Mobility of lipid in complexes of amylose–fatty acids by deuterium and C solid state NMR

Palmitic and lauric acid complexes with amylose were studied by solid state methods: ¹³C CP/MAS NMR, deuterium NMR, X-ray powder diffraction and differential scanning calorimetry (DSC). The crystalline amylose complexes were found to be in a V-type sixfold single chain helix. The melting points of the complexes were over 100°C, at least 40–50°C higher than the melting points of the free fatty acids. CP/MAS ¹³C NMR spectra revealed two resonance peaks at 33.6 and 32.4 ppm for the palmitic acid, which were assigned as free and complexed fatty acid, respectively. A single resonance peak at 32.4 ppm was found for the lauric acid and assigned to the complex. The chemical shift of 32.4 ppm for the complexed fatty acids suggests a combined trans and gauche conformation for the fatty acid chain in the complex. T₁ relaxation measurements on the two palmitic acid resonances show different behavior: a very slow relaxation for the 33.6 ppm and a much faster relaxation (1.2 s) for the 32.4 ppm resonances. The latter was similar to the relaxation of the single resonance of the lauric acid (1.1 s). Temperature dependent deuterium spectra of the amylose–lauric acid and amylose–palmitic acid complexes suggest a complete complexation for the amylose–lauric acid, whereas the amylose–palmitic acid complex is partially disassociated by the thermal treatment. Based on the overall data, a partially disordered model is proposed: an imperfect helix with the fatty acid partly inside and partly out, depending on crystallization conditions and the necessity of placing the carboxyl head outside the V-helix.     

Role of organic solvents on Pa-hydroxynitrile lyase interfacial activity and stability

Catalytic activity and adsorption of Pa-hydroxynitrile lyase (Pa-Hnl) was investigated at various organic solvent/water interfaces. We focused on the role of solvent polarity in promoting activity and stability in two-phase systems, specifically for the solvents heptane, dibutyl ether (DBE), diisopropyl ether (DIPE), butylmethyl ether (BME), and methyl tert-butyl ether (MTBE). Enzyme activity towards mandelonitrile cleavage was determined in a recycle reactor with a well-defined interfacial area as described by Hickel, et al. 1999. Here the recycle reactor was modified to permit exchange of the aqueous phase. With this modification, irreversibility of enzyme adsorption was determined as a function of the adsorption time at the interface. Irreversibility of enzyme adsorption was also investigated by measuring the surface pressure of a sessile-drop upon washout. We find that Pa-Hnl exhibits the highest stability but the lowest initial catalytic activity at the aqueous/organic solvent interface with the most polar organic solvents. Thus, DIPE and MTBE display no loss in enzyme activity over a period of several hours. However, the more apolar the solvent is the higher the initial Pa-Hnl activity, but the faster the loss of activity. Dynamic tensiometry reveals that Pa-Hnl adsorbs more strongly at the interface of the more apolar solvents. Surprisingly, Pa-Hnl develops some irreversible adsorption after 30 min at the DIPE/water interface, but does not lose catalytic activity.     

Candida Antarctica Lipase B-Catalysed Synthesis Of Dihydroxyacetone Fatty Acid Esters

The enzymatic syntheses of 1-lauroyl-dihydroxyacetone and 1, 3-dilauroyl-dihydroxyacetone were investigated. Lipase B from Candida Antarctica (SP435) was used to catalyse the acylation of dihydroxyacetone (DHA) with lauric acid in organic solvent media at controlled water activity. High conversions of dihydroxyacetone (< 90%) are achieved when the water activity is 0.11 or below in solvents of various hydrophobicities, such as diethyl ether, methyl-terr-butyl ether (MTBE) and diphenyl ether. The main product in the esterification of DHA with lauric acid is 1-lauroyl-DHA, while the amount of 1, 3-dilauroyl-DHA that is produced can be increased by changing the reaction conditions. Thus, hasing the water activity from 0.75 to 0.06 resulted in an increase in the total yield of 1, 3-dilauroyl-DHA from 3% to 20%. Solvents which have high logP values favoured the acylation of 1-lauroyl-DHA and thereby the formation of 1, 3-dilauroyl-DHA. Thus, when diphenyl ether was used in this reaction, the yield of 1, 3-dilauroyl-DHA was 45%. Complete acylation to 1, 3-dilauroyl-DHA was achieved when a fatty acid vinyl ester was used as acyl donor in a closed reactor.     

Regulation of carboxylester lipase adsorption to surfaces. 2. Physical state specificity

The physical specificity of adsorption of porcine pancreatic carboxylester lipase to mixed-lipid surfaces was examined by using films at the argon-buffer interface. They were comprised of 1-palmitoyl-2-oleoylphosphatidylcholine and triolein, 1,3-diolein, methyl oleate, oleonitrile, oleyl alcohol, or 13,16-docosadienoic acid. Under conditions where the surfaces are thermodynamically well-defined, each of these binary systems exhibits the formation of a lipid-lipid complex that is completely miscible with uncomplexed non-phospholipid [Smaby, J. M., & Brockman, H. L. (1985) Biophys. J. 48, 701-707]. Initial rates of adsorption of enzyme to the complexes were less than or equal to 5% of those measured in the absence of phospholipid and comparable to its rate of adsorption to phospholipid alone. This occurred despite there being up to 46% of the surface area occupied by non-phospholipid in the complexes. Equilibrium binding measurements were made at a composition where phospholipid-fatty acid complex was the predominant species. These showed that the low rates were due to an absence of adsorption sites relative to surfaces of fatty acid alone. With diolein or fatty acid and phospholipid, equilibrium binding was also measured at compositions intermediate between that of the complex and pure non-phospholipid. In both systems surface concentrations of enzyme varied nonideally with respect to either the mole fraction or area fraction of complex and uncomplexed diolein or fatty acid in the film. At area fractions of uncomplexed lipid of 0.35 and 0.67, dissociation constants for enzyme adsorption were increased 10-20-fold relative to pure fatty acid or diolein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Solvation properties of ubiquinone-10 in solvents of different polarity

The solvation properties of ubiquinone-10 and ubiquinol-10 in a wide variety of solvents of polarity varying from alkanes to water are reported. Greatest solubility is observed in solvents of intermediate polarity and particularly where low polarity is combined with a pronounced tendency to interact with the benzoquinone substituent of the ubiquinone molecule. This includes solvents like chloroform and benzene. Ubiquinone-10 is somewhat less polar than ubiquinol-10 as judged by comparative solubilities of the two molecules. Proton-NMR chemical shift measurements and aggregation studies in selected solvents indicate that in ubiquinone-10 in the liquid phase and in solution in hydrocarbons like dodecane the molecules have a preferred association possibly involving stacking of the benzoquinone rings. Surface balance studies indicated that the surface-active character of ubiquinone-10 is relatively weak and only in a comparatively polar and highly structured solvent, formamide, was there evidence of an effect on surface tension of the solvent. The critical micelle concentratiom in this solvent was estimated to be about 5 M on the basis of surface tension measurements. Ubiquinone-10 is well known to form virtually insoluble monolayers at the air/water interface. Studies of the partition of ubiquinone-10 in binary mixtures of solvents suggest that the interaction of the benzoquinone ring substituent with structured polar solvents is considerably weaker than the internal cohesion between molecules of the solvent. No evidence on the basis of wide-angle X-ray diffraction measurements was obtained to indicate that solvent molecules were a component of the crystal lattice of ubiquinone-10 that had precipitated from solvent mixtures.     

Thermal stability of fatty acid-serum albumin complexes studied by differential scanning calorimetry.

Differential scanning calorimetry has been used to study the thermal stability of bovine serum albumin as affected by binding of fatty acids (lauric acid and stearic acid) and sodium dodecyl sulfate (SDS). All the ligands stabilized the protein molecules in a similar manner, but to different levels. A maximum increase in denaturation temperature of 30 degrees C was obtained with lauric acid. The thermograms indicate the presence of several ligand-albumin complexes having different heat stabilities. Variations in pH in 0.9% NaCl affected the heat stability of both ligand-poor and ligand-rich albumin, the former being more sensitive to variations in pH within the physiological range. Variations in NaCl concentration affected the thermal stabilities at neutral pH, expecially at low salt concentrations. While ligand-rich albumin was somewhat destabilized by increasing NaCl concentrations, ligand-poor albumin was strongly stabilized. The potential use of differential scanning calorimetry in ligand-albumin research is discussed.     

Titration and exchange studies of liver fatty acid-binding protein with 13C-labeled long-chain fatty acids

Uniformly (13)C-labeled long-chain fatty acids were used to probe ligand binding to rat liver fatty acid-binding protein (LFABP), an atypical member of the fatty acid-binding protein (FABP) family that binds more than one molecule of long-chain fatty acid, accommodates a variety of diverse ligands, and exhibits diffusion-mediated lipid transport to membranes. Two sets of (1)H-(13)C resonances were found in a titration series of NMR spectra for oleate-LFABP complexes, indicating that two molecules of the fatty acid are situated in the protein cavity. However, no distinct resonances were observed for the excess fatty acid in solution, suggesting that at least one ligand undergoes rapid exchange with oleate in the bulk solution. An exchange rate of 54 +/- 6 s(-1) between the two sets of resonances was measured directly using (13)C z,z-exchange spectroscopy. In light of these NMR measurements, possible molecular mechanisms for the ligand-exchange process are evaluated and implications for the anomalous fatty acid transport mechanism of LFABP are discussed.     

Beta-oxidation of medium chain (C8-C14) fatty acids studied in isolated liver cells

The beta-oxidation and esterification of medium-chain fatty acids were studied in hepatocytes from fasted, fed and fructose-refed rats. The beta-oxidation of lauric acid (12:0) was less inhibited by fructose refeeding and by (+)-decanoyl-carnitine than the oxidation of oleic acid was, suggesting a peroxisomal beta-oxidation of lauric acid. Little lauric acid was esterified in triacylglycerol fraction, except at high substrate concentrations or in the fructose-refed state. With [1-14C]myristic acid (14:0), [1-14C]lauric acid (12:0), [1-14C]octanoic acid (8:0) and [2-14C]adrenic acid (22:4(n - 6] as substrate for hepatocytes from carbohydrate-refed rats, a large fraction of the 14C-labelled esterified fatty acids consisted of newly synthesized palmitic acid (16:0), stearic acid (18:0) and oleic acid (18:1) while intact [1-14C]oleic acid substrate was esterified directly. With [9,10-3H]myristic acid as the substrate, small amounts of shortened 3H-labelled beta-oxidation intermediates were found. With [U-14C]palmitic acid, no shortened fatty acids were detected. It was concluded that when the mitochondrial fatty acid oxidation is down-regulated such as in the carbohydrate-refed state, medium-chain fatty acids can partly be retailored to long-chain fatty acids by peroxisomal beta-oxidation followed by synthesis of C16 and C16 fatty acids which can then stored as triacylglycerol.     

Saturated and polyunsaturated fatty acids reciprocally modulate dendritic cell functions mediated through TLR4

TLRs provide critical signals to induce innate immune responses in APCs such as dendritic cells (DCs) that in turn link to adaptive immune responses. Results from our previous studies demonstrated that saturated fatty acids activate TLRs, whereas n-3 polyunsaturated fatty acids inhibit agonist-induced TLR activation. These results raise a significant question as to whether fatty acids differentially modulate immune responses mediated through TLR activation. The results presented in this study demonstrate that the saturated fatty acid, lauric acid, up-regulates the expression of costimulatory molecules (CD40, CD80, and CD86), MHC class II, and cytokines (IL-12p70 and IL-6) in bone marrow-derived DCs. The dominant negative mutant of TLR4 or its downstream signaling components inhibits lauric acid-induced expression of a CD86 promoter-reporter gene. In contrast, an n-3 polyunsaturated fatty acid, docosahexaenoic acid, inhibits TLR4 agonist (LPS)-induced up-regulation of the costimulatory molecules, MHC class II, and cytokine production. Similarly, DCs treated with lauric acid show increased T cell activation capacity, whereas docosahexaenoic acid inhibits T cell activation induced by LPS-treated DCs. Together, our results demonstrate that the reciprocal modulation of both innate and adaptive immune responses by saturated fatty acid and n-3 polyunsaturated fatty acid is mediated at least in part through TLRs. These results imply that TLRs are involved in sterile inflammation and immune responses induced by nonmicrobial endogenous molecules. These results shed new light in understanding how types of dietary fatty acids differentially modulate immune responses that could alter the risk of many chronic diseases.     

酸枣果抗菌增敏活性成分的提取及生物学活性研究

采用不同极性的溶剂,从野生酸枣果和木枣果中由低极性到高极性依次提取获得不同极性范围的提取物,通过检测其抗菌作用和提取物与抗生素的协同抗菌作用,从中筛选具有抗菌增敏作用的活性提取物,并经活性追踪的柱层析分离纯化进一步得到活性精提物,通过GC-MS分析确定其组成成分,最后检测了该活性精提物的生物学活性。结果表明:(1)在所有的枣果提取物中仅酸枣果氯仿提取物具有广谱的抗菌作用,并能显著增强铜绿假单胞菌对氨苄青霉素的敏感性,而其他提取物均无相应的生物学活性。(2)由酸枣果氯仿提取物进一步精制得到的Fr.2a组分,经GC-MS初步分析显示它包含49.59%1,3-二氯丙醇、5.49%1,1-二氯甲醚、0.96%六氯乙烷、7.81%1,1,2,3-四氯-2-丙烯、1.33%月桂酸、1.34%十四酸、0.87%棕榈油酸、7.37%棕榈酸、9.75%邻苯二甲酸二丁酯、2.02%反式-13-十八碳烯酸、1.88%油酸酰胺、3.06%β-香树精、0.93%α-菖蒲醇、6.20%羽扇豆醇和1.42%乌索醛等成分。(3)酸枣活性提取物Fr.2a与多种抗生素联用显示出广泛的协同抗菌作用,同时Fr.2a呈剂量依赖性地促进微生物生物膜的形成,降低微生物的运动性和显著抑制牛奶中微生物的生长。该研究结果为酸枣果的药用产品和天然防腐剂的开发奠定了基础。     

Sequential extraction of chlorophyll from chlorophyll-protein complexes in lyophilized pea thylakoids with solvents of different polarity

Lyophilized chloroplasts of Pisum sativum (pea) have been extracted with petroleum ether of different polarity (obtained by adding varying amounts of ethanol to the petroleum ether). Extracted thylakoids have then been solubilized by sodium dodecyl sulphate (SDS) and chlorophyll-protein complexes have been isolated by polyacrylamide gel electrophoresis (PAGE). Absorption- and low temperature fluorescence emission spectro-scopy have been used to characterize thylakoids and purified chlorophyll-protein complexes. Weakly polar solvents extracted mainly chlorophyll a. SDS-PAGE scan profiles of similarly extracted thylakoids contained no photosystem II chlorophyll a reaction center antennae (CP-a_n) and the amount of photosystem I chlorophyll a reaction center antennae (CP-a₁) was reduced as compared with an unextracted control. This was due partly to the extraction of chlorophyll a prior to SDS-PAGE, and partly to the increased solubilization of chlorophyll a by SDS as a result of β-carotene extraction. By increasing the polarity of the solvent CP-a₁ also disappeared in the scan profile, leaving only the light-harvesting chlorophyll a/b-protein complex (CP-a/b) and SDS complexed chlorophyll. From these results we conclude that the chlorophyll molecules in the reaction center antennae are relatively more hydrophobically associated than the molecules in the light-harvesting CP-a/b complex. The chlorophyll a of CP-a_u and the far red absorbing chlorophyll a fraction of CP-a₁ appear to be the most hydrophobically associated chlorophyll molecules.     

Conformational preferences and self-association modes of two diastereomeric statine derivatives

The conformational preferences and self-association modes of the two diastereomeric N-acetyl, methylamides of 3-hydroxy, 4-amino, 6-methylheptanoic acid (statine) with (R, S) and (S, S) configurations at the 3-hydroxy and 4-amino carbons, respectively, have been determined in solution as well as in the solid state by infrared absorption, 1H nuclear magnetic resonance, and X-ray diffraction. Conformational energy computations have also been performed in parallel. In the crystal state, the change in chirality of the hydroxyl group induces different intermolecular H-bonding schemes in the (R, S) isomer compared to the two structurally distinct molecules in the asymmetric unit of the (S, S) isomer. Different propensities to self-aggregate are seen in solvents of low polarity. In solvents of high polarity, however, the molecules of both isomers are largely solvated, while still keeping some local conformational restriction. Conformational energy computations indicate that in vacuo the two diastereomers exhibit different flexibility, and a preferred conformation with a different type of intramolecular H-bond.     

Membrane dipole potentials, hydration forces, and the ordering of water at membrane surfaces.

We have compared hydration forces, electrical dipole potentials, and structural parameters of dispersions of dipalmitoylphosphatidylcholine (DPPC) and dihexadecylphosphatidylcholine (DHPC) to evaluate the influence of fatty acid carbonyl groups on phospholipid bilayers. NMR and x-ray investigations performed over a wide range of water concentrations in the samples show, that in the liquid crystalline lamellar phase, the presence of carbonyl groups is not essential for lipid structure and hydration. Within experimental error, the two lipids have identical repulsive hydration forces between their bilayers. The higher transport rate of the negatively charged tetraphenylboron over the positively charged tetraphenylarsonium indicates that the dipole potential is positive inside the membranes of both lipids. However, the lack of fatty acid carbonyl groups in the ether lipid DHPC decreased the potential by (118 +/- 15) mV. By considering the sign of the potential and the orientation of carbonyl groups and headgroups, we conclude that the first layer of water molecules at the lipid water interface makes a major contribution to the dipole potential.     

Altering the regioselectivity of the subterminal fatty acid hydroxylase P450 BM-3 towards gamma- and delta-positions

Cytochrome P450 BM-3 monooxygenase from Bacillus megaterium (CYP102A1) catalyzes the subterminal hydroxylation of fatty acids with a chain length of 12-22 carbons. Wild-type P450 BM-3 oxidizes saturated fatty acids at subterminal positions producing a mixture of omega-1, omega-2 and omega-3 hydroxylated products. Using a rational site-directed mutagenesis approach, three new elements have been introduced into the substrate binding pocket of the monooxygenase, which greatly changed the product pattern of lauric acid hydroxylation. Particularly, substitutions at positions S72, V78 and I263 had an effect on the enzyme regioselectivity. The P450 BM-3 mutants V78A F87A I263G and S72Y V78A F87A were able to oxidize lauric acid not only at delta-position (14% and 16%, respectively), but also produced gamma- and beta-hydroxylated products. delta-Hydroxy lauric and gamma-hydroxy lauric acid are important synthons for the production of the corresponding lactones.     

NMR Structure of a Viral Peptide Inserted in Artificial Membranes: A VIEW ON THE EARLY STEPS OF THE BIRNAVIRUS ENTRY PROCESS*

Nonenveloped virus must penetrate the cellular membrane to access the cytoplasm without the benefit of membrane fusion. For birnavirus, one of the peptides present in the virus capsid, pep46 for infectious bursal disease virus, is able to induce pores into membranes as an intermediate step of the birnavirus-penetration pathway. Using osmotic protection experiments, we demonstrate here that pep46 and its pore-forming N-terminal moiety (pep22) form pores of different diameters, 5–8 and 2–4 nm, respectively, showing that both pep46 moieties participate to pore formation. The solution structures of pep46, pep22, and pep24 (the pep46 C-terminal moiety) in different hydrophobic environments and micelles determined by ¹H NMR studies provide structural insights of the pep46 domain interaction. In CDCl₃/CD₃OH mixture and in dodecylphosphocholine micelles, the N-terminal domain of pep46 is structured in a long kinked helix, although the C terminus is structured in one or two helices depending upon the solvents used. We also show that the folding and the proline isomerization status of pep46 depend on the type of hydrophobic environment. NMR spectroscopy with labeled phospholipid micelles, differential scanning calorimetry, and plasmon waveguide resonance studies show the peptides lie parallel to the lipid-water interface, perturbing the fatty acid chain packing. All these data lead to a model in which the two domains of pep46 interact with the membrane to form pores.     

Inclusion/exclusion of fatty acids in amylose complexes as a function of the fatty acid chain length

Structural models are proposed for amylose-fatty acid complexes depending on the respective chain lengths of their constituents. The three studied fatty acids induce the Vh amylose crystalline type. However, in contrast to lauric and palmitic acids, caprylic acid is not present in crystals. On the basis of the relative amounts of amylose and fatty acid determined in complexes and previous results of molecular modelling, inclusion of lauric and palmitic acids inside the amylose helices is proposed; the acyl chains are included in crystalline areas and the car☐ylic groups in amorphous areas. The absence of caprylic acid in crystals could be due to the solubility of this compound in the crystallization medium.     

Relationships between fatty acids and psychophysiological parameters in depressive inpatients under experimentally induced stress

Fatty acids can influence important cellular and hormonal processes in the human body. Non-adequate contents of fatty acids, e.g., in blood, can cause and/or result in various diseases. In depressive patients, changes in fatty acid concentrations were found (deficits in omega3-fatty acids, in particular). This paper poses the question whether there are any relations between psychophysiological parameters and changes in fatty acid compositions. The concentration of fatty acids in serum of 118 psychiatric inpatients measured directly before and after experimentally induced stress of about 1h were analysed in relation to psychophysiological parameters continuously registered during the experimental sessions at admission, discharge and at 3 months follow-up. Systolic and diastolic blood pressure, finger pulse amplitude, forehead temperature (FD) and the EMG activity of the musculus zygomaticus consistently correlated with concentrations of single unsaturated oleic (18:1n-9) and erucic acid (22:1) and saturated myristic (14:0) and lauric acid (12:0). Negative relations were found between FD and the concentration of arachidonic acid (20:4n-6) as well as of palmitoleic acid (16:1). Furthermore, the higher the concentration of the erucic acid at discharge the higher the depression score as assessed by the Beck depression inventory (BDI). High concentrations of palmitoleic acid and lauric acid were related to a low level of depression (BDI and Hamilton scores). The implications of these findings for add-on treatment regimens in depression are discussed.     

Changes of the phospholipid bilayer structure under the adsorption of ferricytochrome c on its surface]

Changes in the mobility of phospholipid molecules in liposomes membranes under adsorption ferricytochrome c on its surface were studied by means of NMR and EPR spectroscopy. It is found that the interaction of cytochrome molecules with vesicles causes the broadening of 1H-NMR signals of hydrophobic as well as polar groups in cardiolipin and phosphatidylcholine in the presence of lauric or phosphatidic acid. This broadening of 1H-NMR signals in hydrophobic groups may be caused by decrease in the rate of lateral diffusion of phospholipid molecules. The changes in the correlation time of hydrophobic spin-proub in liposomes containing phosphatydiloholine and cardiolipin with the increase of ferricytochrome c concentration were also observed. These changes suggest that the formation of protein-phospholipid clusters results in the impair of the regular structure of phospholipid bilayer.     

Chemical synthesis and NMR characterization of structured polyunsaturated triacylglycerols

The chemical synthesis of pure triacylglycerol (TAG) regioisomers, that contain long chain polyunsaturated fatty acids, such as arachidonic acid (AA) or docosahexaenoic acid (DHA), and saturated fatty acids, such as lauric acid (La) or palmitic acid (P), at defined positions, is described. A single step methodology using (benzotriazol-1-yloxy)-tripyrrolidinophosphonium hexafluorophosphate (PyBOP), an activator of carboxyl group commonly used in peptide synthesis and occasionally used in carboxylic acid esterification, has been developed for structured TAG synthesis. Identification of the fatty acyl chains for each TAG species was confirmed by atmospheric pressure chemical ionisation mass spectrometry (APCI-MS) and fatty acid positional distribution was determined by (1)H and (13)C NMR spectra. The generic described procedures can be applied to a large variety of substrates and was used for the production of specific triacylglycerols of defined molecular structures, with high regioisomeric purity. Combination of MS and NMR was shown to be an efficient tool for structural analysis of TAG. In particular, some NMR signals were demonstrated to be regioisomer specific, allowing rapid positional analysis of LC-PUFA containing TAG.     

Effect of chitosan type on protein and water recovery efficiency from surimi wash water treated with chitosan-alginate complexes

Previous research has shown that soluble protein recovery by chitosan (Chi) complexes with polyanions such as alginate (Alg) is more effective than using chitosan alone. In this study, Chi-Alg complexes were used to recover soluble proteins from surimi wash water (SWW) slightly acidified to pH 6. Six Chi samples differing in molecular weight (MW) and degree of deacetylation (DD) were used at 20, 40 and 100mg/L SWW Chi-Alg complexes prepared with a Chi:Alg mixing ratio previously optimized (MR=0.2). FTIR analysis of the solids recovered revealed the three characteristic amide bands observed in the same region for untreated SWW confirming protein adsorption by Chi-Alg. The superior effectiveness of Chi complexes was confirmed but differences among chitosan types could not be correlated to MW and DD. Experimental Chi samples with 94%, 93%, 75% and 93% DD and 22, 47, 225 and 3404 x 10(3)Da, respectively, showed 73-76% protein adsorption while a commercial chitosan sample with 84% DD and 3832 x 10(3)Da had 74-83% protein adsorption. An experimental chitosan, SY-1000 with 94% DD and 1.5 x 10(6)Da, showed the highest protein adsorption (79-86%) and turbidity reduction (85-92%) when used at 20mg/L SWW.