Affinity chromatography of trypsin and related enzymes. V. Basic studies of quantitative affinity chromatography.

A detailed study of the quantitative affinity chromatography of trypsin [EC 3.4.21.4] is reported here. Frontal chromatography using an enzyme solution of very low concentration on an affinity adsorbent gave the dissociation constant of the enzyme-immobilized ligand complex (Kd). Kd values determined under various conditions enabled us to discuss in detail the interaction of trypsin and affinity adsorbents (mainly Gly-Gly-Arg Sepharose). The pH dependence of Kd was consistent with that of the interaction of trypsin and product-type compounds. The effects of changes in temperature, ionic strength, dielectric constant, etc., were also studied. The Ki values of soluble competitive inhibitors can be determined by analysis of their effects on the elution volume of the enzyme. The values obtained were in good agreement with those obtained by kinetic analysis. The present method proved to be useful as a general procedure to investigate the interaction of a protein and a specific ligand.     

Trypsin immobilization by direct adsorption on metal ion chelated macroporous chitosan-silica gel beads

Silica gel bead coated with macroporous chitosan layer (CTS-SiO₂) was prepared, and the metal immobilized affinity chromatographic (IMAC) adsorbents could be obtained by chelating Cu²⁺, Zn²⁺, Ni²⁺ ions, respectively on CTS-SiO₂, and trypsin could be adsorbed on the IMAC adsorbent through metal–protein interaction forces. Batch adsorption experiments show that adsorption capacity for trypsin on these IMAC adsorbent variated with change of pH. The maximal adsorption reached when the solution was in near neutral pH in all three IMAC adsorbents. Adsorption isothermal curve indicated that maximal adsorption capacity could be found in the Cu²⁺-CTS-SiO₂ with the value of 4980 ± 125 IU g⁻¹ of the adsorbent, while the maximal adsorption capacity for trypsin on Zn²⁺ and Ni²⁺ loaded adsorbent was 3762 ± 68 IU g⁻¹ and 2636 ± 53 IU g⁻¹, respectively. Trypsin immobilized on the IMAC beads could not be desorbed by water, buffer and salt solution if the pH was kept in the range of 5–10, and could be easily desorbed from the IMAC beads by acidic solution and metal chelating species such as EDTA and imidazole. The effect of chelated metal ions species on CTS-SiO₂ beads on the activity and stability of immobilized trypsin was also evaluated and discussed. Trypsin adsorbed on Zn-IMAC beads retained highest amount of activity, about 78% of total activity could be retained. Although the Cu-IMAC showed highest affinity for trypsin, only 25.4% of the calculated activity was found on the beads, while the activity recovery found on Ni-IMAC beads was about 37.1%. A remarkable difference on stability of trypsin immobilized on three kinds of metal ion chelated beads during storage period was also found. Activity of trypsin on Cu-IMAC decreased to 24% of its initial activity after 1-week storage at 4 °C, while about 80% activity was retained on both Ni-IMAC and Zn-IMAC beads. Trypsin immobilized on Zn-CTS-SiO₂ could effectively digest BSA revealed by HPLC peptide mapping.     

Preparation of immobilized enzyme with high activity using affinity tag based on proteins A and G

Affinity tag AG consisting of immunoglobulin G (lgG)-binding domains of protein A from Staphylococcus aureus (EDABC) and those of protein G from Streptococcus strain G148 (C2C3) were used to facilitate immobilization of beta-galactosidase (betagal) from Escherichia coli. Poly(methylmethacrylate/N-isopropylacrylamide/methacrylic acid) [P(MMA/NIPAM/MAA)] and poly(styrene/N-isopropylacrylamide/methacrylic acid) [P(St/NIPAM/MAA)] latex particles, which show thermosensitivity, were used as support materals to prepare affinity adsorbents. Human gamma-globulin (HgammaGb), whose major fraction is lgG, was used as an affinity ligand and was covalently immobilized onto the both latex particles by the carbodiimide method under various conditions. A fusion protein, AGbetagal, was immobilized at pH 7.3 by the specific binding of affinity tag to these affinity adsorbents. The amount of adsorbed AGbetagal per unit amount of immobilized HgammaGb, namely, efficiency of ligand utilization, was strongly affected by the type of latex particles and pH value for HgammaGb immobilization. The efficiency of ligand utilization was maximum in the affinity adsorbents prepared at pH 6.0 to 7.0, and that in the HgammaGb-P(MMA/NIPAM/MAA) latex particles was high. This result could be explained by the conformation and orientation of immobilized HgammaGb molecules. Immobilized AGbetagal retained approximately 75% of its activity in solution and the binding is stable enough to allow repeated use. These results clearly demonstrate that combination of the affinity tag AG and the affinity adsorbents, based on the thermosensitive latex particles, offers a simple and widely applicable method for preparation of immobilized enzyme with high activity. (c) 1995 John Wiley & Sons, Inc.     

Integrated enzyme purification and immobilization processes with immobilized metal affinity adsorbents

Silica-based immobilized metal affinity chromatography adsorbents with various ligand densities were prepared for the purification and immobilization of poly(His)-tagged d-hydantoinase (DHTase). An adsorbent with a ligand density of 13.0 μmol Cu²⁺/g gel exhibiting the optimal selectivity and a capacity of 1.4 mg/g gel toward the poly(His)-tagged enzyme was identified. The adsorbent was used for the one-step purification of His-tagged enzymes from crude cell lysate with a purity above 90%. The silica-based affinity adsorbents are particularly well suited for industrial scale operations due to their robustness. A packed-bed bioreactor with the DHTase-loaded adsorbents was used for the continuous conversion of d,l-p-hydroxyphenylhydantoin (d,l-HPH) to N-carbamoyl-d-hydroxyphenylglycine, an intermediate for the production of d-hydroxylphenylglycine. Under optimal conditions, 60 °C and pH 8.0, a conversion of 60% was obtained at a residence time of 30 min. Upon extended operation, the catalytic activity of the biocatalysts declined significantly due to enzyme leakage and enzyme denaturation. The extent of enzyme leakage can be attenuated by crosslinking with glutaraldehyde. In this study, we successfully demonstrate that a packed-bed bioreactor containing silica-based IMAC adsorbents can be used for the direct purification and immobilization of poly(His)-tagged enzymes for biotransformation.     

以壳聚糖为载体亲和层析胰蛋白酶

用活化的壳聚糖为载体,鸡卵粘蛋白(CHOM)为配基,制备了胰蛋白酶的亲和吸附剂。采用该吸附剂亲和层析胰酶,所得产物经SDS-PAGE电泳检测,带中只有一条带颜色较深,且与标准胰蛋白酶带位置几乎相同。实验结果表明1 g壳聚糖可以固定60 mg鸡卵粘蛋白,制成的亲和吸附剂可吸附胰蛋白酶的最大量为118 U/g。以壳聚糖为载体的亲和吸附剂制备过程简单、安全。     

Human plasma kallikrein. Purification and preliminary characterization

A method is described for the convenient purification of the protease plasma kallikrein from human Cohn fraction IV-1. The enzyme was produced by endogenous activation after acid treatment to remove an inhibitor and was concentrated by the successive use of affinity adsorbents prepared by the immobilization of soybean trypsin inhibitor and aminobenzamidine. The esterase- and kinin-producing activities were enriched about 1100-fold from fraction IV-1.Several properties of plasma kallikrein strengthen the impression that it is related to trypsin, namely, competitive inhibition by benzamidine and the formation of a stable p-guanidinobenzoyl acyl enzyme intermediate. Inactivation by affinity labeling with Z-LysCH₂Cl was successful in contrast to the inertness of Tos-LysCH₂Cl.     

Affinity chromatography of amine oxidase from Aspergillus niger.

Omega-Aminohexyl-Sepharose 4B served as an excellent biospecific adsorbent for affinity chromatography of amine oxidase (monoamine:O2 oxidoreductase (deaminating), EC 1.4.3.4) from Aspergillus niger. The enzyme was completely adsorbed on this affinity resin when applied to a column in 0.1 M potassium phosphate buffer (pH 7.2). Although a small part of the enzyme was retained on the column through ionic interaction and eluted with 1.0 M potassium phosphate buffer (pH 7.2), most of the enzyme adsorbed was eluted with 0.5 M potassium phosphate buffer (pH 7.2) containing 10 mM butylamine. Essentially no retention of the enzyme on a column of epsilon-aminopentyl-Sepharose or delta-aminobutyl-Sepharose occurred under the same conditions, indicating that an appropriate length (more than approx. 12 A) of a hydrocarbon extension between the agarose matrix and the terminal amino group would be necessary for efficient adsorption of amine oxidase. The modification of the enzyme with 3-methyl-2-benzothiazolinone hydrazone (carbonyl inhibitor) or dithionite (reducing agent) resulted in loss of the ability to bind to omega-aminohexyl-Sepharose. It was also demonstrated that the affinity chromatography on omega-aminohexyl-Sepharose can be used as a powerful means of purifying this enzyme from crude extracts of Aspergillus niger. All of the three adsorbents were effective as a substrate in the amine oxidase reaction, but their substrate activities were as low as the corresponding free diamines.     

A mutant trypsin-like enzyme from Streptomyces fradiae,created by site-directed mutagenesis,improves affinity chromatography for protein trypsin inhibitors

 The Ser-170 residue of a trypsin-like enzyme from Streptomyces fradiae (SFT), which is considered to be the active-site serine, was replaced with alanine by site-directed mutagenesis to improve the affinity chromatography step for a Kazal-type trypsin inhibitor, pancreatic secretory trypsin inhibitor (PSTI). The resulting mutant SFT, designated as [S170A]SFT, was expressed in Streptomyces lividans and purified to homogeneity. [S170A]SFT was catalytically inactive, but still had the ability to bind tightly to PSTI and to soybean trypsin inhibitor with dissociation constants of 3.1×10^-7 M and 1.9×10^-8 M respectively. We further demonstrated that recombinant human PSTI secreted into Saccharomyces cerevisiae culture broth could be purified to homogeneity with a one-step [S170A]SFT-affinity column. The purified PSTI contained no molecules intramolecularly cleaved by active trypsin, which are found when trypsin-affinity chromatography is used for the purification. This eliminated the need for further separation of intact PSTI from intramolecularly cleaved PSTI by high-performance liquid chromatography, thus simplifying and improving its purification process. Received: 29 November 1995/Received revision: 24 January 1996/Accepted: 17 March 1996     

CONVERSION OF TRYPSIN TO A COPPER ENZYME: TYROSINASE/CATECHOL OXIDASE BY CHEMICAL MODIFICATION

New active sites can be introduced into naturally occurring enzymes by the chemical modification of specific amino acid residues in concert with genetic techniques. Chemical strategies have had a significant impact in the field of enzyme design such as modifying the selectivity and catalytic activity which is very different from those of the corresponding native enzymes. Thus, chemical modification has been exploited for the incorporation of active site binding analogs onto protein templates and for atom replacement in order to generate new functionality such as the conversion of a hydrolase into a peroxidase. The introduction of a coordination complex into a substrate binding pocket of trypsin could probably also be extended to various enzymes of significant therapeutic and biotechnological importance.

The aim of this study is the conversion of trypsin into a copper enzyme: tyrosinase by chemical modification. Tyrosinase is a biocatalyst (EC.1.14.18.1) containing two atoms of copper per active site with monooxygenase activity. The active site of trypsin (EC 3.4.21.4), a serine protease was chemically modified by copper (Cu⁺²) introduced p-aminobenzamidine (pABA- Cu⁺²: guanidine containing schiff base metal chelate) which exhibits affinity for the carboxylate group in the active site as trypsin-like inhibitor. Trypsin and the resultant semisynthetic enzyme preparation was analysed by means of its trypsin and catechol oxidase/tyrosinase activity. After chemical modification, trypsin-pABA-Cu⁺² preparation lost 63% of its trypsin activity and gained tyrosinase/catechol oxidase activity. The kinetic properties (K_cat, K_m, K_cat/K_m), optimum pH and temperature of the trypsin-pABA-Cu⁺² complex was also investigated.     

The interaction ofClostridium perfringens sialidase with immobilized sialic acids and sialyl-glycoconjugates

Clostridium perfringens sialidase is adsorbed by sialic acid immobilized on adipic acid dihydrazido-Sepharose 4B and/or polymethylacrylic hydrazido-Sepharose 4B, through its carboxyl group, C-7 to C-9 side chain, or its amino function asd-neuraminic acid--methyl glycoside or 2-deoxy-2,3-didehydroneuraminic acid. Sialidase binding was strongest to the amino-linked adsorbents, but purification was low and the enzyme could not be eluted with substrate or free sialic acid. Low binding of the sialidase to the non-substituted, blocked supports suggested that hydrophobic interactions were involved, and this was confirmed by adsorption of the enzyme on alkyl agaroses with approximately 80% of total sialidase adsorbed on decyl-agarose. Genuine affinity chromatography of sialidases is possible on immobilized sialyl-glycoconjugates, andC. perfringens sialidase could be purified to the same specific activity as the electrophoretically homogeneous enzyme using submandibular gland mucus glycoprotein adsorbents. Sialidases fromVibrio cholerae, Arthrobacter ureafaciens, Newcastle disease virus, Fowl plague virus and Influenza A₂ virus also bound to immobilized sialic acids and sialyl-glycocojugates.Dedicated to Prof. Dr. Hans Faillard on the occasion of his 60th birthday.     

Affinity chromatography of Bacillus subtilis glutamine phosphoribosylpyrophosphate amidotransferase.

Purified glutamine phosphoribosylpyrophosphate amidotransferase from Bacillus subtilis bound to affinity adsorbents containing immobilized adenine nucleotides. Although the enzyme probably bound via an allosteric site at which AMP acts most effectively, 50 times more enzyme was bound by N⁶-(aminohexyl)-ATP-agarose than by N⁶-(aminohexyl)-AMP-agarose. The enzyme could be efficiently and specifically eluted from N⁶-(aminohexyl)-ATP-agarose with the substrate phosphoribosylpyrophosphate, which antagonizes AMP inhibition in kinetic experiments. Elution could also be effected by 0.5 m KCl or by chelation of Mg²⁺ ions. The usefulness of these techniques in purification of partially purified amidotransferase was demonstrated.     

The perturbation of thrombin binding to human platelets by trypsin and neuraminidase

The initial step in the interaction of thrombin with human platelets in binding of the enzyme to the platelet surface. The effects of digestion of isolated platelets with trypsin and neuraminidase on aggregation, release of serotonin and binding of thrombin have been examined.Trypsin is a powerful inducer of platelet aggregation as well as the release reaction. The aggregation effect of trypsin may be blocked with disodium ehtylenediaminetatraacetate (EDTA). Further, in the presence of EDTA, trypsin-induced release of [¹⁴C]serotonin is 15–20% lower compared to controls and the initial lag period is prolonged. Conditions were developed under which trypsin did neither aggregate nor release serotonin from platelets. Even under these conditions, trypsin caused a profound loss in the thrombin binding capacity of platelets. Thus, the trypsin-induced fall in the thrombin binding capacity and the platelet response are dissociated. This loss in the thrombin binding by trypsin is due to a lower number of binding sites available on the platelet surface and is not due to an altered affinity.Neuraminidase did not induce platelet aggregation or the release reaction. The ability of platelets to bind thrombin was also unimpaired by prior digestion with neuraminidase. Thus, the sialic acid at the platelet surface is not essential in the function of thrombin recognition by the receptor. This moiety may nontheless be a constituent of a glycoprotein which might act as the thrombin receptor.     

Synthesis of a disulfide affinity adsorbent for purification of estrogen receptor

Synthesis of an estrogen affinity adsorbent containing a disulfide linkage between the steroid and stationary matrix permitted facile purification of high affinity estrogen binding proteins. Following affinity chromatography of either antibody directed against estrone 17-carboxymethyloxime — bovine serum albumin or immature calf uterine cytoplasmic estrogen receptor proteins, the specifically bound protein was recovered by incubating the adsorbent with 2-mercaptoethanol. Crude antibody and uterine cytosol was prepared for affinity chromatography in buffer containing 10^?3 to 10^?2M cystamine (S-S) to block SH-containing proteins, in order to protect the adsorbent against protein-mediated S-S ag SH exchange. Cystamine was found to markedly stabilize crude cytosol receptor protein by 200–300% compared with preparations obtained under ordinary conditions. Disulfide affinity adsorbents are versatile in that they can be used either under conventional conditions of specific protein recovery, or with 2-mercaptoethanol which removes the ligand and bound protein from the stationary matrix quantitatively.     

Large-scale separation of magnetic bioaffinity adsorbents

Flat magnetic separator was used to separate magnetic bioaffinity adsorbents from litre volumes of suspensions. Both magnetic cross-linked erythrocytes and magnetic chitosan were efficiently separated; at least 95% adsorbent recovery was achieved at maximum flow rate (1680 ml min^–1). Using this system low amounts of trypsin were concentrated from large sample volumes using magnetic erythrocytes as affinity adsorbent.     

The affinity chromatography of transketolase.

A number of possible affinity adsorbents for transketolase (sedoheptulose-7-phosphate:D-glyceraldehyde-3-phosphateglycolaldehydetransferase, EC 2.2.1.1) were prepared. The behaviour of the enzyme from Candida utilis and from Baker's yeast on columns of these and of Blue Sepharose CL-6B was examined, together with the behaviour of the contaminating enzyme, ribulose 5-phosphate 3-epimerase (EC 5.1.3.1). A procedure for removing bound thiamine pyrophosphate by dialysis against EDTA was developed. The competitive inhibition of transketolase by oxythiamine and neopyrithiamine was measured and the Ki values obtained of 1.4 and 4.3 mM, respectively, were compared with the affinity of adsorbents prepared from these two inhibitors. Adsorbents containing bound thiamine pyrophosphate were relatively ineffective but those containing epoxy-linked neopyrithiamine and D-ribose 5-phosphate adsorbed the enzyme at pH 7.4 and it could be eluted in a specific manner.     

Design and study of peptide-ligand affinity chromatography adsorbents: application to the case of trypsin purification from bovine pancreas

The purification of trypsin from bovine pancreas was employed in a case study concerning the design and optimization of peptide-ligand adsorbents for affinity chromatography. Four purpose-designed tripeptide-ligands were chemically synthesized (>95% pure), exhibiting an Arg residue as their C-terminal (site P(1)) for trypsin bio-recognition, a Pro or Ala in site P(2), and a Thr or Val in site P(3). Each tripeptide-ligand was immobilized via its N-terminal amino group on Ultrogel A6R agarose gel, which was previously activated with low concentrations of cyanuric chloride (10.5 to 42.5 mumol/g gel). Well over 90% of the peptide used was immobilized. Three different concentrations were investigated for every immobilized tripeptide-ligand, 3.5, 7.0, and 14 mumol/g gel. The K(D) values of immobilized tripeptide-trypsin complexes were determined as well as the purifying performance and the trypsin-binding capacity of the affinity adsorbents. The K(D) values determined were in good agreement with the trypsin purification performance of the respective affinity adsorbents. The tripeptide sequence H-TPR-OH displayed the highest affinity for trypsin (K(D) 8.7 muM), whereas the sequence H-TAR-OH displayed the lowest (K(D) 38 muM). Dipeptide-ligands have failed to bind trypsin. When the ligand H-TPR-OH was immobilized via its N-terminal on agarose, at a concentration of 14 mumol/g gel, it produced the most effective affinity chromatography adsorbent. This adsorbent exhibited high trypsin-binding capacity (approximately 310,000 BAEE units/mL of adsorbent); furthermore, it purified trypsin from pancreatic crude extract to a specific activity of 15,200 BAEE units/mg (tenfold purification), and 82% yield. (c) 1997 John Wiley & Sons, Inc.     

Effects of poly(ethylene glycol) and salt on the binding of α-amylase from the fermentation broth of Bacillus amyloliquefaciens by Cu2+-β-CD affinity adsorbent

α-Amylase from Bacillus amyloliquefaciens was purified by the immobilized metal ion affinity adsorbent, β-CD_cl-IDA-Cu²⁺. The adsorbent was prepared by reacting the cross-linked β-cyclodextrin (β-CD) with the ligand, iminodiacetic acid (IDA). The copper ion was further linked to the adsorbent. Poly(ethylene glycol) (PEG) was added to the fermentation broth to improve the adsorption efficiency of the adsorbent toward α-amylase. The effort was to provide hydrophobic interactions with the impurities which might interfere with the adsorption of α-amylase. It also provided a polymer shielding effect to prevent non-specific interactions. With the addition of PEG, the adsorption efficiency could be increased to 98%. Imidazole containing a phosphate buffer and NaCl was used to elute the bound α-amylase. By consecutive adsorption/desorption steps, up to 81% of the α-amylase activity could be recovered. Regarding the reutilization of the affinity adsorbents, α-amylase could be adsorbed and desorbed six times consecutively without a significant loss of α-amylase activity.     

Phospholipase C assay using p-nitrophenylphosphoryl-choline together with sorbitol and its application to studying the metal and detergent requirement of the enzyme.

A simple, rapid procedure is described for eliminating protease contaminants from commercially available neuraminidase by affinity adsorption to celluloseimmobilized fetuin. Neuraminidase activity is enriched 10- to 25-fold depending on the enzyme source. Recovery of activity from batchwise adsorption is approximately 60%, while column chromatography recovery is better than 95%. Affinityadsorbed neuraminidase is virtually free of protease activity when evaluated using [³H]hemoglobin as a substrate. The affinity adsorbent can be reused after elution of the enzyme, and defined proteases such as trypsin and pronase do not bind under experimental conditions. The analytical value of protease-free neuraminidase is discussed in relation to studies of the biological fates of desialated glycoproteins and tumor cells.     

Solubilization of a divalent cation dependent ATPase from dog heart sarcolemma

Heart sarcolemma has been shown to contain an ATPase hydrolizing system which is activated by millimolar concentrations of divalent cations such as Ca²⁺ or Mg²⁺. Although Ca²⁺-dependent ATPase is released upon treating sarcolemma with trypsin, a considerable amount of the divalent cation dependent ATPase activity was retained in the membrane. This divalent cation dependent ATPase was solubilized by sonication of the trypsin-treated dog heart sarcolemma with 1% Triton X-100. The solubilized enzyme was subjected to column chromatography on a Sepharose-6B column, followed by ion-exchange chromatography on a DEAE cellulose column. The enzyme preparation was found to be rather labile and thus the purity of the sample could not be accurately assessed. The solubilized ATPase preparations did not show any cross-reactivity with dog heart myosin antiserum or with Na⁺ + K⁺ ATPase antiserum. The enzyme was found to be insensitive to inhibitors such as ouabain, verapamil, oligomycin and vanadate. The enzyme preparation did not exhibit any Ca²⁺-stimulated Mg²⁺ dependent ATPase activity. Furthermore, the low affinity of the enzyme for Ca^2– (Ka = 0.3 mM) rules out the possibility of its involvement in the Ca²⁺ pump mechanism located in the plasma membrane of the cardiac cell.