Isolation and purification of biopolymers by affinity chromatography. VI. Preparation and properties of an affinity adsorbent with a polysaccharide spacer for the purification of proteolytic enzymes

A new affinity sorbent has been synthesized — soybean trypsin inhibitor (STI)-amylopectin-hydrazidosuccinyl-Sepharose — and its properties have been studied in comparison with those of an analogous adsorbent without the spacer STI-Sepharose. The STI-amylopectin-hydrazidosuccinyl-Sepharose adsorbent has been used for the purification of trypsin from porcine pancreas and of callicrein from human blood plasma.     

Coupling of effector molecules to solid supports

In view of the limited stability of the isourea bond, formed in ligand coupling to CNBractivated polysaccharides, an alternative to this current activation method has been developed. 2,4,6-Trifluoro-5-chloropyrimidine (FCP), known as a reactive group in reactive dyes, was used to activate Sepharose. Under appropriate conditions a thermally stable product with unimpaired beaded structure was obtained, which was reactive toward amines and mercaptans. Coupling with hexamethylenediamine, aniline, and ethanethiol, respectively, yielded an incorporation of 0.2-2.7, 0.9-1.7, and 1.1 mmol ligand/g dry agarose. The stability of immobilized ligands based on FCP-Sepharose between pH 4 and 8 was about 200 times higher as compared to products originating from CNBr-Sepharose; ligand leakage was only 0.5 x 10^p-3%/h. The possibility of obtaining a high degree of substitution is a further advantage of the FCP activation. In addition, the FCP-activated Sepharose can be stored in the wet state at 4°C without substantial decrease in coupling capacity. The FCP analogs 2,4,5,6-tetrachloro- and 2,4,5,6-tetrafluoropyrimidine, and other polymers (cellulose, Sephadex, aminomethylpolystyrene) appeared to be applicable also.     

Preparation and properties of insoluble forms of bacteriophage T4 lysozyme and chicken egg white lysozyme

Bacteriophage T4 lysozyme and chicken egg white lysozyme were covalently bound to cyanogen bromide activated Sepharose and to glutaraldehyde activated polyacrylhydrazido-Sepharose. The latter method seemed less favorable for T4 lysozyme, since the poly-acrylhydrazido-agarose conjugate exhibited low activity compared to the agarose conjugate. Whole bacteria (M.luteus and chloroform-treatedE. coli B cells) and the soluble uncross-linked peptidoglycan polymer fromM. luteus were used as substrates. Both types of conjugates exhibited low specific activity (lytic activity) toward insoluble substrates (cells), but surprisingly high specific activity toward the soluble substrate (hydrolytic activity). Product analysis showed that the enzyme conjugates retained their specificity of action, i.e., the same products were formed, and their rates of production were the same as those observed with the soluble (native) enzyme. The cell wall disaccharide-tetrapeptide GlcNAc-MurNAc-L-ala-D-gIu-(A₂pm-D-Ala) (C₆) inhibits the hydrolytic activity of both the native and the agarose bound T4 lysozyme. Only a slightly increased thermal stability was observed upon immobilization of T4 lysozyme, whereas the stability of the enzyme during storage and handling was greatly improved. The pH optimum of the lytic activity of Sepharose-T4 lysozyme was shifted about 1 pH unit to the alkaline side, compared to that found for the soluble enzyme, whereas no pH shift was observed for the polyacrylhydrazido-Sepharose conjugate. The optimum of the hydrolytic activity of Sepharose-T4 lysozyme was shifted to the acidic side. The pH optima of the lytic activity of the various lysozymes toward the bacterial cells were all very similar (>7), and differed greatly from the pH optima (<6) observed for their hydrolytic activities toward the negatively charged soluble peptidoglycan polymer. It is proposed that the observed differences in pH optima primarily reflect the basically different properties measured, i.e., the β(1–4) cleaving activity (hydrolytic activity), and dissolution process of the damaged cells (lytic activity).     

Separation of aspartate aminotransferase from albumin on substituted agaroses

The affinity of aspartate aminotransferase to its inhibitors coupled to Sepharose 4 B was tested. The affinity was measured as retardation of the enzyme compared to “inert” bovine serum albumin. Carboxylic ligands of citrate and 2-oxoglutarate bound to aminoethyl-Sepharose were the best of those tested in separation of the proteins. Because the ligands were not essentially hydrophobic and because it was shown that ion-exchange is not significant in the elution conditions used, it was suggested that the separation is based on the recognition of substrate or effector by the enzyme.     

Synthesis of the bifuncttonal dinucleotide AMP-ATP and its application in general ligand affinity chromatography

A new AMP derivative substituted with spacer arms both at position N⁶ and C8 of the adenine moiety was synthesized and immobilized to Sepharose. To the immobilized ligand was subsequently coupled C8-substituted ATP in a solid-phase synthesis fashion yielding the bifunctional general ligand AMP-ATP. This affinity material was used in the separation of two major groups of enzymes, dehydrogenases and kinases. It was found that on passage of crude homogenates obtained from mouse kidney through the affinity column, several dehydrogenases and kinases were bound, which could be eluted separately using pulses of NADH and ATP, respectively. In the fractions obtained on NADH elution, lactate dehydrogenase, malate dehydrogenase, and α-glycerol phosphate dehydrogenase were found, whereas ATP eluted 3-phosphoglyceric acid kinase, pyruvate kinase, and aldolase.     

Ethylenediamine-Derived Chromatographic Ligand to Separate BSA,Lysozyme, and RNase A

Chromatography has become an essential tool for the purification of proteins, since most purification schemes involve some forms of this methodology. Recently, using chromatographic matrices prepared from symmetrical aminosquarylium cyanine dyes immobilized on Sepharose via a central alkylamino residue, we were able to isolate lysozyme, α-chymotrypsin and trypsin from a mixture. Following this, we envisioned that the immobilization of an asymmetric squarylium dye bearing an N-carboxyethyl group in one of its ending nuclei, on ethylenediamine-activated Sepharose, through EDC/NHS amidation coupling, could enhance the ligand’s mobility and improve the interactions with the target proteins. The prepared support was found to separate an artificial mixture of BSA, lysozyme, and RNase A. Unexpectedly, the support prepared in the absence of the dye exhibited a separation performance similar to that of the dyed support, contrary to that observed in all previous studies using cyanine dyes as ligands for affinity chromatography, which prompted us to try to determine the structural molecular constitution of the matrix surface. A synthetic route to the final chromatographic support could be devised, which is believed to consist in the cyclization of two nearby ethylenediamine units, involving the inclusion of a succinimide-derived residue between them and the EDC-mediated Lossen rearrangement of an intermediary hydroxamic acid.     

Properties of human parotid amylase immobilized by covalent binding to glass or sepharose or by reaction with immobilized antibody

Human parotid amylase was immobilized by covalent binding to CNBr-activated Sepharose, to Corning GAO-3940 silica glass biomaterial support by the diazonium reaction or reaction with glutaraldehyde, or as a result of the antigen-antibody reaction between rabbit antihuman parotid amylase IgG that was covalently bonded to GAO glass and soluble amylase. The amylase directly bonded to the supports showed constant activity at flow rates of 3-15 ml/min through a 1.76-cm³ (8-mm diameter) support bed, did not lose enzyme into a circulating starch solution, retained its activity in the presence of soluble antiamylase IgG, was optimally active at 35°-40°C, and lost activity at 40°-45°C. When the enzyme was bound by interaction with immobilized antibody, full activity was expressed, but some enzyme was solubilized by a circulating starch solution. Immobilization of either amylase or antiamylase IgG makes dissolution of the antigen-antibody bond difficult.     

Stability of immobilized frog epidermis tyrosinase

Purified frog epidermis tyrosinase was immobilized on the following supports: CNBr-Sepharose 4B, Enzacryl AA, Enzacryl AH, Enzacryl Polythiolactone, and Enzacryl Polyacetal. The enzyme was active on all supports except when Enzacryl Polyacetal was used. The stability increased on immobilization. Enzacryl AA was the best support assayed. The Enzacryl AA-enzyme complex was 30- to 40-fold more stable to inactivation reaction than soluble enzyme, and maintained its activity when stored and assayed repeatedly. The immobilized enzyme on the other supports was also more stable than the soluble form. The pH-activity profile, thermal stability, storage stability, and the effect of protein concentration on activity of the immobilized enzyme have been studied. The properties observed for the immobilized enzyme were different than those of the soluble enzyme. The main reason for this difference could be due to enzyme modification through tyrosine groups of the enzyme; to conformational changes produced in the union to the matrix; and to microenvironmental differences created by the matrix.     

Purification and some properties of tryptophan-5-monooxygenase from rabbit hindbrain

An affinity chromatography procedure for the rapid purification of tryptophan-5-monooxygenase from rabbit hindbrains was developed using e-aminocaproyl-D-tryptophan methyl ester-Sepharose-4B gels. The precise requirements for the optimal biospecific interaction between the affinity ligand and the ligate (enzyme) was established from a study of the effects of the variation in the length of the "spacer’’ on the affinity properties of the gel. The enzyme preparation isolated by this procedure was found to be essentially homogeneous and was characterized by a molecular weight of 200,000 ±20,000. SDS-polyacrylamide gel electrophoresis of the enzyme revealed it to be a dimer, the molecular weight of each subunit being approximately 90,000. The specific activity of the enzyme preparation is approxi-mately 7-10 times that of the crude homogenate, but a further fivefold enhancement in the specific activity could be obtained by limited proteolysis with trypsin. The extreme lability of the enzyme could be circumvented by its immobilization on activated Sepharose or by cross-linking with dimethyl suberimidate. The kinetic properties as well as the advantages of such stabilized enzyme preparations are presented.     

Preparation of immobilized sepharose-micrococcal nuclease derivatives: activity and stability

Micrococcal nuclease has been covalently attached to CNBr-activated Sepharose 4B by coupling through three different enzyme functions: (a) amino groups; (b) carboxyl groups; and (c) tyrosyl or histidyl residues. On the basis of coupling yield and catalytic efficiency, Sepharose-(NH₂) nuclease derivatives were chosen for further activity andstability studies. The activity of the insoluble enzyme has been evaluated with macromolecular (DNA) and small (synthetic nucleotide) substrates; with the latter the enzyme retains 70% of native enzyme activity. Good enhancement of enzyme stability in the 4–40°C range has been observed.     

Reduction in the antigen-binding in polyacrylamide gel

Under conditions of antibody excess, antibodies that had been immobilized by physical entrapment in a polyacrylamide gel matrix consistently removed less radiolabeled microprotein antigen from solution than did the same antibodies chemically conjugated to Sepharose beads. This reaction is believed to relate to the difficulty of formation of secondary antibody-antigen lattices when the molecules are held in “cells” in the polymer matrix.     

Facile formation of stimuli-responsive,fluorescent and magnetic nanoparticles based on cellulose stearoyl ester via nanoprecipitation

In comparison to stimuli-responsive, multi-functional nanoparticles (NPs) from synthetic polymers, such NPs based on sustainable, naturally occurring polysaccharides are still scarce. In the present study, stable stimuli-responsive, fluorescent and magnetic NPs were fabricated using cellulose stearoyl esters (CSEs) consisting of cellulose and stearoyl groups. The multifunctional NPs with the average diameters between 80 and 250 nm were obtained after facile nanoprecipitation using CSE solutions containing Fe₃O₄-NPs. Using the aqueous solution of fluorescent rhodamine B as precipitant, NPs with rhodamine B on NP surface were obtained. Rhodamine B could be released depending on the temperature. In comparison, stearoylaminoethyl rhodamine B can be encapsulated in CSE-NPs, which renders obtained NPs reversible fluorescence in response to UV illumination and heat treatment.     

Impact of PS/SiO2 morphologies on the SERS activity of PS/SiO2/Ag nanocomposite particles

To understand the relationship between the morphology of carboxyl-functionalized polystyrene/silica (PS/SiO₂) nanocomposite microspheres and the surface-enhanced Raman scattering (SERS) performance of PS/SiO₂/Ag nanocomposite particles, core-shell and raspberry-like PS/SiO₂ composite microspheres were used as templates to prepare PS/SiO₂/Ag nanocomposite particles. The core-shell and raspberry-like structured PS/SiO₂ templates were prepared via in situ sol-gel reaction by hydrolysis tetraethyl orthosilicate (TEOS) in alkali solution. Silver nanoparticles (10–50 nm) were loaded on the PS/SiO₂ templates’ surface by chemical reduction. The morphology and structure of the PS/SiO₂/Ag particles were characterized by TEM, SEM, X-ray diffraction (XRD), and ultraviolet-visible (UV-vis) spectroscopy. Rhodamine 6G (R6G) was selected as a model chemical to study the enhancement performance of substrate constructed by PS/SiO₂/Ag nanocomposite. Results indicated that the PS/SiO₂/Ag nanocomposite prepared based on the core-shell templates showed higher SERS activity. The beneficial effect was associated with a lower specific area of core-shell structure and the larger average diameter of nanosilvers than that of the raspberry-like templates.     

Use of an affinity immunosorbent for the isolation of lactoferrin from breast milk serum

An affinity or biospecific method of isolating an iron-binding glycoprotein — lactoferrin — from breast milk is described which permits in a single chromatographic operation the isolation of lactoferrin homogeneous according to the results of electrophoresis in polyacrylamide gel. The affinity method of isolating lactoferrin is based on the use of a specific immunosorbent consisting of antibodies to lactoferrin covalently conjugated with cyanogen-bromide-activated Sepharose 4B.     

Immobilized citrate synthase

Kinetic properties of pig heart citrate synthase immobilized on Sepharose were determined. Compared to the free enzyme the K_m values for both acetyl-CoA and oxalacetate were increased. The kinetic pattern of the Lineweaver-Burk plots of both substrates for the immobilized enzyme was that of lines intersecting on thex axis. This is the same as that obtained for the free enzyme and indicates that there is no change in the kinetic mechanism of the reaction. The pH response and the Arrhenius plot of both the immobilized and free enzyme were the same. The enzymes show a break in their Arrhenius plots. The immobilized enzyme exhibits greater heat stability than does the free enzyme.     

Heat of reaction and curing of epoxy resin

The heat of reaction and kinetics of curing of diglycidyl ether of bisphenol-A (DGEBA) type of epoxy resin with catalytic amounts of ethylmethylimidazole (EMI) have been studied by differential power-compensated calorimetry as a part of the program for the study of process monitoring for composite materials. The results were compared with those from 1∶1 and 1∶2 molar mixtures of DGEBA and EMI. A method of determination of heat of reaction from dynamic thermoanalytical instruments was given according to basic thermodynamic principles. The complicated mechanism, possibly involving initial ionic formation, has also been observed in other measurements, such as by time-domain dielectric spectroscopy. The behavior of commercially available DGEBA resin versus purified monomeric DGEBA were compared. The melting point of purified monomeric DGEBA crystals is 41.4 °C with a heat of fusion of 81 J/g. The melt of DGEBA is difficult to crystallize upon cooling. The glass transition of purified DGEBA monomer occurs around ?22 °C with aΔC _p of 0.60 J/K/g.     

Structural and thermal properties of HDPE/n-AlN polymer nanocomposites

High-density polyethylene (HDPE) containing various volume fractions (0–20 vol%) of aluminum nitride nanoparticles (n-AlN) is prepared by melt mixing. Structural and morphological characterizations of the prepared composites are carried out by X-ray diffraction (XRD), high-resolution transmission electron microscopy (HR-TEM), and atomic force microscopy (AFM). Thermal stability and degradation kinetics of HDPE/AlN (nano) composites are investigated by Thermogravimetric analysis (TG). HR-TEM micrographs confirm fairly uniform dispersion of AlN nanoparticles, as well as the existence of long interconnected chain-like aggregates. AFM images also confirm homogeneous dispersion of n-AlN in the polymer matrix. Roughness analysis from the AFM data indicates the presence of substantial undulation from the mean surface level. Thermogravimetric data indicate small improvement in the thermal stability of the composites. Kinetic parameters, viz., the activation energy (E _a), frequency factor (A), and reaction order (n) are estimated using the isoconversional methods of Kissinger, Flynn–Wall–Ozawa (FWO), KAS, and Friedman. Activation energies (E _a) calculated by the above four models display nearly similar features and are enhanced by the presence of AlN nanoparticles. Kinetics of degradation of HDPE-AlN (nano) composites follows a first-order reaction.     

The role of octanol in the extraction of hydrochloric acid by trilaurylamine dissolved in benzene

The extraction of hydrochloric acid by trilaurylamine (TLA) dissolved in benzene was studied in the presence and in absence of n-octanol. The extraction of HCl was found to be enhanced by the addition of octanoi to the organic phase. In order to explain this effect by means of the law of mass action, the systems TLA-HCL-benzene and n-octanol-HCl-benzene as well as TLA-octanol-benzene were also studied. It was found that TLA reacts with octanol to form a complex, TLAROH, while the octanol itself associates in benzene to form dimers and tetramers, although it does not extract HCl alone from the dilute solutions used in the present study. The enhancement of the extraction of HCl by TLA upon the addition of n-octanol could be described by the formation of the species TLA·ROH·HCl and its stability constant was determined.