A surface plasmon resonance immunosensor based on the streptavidin-biotin complex.

It is shown that a streptavidin monolayer immobilized onto an evaporated gold film with biotin forms the basis of a highly specific sensing element. As an example, we show that by immobilizing the biotinylated antibody sex hormone binding globulin (alpha-SHBG) to the bound streptavidin monolayer a specific sensor for the antigen SHBG is readily fabricated. The interaction between immobilized antibody and corresponding antigen is monitored by surface plasmon resonance spectroscopy and is shown to follow a classic Langmuir isotherm. Detection of SHBG at nanomolar concentrations is demonstrated.     

生物素化ATP硫酸化酶的表达、固定化与应用

现代大规模焦测序技术的产生是DNA测序技术的一次革命,其关键技术之一是得到高活性的、固定于磁性微球表面的ATP硫酸化酶．生物素化的ATP硫酸化酶可以通过生物素与亲和素之间的特异结合特性固定在包被亲和素的磁性微球表面,但是利用化学修饰法将ATP硫酸化酶进行生物素化修饰很可能会影响酶的活性．利用融合表达策略,将大肠杆菌生物素酰基载体蛋白C端87个氨基酸肽段(BCCP87)与ATP硫酸化酶在大肠杆菌内融合表达,经SDS-PAGE和Western blot分析,表达的融合蛋白分子质量约为64 ku,并且能够在大肠杆菌内被生物素化．生物素化的ATP硫酸化酶能够与亲和素包被的磁珠结合,固定后的ATP硫酸化酶具有活性,并且能够用于定量检测焦磷酸盐(PPi)和焦测序,为今后建立高通量大规模焦测序系统提供了一个有效的工具酶．     

Composite surface for blocking bacterial adsorption on protein biochips

The design and fabrication of protein biochips requires characterization of blocking agents that minimize nonspecific binding of proteins or organisms. Nonspecific adsorption of Escherichia coli, Listeria innocua, and Listeria monocytogenes is prevented by bovine serum albumin (BSA) or biotinylated BSA adsorbed on SiO(2) surfaces of a biochip that had been modified with a C(18) coating. Biotinylated BSA forms a protein-based surface that in turn binds streptavidin. Because streptavidin has multiple binding sites for biotin, it in turn anchors other biotinylated proteins, including antibodies. Hence, biotinylated BSA simultaneously serves as a blocking agent and a foundation for binding an interfacing protein, avidin or streptavidin, which in turns anchors biotinylated antibody. In our case, the antibody is C11E9, an IgG-type antibody that binds Listeria spp. Nonspecific adsorption of another bacterium, Escherichia coli, is also minimized due to the blocking action of the BSA. The blocking characteristics of BSA adsorbed on C(18)-derivatized SiO(2) surfaces for construction of a protein biochip for electronic detection of pathogenic organisms is investigated.     

Noncovalent Immobilization of Streptavidin on In Vitro- and In Vivo-Biotinylated Bacterial Magnetic Particles

Biotinylated magnetic nanoparticles were constructed by displaying biotin acceptor peptide (BAP) or biotin carboxyl carrier protein (BCCP) on the surface of bacterial magnetic particles (BacMPs) synthesized by Magnetospirillum magneticum AMB-1. BAP-displaying BacMPs (BAP-BacMPs) were extracted from bacterial cells and incubated with biotin and Escherichia coli biotin ligase. Then the in vitro biotinylation of BAP-BacMPs was confirmed using alkaline phosphatase-labeled antibiotin antibody. In contrast, BacMPs displaying the intact 149 residues of AMB-1 BCCP (BCCP-BacMPs) and displaying the COOH-terminal 78 residues of BCCP (BCCP78-BacMPs) were biotinylated in AMB-1 cells. The in vivo biotinylation of BCCP-BacMPs and BCCP78-BacMPs was thought to be performed by endogenous AMB-1 biotin ligase. Streptavidin was introduced onto biotinylated BacMPs by simple mixing. In an analysis using tetramethyl rhodamine isocyanate-labeled streptavidin, approximately 15 streptavidin molecules were shown to be immobilized on a single BCCP-BacMP. Furthermore, gold nanoparticle-BacMP composites were constructed via the biotin-streptavidin interaction. The conjugation system developed in this work provides a simple, low-cost method for producing biotin- or streptavidin-labeled magnetic nanoparticles. Various functional materials can be site selectively immobilized on these specially designed BacMPs. By combining the site-selective biotinylation technology and the protein display technology, more innovative and attractive magnetic nanomaterials can be constructed.     

Functionalization of gold and glass surfaces with magnetic nanoparticles using biomolecular interactions

Advances in nanotechnology have enabled the production and characterization of magnetic particles with nanometer-sized features that can be functionalized with biological recognition elements for numerous applications in biotechnology. In the present study, the synthesis of and interactions between self-assembled monolayers (SAMs) on gold and glass surfaces and functionalized magnetic nanoparticles have been characterized. Immobilization of 10-15 nm streptavidin-functionalized nanoparticles to biotinylated gold and glass surfaces was achieved by the strong interactions between biotin and streptavidin. Fluorescent streptavidin-functionalized nanoparticles, biotinylated surfaces, and combinations of the two were characterized by Fourier transform infrared spectroscopy, X-ray photoelectron spectroscopy, and electron and fluorescent microscopy to confirm that little or no functionalization occurred in nonbiotinylated regions of the gold and glass surfaces compared to the biotinylated sites. Together these techniques have potential use in studying the modification and behavior of functionalized nanoparticles on surfaces in biosensing and other applications.     

Colorimetric competitive inhibition method for the quantification of avidin, streptavidin and biotin.

A colorimetric competitive inhibition assay for avidin, streptavidin and biotin was developed. The method for avidin or streptavidin was based on the competitive binding between avidin or streptavidin and a streptavidin-enzyme conjugate for biotinylated dextrin immobilized on the surface of a microtitre plate. For biotin quantitation the competition is between free biotin and the immobilized biotin for the streptavidin-enzyme conjugate. The limits of detection which was determined as the concentration of competitor required to give 90% of maximal absorbency (100% inhibition) was approximately 20 ng/100 microl per assay for avidin and streptavidin and 0.4 pg/100 microl per assay for biotin. The methods are simple, rapid, highly sensitive and adaptable to high throughput analysis.     

Protein engineering of streptavidin for in vivo assembly of streptavidin beads

Escherichia coli was engineered to intracellularly manufacture streptavidin beads. Variants of streptavidin (monomeric, core and mature full length streptavidin) were C-terminally fused to PhaC, the polyester granule forming enzyme of Cupriavidus necator. All streptavidin fusion proteins mediated formation of the respective granules in E. coli and were overproduced at the granule surface. The monomeric streptavidin showed biotin binding (0.7 ng biotin/microg bead protein) only when fused as single-chain dimer. Core streptavidin and the corresponding single-chain dimer mediated a biotin binding of about 3.9 and 1.5 ng biotin/mug bead protein, respectively. However, biotin binding of about 61 ng biotin/mug bead protein with an equilibrium dissociation constant (KD) of about 4 x 10(-8)M was obtained when mature full length streptavidin was used. Beads displaying mature full length streptavidin were characterized in detail using ELISA, competitive ELISA and FACS. Immobilisation of biotinylated enzymes or antibodies to the beads as well as the purification of biotinylated DNA was used to demonstrate the applicability of these novel streptavidin beads. This study proposes a novel method for the cheap and efficient one-step production of versatile streptavidin beads by using engineered E. coli as cell factory.     

Investigation of biotin-streptavidin binding interactions using microcantilever sensors

We report the investigation of biotin-streptavidin binding interactions using microcantilever sensors. A symmetric cantilever construction is employed to minimize the effects of thermal drift and the control of surface chemistry on the backside of the cantilever is demonstrated to reduce the effects of non-specific binding interactions on the cantilever. Three structurally different biotin modified cantilever surfaces are used as a model system to study the binding interaction with streptavidin. The cantilever response to the binding of streptavidin on these biotin sensing monolayers is compared. The lowest detection limit of streptavidin using biotin-HPDP is found to be between 1 and 10nM limited by the optical measurement setup. Surface characterization using quartz crystal microbalance (QCM) and high-resolution atomic force microscope (AFM) is used to benchmark the cantilever sensor response. In addition, the QCM and AFM studies reveal that the surface density of bound streptavidin on biotin modified surfaces was low, thereby implying that effects other than steric hindrance are responsible for defining cantilever response.     

Biotin-assisted folding of streptavidin on the yeast surface

Yeast surface display allows heterologously expressed proteins to be targeted to the exterior of the cell wall and thus has a potential as a biotechnology platform. In this study, we report the successful display of functional streptavidin on the yeast surface. Streptavidin binds the small molecule biotin with high affinity (K(d) ≈ 10(-14)M) and is used widely in applications that require stable noncovalent interaction, including immobilization of biotinylated compounds on a solid surface. As such, engineering functional streptavidin on the yeast surface may find novel uses in future biotechnology applications. Although the molecule does not require any post-translational modification, streptavidin is difficult to fold in bacteria. We show that Saccharomyces cerevisiae can fold the protein correctly if induced at 20°C. Contrary to a previous report, coexpression of anchored and soluble streptavidin subunits is not necessary, as expressing the anchored subunit alone is sufficient to form a functional complex. For unstable monomer mutants, however, addition of free biotin during protein induction is necessary to display a functional molecule, suggesting that biotin helps the monomer fold. To show that surface displayed streptavidin can be used to immobilize other biomolecules, we used it to capture biotinylated antibody, which is then used to immunoprecipitate a protein target.     

Colloidal gold as an electrochemical label of streptavidin-biotin interaction

A new electrochemical method to monitor biotin-streptavidin interaction, based on the use of colloidal gold as an electrochemical label, is investigated. Biotinylated albumin is adsorbed on the pretreated surface of a carbon paste electrode (CPE). This modified electrode is immersed in colloidal gold-streptavidin labelled solutions. Adsorptive voltammetry is used to monitor colloidal gold bound to streptavidin, obtaining a good reproducibility of the analytical signal (R.S.D. = 3.3%). A linear relationship between peak current and streptavidin concentration from 2.5 x 10(-9) to 2.5 x 10(-5) M is obtained when a sequential competitive assay between streptavidin and colloidal gold-labelled streptavidin is carried out. On the other hand, the adsorption of streptavidin on the electrode surface was performed, followed by the reaction with biotinylated albumin labelled with colloidal gold. In this way, a linear relationship between peak current and colloidal gold labelled biotinylated albumin concentration is achieved with a limit of detection of 7.3 x 10(9) gold particles per ml (5.29 x 10(-9) M in biotin).     

New antibody immobilization method via functional liposome layer for specific protein assays

A specific protein assay system based on functional liposome-modified gold electrodes has been demonstrated. To fabricate such assay system, a liposome layer was initially grown on top of a gold layer. The liposome layer contained two kinds of functional molecules: biotin molecules for the binding sites of streptavidin and N-(10,12-pentacosadiynoic)-acetylferrocene molecules for the facile redox probe in electrochemical detections. Then, streptavidin was attached on the functional liposme-modified layer using the interaction of streptavidin-sbiotin complex. On the streptavidin-attached surface, antibody molecules, anti-human serum albumin antibodies could be immobilized without any secondary antibodies. AFM imaging of the streptavidin-attached liposome surface revealed a uniform distribution of closely packed streptavidin molecules. In situ quartz-crystal microbalance and electrochemical measurements demonstrated that the wanted antibody-antigen reactions should occur with high specificity and selectivity. Our specific antibody assay system, based on a functional liposome modified electrode, can be developed further to yield sophisticated structures for numerous protein chips and immunoassay sensors.     

Bioluminescent assays using glucose-6-phosphate dehydrogenase: application to biotin and streptavidin detection

A streptavidin-glucose-6-phosphate dehydrogenase (G6PDH) conjugate was synthesized and its properties were studied, along with those of biotin-G6PDH conjugates. Two bioluminescent assays were used. Streptavidin was assayed in two steps: streptavidin samples were first incubated with a small amount of biotin-G6PDH and then with biotinylated rabbit gamma-globulins. The complex was immobilized on a bioluminescent immunoadsorbent. In the single-step biotin assay, free biotin was allowed to compete with biotin linked to rabbit gamma-globulins for binding to streptavidin-G6PDH in the presence of the bioluminescent immunoadsorbent. Neither assay required washing or separation steps and the sensitivity was 0.2 ng for streptavidin and 100 fg for biotin. Different applications are described: studies of biotin reactivity when linked to probes in solution or immobilized, and quantitation of biotin in biotinylated DNA probes and oligonucleotides.     

Immobilization of biomolecules on polyurethane membrane surfaces.

Lipophilic polymer membranes incorporating binding sites are widely used in various potentiometric, amperometric, and optical sensors. Here, we report on the biofunctional modification of the surface of a Ca(2+)-selective membrane. A photoactivatable biotin derivative was synthesized and covalently immobilized on a soft polyurethane membrane. The modified polymer was characterized by X-ray photoelectron spectroscopy (XPS) as well as by potentiometric measurements. The selective binding of streptavidin by the photo-cross-linked biotin derivative was demonstrated. The surface coverage obtained with different experimental protocols was analyzed by autoradiography using [(35)S]-streptavidin. The new approach may significantly extend the scope of applicability of potentiometric sensors.     

A sensitive enzyme assay for biotin, avidin, and streptavidin

Reciprocal enzyme assays are described for the vitamin biotin and for the biotin-binding proteins avidin and streptavidin. The assays are based on the following steps: (a) biotinylated bovine serum albumin is adsorbed onto microtiter plates; (b) streptavidin (or avidin) is bound to the biotin-coated plates; (c) biotinylated enzyme (in this case alkaline phosphatase) is then interacted with the free biotin-binding sites on the immobilized protein. For biotin assay, competition between the free vitamin and the biotinylated enzyme is carried out between steps (b) and (c). The method takes advantage of the four biotin-binding sites which characterize both avidin and streptavidin. The method is extremely versatile and accurate over a concentration range exceeding three orders of magnitude. The lower limits of detection are approximately 2 pg/ml (0.2 pg/sample) for biotin and less than 100 ng/ml (10 ng/sample) for either avidin or streptavidin.     

Design,production, and characterization of a monomeric streptavidin and its application for affinity purification of biotinylated proteins

To expand the application of the streptavidin-biotin technology for reversible affinity purification of biotinylated proteins, a novel form of monomeric streptavidin was engineered and produced using Bacillus subtilis as the expression host. By changing as little as two amino acid residues (T90 and D128) to alanine, the resulting mutant streptavidin designated DM3 was produced 100% in the monomeric form as a soluble functional protein via secretion. It remained in the monomeric state in the presence or absence of biotin. Interaction of purified monomeric streptavidin with biotin was studied by surface plasmon resonance-based BIAcore biosensor. Its on-rate is comparable to that of monomeric avidin while its off-rate is seven times lower. The dissociation constant was determined to be 1.3 x 10(-8)M. These properties make it an attractive agent for affinity purification of biotinylated proteins. An affinity matrix with immobilized DM3 mutein was prepared and applied to purify biotinylated cytochrome c from a crude extract. Biotinylated cytochrome c could be purified to homogeneity in one step and was shown to retain full biological activity. Advantages of using DM3 mutein over other traditional methods in the purification of biotinylated proteins are discussed.     

Antibody-antigenic peptide interactions monitored by SPR and QCM-D. A model for SPR detection of IA-2 autoantibodies in human serum

This work reports on a complementary use of surface plasmon resonance (SPR) and quartz crystal microbalance with dissipation monitoring (QCM-D) technologies to study interactions between a peptide antigen and polyclonal antibodies, in an experimental format suitable for diagnostic assays of autoimmune diseases. In the chosen model, a synthetic peptide from the juxtamembrane region of IA-2 (a type 1 diabetes associated antigen) was immobilized by an optimized chemical protocol applicable to both BIACORE and QCM-D sensors. A thorough study of the peptide immobilization was performed to optimize the signal-to-noise ratio using mixed self-assembled monolayers (SAM) on a gold surface. Introduction of polyethylene glycol (EG₆) chains into mixed SAM layers and addition of an anionic surfactant to the human serum reduced non-specific binding without modifying the viscoelasticity properties of the layer. Under our conditions, the antibody SPR detection limit was determined to be 0.2 nM in diluted human serum. This value is in agreement with the reported rank distribution of IA-2 antibodies in diabetic patient sera. Label-free and real-time technologies such as SPR and/or QCM-D could be precious tools in future diagnostic assays.     

Controlled layer-by-layer immobilization of horseradish peroxidase.

Horseradish peroxidase (HRP) was biotinylated with biotinamidocaproate N-hydroxysuccinimide ester (BcapNHS) in a controlled manner to obtain biotinylated horseradish peroxidase (Bcap-HRP) with two biotin moieties per enzyme molecule. Avidin-mediated immobilization of HRP was achieved by first coupling avidin on carboxy-derivatized polystyrene beads using a carbodiimide, followed by the attachment of the disubstituted biotinylated horseradish peroxidase from one of the two biotin moieties through the avidin-biotin interaction (controlled immobilization). Another layer of avidin can be attached to the second biotin on Bcap-HRP, which can serve as a protein linker with additional Bcap-HRP, leading to a layer-by-layer protein assembly of the enzyme. Horseradish peroxidase was also immobilized directly on carboxy-derivatized polystyrene beads by carbodiimide chemistry (conventional method). The reaction kinetics of the native horseradish peroxidase, immobilized horseradish peroxidase (conventional method), controlled immobilized biotinylated horseradish peroxidase on avidin-coated beads, and biotinylated horseradish peroxidase crosslinked to avidin-coated polystyrene beads were all compared. It was observed that in solution the biotinylated horseradish peroxidase retained 81% of the unconjugated enzyme's activity. Also, in solution, horseradish peroxidase and Bcap-HRP were inhibited by high concentrations of the substrate hydrogen peroxide. The controlled immobilized horseradish peroxidase could tolerate much higher concentrations of hydrogen peroxide and, thus, it demonstrates reduced substrate inhibition. Because of this, the activity of controlled immobilized horseradish peroxidase was higher than the activity of Bcap-HRP in solution. It is shown that a layer-by-layer assembly of the immobilized enzyme yields HRP of higher activity per unit surface area of the immobilization support compared to conventionally immobilized enzyme.     

Layer-by-layer assembly of bioengineered flagella protein nanotubes

Flagella nanotubes present on the surface of E. coli bacteria were bioengineered to display arginine-lysine and glutamic acid-aspartic acid peptide loops. These protein bionanotubes were demonstrated to self-assemble, layer-by-layer, by atomic force microscopy (AFM) on gold-coated mica and quartz surfaces. Flagella with arginine-lysine loops were assembled in a bottom-up manner on a gold-coated mica surface by employing the molecular complementarity of the biotin-streptavidin interaction. Self-assembled monolayers of alkylamines on the gold surface were derivatized with biotin, followed by binding of streptavidin to the biotinylated surface. The amine groups of the flagella peptide loops were chemically attached to biotin through a polyethyleneoxide spacer and paired with streptavidin on the gold surface. This process could be repeated to generate multiple layers of flagella. Flagella with glutamic acid-aspartic acid peptide loops were self-assembled on quartz surfaces by electrostatic attraction to protonated amine groups. The quartz surface was silanized to obtain amine groups, which were used to assemble the first layer of glutamic acid-aspartic acid peptide loop flagella nanotubes. This layer was covered with polyethyleneimine through electrostatic attraction and employed to assemble a second layer of flagella. The self-assembled glutamic acid-aspartic acid flagella were also used to demonstrate the biomineralization of CaCO 3. The layer-by-layer self-assembly employing electrostatic attraction yielded a more uniform layer of flagella than the one obtained with the molecular complementarity of the biotin-streptavidin pair.     

A streptavidin surface on planar glass substrates for the detection of biomolecular interaction

Based on the requirements of biomolecular interaction analysis on direct optical transducers, a streptavidin surface is examined. A general protocol was developed allowing the immobilization of biotinylated compounds using the rife biotin-streptavidin system. This type of surface modification can be applied to all biosensors using glass surfaces as sensor devices. Reflectometric interference spectroscopy (RIfS), a label-free, direct optical method was used to demonstrate the quality of the transducer surfaces. The surface modification is based on an aminofunctionalized polyethylene glycol layer covalently bound to the silica surface of the transducer and shows very little nonspecific binding. Biotin molecules can be easily coupled on such layers. Streptavidin followed by a biotinylated estrone derivative was immobilized by incubation of the biotinylated transducer surface. For the streptavidin layer we obtained interference signals corresponding to a protein monolayer. Finally, using a surface prepared as described above, biomolecular interaction experiments with an antibody against estrone were carried out to show the quality of the transducer surface. With RIfS all of the affinity-based surface modifications can be detected online and time resolved.     

Mild conditions for releasing mono and bis-biotinylated macromolecules from immobilized streptavidin

The high affinity (kd= approximately 10(-15)M) of streptavidin and avidin for biotin is key to a large number of biological applications and is essentially irreversible unless the complex is exposed to harsh conditions (e.g. heat (100 degrees C for 10 min)), detergents, and/or denaturants which damage macromolecules. Thus, high binding affinity becomes a disadvantage when a biotinylated target must be released for further processing. This work describes relatively mild conditions that release biotin and mono- and bis-biotinylated macromolecules from immobilized streptavidin on monodispersed magnetic beads.