Non-Isotopic Receptor Assay for Benzodiazepine Drugs Using Biotin-Benzodiazepine Conjugate

Abstract

A new receptor assay method for benzodiazepine was developed using biotin-1012S conjugate as a non-isotopic ligand. The concentration of free ligand in the benzodiazepine receptor suspension was determined by an enzymatic solid-phase avidin-biotin binding assay. The competition reaction between the conjugate and diazepam gave a well-defined dose/response curve for diazepam. The receptor assay could also be applied to the determination of an inverse agonist, n-butyl-P-carboline-3 carboxylate.     

New fluorometric enzyme immunoassay for 17beta-estradiol by homogeneous reaction using biotinylated estradiol

A new fluorometric enzyme immunoassay for 17β-estradiol (E2) using biotinylated estradiol (BE) as a probe ligand, is described. In this method, E2 is detected indirectly by a solid-phase avidin-biotin binding assay, in which the biotin is immobilized on a microtiter plate (biotin-plate). After the competitive reaction between E2 and BE for the anti-E2 antibody in solution, the free E2 and BE are separated from the bound forms by means of ultrafiltration. The concentration of BE in the solution is determined from the reaction between the biotin immobilized on the plate and the free BE for the limited biotin binding sites of avidin conjugated with horseradish peroxidase (avidin-HRP), which is added to the solution. The enzymatic reaction of HRP was measured by a fluorometric analysis with the QuantaBlu™ Fluorogenic Peroxidase Substrate (QFPS) in order to detect of the avidin-biotin binding with a high degree of sensitivity. The detection limit and linear range for the determination of E2 were 0.12 nM and from 0.12 to 25 nM, respectively. The relative standard deviations (R.S.D.) for the E2 assay were between 2.2 and 9.1% (n = 3). The cross-reactivity for several other estrogens was also evaluated.     

Biotin-β-Cyclodextrin: A New Host-Guest System for the Immobilization of Biomolecules

The formation of stable supramolecular interactions between biotin and β-cyclodextrin was studied. An association constant of 3 × 10(2) M(-1) could be determined by NMR measurements by mapping the high field shift differences of the β-cyclodextrin protons (H-3) at different biotin concentrations. With the aim to demonstrate a new alternative for the immobilization of bioreceptors, biotin and β-cyclodextrin tagged biomolecules were immobilized on transducer surfaces, which were functionalized with the correspondent host-guest partner. The reliability of this new affinity system was investigated using two enzymes (glucose oxidase and polyphenol oxidase) as biomolecule models. This supramolecular inclusion complex shows clear advantages to the classic biotin-(strept)avidin-biotin system due to a detrimental effect of the additional avidin layer reducing the transduction efficiency. A 7-fold increase in the maximum current density and an almost 20 times higher sensitivity were exhibited by the immobilized biological layer obtained using this new host-guest system.     

Immobilization of binding proteins on nonporous supports

Four different nonporous particulate materials, nylon, polystyrene, soda-lime silicate glass, and fused silica glass, have been evaluated for their appropriateness as immobilization supports for immunoglobulins. A method of protein quantitation that is usually applied to solutions, the bicinchoninic acid (BCA) assay, was used successfully to directly measure ng amounts of protein immobilized on the supports. Two proteins, a monoclonal antibody to theophylline and the biotin binding protein avidin, were studied. Radioactive theophylline and radioactive biotin were used to measure the activity of the immobilized protein. Ligand binding capacity per mm2 of support was measured as a function of amount of protein immobilized. By measuring both the amount of protein immobilized and its ligand binding capacity, we have determined that antitheophylline antibody adsorbed on polystyrene balls loses almost 90% of its binding activity after 65 h, although little protein is lost from the balls over this time. Avidin retains nearly full activity for biotin on polystyrene. The binding activity of biotinyl-antibody conjugate immobilized on avidin-adsorbed polystyrene is stable, even when stored for over 22 wk. Antibody covalently immobilized on soda-lime silicate glass beads retains its binding activity over long-term storage, although only 0.1 mol of 3H-theophylline bind per mol of immobilized antibody. Using fused silica glass particles as the solid support, the same antibody binds approx 0.6 mol of ligand per mol of immobilized antibody protein. The structural "softness" of the immunoglobulin requires that interaction with the surface be prevented in order to maintain activity.     

Monolithic columns with immobilized monomeric avidin: preparation and application for affinity chromatography

A poly(glycidyl methacrylate-co-acrylamide-co-ethylene dimethacrylate) monolith and a poly(glycidyl methacrylate-co-ethylene dimethacrylate) monolith were prepared in fused silica capillaries (100 μm ID) and modified with monomeric avidin using the glutaraldehyde technique. The biotin binding capacity of monolithic affinity columns with immobilized monomeric avidin (MACMAs) was determined by fluorescence spectroscopy using biotin (5-fluorescein) conjugate, as well as biotin- and fluorescein-labeled bovine serum albumin (BSA). The affinity columns were able to bind 16.4 and 3.7 μmol biotin/mL, respectively. Columns prepared using the poly(glycidyl methacrylate-co-ethylene dimethacrylate) monolith retained 7.1 mg BSA/mL, almost six times more than commercially available monomeric avidin beads. Protocols based on MALDI-TOF mass spectrometry monitoring were optimized for the enrichment of biotinylated proteins and peptides. A comparison of enrichment efficiencies between MACMAs and commercially available monomeric avidin beads yielded superior results for our novel monolithic affinity columns. However, the affinity medium presented in this work suffers from a significant degree of nonspecific binding, which might hamper the analysis of more complex mixtures. Further modifications of the monolith’s surface are envisaged for the future development of monoliths with improved enrichment characteristics.     

Time-Resolved Fluorescence Receptor Assay for Benzodiazepines

Abstract

A novel non-isotopic receptor binding technique for the detection of benzodiazepines is described. A benzodiazepine labeled with europium chelate was prepared and employed as a labeled ligand, and time-resolved measurements of the long lifetime fluorescence of europium chelate allowed avoidance of interference due to proteins in the receptor preparation. Experimental results demonstrate a sigmoid inhibition curve, with binding of the labeled ligand inhibited by comparable concentrations of the unlabeled drug. The proposed assay may provide a simple procedure for the measurement of benzodiazepines in biological systems and a useful tool in the screening of natural substances for new classes of benzodiazepine-like compounds.     

A new chemically amplified electrochemical system for the detection of biological affinity reactions: direct and competitive biotin assay

Quantitation of biological affinity reactions by a newly developed chemically amplified electrochemical detection method was demonstrated with the biotin-avidin binding pair. In the method, ruthenium tris(2,2'-bipyridine)(Ru-bipy) was used as an electrochemical signal-generating tag. Its oxidation current on an indium tin oxide (ITO) electrode was amplified with a sacrificial electron donor, oxalate. Because oxalate itself produced negligible current on the electrode, the signal-to-background ratio was greatly enhanced in comparison with other chemical amplification systems. Although the Ru-bipy/oxalate redox couple has been employed previously in electrochemiluminescent and photoelectrochemical detection, its use in a catalytic amperometric detection of biological binding assays has not been reported. To implement the method in the detection of biotin-avidin recognition, avidin was immobilized on an ITO electrode, and was reacted with biotin in solution. Immobilization of avidin by passive adsorption was found to be relatively stable under the condition of the affinity reaction. In the direct assay, biotin labelled with Ru-bipy was recognized by avidin and accumulated on the electrode surface, which was then detected electrochemically in the presence of oxalate. A linear relationship between electrochemical current and biotin concentration was obtained in the range of 1-300 ng mL(-1). In the competitive assay, a mixed solution of unlabelled biotin (the analyte) of various concentrations and 100 ng mL(-1) labelled biotin was reacted with avidin on the surface. As the concentration of the unlabelled biotin increased, less labelled biotin bound to avidin, leading to a reduction in the electro-catalytical response of Ru-bipy. A detection limit of 1 ng mL(-1) biotin was obtained in the competitive assay, which is close to the sensitivity of some enzyme-labelled amperometric assays.     

Design of a reversible biotin analog and applications in protein labeling, detection, and isolation

To expand the applicability of the biotin-(strept)avidin system, a biotin analog with reversible binding under non-denaturing conditions has been designed, and its applications in protein labeling, detection, and isolation have been evaluated.     

Voltammetric detection of avidin and biotin by biotin labeled with cysteine

An avidin-biotin assay was developed from a voltammetric procedure using biotin labeled with cysteine. Mercury(II) as a marker was used to detect avidin and biotin, because the oxidation wave of mercury decreases when the cysteine part of labeled biotin(LB) complexes with mercury(II).The formation of the mercury(II)-cysteine complex is suppressed when the LB binds to the biotin site of avidin. Accordingly, the concentration of avidin can be estimated from the increasing mercury peak current. Detection of biotin is also carried out by a competitive reaction of biotin and the LB to the binding site on avidin, where the addition of biotin decreases the peak current of mercury. Limits of detection for avidin and biotin were in the 10^–9 mol/L range. The length of the spacer between the cysteine and biotin was investigated. It was observed that the strength of binding increased with increasing length of spacer. Size considerations rules out steric influences, so it is suggested that the binding constant depends on hydrophobic interactions in the binding site.     

Why 1-NH and 3-NH protons of D-biotin exhibit different activities in aqueous solution

Quantum chemical calculations, combined with the molecular dynamics results, have been employed to explain why the 1- and 3-NH protons of biotin exhibit different activities in aqueous solution. They suggested that the relative proportion of the three different conformations of biotin in the solution was responsible for different activities of the two amide protons of biotin. The relative activity of the two amide protons calculated by theoretical work here is 6, which is in good agreement with the experimental data, which is 5, reinforcing the viewpoint that biotin jumps between the three conformations in aqueous solution and the relative proportion of extended, semifolded, and folded biotin in water is 24:3.6:1. The method for computing the relative activity of the two amide protons of biotin in water here may be used to predict the relative activity in other solutions. The behavior of biotin in aqueous solution may be helpful for better understanding the unusual strong biotin-(strept)avidin binding.     

Biotin ligands labeled with daunomycin as an electrochemical probe for avidin and biotin interaction

Electroactive biotin ligands were prepared by the reaction of daunomycin with biotinylating reagents with a different spacer. These biotin ligands exhibited similar electrochemical properties to those of daunomycin, but the adsorptivity of the ligands on the electrode increased with increasing length of the spacer. The electrode response of these ligands decreased when specifically bound with avidin. This made it possible to detect electroinactive avidin indirectly. Biotin was detected by observing the competitive reaction between biotin and the ligands for the limited binding sites of avidin. The binding strength of the labeled biotins with avidin was compared with that of unlabeled biotin by using an enzyme assay.     

Electrochemical Evaluation of the Interaction between Avidin and Biotin at Biotinylated Polypyrrole Electrode Using a Redox Marker

The interaction between avidin and biotin was evaluated electrochemically by monitoring the change in the electrode response of redox markers. Biotin was immobilized on the electrode surface by means of the electrochemical polymerization of biotinylated pyrrole and pyrrole. When avidin was introduced onto the biotinylated polypyrrole electrode surface, the large change in the electrode response of the redox marker was detected. The fact that the change in the electrode response of a marker ion could be attributed to the electrostatic interaction between avidin on the electrode surface and the redox marker ion present in a solution was verified by replacing avidin with NutrAvidin. At a pH lower than the isoelectric point of avidin, the electrode response of ferrocyanide as an anionic marker ion increased linearly within the range of 5.0×10^?9 ?3.0×10^?8 M avidin. The relative standard deviation at 1.5×10^?8 M avidin was about 5.4% (n=5). The detection of biotin was also performed using a competitive reaction between biotin in solution and biotin that had been immobilized on the electrode surface in the form of the biotinylated polypyrrole.     

Half‐Sandwich Ruthenium(II) Biotin Conjugates as Biological Vectors to Cancer Cells

Ruthenium(II)–arene complexes with biotin‐containing ligands were prepared so that a novel drug delivery system based on tumor‐specific vitamin‐receptor mediated endocytosis could be developed. The complexes were characterized by spectroscopic methods and their in vitro anticancer activity in cancer cell lines with various levels of major biotin receptor (COLO205, HCT116 and SW620 cells) was tested in comparison with the ligands. In all cases, coordination of ruthenium resulted in significantly enhanced cytotoxicity. The affinity of Ru^II–biotin complexes to avidin was investigated and was lower than that of unmodified biotin. Hill coefficients in the range 2.012–2.851 suggest strong positive cooperation between the complexes and avidin. To estimate the likelihood of binding to the biotin receptor/transporter, docking studies with avidin and streptavidin were conducted. These explain, to some extent, the in vitro anticancer activity results and support the conclusion that these novel half‐sandwich ruthenium(II)–biotin conjugates may act as biological vectors to cancer cells, although no clear relationship between the cellular Ru content, the cytotoxicity, and the presence of the biotin moiety was observed.     

Specific binding of a biotinylated,metallocarbonyl‐labelled dendrimer to immobilized avidin detected by diffuse‐reflectance infrared Fourier transform spectroscopy

Molecular recognition between avidin covalently immobilized at the surface of acrylic resin beads and a transition metallocarbonyl tracer of the biotin ligand was detected using diffuse reflectance infrared Fourier transform spectroscopy. Copyright © 2004 John Wiley & Sons, Ltd.     

A spectrophotometric assay for biotinbinding sites of immobilized avidin

A rapid and sensitive spectrophotometric assay was developed for the measurement of biotin-binding sites of immobilized avidin. The method is based on the reaction of avidin with excess biotin followed by assay of the unbound biotin using the HABA (2-[4′-hydroxyazobenzene] benzoic acid) method. Three solids possessing variable amounts of monomeric avidin were examined; viz., succinamidopropyl-controlled-pore glass (CPG-500), crosslinked 6% beaded agarose (Sepharose-CL-6B**), and crosslinked bis-acrylamide/azlactone (3M Emphaze Biosupport Medium AB₁. Results indicate that the total biotin-binding sites of monomeric avidin immobilized on CPG-500, Sepharose-CL-6B, and 3M Emphaze are 0.229, 0.093, and 0.218 μmol biotin per mL beads, respectively. Assays for exchangeable biotinbinding sites gave values greater than 90% of the total sites. The spectrophotometric HABA method described is an alternative to assays based on tracers, thus the handling of radioactive material is avoided. The use of trade names in this publication does not imply endorsement by the North Carolina Agricultural Research Service of products named, nor criticism of similar ones not mentioned.     

Homogeneous enzyme-linked competitive binding assay for biotin based on the avidin-biotin interaction

A homogeneous enzyme-linked competitive-binding assay for biotin with glucose-6-phosphate dehydrogenase (G6PDH), is described. This assay is based on the interaction between a G6PDH/biotin conjugate with avidin, a natural binder for biotin. In the absence of biotin in the assay mixture, this interaction results in 100% inhibition of the enzyme conjugate. In the presence of biotin, the enzymatic activity of the conjugate is regained in an amount related to the concentration of the vitamin in the sample. Extremely steep, gate-like dose/response curves, attributable to the relative binding affinities of avidin for biotin and the conjugate, are observed. The detection limits of the system vary with the amounts of avidin and enzyme/biotin conjugate used. The method is rapid and sensitive and is evaluated for the direct determination of biotin in vitamin tablets.     

Quantitative analysis of 17beta-estradiol in river water by fluorometric enzyme immunoassay using biotinylated estradiol.

A sensitive and simple immunoassay to determine 17beta-estradiol (E2) in fresh water was developed. The method is based on a solid-phase avidin-biotin binding assay and solid phase extraction. The binding event of E2 to the antibody is detected indirectly by the competitive reaction between E2 and biotinylated estradiol (BE) as a tracer for the limited binding sites of antibodies immobilized onto the wall of a microtiter plate. Namely, E2 concentrations are determined from the strong interaction between BE and avidin conjugated with horseradish peroxidase (avidin-HRP). In order to achieve a sensitive measurement for the binding of BE to the antibody immobilized on the microtiter plate substrate, QuantaBlu fluorogenic peroxidase substrate (QFPS) was employed. The detection limit and the linear range of E2 determination were 27 pM and 27 - 7480 pM, respectively. The relative standard deviations (RSD) for the E2 assay were between 0.3 and 12.0% (n = 3). The cross-reactivities of several other estrogens in this assay system were also investigated. No serious influences from any cross-reaction caused by other estrogens tested in this experiment were observed. The determination of E2 in water samples from eight rivers and a marsh in Hokkaido was performed by the immunoassay combined with solid phase extraction. It was found that the concentration of E2 was in the range between 0.06 and 67 pM.     

Theoretical and experimental studies of biotin analogues that bind almost as tightly to streptavidin as biotin

We have used a newly developed qualitative computational approach, PROFEC (Pictorial Representation of Free Energy Changes), to visualize the areas of the ligand biotin where modifications of its structure might lead to tighter binding to the protein streptavidin. The PROFEC analysis, which includes protein flexibility and ligand solvation/desolvation, led to the suggestion that the pro-9R hydrogen atom of biotin, which is in alpha-position to the CO(2)(-) group, might be changed to a larger group and lead to better binding with streptavidin and avidin. Free energy calculations supported this suggestion and predicted that the methyl analogue should bind approximately 3 kcal/mol more tightly to streptavidin, with this difference coming exclusively from the relative desolvation free energy of the ligand. The PROFEC analysis further suggested little or no improvement for changing the pro-9S hydrogen atom to a methyl group, and great reduction in changing the ureido N-H groups to N-CH(3). Stimulated by these results, we synthesized 9R-methylbiotin and 9S-methylbiotin, and their binding free energies and enthalpies were measured for interaction with streptavidin and avidin, respectively. In contrast to the calculated results, experiments found both 9-methylbiotin isomers to bind more weakly to streptavidin than biotin. The calculated preference for the binding of the 9R- over the 9S-stereoisomer was observed. In addition, 9-methylbiotin is considerably less soluble in water than biotin, as predicted by the calculation, and the 9R isomer is, to our knowledge, thus far the tightest binding analogue of biotin to streptavidin. Subsequently, X-ray structures of the complexes between streptavidin and both 9R- and 9S-methylbiotin were determined, and the structures were consistent with those used in the free energy calculations. Thus, the reason for the discrepancy between the calculated and experimental binding free energy does not lie in unusual binding modes for the 9-methylbiotins.     

A reagentless electrochemical biosensor based on a protein scaffold

Apo-myoglobin, labeled with the environmentally sensitive redox probe RuII(NH3)4(1,10-phenanthroline-5-maleimide)2+, was immobilized onto gold electrodes modified with 11-mercaptoundecanoic acid and subsequently labeled with biotin; avidin binding to the immobilized biotin was specifically and quantitatively detected by a change in cyclic voltammetry of the co-immobilized probe.     

Enhanced electrochemical activity of redox-labels in multi-layered protein films on indium tin oxide nanoparticle-based electrode

Facile electrical communication between redox-active labeling molecules and electrode is essential in the electrochemical detection of bio-affinity reactions. In this report, nanometer-sized indium tin oxide (ITO) particles were employed in the fabrication of porous thick film electrodes to enhance the otherwise impeded electrochemical activity of redox labels in multi-layered protein films, and to enable quantitative detection of avidin/biotin binding interaction. To carry out the affinity reaction, avidin immobilized on an ITO electrode was reacted with mouse IgG labeled with both biotin and ruthenium Tris-(2,2′-bipyridine) (Ru-bipy). The binding reaction between avidin and biotin was detected by the catalytic voltammetry of Ru-bipy in an oxalate-containing electrolyte. On sputtered ITO thin film electrode, although a single layer of Ru-bipy labeled avidin exhibited substantial anodic current, attaching the label to the outer IgG layer of the avidin/biotin-IgG binding pair resulted in almost complete loss of the signal. However, electrochemical current was recovered on ITO film electrodes prepared from nanometer-sized particles. The surface of the nanoparticle structured electrode was found by scanning electron microscopy to be very porous, and had twice as much surface binding capacity for avidin as the sputtered electrode. The results were rationalized by the assumption of different packing density of avidin inner layer on the two surfaces, and consequently different electron transfer distance between the electrode and Ru-bipy on the IgG outer layer. A linear relationship between electrochemical current and IgG concentration was obtained in the range of 40-4000 nmol L⁻¹ on the nanoparticle-based electrode. The approach can be employed in the electrochemical detection of immunoassays using non-enzymatic redox labels.