The use of enzymatic preparation for the production of low molecular-weight chitosan from the king crab hepatopancrease

This article describes the optimal conditions for the enzymatic hydrolysis of chitosan and its chemically-modified derivatives using the preparation extracted from the king crab hepatopancrease possessing pronounced hydrolythic activity. The following preparations were used: chitosan with a molecular weight of 700 kDa and an acetylation level of 0.15, carboxymethyl chitosan 200 kDa witih an extent of replacement of 0.23, and N-succinyl chitosan 390 kDa with an extent of replacement of 0.8. Low molecular-weight samples of chitosan and of its modified derivatives were obtained with the yields of 85, 55, and 80%, respectively. The conditions of the hydrolysis were as follows: an enzyme: substrate ratio of 1: 200, 37°C, and 20 h duration of hydrolysis.     

Hydrolysis of Chitosan Sulfate with an Enzyme Complex from Streptomyces kurssanovii

The possibility of enzymatic hydrolysis of chitosan was shown. The optimum conditions for the process are sodium acetate buffer pH 6.0, 37°C, 24 h, and a chitosan sulfate–protein volume ratio of 500 : 1 in the enzyme preparation. During hydrolysis, the intrinsic viscosity of chitosan sulfate solution decreased by a factor of 2.7.     

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.     

Depolymerization of high-molecular-weight chitosan by the enzyme preparation Celloviridine G20x

A low-molecular-weight water-soluble chitosan was obtained from high-molecular-weight crab chitosan using the enzyme preparation Celloviridine G20x. Optimum conditions for the enzymatic hydrolysis were designed. The reaction should be performed for 4 h in a sodium-acetate buffer (pH 5.2) at 55 degrees C and the enzyme to substrate ratio of 1:400. Fractional extraction of chitosan hydrolysate by aqueous ethanol (ethanol: distilled water) yielded fractions with molecular weights in the range 3.2-26.4 kDa.     

Enzymatic method for determination of the degree of deacetylation of chitosan.

A new method was developed for the accurate determination of the degree of deacetylation of chitosan. The method involves the complete hydrolysis of chitosan to glucosamine and N-acetylglucosamine by a cooperative action of chitosanolytic enzymes exo-beta-D-glucosaminidase, beta-N-acetylhexosaminidase, and chitosanase, and subsequent determination of the monosaccharides by specific colorimetric assays or HPLC. The conditions required for the complete hydrolysis of chitosan were examined and the degree of deacetylation of several chitosan samples was determined.     

Depolymerization of High-Molecular-Weight Chitosan by the Enzyme Preparation Celloviridine G20x

A low-molecular-weight water-soluble chitosan was obtained from high-molecular-weight crab chitosan using the enzyme preparation Celloviridine G20x. Optimum conditions for enzymatic hydrolysis were designed. The reaction should be performed for 4 h in a sodium-acetate buffer (pH 5.2) at 55°C and an enzyme to substrate ratio of 1 : 400. Fractional extraction of chitosan hydrolysate by aqueous ethanol (ethanol:distilled water) yielded fractions with molecular weights in the range 3.2–26.4 kDa.     

The use of chitosan solutions for defatting and clarification of protein hydrolysates]

The possibility of the use of small amounts of chitosan for defatting and clarification of protein solutions prepared by enzymatic hydrolysis was tested. The following treatment conditions were shown to be optimal: chitosan concentration range, from 1.0 to 1.5 g per kg raw weight; pH of precipitation medium, from 8.0 to 8.5; and duration of incubation of protein hydrolysate solution with chitosan, less than 1 h. The hydrolysate defatting grade was found to depend on the degree of chitosan deacetylation. A possible mechanism of the chitosan-induced effects was suggested. The use of chitosan allows the mass fraction of enzyme protein hydrolysates to be reduced fourfold to fivefold.     

Effect of bipolar membrane electrobasification on chitosanase activity during chitosan hydrolysis

Chitosanase is an enzyme that hydrolyzes chitosan, a beta-(1-4) glucosamine polymer, into size-specific oligomers that have pharmaceutical and biological properties. The aim of the present work was to use the bipolar membrane technology, in particular the OH(-) stream produced by water splitting, for inactivation of chitosanase at alkaline pH in order to terminate the enzymatic reaction producing chitosan oligomers. The objectives consisted of studying the effect of pH: (a) on the stability of chitosanase, and (b) on the catalytic activity of chitosanase during chitosan hydrolysis. The enzyme was found to be stable in the pH range of 3-8 during at least 7h, and partially lost its activity after 1h at pH 8. The catalytic activity of chitosanase during chitosan hydrolysis decreased after pH adjustment by electrobasification. The reaction rate decreased by 50% from pH 5.5 to 6, whereas the reaction was completely inhibited at pH>7. The decrease of reaction rate was due to chitosan substrate insolubilization and chitosanase denaturation at alkaline pH values.     

Defatting and Clarification of Protein Hydrolysates by Using Chitosan Solutions

The possibility of the use of small amounts of chitosan for defatting and clarification of protein solutions prepared by enzymatic hydrolysis was tested. The following treatment conditions were shown to be optimal: a chitosan concentration range, from 1.0 to 1.5 gram per kilogram raw weight; pH of the precipitation medium from 8.0 to 8.5; and duration of the incubation of the protein hydrolysate solution with chitosan, less than 1 h. The hydrolysate defatting grade was found to depend on the degree of chitosan deacetylation. A possible mechanism of the chitosan-induced effects was suggested. The use of chitosan allows the mass fraction of enzyme protein hydrolysates to be reduced fourfold to fivefold.     

绿色木霉粗纤维素酶液水解壳聚糖的研究

利用自制绿色木霉粗纤维素酶液降解壳聚糖制备低聚壳聚糖.采用粘度法、乙酰丙酮法和还原糖浓度分析,研究了温度、pH值及反应时间等因素对壳聚糖水解程度和产物相对分子质量的影响,并采用质谱法对水解产物进行定性分析.结果表明,粗纤维素酶液水解壳聚糖作用的最适pH为5.0、最适反应温度为50 ℃、最适反应时间为12 h.粗纤维素酶...     

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.     

Enzymatic hydrolysis of chitosan films in water and physiological solution

It was shown that the processes of enzymatic hydrolysis of chitosan in aqueous acetic acid and on the surface of chitosan films in a solution of hyaluronidase in acetic acid are described by uniform kinetic constants. Kinetic parameters of enzymatic hydrolysis of the chitosan film samples in water and in physiological solution (Ringer–Locke’s solution) were determined. It was found that the introduction of medicinal agents and low-molecular-weight electrolytes to a chitosan-based film material reduces the rate of enzymatic hydrolysis of the films, which may indicate a possible increase in their service life when used on the wound surface.     

Chitooligosaccharides enzymatic production by Metarhizium anisopliae

The products of chitosan hydrolysis are chitooligosaccharides and are used mainly for medical applications due to their specific biological activities. The objective of this study was to detect and identify the products of enzymatic hydrolysis of chitosan (dimers to hexamers) using a crude extract of chitosanolytic enzymes produced by the fungus Metarhizium anisopliae. These fungus was able to produce, during 48 h cultivation in a medium containing chitosan, chitooligosaccharides ranging from dimers, trimers, tetramers and pentamers at concentrations 0.2, 0.19, 0.06, 0.04 mg/mL, respectively, and the enzymatic activity was 2.5 U/L. Using the crude enzyme extract for chitosan hydrolysis, we detected the presence of dimers to hexamers at hydrolysis times of 10, 20, 30, 40, 50 and 60 min of enzymatic reaction, but the yields were higher at 10 min (54%). The hexamers was obtained only with 30 min of reaction with concentration of 0.004 mg/mL.     

Effect of the degree of acetylation of chitosan on its enzymatic hydrolysis with the preparation Celloviridin G20x

The degree of acetylation exerted only insignificant effects on the enzymatic hydrolysis of chitosan, while affecting the composition of the resulting hydrolysates and their water solubility. Chitosan with various degrees of acetylation was produced by reacetylation of the original chitosan (the solvents, methanol and 2% acetic acid, were present at a ratio of 54:51 v/v; the amount of acetic anhydride was in the range 0.1-2.0 mmol per 1 g chitosan). Hydrolysis by the enzymatic preparation Celloviridin G20x was performed at the enzyme to substrate ratio of 1:400 in sodium-acetate buffer, pH 5.2 (55 degrees C) for 1 h.     

Preparation of low-molecular-weight chitosan using phosphoric acid

Two types of low degree of polymerisation (DP) chitosan were prepared by homogeneous hydrolysis of chitosan in 85% phosphoric acid at room temperature for 1–6 weeks. The hydrolysates were collected by addition of excess ethanol, and were fractionated by solubility in water. The changes in yields of water-insoluble (higher DP) and water-soluble (lower DP) fractions were determined as a function of hydrolysis time. The hydrolysis proceeded with further deacetylation of chitosan, resulting in degree of deacetylation of more than 90%. The water-insoluble fraction prepared after the hydrolysis for 4 weeks (43% yield) had a weight-average DP ( ) of 16·8, and showed the ‘tendon’ type X-ray diffraction pattern. The water-soluble fraction (12·5% yield) had a of 7·3, and showed the ‘annealed’ type pattern.     

Effect of the Degree of Acetylation of Chitosan on Its Enzymatic Hydrolysis with the Preparation Celloviridin G20kh

The degree of acetylation was shown to exert only insignificant effects on the enzymatic hydrolysis of chitosan, while affecting the composition of the resulting hydrolysates and their water solubility. Chitosan with various degrees of acetylation was produced by reacetylation of the initial chitosan (the solvents, methanol and 2% acetic acid, were present in a ratio of 54 : 51 v/v; the amount of acetic anhydride was in the range 0.1–2.0 mmol per gram chitosan). Hydrolysis by the enzymatic preparation Celloviridin G20kh was performed at an enzyme-to-substrate ratio of 1 : 400 in sodium–acetate buffer, pH 5.2 (55°C) for 1 h.     

Effect of Cephtriaxone and Cephtasidim Antibiotics on Enzymatic Hydrolysis of Chitosan-Based Pellicular Materials

Enzymatic hydrolysis of chitosan-based films supplemented with cephtasidim and cephtriaxone antibiotics on a substrate saturated with water, diluted acetic acid, or Ringer-Locke physiological saline was studied. Supplementation with antibiotics having the chemical structure of low molecular weight salts reduced the rate of enzymatic hydrolysis of chitosan regardless of the medium used. The decrease was related to the suppression of polyelectrolyte swelling of the polycation rather than enzyme inhibition. The addition of antibiotics to chitosan films can apparently be considered an approach to directed reduction of the film enzymatic hydrolysis rates, which may contribute to an increase in film lifetime on the wound surface.     

Isolation of Chitin and Chitosan from Honeybees

A procedure of isolation of chitin, chitosan, and water-soluble low-molecular-weight chitosan from the corpses of bees has been developed. This procedure includes deproteinization of bee corpses, discoloration of the chitin–melanin complex, deacetylation, and enzymatic hydrolysis of chitosan.     

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 of chitin and chitosan from honey bees

The procedure of isolation of chitin, chitosan, and water-soluble low-molecular-weight chitin from the corpses of bees was developed. This procedure included deproteinization of the corpses of bees, discoloration of the chitin-melanin complex, deacetylation, and enzymatic hydrolysis of chitosan.