Kinetic study of acid depolymerization of chitosan and effects of low molecular weight chitosan on erythrocyte rouleaux formation

In this study, the depolymerization of chitosan was carried out in an acetic acid aqueous solution and was followed by viscometry for molecular weight determination. It was found that the depolymerization rate increased with elevated temperatures and with high acid concentrations. Based on FTIR analysis, the chitosan was depolymerized randomly along the backbone; no other structural change was observed during the acid depolymerization process. Revealed in the TGA study, the degradation temperature and char yield of LMWCs (low molecular weight chitosan) were molecular weight dependent. The blood compatibility of LMWCs was also investigated: rouleaux formation was observed when erythrocyte contacted with LMWCs, which showed that LMWCs are able to interfere with the negatively charged cell membrane through its polycationic properties. Furthermore, as regards a kinetics investigation, the values of M_n (number-average molecular weight) were obtained from an experimentally determined relationship. The kinetics study showed that the complex salt, formed by amine on chitosan and acetic acid, acted as catalyst. Finally, the activation energy for the hydrolysis of the glycosidic linkage on chitosan was calculated to be 40 kJ/mol; the mechanism of acid depolymerization is proposed. In summary, LMWCs could be easily and numerously generated with acid depolymerization for further biological applications.     

Preparation of low molecular weight chitosan using solution plasma system

The solution plasma system was introduced to treat chitosan solution in order to prepare low molecular weight chitosan. The plasma treatment time was varied from 0 min to 300 min. The plasma-treated chitosan was characterized including viscosity, molecular weight by GPC, and chemical characteristics by FT-IR. The results showed that after treated with plasma for 15-60 min, the viscosity of chitosan solution and apparent molecular weight of chitosans were remarkably decreased, compared to those of untreated sample. Longer treatment time had less effect on both viscosity and molecular weight of samples. Eventually, long treatment time (≥180 min) showed no influence on both viscosity and apparent molecular weight. This suggested that the degradation process of chitosan occurred during plasma treatment. FT-IR analysis revealed that chemical structure of chitosan was not affected by solution plasma treatment. TOF-MS results showed that chitooligosaccharides with the degree of polymerization of 2-8 were also generated by solution plasma treatment. The results suggested that solution plasma system could be a potential method for the preparation of low molecular weight chitosan and chitooligosaccharides.     

A comparative study of high molecular weight proteins in various types of muscle across the animal kingdom

A wide range of phyla have been surveyed by SDS-PAGE for the new large proteins of the myofibril. Connectin (or titin) appears to be widely distributed. It is seen as a band of constant intensity and mobility in vertebrate striated muscle, but is absent from smooth muscle. It appears in more variable amounts, in a form of constant but greater mobility in many invertebrates: worms, molluscs (adductor but not gastropod feet), insects, a myriapod, and even in human blood platelets. Nebulin shares the same distribution in vertebrate muscles except for its notable absence in all heart muscle examined. It too is found in many invertebrates, not always with titin. It has been found in a worm, molluscs (adductor and gastropod feet), insects, crustaceans and an echinoderm. The mobility of nebulin varies within the vertebrates and more so between invertebrates (where, as with titin, it is greater). The isoforms of filamin in skeletal, cardiac, and smooth muscles of vertebrates are recorded. C-protein in rabbit muscles has four isoforms: white, alpha-red (X-protein), beta-red, and cardiac.     

3D QSAR study of hypolipidemic asarones by comparative molecular surface analysis

Three-dimensional quantitative structure-activity relationship (3D QSAR) modeled for alpha-asarone derivatives using the comparative molecular surface analysis (CoMSA) allowed us to reveal a correlation between the activity of these compounds and the electrostatic potential at the molecular surface. The grid formalism (s-CoMSA) allowed us to indicate a pharmacophore that is of key importance for compound activity. The CoMSA formalism coupled with the iterative variable elimination method gives a highly predictive model.     

Heavy chain of human high molecular weight and low molecular weight kininogens binds calcium ion

An antibody subpopulation, anti high molecular weight (anti-HMW) kininogen-Ca2+ antibody able to bind specifically to the HMW kininogen-Ca2+ complex, was isolated from anti-HMW kininogen antiserum. Partially purified anti-HMW kininogen antibody was applied to a HMW kininogen-Sepharose column equilibrated with 40 mM tris(hydroxymethyl)aminomethane hydrochloride buffer, pH 7.5, containing 1.0 M NaCl and 1 mM CaCl2, and anti-HMW kininogen-Ca2+ antibody was eluted with 5 mM ethylenediaminetetraacetic acid. As a result of characterization by enzyme-linked immunosorbent assay, this antibody specifically recognized the cyanogen bromide cleaved fragment 1 (CB-1) region (1-160 amino acid sequence) of the heavy chain of kininogen molecules in the presence of Ca2+ or Mg2+. Furthermore, circular dichroism (CD) experiments showed that the conformational changes of HMW kininogen and heavy chain were induced by metal ions such as Ca2+ and Mg2+ and that these changes were due to the conformational change of the CB-1 region of the heavy chain. The dissociation constant (Kd) for the heavy chain-Ca2+ measured by CD analysis at 214 nm was found to be 0.33 +/- 0.09 mM (mean +/- SD). The number of Ca2+-binding sites of heavy chain calculated from the Hill plot was 1.15 +/- 0.04 (mean +/- SD). Then, a possible Ca2+-binding site was found in the amino-terminal portion of the heavy chain of kininogen molecules.     

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.     

The effect of low molecular weight chitosan on bone resorption in vitro and in vivo.

We studied the effect of low molecular weight chitosan (LMWC) on the formation of osteoclast-like multinucleated cells (OCLs) in the co-culture of mouse osteoblastic cells and bone marrow cells in the presence of 1alpha,25-dihydroxyvitamin D3 [1alpha,25(OH)2D3]. LMWC at 440 microg/ml inhibited the formation of tartrate-resistant acid phosphatase (TRAP)-positive OCLs induced by 1alpha,25(OH)2D3. We prepared OCLs in the co-culture of osteoblastic cells and bone marrow cells. The effect of LMWC on pit formation by OCLs was examined using dentin slices, and LMWC inhibited pit formation at 440 microg/ml. Oral administration of the LMWC to ovariectomized rats prevented a decrease in bone mineral density (BMD) of the lumbar vertebra without affecting the body and uterus weights. These results suggested that LMWC prevented a decrease in BMD in vivo by inhibiting osteoclastic bone resorption.     

Covalent functionalization of multiwalled carbon nanotubes with a low molecular weight chitosan

Covalent functionalization of shortened multiwalled carbon nanotubes (MWNTs) with a natural low molecular weight chitosan (LMCS) was accomplished by a nucleophilic substitution reaction. Amino and primary hydroxyl groups of the LMCS contributed mainly to the formation of MWNT-LMCS conjugates. The LMCS content in the MWNT-LMCS is approximately 58 wt %, and approximately four molecular chains of the LMCS are attached to 1000 carbon atoms of the nanotube sidewalls. Most interestingly, the amorphous packing structure of the LMCS changed dramatically when it attached to the MWNTs. The MWNTs might induce the crystalline character of the LMCS. As a novel derivative of MWNTs, the MWNT-LMCS is soluble in dimethylformamide, dimethyl acetamide, dimethylsulfoxide, and acetic acid aqueous solution. The confirmation of the chitosan-based covalent functionalization route might lead to further studies aiming for potential applications in catalysis and environmental protection.     

Antitumor activity of chitosan from mayfly with comparison to commercially available low,medium and high molecular weight chitosans

Insects’ cuticles have a potential to be evaluated as a chitin source. Especially adults of aquatic insects like mayflies (order Ephemeroptera) swarm in enormous numbers in artificially lit areas while mating in spring and then die by leaving huge amounts of dead insects’ bodies. Here in this study, mayfly corpses were harvested and used for production of low MW chitosan. Dried mayfly bodies had 10.21% chitin content; mayfly chitin was converted into chitosan with efficiency rate of 78.43% (deacetylation degree, 84.3%; MW, 3.69 kDa). Cytotoxicity and anti-proliferative activity of mayfly and commercially available shrimp chitosans (low, medium, and high MW) were determined on L929 fibroblast and three different cancer types including HeLa, A549, and WiDr. Apoptosis and necrosis stimulating potential of mayfly and commercial chitosans were also evaluated on A549 and WiDr cells using acridine orange and propidium iodide dual staining to observe morphological changes in nuclei and thus to reveal the predominant cell death mechanism. The effects of chitosans have varied depending on cell types, concentration, and chitosan derivatives. Mayfly and low MW chitosans had a cytotoxic effect at a concentration of 500 μg mL^?1 on non-cancer cells. At concentrations below this value (250 μg mL^?1), mayfly and commercial chitosans except high MW one exhibited strong inhibitory activity on cancer cells especially A549 and WiDr cells. Mayfly chitosan induced early and late apoptosis in A549 cells, but late apoptosis and necrosis in WiDr cells. This study suggests that dead bodies of mayflies can be used for production of low MW chitosan with anti-proliferative activity.     

The molecular structure of low and high molecular weight levans synthesized by levansucrase

The levan synthesized by Bacillus subtilis levansucrase in the presence of alcohols was of only high molecular weight, while in solutions of high ionic strength only low molecular weight (MW) levan was produced. The addition of low MW levan to the enzyme reaction mixture at low ionic strength stimulated synthesis of a high MW levan, but the levan added was not incorporated into this high MW levan. Methylation analysis revealed that low MW levans contained glucose, which was isolated as 2,3,46-tetra-O-methyl alditol acetate showing that the glucose units existed as terminal residues. The molecular weight of levan estimated on the basis of glucose content coincided with that determined by the gel filtration method. Methylation analysis also revealed that the number of fructose residues of the linear fraction linked by leads to 6(F)2 leads to type bonds was 22 for levan with a molecular weight of (8.4(-22)) x 10(3), while it was 11 for that of 2,000 x 10(3). The number of (formula: see text) type branched residues increased with increase in the molecular weight of the levan synthesized.     

Biochemical activities of low molecular weight chitosans derived from squid pens

Chitosans were prepared by H₂O₂ oxidative depolymerization from squid pens with low molecular weights (LMW) of 13,025, 7011, 4169, 2242 and 963 Da. The bile acid binding capacities and antioxidant properties of LMW chitosans were studied in vitro. LMW chitosans exhibited stronger bile acid binding capacities than that of chitosan. The scavenging ability of LMW chitosans against DPPH radicals improved with increasing concentration, and EC₅₀ values were below 1.3 mg/mL. The EC₅₀ values of LMW chitosans against hydroxyl radicals ranged from 0.93 to 3.66 mg/mL. All LMW chitosans exhibited a strong ferrous ion chelating effect and reducing power. At 1 mg/mL, the scavenging ability of chitosan-963 towards superoxide radicals was 67.76%. These results indicated that LMW chitosans which have stronger bile acid binding capacity and antioxidant activities may act as potential antioxidants in vitro.     

Electrophoretic subfractionation of low and high molecular weight humic acids fractions

Summary Soil humic acid was fractionated on a molecular weight basis either using Sephadex gel filtration or electrophoresis on a discontinuous polyacrylamide gel. Low and high molecular weight fractions obtained by these two methods were choosen for subsequent subfractionation using electrophoretic methods. The high and low molecular weight fractions yielded several subfractions after separation by isotachophoresis or isoelectric focusing. Components of the high molecular weight fractions occupied the upper portion of the mobility train; components of the low molecular weight fractions lead the mobility train. Adsorption by Sephadex was avoided by using 4M urea as an eluent. The elution of the humic substances adsorbed to the polyacrylamide gel matrix was achieved by using a 0.1M Tris –0.025M EDTA solution.     

Mapping of functional domains of human high molecular weight and low molecular weight kininogens using murine monoclonal antibodies

Thirty-four monoclonal antibodies directed against human high molecular weight (HMW) and low molecular weight (LMW) kininogens and their derivatives were obtained, and the specificities of the antibodies were assayed by enzyme-linked immunosorbent assay (ELISA). By use of HMW kininogen, kinin-free HMW kininogen, kinin-free and fragment 1.2 (fr 1.2) free HMW kininogen, fr 1.2-light chain of HMW kininogen, LMW kininogen, kinin-free LMW kininogen, heavy chain of LMW kininogen, and light chain of LMW kininogen, the monoclonal antibodies were characterized and classified into four groups: (A) 20 monoclonal antibodies reacting with only the heavy chain, a common region of HMW and LMW kininogens; each of these monoclonal antibodies possessed the specificity to domain 1 (2 monoclonal antibodies), domain 2 (2 monoclonal antibodies), domain 3 (7 monoclonal antibodies), and both domains 2 and 3 (7 monoclonal antibodies) of the heavy chain; (B) 7 monoclonal antibodies reacting with fr 1.2, a unique histidine-rich region; (C) 5 monoclonal antibodies reacting with the light chain of HMW kininogen; (D) 2 monoclonal antibodies reacting with the light chain of LMW kininogen. Two monoclonal antibodies in the first group (group A), designated HKG H7 and H12, effectively suppressed the thiol proteinase inhibitor activity of HMW kininogen to papain and calpains and of LMW kininogen to papain, but the others did not affect it. Further, all the monoclonal antibodies which recognized the fr 1.2 or light chain of HMW kininogen (groups B and C) suppressed the clotting activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Antioxidant and hepatoprotective activities of low molecular weight sulfated polysaccharide from Laminaria japonica

A low molecular weight sulfated polysaccharide (LMWF) was prepared from Laminaria japonica by mild acid hydrolysis. The antioxidant activity of LMWF in vitro was studied using three kinds of oxygen free radical systems. LMWF had effective scavenging abilities on superoxide radical, hydroxyl radical and hypochlorous acid directly in vitro. The hepatoprotective effect of LMWF was studied using two acute liver injury mice models induced by carbon tetrachloride (CCl₄) and D-galactosamine (D-GalN). Addition of LMWF significantly lowered the content of serum malonaldehyde and markedly increased the activities of superoxide dismutase and glutathione peroxidase, compared with the model groups in both kinds of liver injury mice. Moreover, administration of LMWF significantly inhibited the elevation of glutamate pyruvate transaminase induced by CCl₄ and D-GalN in mice. The results suggest that the antioxidant activity of LMWF plays an important role in its hepatoprotective effect in the liver injury mice induced by CCl₄ and D-GalN.     

The high molecular weight and the low molecular weight acid phosphatases of the frog liver and their phosphotyrosine activity

1. Two molecular weight classes of non-specific acid phosphatases (AcPases) (3.1.3.2) are present in the frog (Rana esculenta) liver: a higher molecular weight (HMW) of Mr 140,560 and a lower molecular weight (LMW) of Mr 38,180 enzyme. 2. The LMW AcPase was described earlier and the HMW AcPase of optimum pH 4.8 is shown to be a L(+)-tartrate sensitive, thermolabile, dimeric glycoenzyme slightly activated by DTT. 3. The HMW and the LMW AcPases exhibit activity for phosphotyrosine which showed similar sensitivity to various effectors as the p-nitrophenyl phosphatase activity; however, both enzymes differed substantially in this respect suggesting that they might be involved in different metabolic steps.     

A tunable switch to regulate the synthesis of low and high molecular weight microbial polyesters

The addition of poly(ethylene glycol) (Mn = 200 g/mol) (PEG-200) to the fermentation media of Alcaligenes eutrophus and Alcaligenes latus at various stages of growth resulted in the synthesis of poly(3-hydroxybutyrate) (PHB) with bimodal molecular weight distributions. The presence of 2% w/v-PEG-200 did not have deleterious effects on PHB volumetric yields and cell productivity. In general, the Mn values of the high (H) and low (L) fractions showed little variability as a function of the time at which PEG-200 was added to the cultures. By this approach, the H:L ratios (w/w) of the PHB synthesized by A. eutrophus and A. latus were varied from 9:91 to 76:24 and from 16:84 to 88:12, respectively. It is believed that the H fractions were formed prior to the addition of PEG-200 to the cultures. Also, once PEG-200 was made available to the cells, PEG-200 acted as a switch so that the reduced molecular weight fraction was formed. In addition, a necessary requirement for the above is that the frequency of transesterification reactions during polymer synthesis was small. The efficiency that PEG-200 reduced the molecular weight of the PHBs formed by both bacteria appears similar. Indirect evidence suggests that the PHB L fractions formed by A. latus subsequent to PEG-200 addition consist primarily of chains that have PEG terminal groups. This terminal chain structure was not observed for PHB formed by A. eutrophus.