Gelatin blends with alginate: gels for lipase immobilization and purification

Blends of natural polysaccharide sodium alginate (5%) with gelatin (3%) cross-linked with glutaraldehyde provide beads with excellent compressive strength (8 x 10(4) Pa) and regular structure on treatment with calcium chloride. Lipases from porcine pancreas, Pseudomonas cepacia, and Candida rugosa were immobilized in such a blend with excellent efficiency. The immobilized enzymes were stable and were reused several times without significant loss of enzyme activity both in aqueous and reverse micellar media. The beads were functionalized with succinic anhydride to obtain beads with extra carboxylic acid groups. These functionalized beads were then successfully used for 7.4-fold purification of crude porcine pancreatic lipase in a simple operation of protein binding at pH 5 and release at pH 8.5.     

Electrochemical potential of free and immobilized Cratylia mollis seed lectin

The electrochemical potentials for free or immobilized Cratylia mollis seed lectin (Cra) were obtained through potentiostatic techniques. A saline solution was used as support to control the charge distribution between saturated calomel electrode and platinum electrode (working electrode). The electrochemical potential to free Cra was determined at the following concentrations: 0.6, 0.9 and 1.0 mg/ml in an aerated environment under different temperatures (5, 10 and 20 degrees C). The best electrochemical potential was obtained with 1.0 mg/ml, at 5 and 10 degrees C, 87 and 102 mV, respectively. Electrochemical potential to Cra immobilized on glass beads activated with 3-aminopropyltriethoxysilane described a linear behavior in relation to the increase in glucose concentration. The development of techniques to define interface electrical parameters will be able to give information about charged groups adsorbed to electrode surface revealing interactions particularly in biological systems.     

Single-step purification of recombinant Thermus aquaticus DNA polymerase using DNA-aptamer immobilized novel affinity magnetic beads

A DNA aptamer specific for Thermus aquaticus DNA polymerase (Taq-polymerase) was immobilized on magnetic beads, which were prepared in the presented study. The effect of various parameters including pH, temperaturem and aptamer concentration on the immobilization of 5'-thiol labeled DNA-aptamer onto glutaric dialdhyde activated magnetic beads was evaluated. The binding conditions of Taq-polymerase on the aptamer immobilized magnetic beads were studied using commercial Taq-polymerase to characterize the surface complexation reaction. Efficiency of affinity magnetic beads in the purification of recombinant Taq-polymerase from crude extracts was also evaluated. For this case, the enzyme "recombinant Taq-DNA polymerase" was cloned and expressed using an Amersham E. coli GST-Gene Fusion Expression system. Crude extracts were in contact with affinity magnetic beads for 30 min and were collected by magnetic field application. The purity of the eluted Tag-polymerase from the affinity beads, as determined by HPLC, was 93% with a recovery of 89% in a one-step purification protocol. Apparently, the system was found highly effective as one step for the low-cost purification of Taq-polymerase in bacterial crude extract.     

Essential role of the concentration of immobilized ligands in affinity chromatography:: Purification of guanidinobenzoatase on an ionized ligand

Guanidinobenzoatase, a plasma protein with possible application as a ‘tumor marker’, has been fully purified by one-step affinity chromatography. The affinity matrix was prepared by ‘controlled’ immobilization of an enzyme inhibitor (agmatine) onto commercial agarose gels containing carboxyl moieties activated as N-hydroxysuccinimide esters. In this way, agmatine becomes immobilized through an amido bond and preserves an ionized guanidino moiety. Different matrices with different concentration of ligands were prepared in order to evaluate their properties as affinity supports. Interestingly, matrices with a very low concentration of immobilized ligands (2 μmol/ml, corresponding to the modification of only 5% of active groups in the commercial resins) exhibited a low capacity for unspecific adsorption of proteins (as anion-exchange resins) and displayed also a high capacity for specific adsorption of our target protein. On the other hand, when affinity matrices possessed a moderate concentration of agmatine (10 μmol/ml of gel or higher), two undesirable phenomena were observed: (a) the matrix behaves as a very good anionic exchange support able to non-specifically adsorb most of plasma proteins and (b) the specific adsorption of our target protein becomes much lower. The latter phenomenon could be due to steric hindrances promoted by the interaction between each individual immobilized ligand and the corresponding binding pocket in the target protein. These hindrances could also be promoted by the presence of a fairly dense layer of immobilized ligands covering the support surface, thus preventing interactions between immobilized ligands and partially buried protein-binding pockets. In this way, a successful affinity purification (23.5% yield, ×220 purification factor, a unique electrophoretic band) could be achieved by combination of three approaches: (i) the use of affinity matrices possessing a very low density of immobilized ligands, (ii) performing affinity adsorption at high ionic strength and (iii) performing specific desorption with substrates or substrate analogues.     

An antigen-capture enzyme-linked immunosorbent assay (ELISA) to detect isometamidium chloride in Oncorhynchus spp

An antigen-capture enzyme-linked immunosorbent assay (ELISA) was developed to detect and measure isometamidium chloride in the plasma of Oncorhynchus tshawytscha and O. mykiss. Isometamidium-ovalbumin conjugate and anti-isometamidium antibodies were used to coat polystyrene plates. The peroxidase saturation technique was used to optimize the coating antigen concentration; it demonstrated low affinity of the isometamidium-ovalbumin conjugate but high affinity of the anti-isometamidium antibodies for polystyrene surface sites. The optimal conditions of antiisometamidium antibodies to coat plates was at pH 7.3 and a 1:1000 dilution (0.0012 mg ml(-1) protein). The ELISA was sensitive as it detected 0.0006 mg ml(-1) of isometamidium in fish plasma. Isometamidium diluted with saline could not be detected at concentrations less than 0.05 mg ml(-1). The results indicate that this ELISA is much more sensitive when isometamidium is bound to plasma than unbound isometamidium in saline.     

Stability of antibody attachment in immunosorbent chromatography

Detachment of immobilized antibody from its support matrix in an immunosorbent system prepared by the cyanogen bromide activation route was demonstrated. The immunosorbent system, however, was stable under slightly basic conditions. Detachment of antibody from the support material occurred mainly during the elution of the antigen complexed with the immobilized antibody. The antibody was detached from the matrix by different elution buffers. The detachment pattern of antibody was independent of the number of cycles used and also independent of the support materials. A change in the molecular structure of the detached antibody occurred as revealed by an alteration in the ultraviolet absorption spectra of the released antibody. The antibody detachment from the support matrix occurred in more than one antigen-antibody system suggesting that the leakage phenomenon may be a widespread disadvantage associated with the cyanogen bromide activation procedure. Detachment of the antibody could be reduced to < 10 ng ml⁻¹ by immobilizing antibody on the properly oxidized polysaccharide support material or on the N-hydroxysuccinimide activated ester gel. Antibody dissociation from the matrix did not occur when antibodies were immobilized by either amine or amide attachment, thus, immunosorbents prepared by such strategies are suitable for the immunochromatographic purification of proteins from complex mixtures.     

Continuous recording of the formation of a photolabile fluorophore.

DNA immobilized on cellulose or agarose has been found very useful for the separation and purification of DNA-binding proteins (1–4).A variety of methods for DNA immobilization has been proposed, including absorption (3), entrapment in gels (4), and covalent binding (1).In the course of a study of the behavior of a complex between histones and immobilized DNA, we have met the need of a particularly stable DNA-cellulose preparation, i.e., involving not only covalent bonds between the nucleic acid and the polysaccharide, but bonds resistent to extremes of pH, particularly in the alkaline region.It has been found that cellulose activated with cyanuric chloride affords a convenient material for the preparation of DNA-cellulose, which has the following favorable characteristics: (i) It can be prepared by an easy and reproducible method; (ii) double-stranded DNA is bound in satisfactory amounts; (iii) the material is very stable, even in urea and in alkaline conditions.     

Immunoaffinity chromatography

Immunoaffinity chromatography is a process in which the binding affinity of an antigen to a parent antibody is utilized as a basis of separation. Owing to the customized avidity and specificity, monoclonal antibodies (Mabs) have become indispensable for both protein characterization and purification. The immunosorbent performance is dependent on the support matrix upon which the antibody is immobilized and on the activation chemistry used couple the antibody to the matrix. This report details, protocols to immobilize Mabs on commercially available supports, and a method to compute immunosorbent efficiency.     

Method for continuous purification of biological material using immunosorbent.

A mechanical device for the continuous purification of biological material using immunosorbent was developed. The system consists of heat-sealed nylon pouches containing agarose-bound antibody, attached to an endless 35 mm wide Mylar belt that passes through four chambers sequentially. The biological material is bound and dissociated, and the immobilized antibody is regenerated for repeated isolation and purification of antigen. The belt design incorporates features to minimize carry-over between chambers and prevent damage to the agarose-bound antibody in repeated passes through the system. An existing batch method for the purification of human placental alkaline phosphatase using immobilized rabbit antisera was adapted to continuous purification in the device. The belt contained a low affinity immunosorbent and made five complete passes through the system. A decrease in antigen binding capacity between free immunosorbent suspensions and belt immunosorbent in pouches was observed. This was shown to be the result of the diffusion resistance offered by the pouch and the short exposure times of each pouch in the chambers. A decrease in antigen binding capacity between successive belt passes was also observed, and resulted from the inability of the agarose in the pouches to resuspend completely after each pass. The low efficiency of the agitation method and the roller device used to squeeze the pouches were the reasons for this deficiency.     

Properties of cellulase immobilized on agarose gel with spacer

Cellulase produced by fungus Trichoderma viride was immobilized on agarose beads (Sepharose 4B) activated by cyanogen bromide and also on activated agarose beads that contained spacer arm (activated CH-Sepharose 4B and Affi-Gel 15). The CMCase activity retained by immobilized cellulase on activated Sepharose containing the spacer tended to be higher than that immobilized without spacer, although the extent of protein immobilization was lower. Also, the higher substrate specificity for cellulase immobilized on beads with spacer was obtained for cellobiose, acid-swollen cellulose, or cellulose powder. The hydrolysis product from their substrates was mainly glucose.     

Production, characterization, and applications of monoclonal antibodies reactive with soybean nodule xanthine dehydrogenase

Seven monoclonal antibodies were produced against soybean nodule xanthine dehydrogenase, an enzyme involved in ureide synthesis. Specificity of the seven monoclonal antibodies for xanthine dehydrogenase was demonstrated by immunopurifying the enzyme to homogeneity from a crude nodule extract using antibodies immobilized to Sepharose 4B beads. Each monoclonal antibody was covalently bound to Sepharose 4B beads for the preparation of immunoaffinity columns for each antibody. All seven antibodies were found to be of the IgG1,K subclass. A competitive, indirect enzyme-linked immunosorbent assay demonstrated that two of the seven antibodies shared a common epitope while the remaining five antibodies defined unique determinants on the protein. Rapid, large scale purification of active xanthine dehydrogenase to homogeneity was performed by immunoaffinity chromatography. The presence of xanthine dehydrogenase activity and protein in every organ of the soybean plant was determined. Crude extracts of nodules, roots, stems, and leaves cross-reacted with all seven monoclonal antibodies in an indirect enzyme-linked immunosorbent assay. A positive correlation was observed between the degree of cross-reactivity of a given organ and the level of enzyme activity in that organ. These data demonstrate that xanthine dehydrogenase is not nodule specific. Antigenic variability of xanthine dehydrogenase present in crude extracts from nodules of soybean, wild soybean, cowpea, lima bean, pea, and lupin were detected in the indirect enzyme-linked immunosorbent assay which corresponded to six binding patterns for xanthine dehydrogenase from these plant species. These results correspond well with the epitope determination data which showed that the seven antibodies bind to six different binding determinants on the enzyme.     

Biosorption of Zn(II) on the different Ca-alginate beads from aqueous solution

The performance of a new biosorbent system, consisting of a fungal biomass immobilized within an orange peel cellulose absorbent matrix, for the removal of Zn(2+) heavy metal ions from an aqueous solution was tested. The amount of Zn(II) ion sorption by the beads was as follows; orange peel cellulose with Phanerochaete chrysosporium immobilized Ca-alginate beads (OPCFCA) (168.61 mg/g) > orange peel cellulose immobilized Ca-alginate beads (OPCCA) (147.06 mg/g) > P. chrysosporium (F) (125.0 mg/g) > orange peel cellulose (OPC) (108.70 mg/g) > plain Ca-alginate bead (PCA) (98.26 mg/g). The Zn(2+) concentration was 100 to 1000 mg/L. The widely used Langmuir and Freundlich isotherm models were utilized to describe the biosorption equilibrium process. The isotherm parameters were estimated using linear and non-linear regression analysis. The Box-Behnken model was found to be in close agreement with the experimental values, as indicated by the correlation coefficient value of 0.9999.     

Characterization and immobilization of liposome-bound cellulase for hydrolysis of insoluble cellulose

The liposome-bound cellulase was prepared by covalently coupling cellulase with the enzyme-free liposomes bearing aldehyde groups so that cellulase was located solely on the outer membrane of liposomes. The modified cellulase possessed the higher activity efficiency and lipid-based specific activity than the cellulase-containing liposomes reported previously. The enzyme-free liposomes bearing aldehyde groups were covalently immobilized with the chitosan gel beads and the free cellulase was coupled with the treated gel beads to prepare the immobilized liposome-bound cellulase. The activity efficiency of the immobilized liposome-bound cellulase was much higher than that of the conventionally immobilized cellulase. The results on reusability of the immobilized liposome-bound cellulase in the hydrolysis of either soluble or insoluble cellulose showed that the immobilized liposome-bound cellulase had the higher remaining cellulase activity and reusability than the conventionally immobilized cellulase for the hydrolysis of either type of cellulose. The liposomal membrane was suggested to be efficient in maintaining the cellulase activity during the hydrolysis.     

Activating hydroxyl groups of polymeric carriers using 4-fluorobenzenesulfonyl chloride.

4-Fluorobenzenesulfonyl chloride (fosyl chloride), due to the strong electron-withdrawing property of its fluoride atom, is found to be an excellent activating agent for the covalent attachment of biologicals to a variety of solid supports (e.g. functionalized polystyrene microspheres, Sepharose beads, or cellulose rods and hollow fibers). This reagent reacts rapidly with primary or secondary hydroxyl groups, at ambient temperature and pressure, to form 4-fluorobenzenesulfonate leaving groups. The activated solid support can be used immediately or preserved for several months without loss of activity by freeze-drying or by storage at 4 degrees C in aqueous solution at pH 5. Enzymes, antibodies, avidin, and other biologicals can be covalently attached to the activated solid phase with excellent retention of biological function. Potential therapeutic applications of the fosyl chloride chemistry for bioselective separation of human lymphocyte subsets from whole blood and tumor cells from bone marrow are presented.     

Application of bacterial cellulose pellets in enzyme immobilization

Over recent years, there has been a growing interest in the use of cellulose materials in bioprocessing technologies. Bacterial cellulose which is the pure cellulose has unique physical properties which differ from those of plant cellulose and has therefore attracted attention as a new functional material. The applications of bacterial cellulose rarely use the pellet type but it has potential in enzyme immobilization since pellet form is usually used in this field. In this research, Glucoamylase which is widely used in the food industry was immobilized on bacterial cellulose beads after testing using various activation procedures. The results showed that the epoxy method with glutaraldehyde coupling was the best method. After comparison of the different types of bacterial cellulose beads for glucoamylase immobilization, the wet bacterial cellulose beads of the smallest size (0.5–1.5 mm) were the best support. The immobilization of enzyme enhances its stability against changes in the pH value and temperature especially in the lower temperature region. The relative activity of the immobilized glucoamylase was still above 77% at pH 2.0 and it was the highest value in the literature. The relative activities were more than 68% in the lower temperature region even at 20 °C. Thus, bacterial cellulose beads are a practical potential support for the preparation of immobilized enzymes in industrial applications.     

Site-specific antibodies to human erythropoietin: immunoaffinity purification of urinary and recombinant hormone

The 19-amino acid domain Ala111----Pro129 of human erythropoietin was identified as an accessible surface antigen based on the binding of radio-iodinated and of unmodified hormone to antibodies prepared against a synthetic peptide of homologous sequence. The specificity and affinity of this binding was sufficient to provide for the use of anti-peptide antibodies in the preparation of an immunosorbent for the purification of urinary, and of recombinant human erythropoietin. Immobilization of anti-peptide antibodies using agarose activated either with CNBr or with N-hydroxysuccinimido groups largely inactivated binding sites for erythropoietin. In contrast, antibodies crosslinked to N-acetyl-DL-homocysteine agarose through the hetero-bifunctional reagent succinimidyl 4-(N-maleimidomethyl)cyclohexane-1-carboxylate retained their antigen-binding capacity virtually completely and provided a superior immunosorbent for hormone. Urinary erythropoietin with a specific bioactivity of 100 U/A280 was prepared initially by chromatography on phenyl-Sepharose. Subsequent immunoaffinity chromatography resulted in a 350-fold purification with 46.2% recovery yielding erythropoietin with a specific bioactivity of 35,200 U/A280 (44,300 U/mg). Radioiodination of this purified protein and subsequent SDS-polyacrylamide gel electrophoresis indicated that this preparation contained a single major component (Mr 30,000) which co-migrated in gels with unmodified biologically active hormone. Recombinant erythropoietin, which was prepared by the cloning of the human erythropoietin gene and its expression in COS cells using the SV40-derived vector pSV2, was purified by the same scheme. Chromatography on phenyl-Sepharose of medium derived from transfected cells (400 U/ml, 170 U/A280) provided for a 3.6-fold purification of recombinant hormone with an apparent recovery of 122%. This erythropoietin bound to the anti-peptide antibody gel and was purified to a specific bioactivity of 10,370 U/A280 with 55% recovery. The procedure described here for attaching antibodies to a solid support maximizes their antigen-binding capacity and is generally applicable. The development of an anti-peptide immunosorbant for human erythropoietin provides a valuable means for isolating hormone for use in studies of its receptor and its presently unresolved mechanism of action.     

l-Dopa synthesis using tyrosinase immobilized on magnetic beads

Magnetic beads were prepared via suspension polymerization of glycidyl methacrylate (GMA) and methyl methacrylate (MMA) in the presence of ferric ions. Following polymerization, thermal co-precipitation of the Fe(III) ions in the beads with Fe(II) ions under alkaline condition resulted in encapsulation of Fe₃O₄ nano-crystals within the polymer matrix. The magnetic beads were activated with glutaraldehyde, and tyrosinase enzyme was covalently immobilized on the support via reaction of amino groups under mild conditions. The immobilized enzyme was used for the synthesis of l-Dopa (1-3,4-dihydroxy phenylalanine) which is a precursor of dopamine. The immobilized enzyme was characterized by temperature, pH, operational and storage stability experiments. Kinetic parameters, maximum velocity of the enzyme (V_max) and Michaelis–Menten constant (K_m) values were determined as 1.05 U/mg protein and 1.0 mM for 50–75 μm and 2.00 U/mg protein and 4.0 mM for 75–150 μm beads fractions, respectively. Efficiency factor and catalytic efficiency were found to be 1.39 and 0.91 for 75–150 μm beads and 0.73 and 0.75 for 50–75 μm beads fractions, respectively. The catalytic efficiency of the soluble tyrosinase was 0.37. The amounts of immobilized protein were on the 50–75 μm and 75–150 μm fractions were 2.7 and 2.8 mg protein/g magnetic beads, respectively.     

免疫亲和层析技术研究:间隔臂对配体偶联效率及固相抗体活性的影响

 本文研究了两种二胺类间隔臂EDA、IBPA在免疫亲和层析中的应用。结果表明,与无间隔臂的支持物(DST-支持物)比较,间隔臂的引入可大幅度降低固相抗体(单克隆和多克隆)活性的损失。这项工作可供免疫吸附剂的设计及固相配体性质的研究作为参考。     

Protein A immobilized affinity cartridge for immunoglobulin purification

Recombinant Protein A was immobilized on a cellulose and acrylic composite matrix through Schiff base formation. Various factors that could affect the binding of immunoglobulin by the Protein A molecules immobilized on the solid matrix were studied to achieve optimum affinity purification. The spacer arm length and ligand concentration of Protein A were verified as factors crucial to optimized IgG purification. Liquid-phase environmental conditions such as pH and salt concentration also play important roles in adsorption capacity by affecting the molecular interaction between IgG and the immobilized Protein A. The rate of interaction between Protein A and IgG is rather fast, with minimal differences observed at 10-fold increases in the cartridge loading rate. This paper describes a cellulose/acrylic composite matrix for immobilizing Protein A, at an optimized ligand concentration, installed on a spacer arm of adequate length, to purify immunoglobulins from animal plasma. The fast-flow property of the cartridge made from such a matrix and its simplicity in operation provide effective means for purifying immunoglobulins on a relatively large scale.     

Biosorption of Cr (VI) with Trichoderma viride immobilized fungal biomass and cell free Ca-alginate beads

Ability of Cr (VI) biosorption with immobilized Trichoderma viride biomass and cell free Ca-alginate beads was studied in the present study. Biosorption efficiency in the powdered fungal biomass entrapped in polymeric matric of calcium alginate compared with cell free calcium alginate beads. Effect of pH, initial metal ion concentration, time and biomass dose on the Cr (VI) removal by immobilized and cell free Ca-alginate beads were also determined. Biosorption of Cr (VI) was pH dependent and the maximum adsorption was observed at pH 2.0. The adsorption equilibrium was reached in 90 min. The maximum adsorption capacity of 16.075 mgg(-1) was observed at dose 0.2 mg in 100 ml of Cr (VI) solution. The high value of kinetics rate constant Kad (3.73 x 10(-2)) with immobilized fungal biomass and (3.75 x 10(-2)) with cell free Ca- alginate beads showed that the sorption of Cr (VI) ions on immobilized biomass and cell free Ca-alginate beads followed pseudo first order kinetics. The experimental results were fitted satisfactory to the Langmuir and Freundlich isotherm models. The hydroxyl (-OH) and amino (-NH) functional groups were responsible in biosorption of Cr (VI) with fungal biomass spp. Trichoderma viride analysed using Fourier Transform Infrared (FTIR) Spectrometer.