A comparison of silver ion to streptavidin coated microplates

Direct comparisons are made between covalently linked streptavidin and silver ion coated microplates. Both coatings can immobilize biotinylated molecules. Silver ion coated microplate wells can immobilize 1.8 times higher amounts of biotin labeled horseradish peroxidase. The quantitation range and capacity for the capture of horseradish peroxidase using biotin labeled horseradish peroxidase are also greater for silver ion coated microplates. Approximately twice as many anti-horseradish peroxidase antibodies can be immobilized per well using silver ion coated microplates. Higher capacities are presumed to be due to the smaller footprint of silver ions as compared to streptavidin. A direct comparison between the two coatings for a beta-galactosidase ELISA showed that while the silver ion coated microplates gave higher readings, the streptavidin coated microplates exhibited smaller well-to-well variation. However, higher well to well variation for the silver microplates is attributed to the high density of anti-beta-galactosidase antibodies on the microplates and the weak binding of clone GAL-13 to beta-galactosidase, rather than the silver coating. These studies suggest silver ion coated microplates are a desirable alternative to streptavidin plates for quantitative immunoassays.     

Controlled antibody immobilization onto immunoanalytical platforms by synthetic peptide

Antibody immobilization on a solid surface is inevitable in the preparation of immunochips/sensors. Antibody-binding proteins such as proteins A and G have been extensively employed to capture antibodies on sensor surfaces with right orientations, maintaining their full functionality. Because of their synthetic versatility and stability, in general, small molecules have more advantages than proteins. Nevertheless, no small molecule has been used for oriented and specific antibody immobilization. Here is described a novel strategy to immobilize an antibody on various sensor surfaces by using a small antibody-binding peptide. The peptide binds specifically to the Fc domain of immunoglobulin G (IgG) and, therefore, affords a properly oriented antibody surface. Surface plasmon resonance analysis indicated that a peptide linked to a gold chip surface through a hydrophilic linker efficiently captured human and rabbit IgGs. Moreover, antibodies captured by the peptide exhibited higher antigen binding capacity compared with randomly immobilized antibodies. Peptide-mediated antibody immobilization was successfully applied on the surfaces of biosensor substrates such as magnetic particles and glass slides. The antibody-binding peptide conjugate introduced in this work is the first small molecule linker that offers a highly stable and specific surface platform for antibody immobilization in immunoassays.     

Oriented covalent immobilization of antibodies on physically inert and hydrophilic support surfaces through their glycosidic chains

Immobilization of antibodies by their oxidized sugar chain on aminated supports is a very efficient methodology to have a properly oriented antibody. However, these supports may behave as anionic exchangers, producing the unspecific adsorption of other proteins and reducing the selectivity of the system. To overcome this problem, we have proposed two solutions based in tailor-made support surfaces to immobilize antihorseradish peroxidase (HRP). The first solution was the use of supports having a very low amount of amino groups. These amino groups need to be very reactive with the aldehyde groups generated in the protein sugar chains to be efficient. Using supports having 7 micromol EDA/g (e.g., ethylenediamine modified glyoxyl-agarose), the antibody may be immobilized, keeping over 90% of the anti-HRP functionality. Second, by mixing amino groups and carboxylic groups, a neutral surface of the support has been generated. Again, this support has been unable to adsorb proteins while oxidized anti-HRP could be immobilized, giving functional anti-HRP antibodies. Both preparations retained 100% functionality after 2 months of storage at 4 degrees C. This way, the tailoring of the support surfaces has permitted solving some limitations of the immobilization of sugar-chain oxidized antibodies on primary amino supports.     

Successively amplified electrochemical immunoassay based on biocatalytic deposition of silver nanoparticles and silver enhancement

A successively signal-amplified electrochemical immunoassay has been reported on the basis of the biocatalytic deposition of silver nanoparticles with their subsequent enlargement by nanoparticle-promoted catalytic precipitation of silver from the silver-enhancer solution. The immunoassay was carried out based on a heterogeneous sandwich procedure using polystyrene microwells to immobilize antibody. After all the processes comprising the formation of immunocomplex, biocatalytic deposition of silver nanoparticles and following silver enhancement were completed, the silver on polystyrene microwells was dissolved and quantified by anodic stripping voltammetry (ASV). The effect of relevant experimental conditions, including the concentration of ascorbic acid 2-phosphate (AA-p) substrate and Ag(I) ions, the biocatalytic deposition time, and of crucial importance, the silver enhancement time, were investigated and optimized. The anodic stripping peak current was proportional to the concentration of human IgG in a dynamic range of 0.1-10 ng ml(-1) with a detection limit of 0.03 ng ml(-1). Scanning electron microscope (SEM) was applied to characterize the silver nanoparticles before and after silver enhancement on the surface of polystyrene microplates. By coupling the highly catalytic effect of enzyme and nanoparticles to successively amplify the analytical signal, the sensitivity of immunoassay was enhanced so dramatically that this approach would be a promising strategy to achieve a lower detection limit for bioassays.     

Immobilization of metallothionein to carbon paste electrode surface via anti-MT antibodies and its use for biosensing of silver

In this paper, heavy metal biosensor based on immobilization of metallothionein (MT) to the surface of carbon paste electrode (CPE) via anti-MT-antibodies is reported. First, the evaluation of MT electroactivity was done. The attention was focused on the capturing of MT to the CPE surface. Antibodies incorporated and mixed into carbon paste were stable; even after two weeks the observed changes in signal height were lower than 5%. Further, the interaction of MT with polyclonal chicken antibodies incorporated in carbon paste electrode was determined by square-wave voltammetry. In the voltammogram, two signals--labelled as cys(MT) and W(a)--were observed. The cys(MT) corresponded to -SH moieties of MT and W(a) corresponded to tryptophan residues of chicken antibodies. Time of interaction (300 s) and MT concentration (125 μg/ml) were optimized to suggest a silver(I) ions biosensor. Biosensor (CPE modified with anti-MT antibody) prepared under the optimized conditions was then used for silver(I) ions detection. The detection limit (3 S/N) for silver(I) ions was estimated as 0.5 nM. The proposed biosensor was tested by detection spiking of silver(I) ions in various water samples (from very pure distilled water to rainwater). Recoveries varied from 74 to 104%.     

Comparison of antibody functionality using different immobilization methods

This study investigates the influence of antibody immobilization methods on antigen capture. Adsorption and two surface chemistries, an aminosilane chemistry and a common heterobifunctional crosslinker (N-gamma-maleimidobutyryloxy-succinimide ester, GMBS), were compared and evaluated for their ability to immobilize antibodies and capture antigen. The role of protein A as an orienting protein scaffold component in each of these techniques was also evaluated. Through experimentation it was determined that the GMBS technique immobilized the highest amount of antibody and minimized nonspecific binding. For all techniques, the most functional antibodies were found to be those immobilized with protein A. Interestingly, the aminosilane technique demonstrated the highest antigen capture with antibody alone but also exhibited the highest level of nonspecific binding.     

Comparative study of horseradish peroxidase immobilization on modification of a gold surface using a surface plasmon resonance method

Horseradish peroxidase is immobilized by a periodate method on the gold surfaces previously modified with 16-mercapto-hexadecanoic acid or with hydrogen disulfide and soybean trypsin inhibitor. The effect of gold surface modification conditions on the immobilization of the enzyme as well as on the properties of the immobilized glycoprotein are studied using surface plasmon resonance technique. Restoration of the ability to bind specific antibodies is demonstrated for the immobilized enzyme. The low level of non-specific antibody binding to the immobilized glycoprotein is also shown.     

Covalent DNA immobilization on polymer-shielded silver-coated quartz crystal microbalance using photobiotin-based UV irradiation.

The use of a commercial, silver-coated quartz crystal microbalance (QCM) as a disposable, low-cost, and reliable DNA sensor is presented. This is an incorporation of polymer-based silver electrode shielding and photochemistry-based surface modification for covalent DNA immobilization. To prevent undesired oxidation, the silver electrodes are coated with thin polystyrene films. The polymer surfaces are then modified by a photoreactive biotin derivative (photobiotin) under UV irradiation. The resulting biotin residues on the polymer-shielded surface react with a tetrameric avidin. Consequently a biotin-labeled DNA probe can be immobilized through a biotin-avidin-biotin bridge. A 14-mer single-stranded biotin-DNA probe and a 70-mer single-stranded DNA fragment containing complementary or noncomplementary sequences are used as a model system for DNA hybridization assay on the proposed sensors. The shielding ability of the polystyrene coatings after photo irradiation is investigated. The DNA probe binding capacity, hybridization efficiency, and kinetics are also investigated.     

Sensitive electrochemical immunosensor for cancer biomarker with signal enhancement based on nitrodopamine-functionalized iron oxide nanoparticles

A novel electrochemical immunosensor for sensitive detection of cancer biomarker prostate specific antigen (PSA) based on nitrodopamine (NDA) functionalized iron oxide nanoparticles (NDA-Fe(3)O(4)) is described. NDA-Fe(3)O(4) was used both for the immobilization of primary anti-PSA antibody (Ab(1)) and as secondary anti-PSA antibody (Ab(2)) label. For the preparation of the label, mediator thionine (TH) was first conjugated onto NDA-Fe(3)O(4) based on the amino groups of NDA, and then the amino group of TH was used to immobilize horseradish peroxidase (HRP) and Ab(2). Due to the high amount of NDA anchored onto Fe(3)O(4) surface, the loading of antibodies as well as mediator and enzyme onto NDA-Fe(3)O(4) was substantially increased, which increased the sensitivity of the immunosensor. The resulting immunosensor displayed a wide range of linear response (0.005-50 ng/mL), low detection limit (4 pg/mL), good reproducibility and stability. The immunosensor was used to detect the PSA contents in serum samples with satisfactory results.     

The solid phase in affinity chromatography: strategies for antibody attachment.

Antibodies (Ab) are commonly used in affinity chromatography (AC) as a versatile and specific means of isolating target molecules from complex mixtures. A number of procedures have been developed to immobilize antibodies on the solid matrix. Some of these methods couple the antibody via chemical groups that may be important for specific recognition of antigen, resulting in loss of functionality in a proportion of the antibodies. In other methods, the outcome of immobilization is coupling via unique sites in the Fc region of the antibody molecule, ensuring orientation of the antibody combining sites (Fab) towards the mobile phase. This review discusses the advantages and disadvantages of the various methods available for immobilization and outlines protocols for site-directed, covalent coupling of the antibody to the solid phase that essentially retains the activity of the antibody.     

Preparation and Characterization of Ligand-Modified Labelled Liposomes for Solid Phase Immunoassays

Abstract

Small unilamellar vesicles conjugated with an enzyme label and with specific ligands for biological molecules may prove to be useful as signal enhancement vehicles in the development of enzyme-linked immunoadsorbent assays and other detection applications. Bifunctional vesicles have been prepared by covalently attaching horseradish peroxidase (HRP) and monoclonal antibodies to the outside of the lipid bilayer. The reaction conditions were optimized to obtain 7-12 antibody molecules and 100-200 HRP molecules per vesicle. The enzyme retained 70-80% of its specific activity after immobilization with no apparent change in vesicle stability. These bifunctional vesicles were used in a noncompetitive immunoassay for D-Dimer, a fibrin dimer formed at the early stages of thrombogenesis. The assay results using vesicles led to a detection limit for D-Dimer in human plasma which was five times lower than what was achieved using a conventional enzyme-antibody conjugate assay. HRP labelled (bifunctional) liposomes can also be used in competitive assays for the detection of small ligands in bulk solution. HRP and biotin-conjugated vesicles were prepared and used in competitive assays for biotin in free solution. The lowest detection limit for biotin using vesicles as the signal generation mechanism was found to be a factor of 10 lower than what could be observed with a traditional biotin-HRP conjugate. A model has been developed for the competition between a small ligand in solution and a large ligand-conjugated vesicle for binding sites on a solid surface.     

Optimizing immobilization on two-dimensional carboxyl surface: pH dependence of antibody orientation and antigen binding capacity

The performance of immunosensors is highly dependent on the amount of immobilized antibodies and their remaining antigen binding capacity. In this work, a method for immobilization of antibodies on a two-dimensional carboxyl surface has been optimized using quartz crystal microbalance biosensors. We show that successful immobilization is highly dependent on surface pK_a, antibody pI, and pH of immobilization buffer. By the use of EDC/sulfo-NHS (1-ethyl-3-[3-dimethylaminopropyl] carbodiimide hydrochloride/N-hydroxysulfosuccinimide) activation reagents, the effect of the intrinsic surface pK_a is avoided and immobilization at very low pH is therefore possible, and this is important for immobilization of acidic proteins. Antigen binding capacity as a function of immobilization pH was studied. In most cases, the antigen binding capacity followed the immobilization response. However, the antigen-to-antibody binding ratio differed between the antibodies investigated, and for one of the antibodies the antigen binding capacity was significantly lower than expected from immobilization in a certain pH range. Tests with anti-Fc and anti-Fab₂ antibodies on different antibody surfaces indicated that the orientation of the antibodies on the surface had a profound effect on the antigen binding capacity of the immobilized antibodies.     

Dual immobilization of biomolecule on the glass surface using cysteine as a bifunctional linker

A novel method for highly efficient enzyme immobilization on the glass surface, by incorporating cysteine as a linker has been demonstrated. The internal glass surface of test tube was pretreated with (3-mercaptopropyl) trimethoxysilane sol–gel and cysteine capped silver nanoparticles, to generate a cysteine layer. This, cysteine rich surface is then used to covalently immobilize alkaline phosphatase on both groups (amino and carboxyl) of cysteine through carbodiimide and glutaraldehyde treatment. The cysteine capped silver nanoparticles were synthesized with an average nanoparticle size of 61 nm as determined by particle size analyzer, while cysteine capping of nanoparticles was confirmed by Fourier transform infra-red spectroscopy. Enhanced enzymatic activity of about 73% was obtained using the dual immobilization technique, while 40% enzyme activity was recovered with carboxyl group and 51% with amino group only. The re-usability of the enzyme immobilized test tube was found to be 8 times and the enzyme retained 85% of its initial activity. With such high immobilization efficiency, cysteine provides a new approach for enhanced immobilization and its integration into different industrial processes and biosensor technology.     

Detection of polyclonal antibody against any area of the protein-antigen using immobilized protein-antigens: the critical role of the immobilization protocol

Antigens immobilized on solid supports may be used to detect or purify their corresponding antibodies (Ab) from serum. Direct immobilization of antigens on support surfaces (through short spacer arms) may promote interesting stabilizing effects on the immobilized antigen. However, the proximity of the support may prevent the interaction of some fractions of polyclonal Ab with some regions of the antigen (those placed in close contact with the support surface). Horseradish peroxidase (HRP) was immobilized on agarose by different protocols of multipoint covalent immobilization involving different regions of the antigen surface. Glyoxyl-agarose, BrCN-agarose, and glutaraldehyde-agarose were used as activated supports. Each HRP-immobilized preparation was much more stable than the soluble enzyme, but it was only able to adsorb up to 60-70% of a mixture of polyclonal anti-HRP antibodies. On the other hand, HRP was also immobilized on agarose through a very long, flexible, and hydrophilic spacer arm (dextran). This immobilized HRP was hardly stabilized, but it was able to adsorb 100% of the polyclonal anti-HRP. The absence of steric hindrances seems to play a critical role favoring the complete recognition of all classes of polyclonal Ab. Another solution to achieve a complete adsorption of polyclonal Ab on immobilized-stabilized antigens has been also reached by using a mixture of the differently immobilized and stabilized HRP-agarose preparations. In this case, an improved storage and operational stabilities of the immobilized antigens can be combined with the complete adsorption of any class of antibody.     

Solid supports in enzyme-linked immunosorbent assay and other solid-phase immunoassays

A very large proportion of modern immunoassays involve the use of synthetic solid phases to immobilize one of the reactants. These solid-phase immunoassays (SPIs) therefore involve ligand-receptor interactions that occur within a reaction volume close to the solution/solid phase interface. As a consequence, the immunochemistry/biochemistry of these ligand-receptor interactions differs from that of their counterparts in solution. Furthermore, the immobilization process can significantly alter the biological activity of the reactant; most adsorbed proteins on polystyrene or silicone are partially or largely denatured. Therefore the use of alternative methods of immobilization is attractive but may result in little increase in the amount of total functional reactant. However, all commonly used solid phases do not have the same properties or the same capacity for reactant immobilization or experience the same level of nonspecific binding. Empiricism plays a major role in SPIs. Derivations of mass law equations for measuring the antigen capture of solid-phase antibodies, for determining the affinity of solid phase for protein adsorption, and for estimating antibody affinity are reviewed.     

Heterogeneous inhibition of horseradish peroxidase activity by cadmium

Inhibition of horseradish peroxidase (HRP) activity by cadmium was studied under steady-state kinetic conditions after preincubation of the enzyme with millimolar concentrations of Cd(2+) for various periods of time. The H(2)O(2)-mediated oxidation of o-dianisidine by HRP was used to assess the enzymatic activity. Cd(2+) was found to be either a noncompetitive inhibitor of HRP or a mixed inhibitor of HRP depending both on the duration of incubation with HRP and on Cd(2+) concentration. Furthermore, for the same inhibition type, K(i) values dropped as incubation time increased. These results suggested that Cd(2+) would slowly bind to the enzyme and progressively induce conformational changes. Spectrophotometric analysis showed that indeed Cd(2+) altered the heme Soret absorption band on binding HRP and exhibited a K(d) which decreased as the incubation time of HRP with Cd(2+) increased. Hill plots suggested a cooperative binding of up to three Cd(2+) ions per molecule of HRP. Thus, Cd(2+) binding to HRP resulted in progressive inhibition of enzymatic activity with a change in the inhibition type as the number of Cd(2+) ions per HRP molecule increased. Results also illustrated the potential danger of long-term exposure to heavy metals, even for enzymes with low affinity for them.     

Poly(2-hydroxyethyl methacrylate) for enzyme immobilization: impact on activity and stability of horseradish peroxidase

On the basis of their versatile structure and chemistry as well as tunable mechanical properties, polymer brushes are well-suited as supports for enzyme immobilization. However, a robust surface design is hindered by an inadequate understanding of the impact on activity from the coupling motif and enzyme distribution within the brush. Herein, horseradish peroxidase C (HRP C, 44 kDa), chosen as a model enzyme, was immobilized covalently through its lysine residues on a N-hydroxysuccinimidyl carbonate-activated poly(2-hydroxyethyl methacrylate) (PHEMA) brush grafted chemically onto a flat impenetrable surface. Up to a monolayer coverage of HRP C is achieved, where most of the HRP C resides at or near the brush-air interface. Molecular modeling shows that lysines 232 and 241 are the most probable binding sites, leading to an orientation of the immobilized HRP C that does not block the active pocket of the enzyme. Michaelis-Menten kinetics of the immobilized HRP C indicated little change in the K(m) (Michaelis constant) but a large decrease in the V(max) (maximum substrate conversion rate) and a correspondingly large decrease in the k(cat) (overall catalytic rate). This indicates a loss in the percentage of active enzymes. Given the relatively ideal geometry of the HRPC-PHEMA brush, the loss of activity is most likely due to structural changes in the enzyme arising from either secondary constraints imposed by the connectivity of the N-hydroxysuccinimidyl carbonate linking moiety or nonspecific interactions between HRP C and DSC-PHEMA. Therefore, a general enzyme-brush coupling motif must optimize reactive group density to balance binding with neutrality of surroundings.     

THE INTERACTION OF PARTICULATE HORSERADISH PEROXIDASE (HRP)-ANTI HRP IMMUNE COMPLEXES WITH MOUSE PERITONEAL MACROPHAGES IN VITRO

The uptake, distribution, and fate of particulate horseradish peroxidase (HRP)-anti HRP aggregates has been studied in homogeneous monolayers of mouse macrophages in vitro. Macrophages rapidly interiorize the immune complexes after binding to the cell surface. The rate of interiorization is maximal for complexes formed in a broad zone of 4-fold antibody excess to equivalence and corresponds to a rate of 10% of the administered load/10⁶ cells per hour. This rate is 4000-fold greater than the uptake of soluble HRP. The binding and endocytosis of HRP-anti HRP by macrophages is mediated by the trypsin insensitive F_c receptor. Cytochemically, intracellular HRP is localized within membrane bound vacuoles. After uptake of HRP, the enzymatic activity is degraded exponentially with a half-life of 14–18 hr until enzyme is no longer detectable. This half-life is twice as long as that previously observed for soluble uncomplexed HRP and is related to the combination of HRP with anti-HRP rather than the absolute amounts of enzyme or antibody ingested. The half-life of HRP-¹²⁵I was 30 hr. Exocytosis of cell associated enzyme or TCA precipitable counts was not detected, nor were persistent surface complexes demonstrable. The extensive capacity of macrophages to interiorize and destroy large amounts of antigen after the formation of antibody illustrates a role of this cell in the efferent limb of the immune response.     

Hydrophobic salt-modified Nafion for enzyme immobilization and stabilization

Over the last decade, there has been a wealth of application for immobilized and stabilized enzymes including biocatalysis, biosensors, and biofuel cells. In most bioelectrochemical applications, enzymes or organelles are immobilized onto an electrode surface with the use of some type of polymer matrix. This polymer scaffold should keep the enzymes stable and allow for the facile diffusion of molecules and ions in and out of the matrix. Most polymers used for this type of immobilization are based on polyamines or polyalcohols - polymers that mimic the natural environment of the enzymes that they encapsulate and stabilize the enzyme through hydrogen or ionic bonding. Another method for stabilizing enzymes involves the use of micelles, which contain hydrophobic regions that can encapsulate and stabilize enzymes. In particular, the Minteer group has developed a micellar polymer based on commercially available Nafion. Nafion itself is a micellar polymer that allows for the channel-assisted diffusion of protons and other small cations, but the micelles and channels are extremely small and the polymer is very acidic due to sulfonic acid side chains, which is unfavorable for enzyme immobilization. However, when Nafion is mixed with an excess of hydrophobic alkyl ammonium salts such as tetrabutylammonium bromide (TBAB), the quaternary ammonium cations replace the protons and become the counter ions to the sulfonate groups on the polymer side chains (Figure 1). This results in larger micelles and channels within the polymer that allow for the diffusion of large substrates and ions that are necessary for enzymatic function such as nicotinamide adenine dinucleotide (NAD). This modified Nafion polymer has been used to immobilize many different types of enzymes as well as mitochondria for use in biosensors and biofuel cells. This paper describes a novel procedure for making this micellar polymer enzyme immobilization membrane that can stabilize enzymes. The synthesis of the micellar enzyme immobilization membrane, the procedure for immobilizing enzymes within the membrane, and the assays for studying enzymatic specific activity of the immobilized enzyme are detailed below.     

Immobilization of antibodies through the surface regions having the highest density in lysine groups on finally inert support surfaces

Immobilization of anti-horseradish peroxidase on glyoxyl-agarose proceeds rapidly, and after the immobilization, it was found that the antibody captured almost the same amount of peroxidase than the free antibody. After boiling the antibodies in the presence of SDS and mercaptoethanol, more than 95% of the immobilized antibodies presented the four subunits attached to the support.The reduction of the preparation converts the glyoxyl groups into very hydrophilic and inert hydroxyl-groups. That way, the final support was fully unable to adsorb any protein under any condition, and the only adsorbed proteins on the immobilized antibody are these recognized by the antibody. The immobilized antibody maintained intact their capacity to capture peroxidase after 20 weeks of storage at 4 °C.The high functionality of the immobilized antibody and the fully inert surface suggest that this technique may be a very suitable one to immobilize antibodies for biosensor design or immuno-chromatographic matrices.