-cellulose. The only products of the hydrolysis detectable by paper chromatography were di- and triglucosamine. Sephadex G-100 chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated that the molecular weight of the enzyme was between 29,000 and 26,000. Acid hydrolysates of the enzyme contained no cysteic acid or glucosamine or other carbohydrate. At 25 C, maximum activity was obtained between pH 4.5 and 6.5. The enzymatic hydrolysis of chitosan occurred over a wide range of temperatures and was maximal at 60 C. The rate of the reaction was inhibited by concentrations of soluble chitosan higher than 0.5 g/liter. The apparent Km calculated from a Lineweaver-Burke plot was 0.688 g/liter at pH 5.5. The enzyme prevented spore germination and caused a significant decrease in the turbidity of germinated spore suspensions of the Mucor strains tested. Such a decrease was the result of a partial lysis of the cell wall.     

链霉菌壳聚糖酶的纯化及其酶学性质

分离纯化从烟台近海土壤筛选的链霉菌来源壳聚糖酶,并对其酶学性质进行研究。通过(NH4)2SO4分级沉淀分离得粗酶,透析后经Sephadex G-100柱纯化,得到2种壳聚糖酶(ChA和ChB)。SDS-聚丙烯酰胺凝胶电泳及Sephadex G-75凝胶过滤确定ChA的相对分子质量,研究ChA的最适底物水解条件、热稳定性、水解动力学及金属离子对酶活性影响。结果表明:ChA为单亚基蛋白,相对分子质量为4.16×104,在220和280 nm处呈现两个紫外吸收峰,催化水解壳聚糖的最适pH为5.0～5.5,最适温度为55℃。热稳定性实验表明:30℃温育1 h后酶活为初始酶活的33.3%,40℃温育1 h后酶活为初始酶活的22.2%。ChA的酶促反应初速率为6.2×10-3μmol/(mL.min),Vmax为0.318μmol/(mL.min),Km为1×10-2mg/mL,且对底物表现相对专一性。K+、Na+、Li+、Mg2+、Ca2+、Ba2+Zn2+、Cu2+和Co2+对ChA活力均表现为抑制作用,过渡金属离子Mn2+对酶有激活作用,重金属离子Hg2+、Ag+、Cd2+和Pb2+对酶均有较强的抑制作用。Mn2+和Zn2+的动力学研究表明,Mn2+对酶为混合型激活作用,Zn2+对酶为竞争性抑制作用。