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.     

Voltammetric investigation of avidin-biotin complex formation using an electroactive bisbiotinyl compound

Formation of avidin-biotin complex was investigated using bisbiotinyl thionine (BBT) by means of voltammetric techniques. Thionine is an electroactive compound and has two amino groups that are necessary for the reaction with a biotinylation reagent. The biotinylation of thionine produces a new reagent with two biotin moieties at each end of thionine. Three BBTs of different lengths of the spacer that connects the biotin moiety to the thionine moiety were prepared. The avidin-biotin binding assay was achieved by measuring the electrode response of the thionine moiety in BBT. The binding affinity and the conformation of complex, which depended on the length of spacer, are discussed. BBT in which the spacer is shortest (BBT-S, distance between carbonyl group of the two biotin moieties: 11 Å) binds with only one avidin molecule. BBT with medium length of spacer (BBT-M, 28.8 Å) forms the complex with two avidin molecules. BBT with the longest spacer (BBT-L, 46.6 Å) allows binding with two avidin molecules as well as intramolecular binding within one avidin molecule. The affinity constants of BBT-S, BBT-M and BBT-L for avidin were estimated to be 7.0 × 10¹² M⁻¹, 3.2 × 10¹² M⁻¹ and 4.0 × 10¹² M⁻¹, respectively.     

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.     

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.     

Electrochemical detection of lectin using a galactosamine labeled with daunomycin

To detect a lectin from soybean, an electrochemical procedure was developed by the use of a labeling of galactosamine. Because the lectin has binding sites to galactosamine, galactosamine labeled with daunomycin having electroactivity was prepared. When labeled galactosamine (LG) combines with lectin, the part of daunomycin is taken in the binding sites of the lectin and becomes electroinactive. Therefore, the concentration of the lectin can be estimated by measuring the peak current of the LG. On the other hand, a competitive reaction to the lectin of galactosamine and the LG makes a detection of galactosamine possible. This method has merit that does not require a separation procedure of the free LG from the bound one. An effect of length of spacer between daunomycin and galactosamine was also investigated. It was found that adsorption of reagent on the electrode increased due to introduction of the spacer. Furthermore, the electrode response of the LG was influenced by the type of the spacer.     

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.     

Evaluation of Binding Between Electroactive Biotin Derivative and Streptavidin Immobilized on Chitin Film

Evaluation of the streptavidin‐biotin binding at the surface of chitin film was carried out with voltammetry. Immobilization of streptavidin was attempted to the protonated chitin film, based on an electrostatic interaction that hardly causes any change in the protein structure. The streptavidin‐biotin binding was estimated from changes in the electrode response of biotin labeled with an electroactive compound. Although the response of daunomycin as an electroactive compound did not change at an electrode covered with streptavidin/chitin film, the response of the labeled biotin decreased. This observation shows that streptavidin is immobilized on the chitin film and the biotin binds with immobilized streptavidin. Consequently, it was clear that the chitin film is useful as a reaction field for protein‐ligand binding. Generally, a binding event between protein and its ligand in the living body occurs on the cell surface. The electrochemical evaluation of protein‐ligand binding on a natural polysaccharide like chitin membrane surface is important.     

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.     

Bioconjugation of Ln3+-doped LaF3 nanoparticles to avidin

The binding of Eu3+-doped LaF3 nanoparticles with biotin moieties at the surface of the stabilizing ligand layer to avidin, immobilized on cross-linked aragose beads, is described. The biotin moieties were attached to the nanoparticles by reaction of an activated ester with the amino groups on the surface of the nanoparticles resulting from the 2-aminoethyl phosphate ligands that were coordinated to the surface through the phosphate end. This strategy of employing the reactions of amines with activated esters provides a general platform to modify the surface of the 2-aminophosphate stabilized Ln3+-doped LaF3 nanoparticles with biologically relevant groups. Significant suppression of nonspecific binding to the avidin modified aragose beads has been realized by the incorporation of poly(ethylene glycol) units via the same reaction of a primary amine with an activated ester. The particle size distribution of the functionalized nanoparticles was within 10-50 nm, with a quantum yield of 19% in H2O for the LaF3 nanoparticles codoped with Ce3+ and Tb3+. A discreet, 4 unit poly(ethylene glycol) spaced heterobifunctional cross-linker, functionalized with biotin and N-hydroxysuccinimide at opposite termini, was covalently linked to the 2-aminoethyl phosphate ligand via the N-hydroxysuccinimide activated ester, making an amide bond, imparting biological activity to the particle. Modification of the remaining unreacted amino groups of the stabilizing ligands was done with Me(OCH2CH2)3CH2CH2(C=O)-NHS (NHS = N-hydroxysuccinimide).     

Electrochemical evaluation of avidin-biotin interaction using N-iodoacetyl-N-biotinylhexylenediamine

The avidin-biotin assay was investigated by an electrochemical procedure based on the chemical reaction between cysteine containing a thiol group and N-iodoacetyl-N-biotinylhexylenediamine (IB). In the presence of avidin and biotin this reaction, whereby the thiol group combines with IB, is controlled because IB has a biotin part; that is, avidin and biotin are detected indirectly by measurement of iodide ion or cysteine. To achieve a high sensitivity of detection, Hg(II) was introduced as a marker that interacts with cysteine and the oxidation peak from Hg(0) to Hg(II) was measured. The sensitivity of detection of avidin was at the level of 10⁻⁹ M. The relative standard deviation at 1 × 10⁻⁸ M avidin was 4.8% (n = 5). On the other hand, a response curve to detect biotin was obtained by the competitive reaction between IB and biotin for the limited binding sites of avidin. The change in peak current enables the detection of biotin at the level of 10⁻⁹ M. This method has the advantage that it is not necessary to separate free IB from bound IB.     

Studies on biotin–avidin indirect conjugated technology for a piezoelectric DNA sensor

Because of their high sensitivity, piezoelectric sensor techniques are extremely useful for environmental or clinical analysis. We developed a piezoelectric crystal DNA biosensor for the detection of the hybridization reaction based on the self-assembled monolayer technology and biotin–avidin system. 3,3′-Dithiopropionic acid was applied to form a self-assembled monolayer (SAM) on the gold surface of the quartz crystal. Avidin was coated on the gold electrode conjugated with 1-ethyl-3-[3-(dimethylamino)propyl]-carbodiimide (EDC) and N-hydroxysuccinimide (NHS), and then biotinylated nucleotide acids were immobilized on the gold electrode surface through the specific interaction of biotin and avidin. Our results indicated that, using this immobilization method, the piezoelectric DNA sensor shows a higher sensitivity and specificity in detecting the hybridization reaction. The sensor can be used repeatedly by electrode regeneration.     

Fabrication of Oligomeric Avidin Scaffolds for Valency‐Controlled Surface Display of Functional Ligands

Multivalent surface display of biomolecules is crucial to study and utilize multivalent biological interactions. However, precise valency control of surface‐displayed ligands remains extremely difficult. Now a series of new oligomeric avidin proteins were fabricated that allow facile control of surface multivalency of biotinylated ligands. Naturally dimeric rhizavidin (RA) was engineered to form a mixture of oligomeric avidin assemblies, and discrete RA oligomers from the dimer to octamer of RA, were homogeneously prepared. These oligomeric avidins are in polygonal forms with expected numbers of stable biotin binding sites. Upon immobilization on low‐density biotin‐coated gold surfaces, RA dimer, trimer, and tetramer scaffolds provided accurate mean residual valencies of 2, 3, and 4, respectively, for biotinylated proteins. Valency‐controlled display of antibody binding protein G on these RA surfaces showed clear valency‐dependent enhancement of antibody capturing stability.     

Development of an egg-white bioassay for monitoring biotin levels in urine and serum.

This article reports on the development of a simple and cost-effective bioassay for the detection of biotin in urine and serum, based on the very selective binding of avidin and biotin. Avidin was allowed to react without isolating it from egg white. Egg white was treated with the dye HABA, which binds to avidin. Upon subsequent treatment with biotin, HABA is released due to the high affinity of biotin to avidin. The amount of HABA released is proportional to the amount of biotin used.     

Molecular recognition of avidin on biotin-functionalized gold surfaces detected by FT-IRRAS and use of metal carbonyl probes

Fourier transform infrared reflection-absorption spectroscopy (FT-IRRAS) was successively used to monitor the covalent immobilization of biotin molecules onto a planar gold substrate covered with a self-assembled monolayer of cystamine and to transduce the molecular recognition of avidin and biotin. This detection was greatly facilitated and made selective by the labeling of avidin and of biotin with various transition metal carbonyl probes. The binding of avidin to the surface was optimized by blocking the nonspecific binding sites by adsorption of an unrelated protein, bovine serum albumin. This work exemplifies the feasibility of detecting biomolecular associations involving molecules of any size at a liquid/solid interface by using a simple and accessible surface analysis technique.     

Multiplexed assay for proteins based on sequestration electrochemistry using the protein binding electroactive magnetic microbeads

The paramagnetic microbead-based electrochemical binding assay was demonstrated for detecting two kinds of protein simultaneously. The principle of this assay is based on the sequestration electrochemistry. The protein binding electroactive magnetic microbeads which are conjugated with an electroactive compound and a ligand to bind specifically with a target protein were prepared. The avidin-biotin and soybean agglutinin (SBA)-galactosamine were chosen as model protein-ligand systems. The avidin binding electroactive magnetic microbead (ABEMMb) and SBA binding electroactive magnetic microbead (SBEMMb) are constructed by biotin/thionine and galactosamine/ferrocene modified on paramagnetic microbeads. The voltammetric response for these functionalized microbeads was measured by the Nd-Fe-B magnet-incorporating carbon paste rotating disk electrode. The measurements were performed in a microliter droplet using a rotating disk electrode system. Avidin and SBA were simultaneously detected by the decrease in the current responses from the reduction of ABEMMb and SBEMMb that was caused by the binding with target proteins. The limits of detection for avidin and SBA were 4 × 10(-10) and 2 × 10(-10) M, respectively.     

A Rhizavidin Monomer with Nearly Multimeric Avidin‐Like Binding Stability Against Biotin Conjugates

Developing a monomeric form of an avidin‐like protein with highly stable biotin binding properties has been a major challenge in biotin‐avidin linking technology. Here we report a monomeric avidin‐like protein—enhanced monoavidin—with off‐rates almost comparable to those of multimeric avidin proteins against various biotin conjugates. Enhanced monoavidin (eMA) was developed from naturally dimeric rhizavidin by optimally maintaining protein rigidity during monomerization and additionally shielding the bound biotin by diverse engineering of the surface residues. eMA allowed the monovalent and nonperturbing labeling of head‐group‐biotinylated lipids in bilayer membranes. In addition, we fabricated an unprecedented 24‐meric avidin probe by fusing eMA to a multimeric cage protein. The 24‐meric avidin and eMA were utilized to demonstrate how artificial clustering of cell‐surface proteins greatly enhances the internalization rates of assembled proteins on live cells.     

Dual Signal Amplification Electrochemical Biosensor for Lead Cation

Herein, a sensitive electrochemical Pb²⁺ sensor was developed which based on DNA‐functionalized Au nanoparticles(AuNPs) and nanocomposite modified electrode. The DNA‐functionalized AuNPs includes two types of DNA, namely a Pb²⁺‐mediated DNAzyme comprising a biotin labeled‐enzyme DNA and a substrate strand DNA with a typical stem‐loop structure, and a ferrocene‐labeled linear signal DNA. Without Pb²⁺, the hairpin loop impeded biotin binding to avidin on the electrode. However,when the goal Pb²⁺ exists, the substratum strand was divided into two fragments that lead to the enzyme strand was substratumed on the electrode and biotin was admited by avidin, bringing about DNA‐functionalized AuNP(AuNPs) deposition on the electrode surface.The differential pulse voltammetry (DPV) was used to measure electrochemical response signals connect to signal DNA.For the amplification characters of the DNA‐functionalized AuNPs and nanocomposite, the electrochemical detection signal of Pb²⁺ was greatly improved and revealed high specificity. Under optimum conditions, the resultant biosensor bringed out a high sensitivity and selectivity for the determination of Pb²⁺. The proposed method was able to detect as low as picomolar Pb²⁺ concentrations.     

A novel,simple and sensitive ligand affinity capture method for detecting molecular interactions by MALDI mass spectrometry

A simple and sensitive ligand affinity capture method (LAC) was developed to detect biotinylated biomolecules bound to a biotin–avidin base by matrix‐assisted laser desorption ionization time‐of‐flight mass spectrometry (MALDI ToF MS). Glass slides covered with a metal film for MALDI MS applications were treated with amino‐silane and derivatized with biotin followed by binding of avidin. Washing buffers with high ionic strength increased the specificity of the subsequent binding of biotinylated biomolecules to the avidin layer. A combined thin layer‐dried droplet method using α‐cyano‐4‐hydroxycinnamic acid (CHCA) in acetone or ethyl acetate resulted in the most intense ions of biotinylated polymyxin B, whereas the matrix conditions did not influence the detection of angiotensin II. Addition of biotinylated biomolecules in the low femtomole to low picomole range resulted in sufficient ion intensity for detection by the LAC method. The LAC concept was extended by binding of biotinylated lipopolysaccharide to the biotin–avidin base followed by preferential capture and specific detection of the binding antagonist polymyxin B. Copyright © 2008 John Wiley & Sons, Ltd.     

基于生物素-亲和素相互作用的胶体晶体阵列的构筑与特性

将胶体晶体阵列(crystalline colloidal arrays,CCA)的Bragg衍射特性与水凝胶的刺激响应性功能结合起来,可制成一种有效的对特定分子具有识别和响应能力的传感材料.采用无皂乳液聚合制备的单分散聚(苯乙烯-4-苯乙烯磺酸钠)纳米颗粒,通过表面电荷的静电斥力可自组装形成CCA,经光聚合固定在水凝胶网络内形成聚合胶体晶阵(polymerized CCA).在水凝胶网络中用共价结合引入生物素分子,通过强的亲和相互作用可与蛋白质亲和素生成生物素-亲和素复合物,在水凝胶网络中形成交联点,引起水凝胶体积相变,进而导致CCA晶面间距发生改变,从而引发Bragg衍射波长发生相应的移动.     

Voltammetric homogeneous binding assay of biotin without a separation step using iminobiotin labeled with an electroactive compound.

Avidin, which is one type of glycoprotein, has a strong affinity with biotin (Ka = 10(15) M(-1)). Iminobiotin also forms a complex with avidin (Ka = 10(8) M(-1) at pH 9.5). The avidin-iminobiotin complex changes to the avidin-biotin complex in the presence of biotin because of the difference of the binding constant to avidin. In this study, the interaction between avidin and iminobiotin labeled with an electroactive compound was investigated by voltammetry. After avidin and the labeled iminobiotin (LI) were incubated in 0.1 M phosphate buffer (pH 7.0), the peak currents of LI were measured in various concentrations of biotin. The peak currents increased with increasing the concentration of biotin. Thus, this observation indicates the formation of avidin-biotin complex. On the other hand, the formation of avidin-iminobiotin complex depended on the pH of the solution. LI combines with the avidin at pH 5.6-8.9 and dissociates at pH 4.6.