Biospecific adsorption chromatography of phospholipase A2 from different sources

Methods of biospecific adsorption chromatography of phospholipase A2 obtained from porcine pancreas and Naja naja oxiana, Vipera ursini renardi, Vespa orientalis venoms were developed. Granulated polyamide with covalently linked phosphatidylethanolamine were used as an affinity adsorbent. Chemical inertness of linked phosphatidylethanolamine to the hydrolytic action of phospholipase A2 and its high affinity for biospecific complexes are shown. Forms of phospholipase A2 different in their affinity for an immobilized substrate was isolated by biospecific adsorption chromatography. The role of hydrophobic and electrostatic interactions in formation of enzyme-ligand complexes was studied.     

In situ preparation of peptidylated polymers as ready-to-use adsorbents for rapid immunoaffinity chromatography

Summary The preparation method of peptide ligands employing polymer-supported solid-phase synthesis and leading to biospecific sorbents has been designed and optimized. This approach directly affords porous polymer sorbents for biospecific chromatography and avoids the cleavage of the synthesized peptide moieties from the carrier and their isolation. The specifics of both peptide synthesis and biospecific chromatography using hydrophilic macroporous polymer supports based on porous poly(glycidyl methacrylate-co-ethylene dimethacrylate) beads and discs were also investigated. The protecting groups can be removed from the target peptide (bradykinin) attached to the polymer support by trifluoromethylsulfonic acid without any significant loss of the attached peptide from the polymer carrier. Introduction of styrene as a comonomer into the copolymer structure improves the reactivity of the support. However, no nonspecific adsorption of proteins in the course of the biospecific isolation of antibradykinin antibodies was observed with these media. In contrast, the nonspecific sorption of proteins increases as a result of increasing peptide loading.     

In situ preparation of peptidylated polymers as ready-to-use adsorbents for rapid immunoaffinity chromatography

The preparation method of peptide ligandsemploying polymer-supported solid-phase synthesisand leading to biospecific sorbents has beendesigned and optimized. This approach directlyaffords porous polymer sorbents for biospecificchromatography and avoids the cleavage of thesynthesized peptide moieties from the carrier andtheir isolation. The specifics of both peptidesynthesis and biospecific chromatography usinghydrophilic macroporous polymer supports based onporous poly(glycidyl methacrylate-co-ethylenedimethacrylate) beads and discs were alsoinvestigated. The protecting groups can be removed from the target peptide (bradykinin) attached tothe polymer support by trifluoromethylsulfonic acidwithout any significant loss of the attached peptidefrom the polymer carrier. Introduction of styreneas a comonomer into the copolymer structureimproves the reactivity of the support. However, nononspecific adsorption of proteins in the course ofthe biospecific isolation of antibradykininantibodies was observed with these media. Incontrast, the nonspecific sorption of proteinsincreases as a result of increasing peptide loading.     

Biospecific chromatography of lipolytic enzymes and methods for determining their activity

The review concerns application of affinity chromatography for isolation of phospholipases and lipases, as well as the methods for determining their activities. Main emphasis is laid on the preparation of biospecific supports with lipid ligands as well as on development of new methods for assaying lipolytic activity.     

Preparative isolation of polyphosphoinositides and other anionic phospholipids from natural sources using chromatography on adsorbents containing primary amino groups.

A new method for the preparative isolation of anionic phospholipids with the use of chromatography on adsorbents containing primary amino groups has been developed. The method combines elements of bioaffinity and ion-exchange chromatography. Synthesis of adsorbents based on Spheron and silica supports with immobilized neomycin, L-lysine, or aminoalkyl groups was carried out. Optimal conditions for the separation of phospholipid mixtures on aminosorbents were determined. Separation of rat brain bis- and trisphosphoinositides and preparative isolation of bovine heart cardiolipin and baker's yeast phosphatidylinositol are described. The chromatographic behavior of anionic phospholipids on three types of adsorbent was studied. The contribution of biospecific interactions to the adsorption of polyphosphoinositides on aminosorbents is noted.     

Fractionation of Aspergillus niger cellulases by combined ion exchange affinity chromatography

Eight chemically modified cellulose supports were tested for their ability to absorb components of the Aspergillus niger cellulase system. At least two of the most effective adsorbents, aminoethyl cellulose and carboxymethyl cellulose, were shown to be useful for the fractionation of cellulases. These supports apparently owe their resolving capacity to both ion exchange and biospecific binding effects; however, the relative importance of each effect is unknown. These observations form the basis for a new cellulase fractionation technique, combined ion exchange-affinity chromatography.     

Influence of the nature of coupling agents on insulin adsorption on supports grafted with sialic acid for high-performance affinity chromatography

Porous silica exhibits excellent mechanical properties for use as a stationary phase for high-performance liquid chromatography. However, negative surface charges make it unusable in its native state. For this reason, silica beads are coated with dextran polymers carrying a calculated amount of diethylaminoethyl groups. Both the minimization of non-specific interactions and the hydrophilic character of such supports allow their functionalization with biospecific ligands and finally their use in high-performance affinity chromatography of biological products. The use of these modified supports in high-performance affinity chromatography requires a better understanding of various characteristics of stationary phases. For this purpose, several techniques were utilized, in particular, size-exclusion chromatography and adsorption of radiolabelled albumin. These methods provided complementary information on the structure of these supports. Coated silica-based supports were functionalized with sialic acid by means of different coupling agents. The affinity of these supports for insulin was determined by the establishment of adsorption isotherms and by high-performance affinity chromatography, to evidence the relationships between structural characteristics of the supports and their separation properties. The study of interactions between these supports and insulin allowed us to show the importance of the coupling method on the performances of supports in affinity chromatography.     

Affinity chromatography of aminopeptidases

The recent data are generalized concerning a series of synthetic oligopeptides which are competitive inhibitors of aminopeptidases of animal, plant and microbic origin. A method for biospecific chromatography of these enzymes is developed, using as ligands such inhibitors as diazo derivatives of p-aminophenyl-, chloromethyl- and methylketones of L-amino acids and peptides, amino acids, aliphatic acid amides. It is established that the most effective inhibitors of aminopeptidases contain L-amino group in the uncharged form in the N-end position, hydrophobic lateral chain of L-configuration and a carbonyl group analogous to position of these groups in the substrate. Methods for synthesis of certain peptides are developed with respect to the above requirements. It is shown that peptides with a space-inaccessible peptide link and antibiotics are often used as ligands for affinity chromatography of aminopeptidases. At present a nonspecific (ion-exchange, hydrophobic) interaction of sorbent and aminopeptidases is observed, which necessitates to increase the specificity at the stage of the enzyme desorption in the further studies.     

Hydrophobic chromatography of the HL-60 cellular fraction co-binding with hexamethylene bisacetamide

Methods of separating N-acetyl-1,6-diaminohexane (NADAH) and its immobilization to diol-silica have been developed. Hexamethylene bisacetamide (HMBA) and its metabolite NADAH are used as inducers of leukemia cell differentiation. The inducing mechanism of HMBA is still not clear. Experiments show that HMBA and NADAH undergo relatively strong hydrophobic reactions and do not readily undergo ion-exchange with the proteins of the cytosolic fraction of HL-60 cells during immobilization of NADAH; the retention time of the proteins was longer than that of the phosphatides. These results show that the adsorption of HMBA and NADAH to proteins was higher than that to phosphatides. The expected biospecific receptor binding with HMBA has not been found.     

Chromatography of carboxylic proteinases on sorbents containing the 2,4-dinitrophenyl group. Role of ionic interactions]

The chromatography of porcine pepsin on biospecific sorbents (Sepharose-4B-epsilon-DNP-aminocapronylhydrazide and Sepharose-4B-N-DNP-N'-acetylhexamethylenediamine) was studied. The sorbents in question differ from the previously used hydrophobic sorbent Sepharose-4B-DNP-hexamethylenediamine by the lack of strongly basic groups in the site of the ligand binding to the polymeric matrix. No qualitative differences in the pepsin chromatography on the three sorbents were observed. Presumably the decrease of the pepsin binding to the sorbents, containing the dinitrophenyl group, at pH values above the isoelectric point may be due to the effects of the salt on the binding site in the enzyme molecule rather than to the screening of the positive charges of the sorbent by chlorine ions. A commercial preparation of pepsin was purified 2-fold on the sorbent Sepharose-4B-epsilon-DNP-animocapronylhydrazide. The synthesis of sorbents is described.     

Biospecific immobilization of mannan-penicillin G acylase neoglycoenzyme on Concanavalin A-bead cellulose

The matter of this work was to evaluate possibilities of biospecific immobilization of synthetic mannan-penicillin G acylase neoglycoconjugate on Concanavalin A support. The conjugate containing 37% (w/w) of yeast mannan was prepared. Significant biospecific interaction of this neoglycoenzyme with Con A was confirmed by precipitation method. The biospecific sorption of conjugate was investigated using Concanavalin A-triazine bead celluloses MT-100 with different content of Con A (from 1.4 to 9.8 mgCon A/gwet support). The results obtained under optimal conditions were compared with those from covalent immobilization of PGA. The sorbent capacity was observed higher for covalent binding of enzyme. On the other hand, the biospecifically immobilized neoglycoenzyme retained a greater amount of initial activity. The maximum amount of 6.6mgimmobilizedneoglycoenzyme/gwet Con A-sorbent (18.1 U/g) was achieved. The amount as well as activity of immobilized mannan-penicillin G acylase was increased by its two multiple layering on surface of sorbent (10.1mg, respectively, 23.5 U/gwet sorbent). Determined storage and operational (using flow calorimetric method) stabilities of biospecifically immobilized enzyme, were similar, possibly somewhat higher that those of covalent bound penicillin G acylase.     

Surface-labelling studies on skeletal-muscle cells in vitro. Heterogeneity of iodinated cell-surface proteins.

Some theoretical aspects of the desorption of a column-bound protein by elution with its biospecific ligand are considered in cases where, in comparison with the unliganded protein, the protein-ligand complex has a diminished but finite affinity for the adsorbent. A quantity termed the biospecific sensitivity, B, is introduced to facilitate comparison between different systems. Biospecific sensitivity may be defined as the fractional change in standard free energy of adsorption on formation of the protein-ligand complex. The effects of a moderate-to-low biospecific sensitivity on theoretical desorption profiles have been examined by using a computer simulation of the classical multiple-plate column model. Desorption was simulated under various boundary conditions involving protein-adsorbent and protein-ligand affinities and the initial concentrations of adsorption sites, protein and ligand. These simulations suggest that, when the biospecific sensitivity is low, desorption is optimized if (a) the unliganded protein is adsorbed as weakly as possible, (b) the column is loaded to near-saturation with the required protein, (c) the free ligand concentration is many times greater than that giving near-saturation of the protein in free solution, and (d) protein contaminants with high affinity for the adsorbent, and present in large amount, are removed in preliminary purification steps.     

Affinity chromatographic sorting of carboxypeptidase a and its chemically modified derivatives

Carboxypeptidase A and derivatives obtained by chemical modification of various active center components were subjected to affinity chromatography on a p-aminobenzylsuccinic acid-Sepharose 4B conjugate. Tetardation of the enzyme on the column was dependent on the residue modified when elution was carried out with 0.3 m NaCl at pH 7.0. Both the functional zinc atom and the active site residue Glu-270 are essential for effective adsorption while alteration of residues involved in hydrophobic interaction with substrate or in recognition of its terminal carboxyl group decreased retention on the affinity matrix. Elution of native carboxypeptidase with competing soluble benzylsuccinic acid indicated that only active center binding of the immobilized inhibitor accounts for retardation of the enzyme on the column. Hence, affinity chromatography on this biospecific adsorbent using mild elution conditions (which do not distort protein structure) provides an excellent tool for the rapid isolation and purification of active center modified enzyme even from a complex mixture of reaction products.     

Spectroimmunochemistry using colloidal gold bioconjugates

Using surface-enhanced infrared absorption (SEIRA) spectroscopy of dry films of colloidal gold (CG) bioconjugates with protein A, it is shown that certain characteristic bands of the protein (e.g., amide I, amide II and some other vibration modes) are essentially affected by the metal surface. Thus, the method may be used for controlling the quality of such bioconjugates. Moreover, it is demonstrated that the biospecific reaction of protein A attached to CG particles with human immunoglobulin G (IgG) results in further essential changes in SEIRA spectra, providing a means for an easy and rapid IR spectroscopic detection of biospecific immunochemical interactions (i.e., spectroimmunochemistry). The results obtained can form a basis for developing test systems for detecting various biospecific interactions.     

Versatility of mixed-function adsorbents in biospecific protein desorption: Accidental affinity and an improved purification of aspartate transcarbamoylase from wheat germ

Under appropriate experimental conditions (usually but not invariably including low ionic strength) wheat germ aspartate transcarbamoylase can be specifically desorbed by the substrate, carbamoyl phosphate, from hydroxyapatite, from N-(3-carboxypropionyl)aminooctyl-Sepharose, from 10-carboxydecylamino-Sepharose, from Cibacron Blue F3GA-Sepharose, and from Coomassie Blue R250-Sepharose. Experimental evidence suggests that (a) the enzyme is adsorbed at heterogeneous sites on each column, only some of which are susceptible to substrate-specific desorption; (b) in none of these cases is the initial adsorption essentially biospecific, i.e., these are not cases of classical affinity chromatography; (c) in the case of 10-carboxydecylamino-Sepharose, and therefore presumably also in the other cases, the desorption is biospecific, i.e., involves the formation of the catalytically significant enzyme-carbamoyl phosphate complex. Substrate-specific desorption in these cases appears to derive from “accidental” affinity between, on the one hand, clusters of active (ionic, hydrophobic, aromatic, etc.) groups on the protein and, on the other, complementary clusters on the adsorbent, some of these interactions being perturbed when the ligands binds to the protein. Biospecific desorption from 10-carboxydecylamino-Sepharose has been incorporated as the sole chromatographic step in a new, 8000-fold purification of the enzyme. It is suggested that biospecific desorption from essentially nonbiospecific adsorbents could explain some published purifications currently described as “affinity chromatography.”     

Hydrophobic displacement chromatography of proteins

Displacement chromatography of proteins was successfully carried out in both hydrophobic interaction and reversed-phase chromatographic systems using low-molecular weight displacers. The displacers employed for hydrophobic displacement chromatography were water soluble, charged molecules containing several short alkyl and/or aryl groups. Spectroscopy was employed to verify the absence of structural changes to the proteins displaced on these hydrophobic supports. Displacement chromatography on a reversed-phase material was employed to purify a growth factor protein from its closely related variants, demonstrating the high resolutions that can be achieved by hydrophobic displacement chromatography. This process combines the high-resolution/high-throughput characteristics of displacement chromatography with the unique selectivity of these hydrophobic supports and offers the chromatographic engineer a powerful tool for the preparative purification of proteins.     

Superparamagnetic adsorbents for high-gradient magnetic fishing of lectins out of legume extracts

This work presents the development, testing, and application in high-gradient magnetic fishing of superparamagnetic supports for adsorption of lectins. Various approaches were examined to produce affinity, mixed mode, and hydrophobic charge induction type adsorbents. In clean monocomponent systems affinity supports created by direct attachment of glucose or maltose to amine-terminated iron oxide particles could bind concanavalin A at levels of up to approximately 280 mg g(-1) support with high affinity ( approximately 1 microM dissociation constants). However, the best performance was delivered by adsorbents featuring coupled tentacular dextran chains displaying a maximum binding capacity of 238 mg g(-1) and a dissociation constant of 0.13 microM. Adsorbents derivatized with mixed mode or hydrophobic charge induction ligands likewise demonstrated very high capacities for both concanavalin A and Lens culinaris agglutinin (> or = 250 mg g(-1)) with dissociation constants in the micromolar range, though neither of these systems showed any selectivity for lectins in leguminous extracts. When the affinity supports were applied to carbohydrate containing legume extracts only the dextran-linked adsorbents supplied sufficient competition to dissolved sugars to selectively bind concanavalin A in an extract of jack beans. The dextran-linked supports were employed in a high-gradient magnetic fishing experiment, in which concanavalin A was purified to near homogeneity from a crude, unclarified extract of jack beans.     

Insulin adsorption on coated silica based supports grafted with N-acetylglucosamine by liquid affinity chromatography

Silica beads are coated with dextran carrying a calculated amount of positively charged diethylassminoethyl groups (DEAE) in order to neutralize negative charged silanol groups at the silica surface and in this way to minimize non specific interactions between silica surface and proteins in solution. Dextran-coated silica supports are potentially excellent stationary phases for high-performance liquid chromatography of proteins. These supports combine the advantages of polysaccharide phases with the excellent mechanical characteristics of silica. These supports (silica-dextran-DEAE = SID) are easily functionalized by grafting N-acetylglucosamine (GlcNAc) using conventional coupling methods. The performances of the support bearing GlcNAc are studied by high-performance liquid affinity chromatography (HPLAC) of insulin, the hypoglycemic peptide hormone of the human organism. The study shows that these supports exhibit a reversible and specific affinity towards insulin and allow separations with high purification yields. Moreover, the influence of different physico-chemical parameters (pH, NaCl and insulin concentration) on insulin retention on the support was analysed. This allowed us to optimize the conditions of adsorption and to better understand the interaction mechanisms between insulin and GlcNAc as biospecific ligand.     

Polyclonal anti-chymotrypsin antibodies suitable for oriented immobilization of chymotrypsin

Summary Polyclonal antibodies obtained from the serum of pig immunized by DIP-chymotrypsin were separated into two fractions, anti-chymotrypsin IgG I and anti-chymotrypsin IgG II, by the use of chromatography on biospecific adsorbents prepared by chymotrypsin (CHT) immobilization in different ways. IgG I, which did not decrease the proteolytic activity of CHT, was obtained by biospecific affinity chromatography on a column of Sepharose with CHT attached through an immobilized polyvalent inhibitor, antilysin (AL). IgG II was isolated from the fraction unretarded on the column of CHT-AL-Sepharose by chromatography on a column with CHT directly attached to AH-Sepharose activated by glutaraldehyde. IgG II strongly decreased the proteolytic activity of CHT. Comparison of the proteolytic activity of CHT covalently bound to AH-Sepharose with that of CHT noncovalently intercepted by biospecific sorption to Sepharose with attached anti-CHT-IgG I showed a great advantage of the immobilization of CHT by oriented adsorption.     

Affinity surfactants as reversibly bound ligands for high-performance affinity chromatography

Pyridine was coupled covalently to a nonionic ethoxylated alcohol: octaethylene glycol n-hexadecyl ether. This modified surfactant was found to be a reversible, competitive inhibitor of horse serum cholinesterase. The surfactant bound irreversibly, in aqueous media, to octadecyl-bounded reverse phase silica particles commonly used for high-performance liquid chromatography. The amount of ligand bound was found to be 550 mumol/ml of packing, a concentration that is over 100 times higher than what can be normally bound to agarose affinity chromatography supports. With this packing, a 280-fold purification of cholinesterase from horse serum and a 79-fold purification of human serum cholinesterase were accomplished, with yields greater than 80%, using a 2-cm-long column and a 7-min elution time. The affinity surfactant could be eluted from the column using a 6:4 (v/v) mixture of methanol and isopropanol. This technique should be generally applicable in the development of biospecific supports for high-performance affinity chromatography.