Nucleotide-mimetic synthetic ligands for DNA-recognizing enzymes One-step purification of Pfu DNA polymerase.

The commercial availability of DNA polymerases has revolutionized molecular biotechnology and certain sectors of the bio-industry. Therefore, the development of affinity adsorbents for purification of DNA polymerases is of academic interest and practical importance. In the present study we describe the design, synthesis and evaluation of a combinatorial library of novel affinity ligands for the purification of DNA polymerases (Pols). Pyrococcus furiosus DNA polymerase (Pfu Pol) was employed as a proof-of-principle example. Affinity ligand design was based on mimicking the natural interactions between deoxynucleoside-triphosphates (dNTPs) and the B-motif, a conserved structural moiety found in Pol-I and Pol-II family of enzymes. Solid-phase 'structure-guided' combinatorial chemistry was used to construct a library of 26 variants of the B-motif-binding 'lead' ligand X-Trz-Y (X is a purine derivative and Y is an aliphatic/aromatic sulphonate or phosphonate derivative) using 1,3,5-triazine (Trz) as the scaffold for assembly. The 'lead' ligand showed complementarity against a Lys and a Tyr residue of the polymerase B-motif. The ligand library was screened for its ability to bind and purify Pfu Pol from Escherichia coli extract. One immobilized ligand (oABSAd), bearing 9-aminoethyladenine (AEAd) and sulfanilic acid (oABS) linked on the triazine scaffold, displayed the highest purifying ability and binding capacity (0,55 mg Pfu Pol/g wet gel). Adsorption equilibrium studies with this affinity ligand and Pfu Pol determined a dissociation constant (K(D)) of 83 nM for the respective complex. The oABSAd affinity adsorbent was exploited in the development of a facile Pfu Pol purification protocol, affording homogeneous enzyme (>99% purity) in a single chromatography step. Quality control tests showed that Pfu Pol purified on the B-motif-complementing ligand is free of nucleic acids and contaminating nuclease activities, therefore, suitable for experimental use.

Affinity chromatography on immobilised triazine dyes. Studies on the interaction with multinucleotide-dependent enzymes.

A systematic investigation into the interaction of several triazinyl dyes with two enzymes from purine metabolism, IMP dehydrogenase (IMP: NAD+ oxidoreductase, EC 1.2.1.14( and adenylosuccinate synthetase (IMP: L-aspartate ligase (GDP-forming), EC 6.3.4.4) has been conducted. Evidence from kinetic inhibition studies, enzyme inactivation with specific affinity labels and specific elution techniques from agarose-immobilised dyes indicate that triazine dyes such as Procion Blue H-B (Cibacron Blue F3G-A), Red HE-3B and Red H-3B are able to differentiate between the nucleotide-binding sites of these enzymes. This information has been exploited to design specific elution techniques for the purification of these enzymes by affinity chromatography.

The affinity technology in downstream processing.

The quality criteria imposed on several biochemicals are stringent, thus, high-separation purification technology is important to downstream processing. Affinity-based purification technologies are regarded as the finest available, and each one differs in its purifying ability, economy, processing speed and capacity. The most widely used affinity technology is classical affinity chromatography, however, other chromatography-based approaches have also been developed, for example, perfusion affinity chromatography, hyperdiffusion affinity chromatography, high-performance affinity chromatography, centrifugal affinity chromatography, affinity repulsion chromatography, heterobifunctional ligand affinity chromatography and the various chromatographic applications of 'affinity tails'. On the other hand, non-chromatographic affinity technologies aim at high throughput and seek to circumvent problems associated with diffusion limitations experienced with most chromatographic packings. Continuous affinity recycle extraction, aqueous two-phase affinity partitioning, membrane affinity filtration, affinity cross-flow ultrafiltration, reversible soluble affinity polymer separation and affinity precipitation are all non-chromatographic technologies. Several types of affinity ligands are used to different extents; antibodies and their fragments, receptors and their binding substances, avidin/biotin systems, textile and biomimetic dyes, (oligo)peptides, antisense peptides, chelated metal cations, lectins and phenylboronates, protein A and G, calmodulin, DNA, sequence-specific DNA, (oligo)nucleotides and heparin. Likewise, there are several support types developed and used; natural, synthetic, inorganic and composite materials.

Biomimetic-dye affinity chromatography for the purification of mitochondrial L-malate dehydrogenase from bovine heart.

Seven biomimetic anthraquinone triazinyl dye-ligands, bearing as triazine-linked terminal moiety (keto)carboxylated structures mimicking substrates and inhibitors of malate dehydrogenase (MDH), were immobilised on cross-linked agarose Ultrogel A6R. These biomimetic ligands are terminal-ring analogues of commercial nonbiomimetic Cibacron blue 3GA (CB3GA) and parent Vilmafix blue A-R (VBAR). The biomimetic-dye adsorbents, along with nonbiomimetic adsorbents bearing immobilised CB3GA and VBAR, were evaluated for their ability to purify mitochondrial malate dehydrogenase (mMDH) from bovine heart. All but two biomimetic-dye adsorbents displayed higher purifying ability for MDH, compared to nonbiomimetic-dye adsorbents. Furthermore, immobilised anthraquinone-dyes were able to discriminate between the mitochondrial and the cytoplasmic MDH isoenzymes, binding only to the former. One immobilised biomimetic-dye (BM5), bearing as biomimetic terminal moiety 4-aminophenyloxanylic acid, showed the highest purifying ability. This affinity adsorbent was exploited in the purification of mMDH from unpretreated bovine heart extract in one-step. The procedure afforded mMDH at 54% overall yield and of specific activity approx. 1300 U mg-1 (25 degrees C), using step-elution with a mixture containing 0.1 mM beta-nicotinamide adenine dinucleotide (NAD+) and 1.5 mM sulphite. Commercial analytical-grade bovine heart mitochondrial MDH, when assayed under identical conditions, gave a specific activity not exceeding 950 U mg-1. The well-known adsorbent Cibacron blue 3GA-agarose exhibited 8% lower recovery and 25% lower purification for mMDH. The product obtained from the procedure based on the BM5-adsorbent was free of cytoplasmic MDH, glutamic-oxaloacetic transaminase (GOT) and fumarase, and since it has also shown high specific activity, it should be suitable for analytical applications.

High-performance affinity chromatography for protein separation and purification.

Affinity chromatography (1,2), the most powerful of all protein-fractionation techniques, relies on the formation of reversible specific complexes between a ligand immobilized on an insoluble polymer support, termed affinity adsorbent, and the species to be isolated free in solution. The modern support materials (natural, synthetic, or inorganic), consist of macroporous hydrophilic beaded particles, usually bearing free hydroxyl groups available for ligand immobilization. When the support is made of noncompressible particles of small diameter (e.g., 5-20 µm) and narrow size distribution (e.g., 0.2-2 µm) the technique is termed high-performance affinity chromatography (HPAC) (3-5).

Biomimetic dye affinity chromatography for the purification of bovine heart lactate dehydrogenase.

Three biomimetic dye ligands bearing as a triazine-linked terminal moiety a carboxylated structure, which mimics substrates and inhibitors of L-lactate dehydrogenase (LDH), were immobilized on cross-linked agarose Ultrogel A6R. These biomimetic dyes are purpose-designed analogues of commercial monochlorotriazine Cibacron Blue 3GA (CB3GA) and parent dichlorotriazine Vilmafix Blue A-R (VBAR). The corresponding biomimetic adsorbents, along with non-biomimetic adsorbents bearing CB3GA and VBAR, were evaluated for their ability to purify LDH from bovine heart crude extract. When compared with non-biomimetic adsorbents, all biomimetic adsorbents exhibited a higher purifying ability. Further, one immobilized biomimetic dye, bearing mercaptopyruvic acid as biomimetic moiety, displayed the highest purifying ability. The concentration of immobilized dye affected both the capacity and the purifying ability of the affinity column, exhibiting an optimum value 2.2 mumol dye/g moist gel. This affinity adsorbent was exploited for the purification of LDH from bovine heart in a two-step procedure. The procedure consisted in a biomimetic dye affinity chromatography step (NAD+/sulphite elution, 25-fold purification, 64% step yield), followed by DEAE-agarose ion-exchange chromatography (1.4-fold purification, 78% step yield). The purified enzyme exhibited a specific activity of ca. 480 u/mg at 25 degrees C (content of impurities: pyruvate kinase and glutamic-oxaloacetic transaminase were not detected; malate dehydrogenase, 0.01%), compared with ca. 250 u/mg of commercial bovine heart LDH (malate dehydrogenase, 0.05%) suitable for analytical purposes.

New family of glutathionyl-biomimetic ligands for affinity chromatography of glutathione-recognising enzymes.

Three anthraquinone glutathionyl-biomimetic dye ligands, comprising as terminal biomimetic moiety glutathione analogues (glutathionesulfonic acid, S-methyl-glutathione and glutathione) were synthesised and characterised. The biomimetic ligands were immobilised on agarose gel and the affinity adsorbents, together with a nonbiomimetic adsorbent bearing Cibacron Blue 3GA, were studied for their purifying ability for the glutathione-recognising enzymes, NAD+-dependent formaldehyde dehydrogenase (FaDH) from Candida boidinii, NAD(P)+-dependent glutathione reductase from S. cerevisiae (GSHR) and recombinant maize glutathione S-transferase I (GSTI). All biomimetic adsorbents showed higher purifying ability for the target enzymes compared to the nonbiomimetic adsorbent, thus demonstrating their superior effectiveness as affinity chromatography materials. In particular, the affinity adsorbent comprising as terminal biomimetic moiety glutathionesulfonic acid (BM1), exhibited the highest purifying ability for FaDH and GSTI, whereas, the affinity adsorbent comprising as terminal biomimetic moiety methyl-glutathione (BM2) exhibited the highest purifying ability for GSHR. The BM1 adsorbent was integrated in a facile two-step purification procedure for FaDH. The purified enzyme showed a specific activity equal to 79 U/mg and a single band after sodium dodecylsulfate-polyacrylamide gel electrophoresis analysis. Molecular modelling was employed to visualise the binding of BM1 with FaDH, indicating favourable positioning of the key structural features of the biomimetic dye. The anthraquinone moiety provides the driving force for the correct positioning of the glutathionyl-biomimetic moiety in the binding site. It is located deep in the active site cleft forming many favourable hydrophobic contacts with hydrophobic residues of the enzyme. The positioning of the glutathione-like biomimetic moiety is primarily achieved by the strong ionic interactions with the Zn2+ ion of FaDH and Arg 114, and by the hydrophobic contacts made with Tyr 92 and Met 140. Molecular models were also produced for the binding of BM1 and BM3 (glutathione-substituted) to GSTI. In both cases the biomimetic dye forms multiple hydrophobic interactions with the enzyme through binding to a surface pocket. While the glutathioine moiety of BM3 is predicted to bind in the crystallographically observed way, an alternative, more favourable mode seems to be responsible for the better purification results achieved with BM1.

Designed chimaeric galactosyl-mimodye ligands for the purification of Pseudomonas fluorescens beta-galactose dehydrogenase.

Two chimaeric galactosyl-mimodye ligands were designed and applied to the purification of Pseudomonas fluorescens galactose dehydrogenase (GaDH). The chimaeric affinity ligands comprised a triazine ring on which were anchored: (i) an anthraquinone moiety that pseudomimics the adenine part of NAD+, (ii) a galactosyl-mimetic moiety (D-galactosamine for ligand BM1 or shikimate for ligand BM2), bearing an aliphatic 'linker', that mimics the natural substrate galactose, and (iii) a long hydrophilic 'spacer'. The mimodye-ligands were immobilised to 1,1-carbonyldiimidazole-activated agarose chromatography support, via the spacer's terminal amino-group, to produce the respective mimodye adsorbents. Both immobilized mimodyes successfully bound P. fluorescens GaDH but failed to bind the enzyme from rabbit muscle. Adsorbent BM1 bound GaDH from green peas and Baker's yeast, but adsorbent BM2 failed to do so. The mimodye-ligand comprising D(+)-galactosamine (BM1), compared to BM2, exhibited higher purifying ability and enzyme recovery for P. fluorescens GaDH. The dissociation constants (KD) of BM1 and BM2 for P. fluorescens GaDH were determined by analytical affinity chromatography to be 5.9 microM and 15.4 microM, respectively. The binding capacities of adsorbents BM1 and BM2 were 18 U/mg adsorbent and 6 U/mg adsorbent, respectively. Adsorbents BM1 and BM2 were integrated in two different protocols for the purification P. fluorescens GaDH. Both protocols comprised as a common first step DEAE anion-exchange chromatography, with a second step of affinity chromatography on BM1 or BM2, respectively. The purified GaDH obtained from the protocols using BM1 and BM2 showed specific activities equal to 1077 and 854 U/mg, respectively. The former is the highest reported so far and the enzyme appeared as a single band after sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis.

Biomimetic dyes as affinity chromatography tools in enzyme purification.

Affinity adsorbents based on immobilized triazine dyes offer important advantages circumventing many of the problems associated with biological ligands. The main drawback of dyes is their moderate selectivity for proteins. Rational attempts to tackle this problem are realized through the biomimetic dye concept according to which new dyes, the biomimetic dyes, are designed to mimic natural ligands. Biomimetic dyes are expected to exhibit increased affinity and purifying ability for the targeted proteins. Biocomputing offers a powerful approach to biomimetic ligand design. The successful exploitation of contemporary computational techniques in molecular design requires the knowledge of the three-dimensional structure of the target protein, or at least, the amino acid sequence of the target protein and the three-dimensional structure of a highly homologous protein. From such information one can then design, on a graphics workstation, the model of the protein and also a number of suitable synthetic ligands which mimic natural biological ligands of the protein. There are several examples of enzyme purifications (trypsin, urokinase, kallikrein, alkaline phosphatase, malate dehydrogenase, formate dehydrogenase, oxaloacetate decarboxylase and lactate dehydrogenase) where synthetic biomimetic dyes have been used successfully as affinity chromatography tools.

Galactosyl-biomimetic dye-ligands for the purification of Dactylium dendroides galactose oxidase.

Two anthraquinone galactosyl-biomimetic dye-ligands comprising, as terminal biomimetic moiety, galactose analogues (1-amino-1-deoxy-beta-D-galactose and D(+)-galactosamine) were designed for the enzyme galactose oxidase (GAO), using molecular modelling, synthesized and characterized. The biomimetic ligands were immobilized on agarose beads and the affinity adsorbents, together with a non-biomimetic adsorbent bearing Cibacron Blue 3GA, were studied for their ability to purify GAO from Dactylium dendroides. Both biomimetic adsorbents showed higher purifying ability for GAO compared to the non-biomimetic adsorbent, thus demonstrating their superior effectiveness as affinity chromatography materials. In particular, the affinity adsorbent comprising, as terminal biomimetic moiety, 1-amino-1-deoxy-beta-D-galactose (BM1) exhibited the highest purifying ability for GAO. This affinity adsorbent did not bind galactose dehydrogenase, glucose dehydrogenase, alcohol dehydrogenase, or glucose oxidase. The dissociation constant (K(D)) of the immobilized BM1 ligand with GAO was found to be equal to 45.8 microM, whereas the binding capacity was equal to 709 U per ml adsorbent. Therefore, the BMI adsorbent was integrated in a facile two-step purification procedure for GAO. The purified enzyme showed a specific activity equal to 2038 U/mg, the highest reported so far, approximately 74% overall recovery and a single band after sodium dodecylsulfate-polyacrylamide gel electrophoresis analysis.

Purification of alcohol dehydrogenase from four genotypes of the olive fruit fly Bactrocera (Dacus) oleae.

This is the first report describing the purification of alcohol dehydrogenase (ADH) from four genotypes of the olive fruit fly Bactrocera oleae, the most important pest of olives in the Mediterranean region. The purified enzyme shows a single band after SDS-PAGE analysis, corresponding to subunit mass of 26 kDa. The native ADH shows a molecular mass of 48 kDa, after gel filtration HPLC analysis. The purification method incorporated a preliminary ammonium sulphate precipitation step, followed by an anion-exchange DEAE chromatography step, a dye affinity chromatography step on Cibacron blue 3GA, and an anion-exchange DEAE chromatography step employing the same column of the first step. The present method offers good overall recovery (40%) and high enzyme purity, and it is applicable to different genotypes. Furthermore, the method is rapid and economical, as it employs two cheap, widely used, and commercially available chromatography materials.

Interaction of L-glutamate oxidase with triazine dyes: selection of ligands for affinity chromatography.

Glutamate oxidase (GOX, EC 1.4.3.11) from Streptomyces catalyses the oxidation of L-glutamate to alpha-ketoglutarate. Its kinetic constants for L-glutamate were measured equal to 2 mM for Km and 85.8 s(-1) for kcat. BLAST search and amino acid sequence alignments revealed low homology to other L-amino acid oxidases (18-38%). Threading methodology, homology modeling and CASTp analysis resulted in certain conclusions concerning the structure of catalytic alpha-subunit and led to the prediction of a binding pocket that provides favorable conditions of accommodating negatively charged aromatic ligands, such as sulphonated triazine dyes. Eleven commercial textile dyes and four biomimetic dyes or minodyes, bearing a ketocarboxylated-structure as their terminal biomimetic moiety, immobilized on cross-linked agarose gel. The resulted mini-library of affinity adsorbents was screened for binding and eluting L-glutamate oxidase activity. All but Cibacron Blue 3GA (CB3GA) affinity adsorbents were able to bind GOX at pH 5.6. One immobilized minodye-ligand, bearing as its terminal biomimetic moiety p-aminobenzyloxanylic acid (BM1), displayed the higher affinity for GOX. Kinetic inhibition studies showed that BM1 inhibits GOX in a non-competitive manner with a Ki of 10.5 microM, indicating that the dye-enzyme interaction does not involve the substrate-binding site. Adsorption equilibrium data, obtained from a batch system with BM1 adsorbent, corresponded well to the Freundlich isotherm with a rate constant k of 2.7 mg(1/2)ml(1/2)/g and Freundlich isotherm exponent n of 1. The interaction of GOX with the BM1 adsorbent was further studied with regards to adsorption and elution conditions. The results obtained were exploited in the development of a facile purification protocol for GOX, which led to 335-fold purification in a single step with high enzyme recovery (95%). The present purification procedure is the most efficient reported so far for L-glutamate oxidase.

Dye-ligand chromatography for the resolution and purification of restriction endonucleases.

The resolution of restriction endonucleases from the same microorganism is conventionally achieved by lengthy fractionation protocols. We now report effective single-step procedures that exploit dye-ligand chromatography for the resolution and purification of restriction enzymes. After suitable initial screening, we demonstrated that resolution of two restriction activities can be achieved in one chromatographic step, and further purification can subsequently be effected using selected dye-adsorbents. Accordingly, we resolved in one step, Hpa I from Hpa II, Hind II from Hind III, and Sac I from Sac II. Furthermore, a three-step chromatographic procedure has been developed to purify EcoRV suitable for commercial exploitation, as judged by the "overdigestion" and "cut-ligate-recut" quality control tests.

Sulphonamide-based bombesin prodrug analogues for glutathione transferase, useful in targeted cancer chemotherapy.

Glutathione transferases (GSTs) are enzymes involved in cellular detoxification by catalysing the nucleophilic attack of glutathione (GSH) on the electrophilic centre of a number of toxic compounds and xenobiotics, including certain chemotherapeutic drugs. The encountered chemotherapeutic resistant of tumour cells, thus, has been associated with the increase of total GST expression. GSTs, in addition to GSH-conjugating activity, exhibit sulphonamidase activity, catalyzing the GSH-mediated hydrolysis of sulphonamide bonds. Such reactions are of interest as potential tumour-directed prodrug activation strategies. In the present work we report the design and synthesis of novel chimaeric sulphonamide derivatives of bombesin, able to be activated by the model human isoenzyme GSTA1-1 (hGSTA1-1). These derivatives bear a peptidyl-moiety (analogues of bombesin peptide: R-[Lue(13)]-bombesin, R-[Phe(13)]-bombesin and R-[Ser(3),Arg(10),Phe(13)]-bombesin, where R=C(6)H(5)SO(2)NH-) as molecular recognition element for targeting the drug selectively to tumour cells. The released S-alkyl-glutathione, after hGSTA1-1-mediated cleavage of the sulphonamide bond, provides an inhibitor of varied strength against GSTs from different sources. These prodrugs are envisaged as a plausible means to sensitize drug-resistant tumours that overexpress GSTs.

The applications of reactive dyes in enzyme and protein downstream processing.

Downstream processing of proteins is often a key factor in the overall process of satisfying product specifications and meeting current commercial demands. In this context, affinity chromatography and other techniques based on the affinity concept have revolutionized protein purification technology, although they have failed to demonstrate their broader applicability at the process scale. On the other hand, reactive dyes offer many advantages as pseudoaffinity media and in many occasions have successfully circumvented problems associated with conventional affinity ligands. The main features of reactive dyes include their broad spectrum of interaction with proteins, low cost, ready availability, high reactivity, ease of immobilization, and both biological and chemical stability. Consequently, dye-ligand media now find application in both analytical and process-scale purification of proteins by techniques such as low- and high-pressure performance affinity chromatography, affinity partitioning, and affinity precipitation.

Monosized adsorbents for high-performance affinity chromatography. Application to the purification of calf intestinal alkaline phosphatase and human urine urokinase.

Affinity adsorbents comprising monodisperse spherical synthetic macroporous beads offer the prospect of high-capacity, high-resolution separation of proteins at low operating pressures. Purpose-designed biomimetic dyes were covalently attached to Dynospheres XP-3507 beads and exploited for the purification of calf intestine alkaline phosphatase and human urine urokinase from crude extracts. This study demonstrates that the combination of specifically designed affinity ligands with monosized support materials is a powerful approach to the resolution of proteins by high-performance affinity chromatography.

L-Malate dehydrogenase from Pseudomonas stutzeri: purification and characterization.

L-Malate dehydrogenase (MDH) from Pseudomonas stutzeri was purified to homogeneity by a two-step procedure comprising anion-exchange chromatography and affinity chromatography on immobilized anthraquinone alpha-ketocarboxyl biomimetic dye. The enzyme has molecular mass of 66,500 Da and consists of two identical subunits of molecular mass of approximately 34,000 Da. Initial velocity, product inhibition, and binding studies were consistent with an ordered Bi-Bi mechanism for the enzyme action and the formation of a ternary complex. The enzyme is susceptible to activation and inhibition by its substrates. Thermodynamic analysis and kinetic inhibition studies were performed for determining basic equilibrium and kinetic constants. Malate dehydrogenase was covalently inactivated by a dichlorotriazine dye, Vilmafix Blue A-R (VBAR). The inactivation process follows first-order kinetics, and the results from kinetic analysis suggested the formation of a noncovalent enzyme-dye complex prior to the covalent reaction, with Kd 84.6 microM and a maximum rate constant 0.16 min(-1). The enzyme inactivation process was partially inhibited by substrates and inhibitors. Quantitatively inactivated MDH contained approximately 1 mole of dye per mole of enzyme subunit. The denatured enzyme contains 10 sulfhydryl groups per subunit, as shown after reaction with 5,5'-dithio-bis-(2-nitrobenzoic acid), of which 5 can be titrated also in the native enzyme, exhibiting time-dependent reactivity. One sulfhydryl group is located in the coenzyme binding site. This study shows that the physical and catalytic properties of P. stutzeri MDH strongly resemble those of the mitochondrial eukariotic enzyme. This finding strengthens the existing view that, in the evolution process, the mitochondrial MDH might have appeared before the cytoplasmic.

The interaction of Candida boidinii formate dehydrogenase with a new family of chimeric biomimetic dye-ligands.

Seven chimeric biomimetic dye-ligands (BM) are purpose-designed and synthesized by specific structural modification of the parent anthraquinone dichlorotriazine dye Vilmafix blue A-R (VBAR). Each BM dye is composed of two enzyme-recognition moieties. The terminal biomimetic moiety bears a variable carboxylated structure linked to the triazine ring, thus mimicking the substrate of formate dehydrogenase (FDH). The anthraquinone moiety remains the same as that of the parent dye and recognizes the nucleotide-binding area of the target enzyme. Dyes are purified by liquid column chromatography (typically 99%), analyzed by liquid-paper chromatography, thin-layer chromatography, and high-performance liquid chromatography, and their lambda max and epsilon values are determined. The ability of dyes to act as affinity ligands versus Candida boidinii FDH is evaluated by kinetic studies and determining KD values from both difference spectra and enzyme inactivation studies. The parent dichlorotriazine dye VBAR binds specifically and irreversibly to FDH (k3 0.19 min-1; KD 19.3 microM). The inactivation of the NAD(+)-dependent enzyme by VBAR is competitively inhibited by NAD+, NADH, and ADP. Quantitatively inhibited FDH contained approx 1 mol of dye per mole of active site. The inhibition is irreversible and activity cannot be recovered either on incubation with 10 mM each of NAD+, NADH, and ADP or by extensive dialysis or gel filtration chromatography. The monochlorotriazine BM dyes do not inactivate FDH but inhibit competitively the inactivation by VBAR. When compared to VBAR and Cibacron blue 3GA (CB3GA), all BM dye-ligands exhibited lower KD values. FDH generally preferred binding to BM ligands which bore an aromatic terminal biomimetic moiety substituted with a monocarboxyl group rather than an alpha-ketoacid. Dye binding to FDH is accompanied by a characteristic spectral change in the range 550-800 nm. This phenomenon is perturbed after titration by increasing amounts of NAD+. Electrostatic interactions appeared to play a dominant role in the dye.FDH complex. The BM dye-ligand bearing a m-aminobenzoate at its terminal biomimetic moiety (BM1) exhibited the highest affinity (KD 1.6 microM, 8.0-fold decrease over CB3GA). BM1 differentiated between the binding sites of FDH, displaying uncompetitive inhibition with respect to NAD+ (Ki 15.6 microM) and competitive with respect to formate (Ki 18.1 microM).

Oxaloacetate decarboxylase: on the mode of interaction with substrate-mimetic affinity ligands.

The mode of interaction of the ketocarboxyl-group-recognizing enzyme oxaloacetate decarboxylase (OXAD) from Pseudonomas sp., with purpose-designed (keto)-carboxyl-terminal biomimetic monochlorotriazinyl-dyes (BM) and parent dichlorotriazinyl-dye Vilmafix blue A-R (VBAR) was investigated. Kinetic inhibition studies and determinations of KD values of the respective dye-enzyme complex from both difference spectra and enzyme inactivation studies were employed. Substratemimetic (biomimetic) dye-ligands bear a terminal (keto)carboxyl-moiety linked to the reactive chlorotriazine ring, thus mimicking the organic acid substrate of OXAD. Dichlorotriazine-dye VBAR bound specifically and irreversibly to OXAD (k3 0.22 min-1). The inactivation of OXAD by VBAR was enhanced in the presence of 1 mM Mn+2 (KD 67.2 microM) but in the absence of metal cation was decreased (KD 117 microM). The metal cation behaves as a partial competitive activator. Either of binary complexes dye.OXAD and OXAD.Mn+2 could be formed first, prior to addition of the third constituent to form the ternary complex, although the former route may be favored. The pKa of the catalytically important nucleophile, involved in the specific modification of OXAD, was calculated to 7.4. Biomimetic monochlorotriazine dyes have failed to inactivate OXAD but inhibited competitively the inactivation by VBAR. When compared to commercial VBAR and Cibacron blue 3GA (CB3GA), all BM ligands show lower KD values, therefore, higher affinity for the enzyme. OXAD preferred binding to BM dyes which exhibited a large aliphatic ketocarboxyl-terminal biomimetic moiety. Dye binding to OXAD was accompanied by a characteristic spectral change in the range 550-800 nm. Electrostatic interactions appeared to play a dominant role in the dye.OXAD complex. The BM ligand bearing an aminoethyloxamate as its terminal biomimetic moiety (BM7) displayed the highest affinity (KD 0.5 or 7.0 microM; approx 10-fold decrease over CB3GA). The BM7 ligand behaved as competitive inhibitor (Ki 98 microM) of oxaloacetate decarboxylase against oxaloacetate as variable substrate.

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 micromol/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 micromol/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 microM), whereas the sequence H-TAR-OH displayed the lowest (K(D) 38 microM). 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 micromol/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.