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.     

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.     

Interaction of N-acylated and N-alkylated chitosans included in liposomes with lipopolysaccharide of gram-negative bacteria

The interactions of lipopolysaccharide (LPS) with the polycation chitosan and its derivatives — high molecular weight chitosans (300 kDa) with different degree of N-alkylation, its quaternized derivatives, N-monoacylated low molecular weight chitosans (5.5 kDa) — entrapped in anionic liposomes were studied. It was found that the addition of chitosans changes the surface potential and size of negatively charged liposomes, the magnitudes of which depend on the chitosan concentration. Acylated low molecular weight chitosan interacts with liposomes most effectively. The binding of alkylated high molecular weight chitosan with liposomes increases with the degree of its alkylation. The analysis of interaction of LPS with chitoliposomes has shown that LPS-binding activity decreased in the following order: liposomes coated with a hydrophobic chitosan derivatives > coated with chitosan > free liposomes. Liposomes with N-acylated low molecular weight chitosan bind LPS more effectively than liposomes coated with N-alkylated high molecular weight chitosans. The increase in positive charge on the molecules of N-alkylated high molecular weight chitosans at the cost of quaternization does not lead to useful increase in efficiency of binding chitosan with LPS. It was found that increase in LPS concentration leads to a change in surface ζ-potential of liposomes, an increase in average hydrodynamic diameter, and polydispersity of liposomes coated with N-acylated low molecular weight chitosan. The affinity of the interaction of LPS with a liposomal form of N-acylated chitosan increases in comparison with free liposomes. Computer simulation showed that the modification of the lipid bilayer of liposomes with N-acylated low molecular weight chitosan increases the binding of lipopolysaccharide without an O-specific polysaccharide with liposomes due to the formation of additional hydrogen and ionic bonds between the molecules of chitosan and LPS.     

Depolymerization of chitosan by chinolytic complex from Bacillus sp. 739

Low-molecular-weight (3-6 kDa) water-soluble chitosan was obtained by enzymatic depolymerization. Hydrolysis of crab chitosan was induced by O-glycoside hydrolase (EC 3.2.1), an extracellular chitinolytic complex from Bacillus sp. 739. The optimum conditions for hydrolysis were found (sodium-acetate buffer, pH 5.2; 55 degrees C; an enzyme/substrate ratio 4 U/g chitosan; 1 h).     

Depolymerization of Chitosan with a Chitinolytic Complex from Bacteria of the Genus Bacillussp. 739

Low-molecular-weight (3–6 kDa) water-soluble chitosan was obtained by enzymatic depolymerization. Hydrolysis of crab chitosan was induced by O-glycoside hydrolase (EC 3.2.1), the extracellular chitinolytic complex from Bacillussp. 739. The optimum conditions for hydrolysis were found (sodium–acetate buffer, pH 5.2; 55°C; and an enzyme/substrate ratio of 4 U per g chitosan; 1 h).     

Hydrolysis of chitozan with an enzyme complex from Myceliophthora sp.

Samples of low-molecular weight chitosan with molecular masses of 8–24 kDa, identical deacetylation degrees (85%), and polydispersity indexes soluble at pH 5–7 were obtained by enzymatic hydrolysis using an enzyme complex from the mycelial fungi Myceliophthora fergusii with yields of 50–80%. The optimal conditions for hydrolysis were found (pH 5.6, 37°C, an enzyme/substrate ratio 1/800, 15–60 min).     

The effect of high-molecular weight chitosans on the antioxidant and immune systems of the honeybee

High-molecular weight chitosan (200 kDa, 75% deacetylated) and N-succinoyl chitosan (300 kDa, 75% deacetylated) were shown to have a preadaptive effect and increase the lifespan of honeybees due to the induction of protective antioxidant and immune mechanisms. Chitosan with a molecular weight of 200 kDa had a fungistatic effect on a pathogenic fungus that causes ascospherosis, a disease of bee larvae and pupae.     

The antimicrobial action of low-molar-mass chitosan,chitosan derivatives and chitooligosaccharides on bifidobacteria

The crude fractions of chitooligosaccharides (COS) and low-molar-mass chitosans (LMWC) were prepared by enzyme hydrolysis of chitosan (CS). Specific growth rate of B. adolescentis, B. bifidum, B. breve, B. catenulatum, B. infantis and B. longum ssp. longum was determined in the presence of 0.025 and 0.5 % COS (<5 kDa), LMWC (5–10 kDa), and 0.025, 0.1 and 0.5 % of CS, chitosan succinate and chitosan glutamate in vitro. Minimum inhibitory concentrations (MIC; assayed by colony counting on TPY agar plates) of COS-LMWC and CS ranged from 0.025 % to 0.75 % of CS-LMWC. The growth of all bifidobacterial strains in the presence of chitosan, its derivatives and LMWC decreased at a concentration of 0.025 %; the bacterial growth was completely inhibited at a concentration of 0.5 %. COS did not show any inhibitory effect, an increased growth rate was even observed in the case of B. bifidum, B. catenulatum and B. infantis.     

Obtaining and study of monosaccharide derivatives of low-molecular-weight chitosan

The possibility of obtaining monosaccharide derivatives of low-molecular-weight chitosan with the use of the Maillard reaction was studied. Chitosan derivatives (molecular weight, 24 and 5 kDa) obtained with glucosamine, N-acetyl galactosamine, galactose, and mannose with a substitution degree of 4-14% and a yield of 60-80% were obtained. Some physicochemical and biological properties of these derivatives were studied. We showed that monosaccharide derivatives of low-molecular-weight chitosan exhibited antibacterial activity. Chitosan at a concentration of 0.01% caused 100% death of bacteria B. subtilis and E. coil. The strongest antibacterial effect was exhibited by 24-kDa derivatives: only 0.02-0.08% of cells survived. These derivatives were two orders of magnitude more effective than the 5-kDa chitosan modified with galactose.     

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.     

In vitro binding of human serum low-density lipoproteins by sulfated pectin derivatives

It was shown that sulfated pectin derivatives bind human serum low-density lipoproteins (LDLs) in vitro to a greater extent than native pectins. At the same time, the number of sulfate groups and the molecular weight of sulfated derivatives were crucial factors. The sulfated pectin derivatives with molecular weights more than 200 kDa containing 45 wt % sulfate groups had the greatest ability to bind LDLs, while the sulfated derivatives with molecular weights lower than 50 kDa containing 5% sulfate groups exhibited the lowest activity.     

Effect of chitosan derivatives on the reproduction of Coliphages T2 and T7

The effect of chitosan derivatives with different degrees of polymerization and deamination, as well as of chitosan 6-O-sulfate and chitosan N-succinate-6-O-sulfate, on the reproduction of coliphages T2 and T7 in Escherichia coli and on the growth of this bacterium was studied. Chitosan derivatives decreased the yield of coliphages and exhibited bactericidal activity. The efficiency of inhibition of viral infection and the bactericidal activity of chitosan were found to be dependent on the degree of its polymerization. At the same time, there was no correlation between the degree of chitosan deamination and the extent of inhibition of viral infection. Anionic chitosan derivatives virtually did not possess antiviral or bactericidal activity. It is assumed that chitosan blocks some stages of phage reproduction. The decrease in the phage-producing ability of E. coli may also be due to the bactericidal effect of chitosan.     

Obtaining and study of monosaccharide derivatives of low-molecular-weight chitosan

The possibility of obtaining monosaccharide derivatives of low-molecular-weight chitosan with the use of the Maillard reaction was studied. Chitosan derivatives (molecular weight, 24 and 5 kDa) obtained with glucosamine, N-acetyl galactosamine, galactose, and mannose with a substitution degree of 4–14% and a yield of 60–80% were obtained. Some physicochemical and biological properties of these derivatives were studied. We showed that monosaccharide derivatives of low-molecular-weight chitosan exhibited antibacterial activity. Chitosan at a concentration of 0.01% caused 100% death of bacteria B. subtilis and E. coli. The strongest antibacterial effect was exhibited by 24-kDa derivatives: only 0.02–0.08% of cells survived. These derivatives were two orders of magnitude more effective than the 5-kDa chitosan modified with galactose.     

Derivatives of chitin and chitosan as elicitors of potato resistance to late blight

Water-soluble low-molecular-weight (3-10 kDa) chitosan obtained by enzymatic degradation of high-molecular-weight chitosan, as well as its deaminated derivatives, can be used as elicitors of late blight resistance in potato.     

Chitin and chitosan derivatives as elicitors of potato resistance to late blight

Water-soluble low-molecular-weight (3–10 kDa) chitosan obtained by enzymatic degradation of high-molecular-weight chitosan, as well as its deaminated derivatives, can be used as elicitors of resistance to late blight in potato.     

Relevance of molecular weight of chitosan and its derivatives and their antioxidant activities in vitro

The antioxidant potency of different molecular weight (DMW) chitosan and sulfated chitosan derivatives was investigated employing various established in vitro systems, such as superoxide (O(2)(.-))/hydroxyl ((-.)OH) radicals scavenging, reducing power, iron ion chelating. As expected, we obtained several satisfying results, as follows: firstly, low molecular weight chitosan had stronger scavenging effect on O(2)(.-) and (-.)OH than high molecular weight chitosan. For example the O(2)(.-) scavenging activity of low molecular weight chitosan (9 kDa) and high molecular weight chitosan (760 kDa) were 85.86% and 35.50% at 1.6 mg/mL, respectively. Secondly, comparing with DMW chitosan, DMW sulfated chitosans had the stronger inhibition effect on O(2)(.-). At 0.05 mg/mL, the scavenging activity on O(2)(.-) reached 86.26% for low molecular weight chitosan sulfate (9 kDa), but that of low molecular weight chitosan (9 kDa) was 85.86% at 1.6 mg/mL. As concerning chitosan and sulfated chitosan of the same molecular weight, scavenging activities of sulfated chitosan on superoxide and hydroxyl radicals were more pronounced than that of chitosan. Thirdly, low molecular weight chitosan sulfate had more effective scavenging activity on O(2)(.-) and (-.)OH than that of high molecular weight chitosan sulfate. Fourthly, DMW chitosans and sulfated chitosans were efficient in the reducing power, especially LCTS. Their orders were found to be LCTS>CTS4>HCTS>CTS3>CTS2>CTS1>CTS. Fifthly, CTS4 showed more considerable ferrous ion-chelating potency than others. Finally, the scavenging rate and reducing power of DMW chitosan and sulfated derivatives increased with their increasing concentration. Moreover, change of DMW sulfated chitosans was the most pronounced within the experimental concentration. However, chelating effect of DMW chitosans were not concentration dependent except for CTS4 and CTS1.     

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.     

Chitosan Depolymerization by Enzymes from the Hepatopancreas of the Crab Paralithodes camtschaticus

An enzyme preparation was isolated from the hepatopancreas of Paralithodes camtschaticus thatexhibited chitinase and chitosanase activities. Treatment of chitin and chitosan with this preparation decreased their viscosity-average molecular weights by 96 and 41%, respectively. The chromatographic profiles of the products of chitin and chitosan hydrolysis suggested that the crab hepatopancreas is rich in endochitinases. Enzymatic digestion of chitosan increased its solubility and moderately reduced the extent of its acetylation. A mathematical approach was proposed for calculating the molecular weights of chitosan fractions from weight-average molecular weights determined viscometrically.     

Effect of chitosan derivatives on the reproduction of coliphages T2 and T7

The effect of chitosan derivatives with different degrees of polymerization and deamination, as well as of chitosan 6-O-sulfate and chitosanN-succinate-6-O-sulfate, on the reproduction of coliphages T2 and T7 inEscherichia coli and on the growth of this bacterium was studied. Chitosan derivatives decreased the yield of coliphages and exhibited antibacterial activity. The efficiency of inhibition of viral infection and the antibacterial activity of chitosan were found to be dependent on the degree of its polymerization. At the same time, there was no correlation between the degree of chitosan deamination and the extent of inhibition of viral infection. Anionic chitosan derivatives virtually did not possess antiviral or antibacterial activity. It is assumed that chitosan blocks some stages of phage reproduction. The decrease in the phage-producing ability ofE. coli may also be due to the antibacterial effect of chitosan.     

Chitosan depolymerization by enzymes from hepatopancreas of the crab Paralithodes camtschaticus

An enzyme preparation was isolated from the Paralithodes camtschaticus hepatopancreas that exhibited chitinase and chitosanase activities. Treatment of chitin and chitosan with this preparation decreased their viscosity-average molecular weights by 96 and 41%, respectively. The chromatographic profiles of the products of chitin and chitosan hydrolysis suggested that the crab hepatopancreas in rich in endochitinases. Enzymatic digestion of chitosan increased its solubility and moderately reduced the extent of its acetylation. A mathematical approach was proposed for calculating the molecular weights of chitosan fractions from weight-average molecular weights determined viscometrically.