The supramolecular structure of LPS-chitosan complexes of varied composition in relation to their biological activity.

The complexes of chitosan (Ch) with lipopolysaccharides (LPSs) from Escherichia coli O55:B5 (E-LPS) and Yersinia pseudotuberculosis 1B 598 (Y-LPS) of various weight compositions were investigated using quasi-elastic light scattering, ζ-potential distribution assay and atomic force microscopy. The alteration of ζ-potential of E-LPS-Ch complexes from negative to positive values depending on Ch content was detected. The Y-LPS-Ch complexes had similar positive ζ-potentials regardless of Ch content. The transformation of the supramolecular structure of E-LPS after binding with to Ch was revealed. Screening of E-LPS and Y-LPS particles by Ch in the complexes with high polycation was detected. The ability of LPS-Ch complex to induce biosynthesis of TNF-α and reactive oxygen species in stimulated human mononuclear cells was studied. A significant decrease in activity complexes compared to that of the initial LPS was observed only for E-LPS-Ch complexes.

Determination of the parameters of binding between lipopolysaccharide and chitosan and its N-acetylated derivative using a gravimetric piezoquartz biosensor.

The interaction of endotoxin (lipopolysaccharide - LPS) with low molecular weight chitosan (5.5 kDa), its N-acylated derivative and chitoliposomes was studied using a gravimetric piezoelectric quartz crystal microbalance biosensor. The optimal conditions for the formation of a biolayer based on immobilized LPS on the resonator surface and its regeneration were elaborated. The association and dissociation rate constants for LPS binding to chitosans were determined and the affinity constants (Kaf) were calculated based on the data on changes in the oscillation frequency of the quartz crystal resonator. The Kaf values correlated with the ones obtained using other methods. The affinity of N-acylated chitosan binding to LPS was higher than that of the parent chitosan binding to LPS. Based on the results obtained, we suggest that water-soluble N-acylated derivatives of chitosan with low degree of substitution of amino groups could be useful compounds for endotoxin binding and neutralization.

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.

[Sulfated polysaccharides of brown seaweeds--ligands of toll-like receptors].

The interaction of sulfated polysaccharides--fucoidans from brown seaweeds Laminaria japonica, Laminaria cichorioides and Fucus evanescens with Toll-like receptors (TLRs) expressed on membranes of embryonic human kidney epithelial cells (HEK293-null, HEK293-TLR2/CD14, HEK293-hTLR4/CD14-MD2 and HEK293-hTLR2/6) was investigated. In vitro fucoidans specifically interacted with TLR-2, TLR-4, and the heterodimer TLR-2/6 resultated in activation of transcription nuclear factor NF-kappaB. Analysis of composition the hydrolyzed fucoidan from F. evanescens was carried out by gas-liquid chromatography and chromatography-mass spectrometry. Results indicated the absence of 3-3-hydroxytetradecanoic acid (3-OHC14), the basic component of lipopolysaccharides in the preparation. Thus, the obtained results suggested that fucoidans from brown seaweeds possessing immunotropic activity are independent ligands for TLRs, and are able to induce genetically determined biochemical processes of protection organisms against pathogenic microorganisms.

[Chitosan antiviral activity: dependence on structure and depolymerization method].

Enzymatic (the action of lysozyme) and chemical (hydrogen peroxide) hydrolysis of chitosans with various degree ofacetylation (DA)--25, 17, and 1.5%--was performed. Purification and fractioning of the hydrolysis products were performed using dialysis, ultrafiltration, and gel-penetrating chromatography Low-molecular (LM) derivatives of the polysaccharide with molecular masses from 17 to 2 kDa were obtained. The study of their antiviral activity against the tobacco mosaic virus (TMV) showed that these samples inhibited the formation of local necroses induced by the virus for 50-90%. The antiviral activity of the LM chitosans significantly increased with the lowering of their polymerization degree. Furthermore, the products of the enzymatic hydrolysis possessed higher activity than the chitosan samples obtained as a result of chemical hydrolysis. It was revealed that the exhibition of the antiviral activity weakly depended on the degree of acetylation of the samples.

[Distribution of O-glycosylases in marine fungi of the Sea of Japan and the Sea of Okhotsk: characterization of exocellular N-acetyl-beta-D-glucosaminidase of the marine fungus Penicillium canescens].

The capacity to produce exocellular enmzymes was studied for 92 samples of fungi from various marine habitats in the Sea of Okhotsk (78 strains) and the Sea of Japan (14 strains). Strains producing highly active glycanases and glycosidases were found. Synthesis of O-glycosylhydrolases was stimulated by addition of laminaran to the nutrient medium. Highly purified N-acetyl-beta-D-glucosaminidase was isolated from the marine fungus Penicillium canescens. The molecular weight of the enzyme determined by SDS-Na-electrophoresis was 68 kDa. The enzyme displayed maximum activity at pH 4.5 and temperature 45 degrees C. Inactivation half-time of the enzyme at 50 degrees C was 25 min. N-acetyl-beta-D-glucosaminidase hydrolyzed both beta-glucosaminide and beta-galactosaminide bonds and possessed a high transglycosylazing activity.

Comparative study of electrokinetic potentials and binding affinity of lipopolysaccharides-chitosan complexes.

Electrokinetic properties of complexes of chitosan (Ch) with lipopolysaccharides (LPSs) from Escherichia coli O55:B5, Yersinia pseudotuberculosis 1B 598, and Proteus vulgaris O25 (48/57) and their size distribution were investigated using zeta-potential distribution assay and quasi-elastic light scattering. The interaction of LPS from different microorganisms with chitosan at the same w/w ratio of components (1:1) resulted in the formation of complexes in which the negative charge of LPS was neutralized (LPS from E. coli) or overcompensated (Y. pseudotuberculosis and P. vulgaris). The changing in size of the endotoxin aggregates during binding with chitosan was observed. The binding constants of chitosan with LPSs were determined by a method with using the anionic dye Orange II. The LPS from E. coli possess higher affinity to chitosan in comparison with the two others samples of endotoxin.

Interaction of chitosans and their N-acylated derivatives with lipopolysaccharide of gram-negative bacteria.

The interactions of lipopolysaccharide (LPS) with the natural polycation chitosan and its derivatives--high molecular weight chitosans (80 kD) with different degree of acetylation, low molecular weight chitosan (15 kD), acylated oligochitosan (5.5 kD) and chitooligosaccharides (biose, triose, and tetraose)--were studied using ligand-enzyme solid-phase assay. The LPS-binding activity of chitosans (80 kD) decreased with increase in acetylation degree. Affinity of LPS interaction with chitosans increased after introduction of a fatty acid residue at the reducing end of chitosan. Activity of N-monoacylated chitooligosaccharides decreased in the order: oligochitosan --> tetra- > tri- --> disaccharides. The three-dimensional structures of complexes of R-LPS and chitosans with different degree of acetylation, chitooligosaccharides, and their N-monoacylated derivatives were generated by molecular modeling. The number of bonds stabilizing the complexes and the energy of LPS binding with chitosans decreased with increase in acetate group content in chitosans and resulted in changing of binding sites. It was shown that binding sites of chitooligosaccharides on R-LPS overlapped and chitooligosaccharide binding energies increased with increase in number of monosaccharide residues in chitosan molecules. The input of the hydrophobic fragment in complex formation energy is most prominent for complexes in water phase and is due to the hydrophobic interaction of chitooligosaccharide acyl fragment with fatty acid residues of LPS.

Determination of binding constants of lipopolysaccharides of different structure with chitosan.

The interaction of endotoxins--lipopolysaccharides (LPS) different in degree of the O-specific chain polymerization--with 20- and 130-kD chitosan was studied using the competitive binding of LPS with the complex of chitosan-anionic dye (tropaeolin 000-2) and the direct binding of (125)I-labeled LPS with chitosan immobilized on Sepharose 4B. The interaction of 20-kD chitosan with LPS was non-cooperative, and immobilization of the polycation on Sepharose resulted in its binding to (125)I-labeled LPS with a positive cooperativity. The interaction of LPS possessing a long O-specific chain with 130-kD chitosan was characterized by negative cooperativity. Binding constants of LPS with the polycation and the number of binding sites per amino group of chitosan were determined. The interaction affinity and stoichiometry of the LPS-chitosan complexes significantly depend on the LPS structure and concentration in the reaction mixture. The increase in the length of carbohydrate chains of LPS results in increase in the binding constants and decrease in the bound endotoxin amount.

Modification of biological activity of lipopolysaccharide in the complex with chitosan.

In the complex with chitosan, lipopolysaccharide partially lost its ability to induce lymphokines tumor necrosis factor and interleukin-8, but retained immunostimulating properties and increased phagocytic function of macrophages by improving digestion of bacteria.

Applications of electron-ion dissociation reactions for analysis of polycationic chitooligosaccharides in Fourier transform mass spectrometry.

Singly protonated, doubly protonated, and sodiated pentaglucosamide (GlcNAc)(5), oligoglucosamines (GlcN)(m)(), and (GlcN)(3)GlcN(3OH14:0) were analyzed in an FTICR mass spectrometer by electron-ion dissociation reactions and compared to collision activation. The general fragmentation mode was found as the asymmetrical sequence fragments (B(n)() and minor C(n)() ion series) with full sequence coverage. Molecular mass information of each glucosamide or glucosamine residue can be readily obtained from the ion series. Fragmentation by electron capture dissociation revealed additional fragmentation of the N-acetyl moiety compared to sustained off-resonance irradiation collision-activated dissociation (SORI-CAD) and electron-induced dissociation (EID). Sodiated GlcNAc(5) molecular adduct ions were analyzed by EID and compared to CAD. Both techniques provided full sequence coverage. EID was more effective, but CAD resulted in the cross-ring ion products (0,2)A(n)() and (2,4)A(n)() for all relevant glucosamide residues.

Effect of ionic carbohydrate-containing biopolymers on complement activation.

We studied in vitro effects of charged polysaccharides on the classic and alternative pathways of complement activation. The complement system was affected by substances having different charges. Our findings suggest that the conformation of polysaccharide molecules, but not their charge, plays a primary role in the interaction with C1 and C3 complement components followed by initiation of cascade enzymatic reactions.

Interaction of bacterial endotoxins with chitosan. Effect of endotoxin structure, chitosan molecular mass, and ionic strength of the solution on the formation of the complex.

The interaction of endotoxins of different structure (lipopolysaccharides (LPS) and lipopolysaccharide-protein complexes (LPPC)) with chitosan has been studied. It was shown that the mechanism of interaction is rather complicated and depends on the macromolecular organization of endotoxin as well as on the degree of polymerization of the chitosan. Chitosan with molecular mass of 20 kD reveals higher affinity to LPS than chitosan with molecular mass of 140 kD. Endotoxins with long O-specific chains can bind completely with chitosan with the formation of LPS-chitosan and LPPC-chitosan complexes with weight ratios between the original components of 1:1 and 1:5. When endotoxins with higher degree of hydrophobicity and short O-specific chains were mixed with chitosan, a part of the LPS remained unbound. The stability of the complexes formed depends on ionic strength. It was shown that, in addition to electrostatic forces, other types of forces take part in the formation of the complexes. A decrease in acute toxicity of various LPSs is observed on their binding with chitosans.

[Comparative study of the physico-chemical properties of chitosans with varying degree of polymerization in neutral aqueous solutions]. / Sravnitel'noe izuchenie fiziko-khimicheskikh svoistv khitozanov razlichnoi stepeni polimerizatsii v neitral'nykh vodnykh rastvorakh.

The physicochemical properties of chitosan samples with high (130 kD) and low (30 kD) molecular masses in neutral aqueous solutions (pH 6.0) were studied by the methods of high-speed and equilibrium sedimentation, viscosimetry, and NMR and UV spectroscopies. Differences in the hydrodynamic characteristics of the samples were revealed. It was found that low-molecular-weight chitosan represents flexible linear macromolecules which undergo conformational changes upon temperature increase. The high-molecular-weight chitosan forms more rigid asymmetric structures whose conformation does not vary significantly with temperature increase. It was found that the high-molecular-weight chitosan has a higher constant of binding to the anionic dye tropeoline 000-II, which can be explained by different conformations of their macromolecules in solution.

The effect of temperature on the interaction of Yersinia pseudotuberculosis lipopolysaccharide with chitosan.

The mechanism of binding of lipopolysaccharide (LPS) from Yersinia pseudotuberculosis to low-molecular-weight chitosan was investigated using sedimentation analysis, centrifugation in glycerol and percoll density gradients, and isopicnic centrifugation in cesium chloride. The LPS interaction with chitosan was shown to be a multistage process that depended on time and reaction temperature. A stable LPS-chitosan complex could be formed only after preliminary incubation of the initial components at an elevated temperature (37 degrees C). This temperature caused the LPS dissociation and promoted its binding to chitosan. The LPS binding to chitosan results in further dissociation of the endotoxin and formation of the complex with a molecular weight that is tens of times less than the initial molecular weight of LPS. The obtained complex remained stable in solutions of high ionic strength.

New glycolipids (chitooligosaccharide derivatives) possessing immunostimulating and antitumor activities.

New glycolipids, derived from chitooligosaccharides of dp 2-4 and containing both free and acylated amino groups, were synthesized. The structure of the key compounds (di-, tri-, and tetra-saccharides acylated with different fatty acids) were elucidated by 13C NMR spectroscopy. Only the amino group of the reducing end of the chitooligosaccharides was found to be acylated when equimolecular amounts of reagents were used. The compounds obtained were shown to possess a low toxicity and certain immunostimulatory and antitumor activities. An induction of interleukin-1 and tumor necrosis factor by the immunocompetent cells and an augmentation by 140-180% of the mean life of mice with the Erlich carcinoma were observed.

[Interaction of the outer membrane pore-forming protein of Yersinia pseudotuberculosis with lipid A and its synthetic analogs]. / Vzaimodeistvie poroobrazuiushchego belka vneshnei membrany Yersinia pseudotuberculosis s lipidom A i ego sinteticheskimi analogami.

Interaction of the major outer membrane protein form Yersinia pseudotuberculosis with lipid A was investigated by intrinsic fluorescence, CD spectroscopy and CsCl gradient centrifugation methods. The protein was shown to have two independent binding sites with an association constant 6.1 x 10(4) M-1. The interaction depends on both the type of the glycoside bond and hydrophilic--hydrophobic balance of the glycolipid molecule.

[Synthesis of lipid A analogs: achievements and perspective]. / Sintez analogov lipida A: dostizheniia i perspektivy.

Data on the synthesis of analogues of lipid A, a biologically active fragment of gram-negative bacteria's lipopolysaccharides, are summarized. Main types of the compounds obtained are systematized, and problems of the synthesis of various parts of the molecule considered. The results of studying biological activity of lipid A analogues are discussed, which led to some conclusions on the structure-function relation. Perspectives of further studies are briefly outlived.

[Synthesis of lipid A analogs. Preparation of serologically active glycolipids on the basis of beta-1,4-glucosaminobiose (chitobiose)]. / Sintez analogov lipida A. Poluchenie serologicheski aktivnykh glikolipidov na osnove beta-1,4-gliukozaminobiozy (khitobiozy).

Synthesis of beta-1,4-glucosaminobiose (chitobiose) 4'-phosphates N,N'-diacylated with (R)-3-hydroxymyristic acid is described, the structure being corroborated by 13C-NMR spectra. It was shown that activity of the components in various reactions with antibodies to lipid A from Yersinia pseudotuberculosis is similar to the lipid A activity.