Yannis D. Clonis

A portable fiber-optic pesticide biosensor based on immobilized cholinesterase and sol-gel entrapped bromcresol purple for in-field use

A fiber-optic biosensor for the detection and determination of the pesticides carbaryl and dichlorvos was developed. The sensing bioactive material was a three-layer sandwich. The enzyme cholinesterase was immobilized on the outer layer, consisting of hydrophilic modified polyvinylidenefluoride membrane. The membrane was in contact with an intermediate sol-gel layer that incorporated bromcresol purple, deposited on an inner glass disk. The sensor operated in a static mode at room temperature and the rate of the inhibited reaction served as an analytical signal. Calibration curves were obtained for carbaryl and dichlorvos, with useful concentration ranges 0.11-8.0 mg l(-1) for carbaryl and 5.0-30 microg l(-1) for dichlorvos. The respective detection limits were 108 microg l(-1) and 5.2 microg l(-1). The method reproducibility was in the order of +/-3-5%. The method was successfully applied to the detection and determination of these pesticides in real water samples, without sample preparation steps. Recovery experiments were made and the accuracy of the method was 94.9%. No enzyme regeneration steps were applied and the sensor lifetime was 3 weeks (30% activity reduction). The bioactive mini sandwich can easily be replaced by simply unscrewing the terminal holding ring of the probe and placing a new sandwich, before the sensor is ready for use.

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.

Design and application of bio-mimetic dyes in biotechnology.

The last decade or so has been the introduction of multi-coloured reactive dyes as substitutes for natural biological ligands in the purification of proteins by affinity chromatography. This paper reviews the evidence for the remarkable selectivity of the interaction of reactive dyes with proteins and describes our recent work with dye analogues. Terminal ring, bridging ring and anthraquinone ring analogues of Cibacron Blue F3G-A were synthesised de novo and shown to interact selectively with the NAD+-binding site of horse liver alcohol dehydrogenase but with affinities differing by several orders of magnitude. It is anticipated that these novel dye ligands will lead to affinity adsorbents with improved affinity, capacity and specificity.

Functional and structural roles of the glutathione-binding residues in maize (Zea mays) glutathione S-transferase I.

The isoenzyme glutathione S-transferase (GST) I from maize (Zea mays) was cloned and expressed in Escherichia coli, and its catalytic mechanism was investigated by site-directed mutagenesis and dynamic studies. The results showed that the enzyme promotes proton dissociation from the GSH thiol and creates a thiolate anion with high nucleophilic reactivity by lowering the pK(a) of the thiol from 8.7 to 6.2. Steady-state kinetics fit well to a rapid equilibrium, random sequential Bi Bi mechanism, with intrasubunit modulation between the GSH binding site (G-site) and the electrophile binding site (H-site). The rate-limiting step of the reaction is viscosity-dependent, and thermodynamic data suggest that product release is rate-limiting. Five residues of GST I (Ser(11), His(40), Lys(41), Gln(53) and Ser(67)), which are located in the G-site, were individually replaced with alanine and their structural and functional roles in the 1-chloro-2,4-dinitrobenzene (CDNB) conjugation reaction were investigated. On the basis of steady-state kinetics, difference spectroscopy and limited proteolysis studies it is concluded that these residues: (1) contribute to the affinity of the G-site for GSH, as they are involved in side-chain interaction with GSH; (2) influence GSH thiol ionization, and thus its reactivity; (3) participate in k(cat) regulation by affecting the rate-limiting step of the reaction; and (4) in the cases of His(40), Lys(41) and Gln(53) play an important role in the structural integrity of, and probably in the flexibility of, the highly mobile short 3(10)-helical segment of alpha-helix 2 (residues 35-46), as shown by limited proteolysis experiments. These structural perturbations are probably transmitted to the H-site through changes in Phe(35) conformation. This accounts for the modulation of K(CDNB)(m) by His(40), Lys(41) and Gln(53), and also for the intrasubunit communication between the G- and H-sites. Computer simulations using CONCOORD were applied to maize GST I monomer and dimer structures, each with bound lactoylglutathione, and the results were analysed by the essential dynamics technique. Differences in dynamics were found between the monomer and the dimer simulations showing the importance of using the whole structure in dynamic analysis. The results obtained confirm that the short 3(10)-helical segment of alpha-helix 2 (residues 35-46) undergoes the most significant structural rearrangements. These rearrangements are discussed in terms of enzyme catalytic mechanism.

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.

Molecular modeling for the design of a biomimetic chimeric ligand. Application to the purification of bovine heart L-lactate dehydrogenase

Molecular modeling was employed for the design of a biomimetic chimeric ligand for L-lactate dehydrogenase (LDH). This ligand is an anthraquinone monochlorotriazinyl dye comprising two moieties: (a) the ketocarboxyl biomimetic moiety, 2-(4-aminophenyl)-ethyloxamic acid, linked on the monochlorotriazine ring, mimicking the natural substrate of LDH, and (b) the anthraquinone chromophore moiety, linked also on the same monochlorotriazine ring via a diaminobenzenesulfonate group, acting as pseudomimetic of the cofactor NAD+. The positioning of the dye in the enzymes binding site is primarily achieved by the recognition and positioning of the pseudomimetic anthraquinone moiety. The positioning of the biomimetic ketocarboxylic moiety is based on a match between the polar and hydrophobic regions of the enzymes binding site with those of the biomimetic moiety of the ligand. The length of the biomimetic moiety is predetermined for the ketoacid to approach the enzyme catalytic site and form charge-charge interactions. The biomimetic chimeric ligand and the commercial nonbiomimetic ligand Cibacron(R) blue 3GA (CB3GA), were immobilized on crosslinked beaded agarose gel via their chlorotriazine ring. The two affinity adsorbents were evaluated for their purifying ability for LDH from six sources (bovine heart and pancreas, porcine muscle, chicken liver and muscle, and pea seeds). The biomimetic adsorbent exhibited approximately twofold higher purifying ability for LDH compared to the CB3GA adsorbent; therefore, the former was integrated in the purification procedure of LDH from bovine heart extract. The LDH afforded by this two-step purification procedure shows specific activity equal to 600 U/mg (25 degrees C) and a single band after SDS-PAGE analysis.

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.

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.

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.

Matrix evaluation for preparative high-performance affinity chromatography

Abstract Four microparticulate beaded support materials, namely, wide-pore silica, Eupergit C 3ON, TSK G5000PW and Dynospheres XP-3507 have been substituted wit