Combination of DNA-directed immobilization and immuno-PCR: very sensitive antigen detection by means of self-assembled DNA–protein conjugates

An assay for very sensitive antigen detection is described which takes advantage of the self- assembly capabilities of semi-synthetic conjugates of DNA and proteins. The general scheme of this assay is similar to a two-sided (sandwich) enzyme-linked immunoassay (ELISA); however, covalent single-stranded DNA–streptavidin (STV) conjugates, capable of hybridizing to complementary surface-bound DNA oligomers, are utilized for the effective immobilzation of either capture antibodies or antigens, rather than the chemi- or physisorption usually applied in ELISA. Immuno-PCR (IPCR) is employed as a method for signal generation, utilizing oligomeric reagents obtained by self-assembly of STV, biotinylated DNA and antibodies. In three different model systems, detecting human IgG, rabbit IgG or carcinoembryonic antigen, this combination allowed one to increase the sensitivity of the analogous ELISA ~1000-fold. For example, <0.1 amol/µl (15 pg/ml) of rabbit IgG was detectable. The immunoassay can be carried out in a single step by tagging the analyte with both reagents for capture and read-out simultaneously, thereby significantly reducing handling time and costs of analysis. Moreover, as the spatial selectivity of target immobilization is determined by the specificity of DNA base pairing, the assay is particularly suited for miniaturized microfluidics and lab-on-a-chip devices.     

Performance of antibody microarrays fabricated by either DNA-directed immobilization, direct spotting, or streptavidin-biotin attachment: a comparative study

Antibody microarrays have the potential to revolutionize protein diagnostics. The major problems in the fabrication of antibody arrays, however, concern the reproducibility and homogeneity of the attachment of the proteins on the solid substrate. We here compare the DNA-directed immobilization (DDI) method with two conventional strategies for immobilization of antibodies on glass substrates. DDI is based on the self-assembly of semisynthetic DNA-streptavidin conjugates which converts an array of DNA oligomers into an antibody microarray. DDI was compared with direct spotting of antibodies on chemically activated glass slides and with immobilization of biotinylated antibodies on streptavidin-coated slides. The immobilized antibodies were used as capture reagents in a two-sided (sandwich) immunoassay for the quantification of rabbit IgG as a model antigen. Detection limits down to 0.001nM (150 pg/mL) were attained with all three array formats; however, DDI and direct spotting of the antibodies led to the highest fluorescence intensities. DDI led to the best spot homogeneity and intra- and interexperimental reproducibility. Moreover, DDI allowed highly economical use of antibody materials; that is, at least 100-fold less antibody is needed for preparing an array by DDI instead of by direct spotting. Taking into account the greater versatility and convenience of handling of the self-assembly approach, this study demonstrates that DDI is an advantageous alternative for generating versatile and robust protein arrays.     

Nanostructured dna-protein aggregates consisting of covalent oligonucleotide-streptavidin conjugates

Covalent conjugates consisting of streptavidin and a 24-mer single-stranded DNA oligonucleotide have been oligomerized by cross-linking with a 5',5'-bis-biotinylated 169-base-pair double-stranded DNA (dsDNA) fragment. The oligomeric conjugates formed have been analyzed by nondenaturing gel electrophoresis and scanning-force microscopy (SFM). The comparison of analogous oligomers, prepared from native STV and the bis-biotinylated dsDNA fragment, revealed that the covalent STV-oligonucleotide hybrid conjugates self-assemble to generate oligomeric aggregates of significant smaller size, containing on average only about 2.5 times less dsDNA fragments per aggregate. Likely, this is a consequence of electrostatic or steric repulsion between the dsDNA and the single-stranded oligomer covalently attached to the hybrid, as indicated from control experiments. Nevertheless, the single-stranded oligonucleotide moiety within the oligomeric conjugates can be used as a selective molecular handle for further functionalization and manipulation. For instance, it was used for specific DNA-directed immobilization at a surface, previously functionalized with complementary capture oligonucleotides. Moreover, we demonstrate that macromolecules, such as STV and antibody molecules, which are tagged with the complementary oligonucleotide, specifically bind to the supramolecular DNA-STV oligomeric conjugates. This leads to a novel class of functional DNA-protein conjugates, suitable, for instance, as reagents in immuno-PCR or as building blocks in molecular nanotechnology.     

Development of a one-step immunochromatographic strip test for the detection of sennosides A and B

An immunochromatographic strip test was developed to detect sennoside A (1) and sennoside B (2) using anti-1 and anti-2 monoclonal antibodies. The qualitative assay was based on a competitive immunoassay in which the detector reagent consisted of colloidal gold particles coated with the respective sennoside antibodies. The capture reagents were 1- and 2-human serum albumin (HSA) conjugates immobilised on a nitrocellulose membrane on the test strip. The sample containing 1 and 2, together with detector reagent, passed over the zone where the capture reagents had been immobilised. The analytes in the sample competed for binding to the limited amount of antibodies in the detector reagent with the immobilised 1- and 2-HSA conjugates on the membrane and hence positive samples showed no colour in the capture spot zone. Detection limits for the strip test were 125 ng/mL for both sennosides. The assay system is useful as a rapid and simple screening method for the detection of 1 and 2 in plants, drugs and body fluids.     

Triple-site antigen capture ELISA for human myoglobin can be more effective than double-site assay

Using a panel of monoclonal antibodies against human myoglobin (Mb), we have shown that the sensitivity of antigen-capture ELISA can be significantly increased by simultaneous immobilization of two cooperating capture monoclonal antibodies on a solid phase. This method ("triple-site ELISA") uses three monoclonal antibodies to different epitopes of the same antigen (two capture/one tracer) unlike the traditional double-site assay using one capture and one tracer monoclonal antibody. We developed double- and triple-site ELISA for Mb by varying the capture and tracer monoclonal antibodies. Triple-site assays showed 4-6-fold increase in sensitivity compared to the double-site assays. A model for this effect is suggested; according to the model, in triple-site ELISA, high-affinity cyclic configurations can be formed by an antigen, two capture monoclonal antibodies, and the surface of the solid phase.     

Immobilization strategies for single-chain antibody microarrays

Sandwich ELISA microarrays have great potential for validating disease biomarkers. Each ELISA relies on robust-affinity reagents that retain activity when immobilized on a solid surface or when labeled for detection. Single-chain antibodies (scFv) are affinity reagents that have greater potential for high-throughput production than traditional IgG. Unfortunately, scFv are typically less active than IgG following immobilization on a solid surface and not always suitable for use in sandwich ELISAs. We therefore investigated different immobilization strategies and scFv constructs to determine a more robust strategy for using scFv as ELISA reagents. Two promising strategies emerged from these studies: (i) the precapture of epitope-tagged scFv using an antiepitope antibody and (ii) the direct printing of a thioredoxin (TRX)/scFv fusion protein on glass slides. Both strategies improved the stability of immobilized scFv and increased the sensitivity of the scFv ELISA microarray assays, although the antiepitope precapture method introduced a risk of reagent transfer. Using the direct printing method, we show that scFv against prostate-specific antigen (PSA) are highly specific when tested against 21 different IgG-based assays. In addition, the scFv microarray PSA assay gave comparable quantitative results (R(2) = 0.95) to a commercial 96-well ELISA when tested using human serum samples. In addition, we find that TRX-scFv fusions against epidermal growth factor and toxin X have good LOD. Overall, these results suggest that minor modifications of the scFv construct are sufficient to produce reagents that are suitable for use in multiplex assay systems.     

Enzyme-linked immunosorbent assay. II. Quantitative assay of protein antigen, immunoglobulin G, by means of enzyme-labelled antigen and antibody-coated tubes

Alkaline phosphatase from calf intestinal mucosa has been conjugated to a protein antigen, rabbit IgG. Such conjugates, prepared by glutardialdehyde, have been used in a competitive solid phase immunoassay. In this test native antigen inhibits the binding of the conjugate to homologous antibodies adsorbed to plastic tubes. Using this assay 1-100 ng/ml of the antigen could be determined.     

Comparative ELISA reagents for detection of hepatitis B surface antigen (HBsAg)

Conjugates of goat anti-HBs IgG and horseradish peroxidase (HRP) prepared by two different methods, one using NaIO4 and the other SPDP, were compared. Anti-HBs antibodies obtained from goat, rabbit and guinea-pig were tested as capture serum. The ELISA showed a sensitivity similar to RIA and a level of antigen captation ranging from 4.37 to 8.75 nanograms/ml was obtained when rabbit or guinea-pig captures were used combined with both NaIO4 or SPDP conjugates.     

Protein A-based antibody immobilization onto polymeric microdevices for enhanced sensitivity of enzyme-linked immunosorbent assay

Highly efficient antibody immobilization is extremely crucial for the development of high-performance polymeric microdevices for enzyme-linked immunosorbent assay (ELISA). In this article, a site-selective tyrosinase (TR)-catalyzed protein A strategy for antibody immobilization was developed to enhance the sensitivity of ELISA in poly-(methyl methacrylate) (PMMA) microchannels for interferon-gamma (IFN-gamma) assay. To effectively immobilize the target antibodies, oxygen plasma was first used to activate the inert PMMA. This is followed by poly(ethyleneimine) (PEI) coating, an amine-containing functional polymer. For comparison, protein A was also immobilized through the commonly used amine-glutaraldehyde (GA) chemistry. Oxygen plasma treatment effectively increased the amount of PEI attachment and subsequent binding efficiency of the primary antibody. The antibody immobilized via TR-catalyzed protein A was able to provide much better specific antigen capture efficiency than GA chemistry due to the optimal spacing and orientation. Consequently, by using this new method, the detection signal and the signal-to-noise ratio of the ELISA immunoassay in microdevices were all significantly improved. In comparison to the standard assay carried out in the 96-well microtiter plate, the treated microchannels exhibited a broader detection range and a shorter detection time. And the detection limit was also decreased to 20 pg/mL, much lower than that obtained in other microdevices.     

Supramolecular DNA-streptavidin nanocircles with a covalently attached oligonucleotide moiety

Covalent hybrid conjugates consisting of streptavidin (STV) and a 24-mer single-stranded DNA oligonucleotide have been used as a starting material for the synthesis of supramolecular nanocircles. For this, the covalent hybrid conjugates were oligomerized by cross-linking with 5 ,5 -bis-biotinylated double-stranded DNA (dsDNA) fragments of various length. Heat denaturation of the resulting oligomeric conjugates and subsequent rapid cooling led to the formation of the nanocircles, in which the oligonucleotide-containing STV molecule is coupled with both ends of the circular bis-biotinylated dsDNA fragment. The circular structure of the bioconjugates was established by electrophoretic studies including Ferguson plot analysis as well as by scanning force microscopy (SFM) inspection. The formation process and the stability against degradation by ligand exchange with free D-biotin was compared for the nanocircles obtained from covalent oligonucleotide-STV hybrids and native STV. The former nanocircles revealed a decreased stability with respect to ring opening than the circles obtained from native STV. This suggested that the affinity of the covalent oligonucleotide-STV hybrid for binding biotinylated DNA is significantly decreased. Nevertheless, the single-stranded oligonucleotide moiety of the hybrid nanocircles can be used as a molecular handle for further functionalization. For instance, it was used for the selective DNA-directed immobilization at a surface, previously functionalized with complementary capture oligonucleotides. Moreover, we demonstrate that a pair of nanocircles, containing complementary oligonucleotide moieties, can be hybridized to form specific dimers, thereby generating a novel type of supramolecular DNA-protein nanostructures.     

Immunoenzyme analysis of adenovirus hexons. Indication and characteristics of rabbit and mouse antibodies against hexons

An enzyme-linked immunosorbent assay (ELISA) was developed for analysis of rabbit and mouse IgG antibodies specific to adenoviral hexon. The anti-hexon antibodies were detected by capture with purified hexon coated onto polystyrene microtiter plates and visualizing them by respective anti-IgG horseradish peroxidase conjugates. In the sera from hyperimmunized rabbits and mice as well as in the mouse ascite fluids the ELISA procedure revealed primarily type-specific (epsilon) and genus-specific (alpha) antigenic determinants in hexon but not those of intermediate specificities.     

Anti-VP1 and anti-VP2 antibodies detected by immunofluorescence assays in patients with acute human parvovirus B19 infection

Acute human parvovirus B19 infection is followed by an antibody response to the structural proteins of the viral capsid (VP1 and VP2). We used 80 sera collected from 58 erythema infectiosum and 6 transient aplastic crisis patients to test IgM and IgG antibodies against these two proteins in an immunofluorescence assay (IFA) using Sf9 cells infected with recombinant baculovirus expressing either VP1 or VP2 antigen. Although less sensitive than IgM capture enzyme immunoassay using native antigen (MACEIA), we could detect anti-VP1 or anti-VP2 IgM antibodies by IFA in 49 patients with acute infection (76.6%). Detection of IgG anti-VP1 and anti-VP2 by IFA, however, was as sensitive as IgG detection by indirect enzyme immunoassay. By applying IgG avidity IFA to sera of the 15 IgM IFA negative patients we were able to confirm acute infection in further 12 cases by IFA. Overall, acute infection was confirmed by IFA in 61 (95.3%) of the 64 patients.     

Improving the antigenicity of sTn antigen by modification of its sialic acid residue for development of glycoconjugate cancer vaccines

Sialyl Tn (sTn) antigen is a sialylated disaccharide abundantly expressed by many tumors. To search for effective cancer immunotherapies based on sTn antigen, we designed and synthesized a series of unnatural N-acyl derivatives of sTn and studied their immunological properties. For this purpose, an efficient method was developed to synthesize the natural and unnatural forms of sTn antigen and their protein conjugates. The resultant glycoconjugates were used to immunize C57BL/6 mice, and the immune response was assessed by enzyme-linked immunosorbent assay (ELISA). Whereas the keyhole limpet hemocyanin (KLH) conjugate of sTn elicited low levels of IgM antibodies, the KLH conjugates of N-iso-butanoyl sTn and N-phenylacetyl sTn, especially the latter, induced high titers of antigen-specific IgG antibodies, showing a T-cell-dependent response that is critical for the antitumor activity. The results suggest that the modified forms of sTn, especially N-phenylacetyl sTn, have improved antigenicity and promising immunological properties for use as cancer vaccines.     

A novel and robust homogeneous fluorescence-based assay using nanoparticles for pharmaceutical screening and diagnostics

We have established a new type of homogeneous immunoassay based on nanoparticles (nanoparticle immunoassay, or NPIA) being analyzed using fluorescence intensity distribution analysis (FIDA). This method allows the characterization of single fluorescently labeled molecules or particles with respect to their molecular brightness and concentration. Upon binding of conjugates to molecules coupled to the nanoparticle surface, the brightness of the complex scales with the number of bound conjugates. The complexes can then be distinguished accurately from free conjugate and concentrations of free and bound molecules can be determined reliably. In this study we present various examples of NPIAs where capture antibodies were linked to the nanoparticles, which were either artificial beads or bacteria. Two assay formats have been developed; first, direct labeling of the conjugate was used to quantitate free antigen through competition experiments, and second, an antigen-directed antibody was labeled to establish an assay similar to a sandwich ELISA setup. The major advantages of a NPIA are the robustness and high signal-to-noise ratio at short measurement times, as demonstrated with a miniaturized experiment in a Nanocarriertrade mark holding a volume of 1 microl/well. In addition to the good data quality, NPIAs are straightforward to perform because they require no washing steps. NPIAs open new dimensions for high throughput pharmaceutical screening and diagnostics. Assay development times can be reduced significantly because of a simple toolbox principle that is applicable to most types of assays.     

Signal amplification of electrochemical immunosensor for the detection of human serum IgG using double-codified nanosilica particles as labels

A simple and sensitive method for in situ amplified electrochemical immunoassay of human serum IgG has been developed by using double-codified nanosilica particles as labels based on horseradish peroxidase-doped nanosilica particles (HRP-SiO(2)) with the conjugation of anti-IgG antibodies (anti-IgG-SiO(2)-HRP). With the sandwich-type immunoassay format, the linear range of the developed immunosensor by using anti-IgG-SiO(2)-HRP as tracer and hydrogen peroxide (H(2)O(2)) as enzyme substrate is 0.01-15 nmol/L IgG with a detection limit of 5.0 pmol/L, while the assay sensitivity by directly using HRP-labeled anti-IgG as secondary antibodies is 1.0-10 nmol/L with a detection limit of 0.1 nmol/L IgG. The reproducibility, stability and specificity of the proposed immunoassay method were acceptable. The IgG concentrations of the clinical serum specimens assayed by the developed immunosensor show consistent results in comparison with those obtained by commercially available enzyme-linked immunosorbent assay (ELISA) method.     

A rapid method to improve protein detection by indirect ELISA

The enzyme-linked immunosorbant assay (ELISA) is a rapid, high-throughput, quantitative immunoassay for the selective detection of target antigens. The general principle behind an ELISA is antibody mediated capture and detection of an antigen with a measurable substrate. Numerous incarnations of the ELISA have resulted in its commercialization for sensitive diagnostic applications using a variety of detection platforms. Many of these applications require a pair of antibodies necessary for the capture and detection of a specific antigen (cELISA) in defined substrates. However, the availability of cELISA for target antigens is limited and thus restricts the use of this technique for quantitative measure of antigens during discovery. Alternatively, the indirect ELISA (iELISA) requires only a single antibody directed against a target antigen that has been immobilized to a surface. Unlike the cELISA, which uses an immobilized capture antibody that can bind a native antigen in solution followed by a detector antibody that binds captured antigen, the iELISA uses an antibody the binds directly to an immobilized antigen for detection. Although the iELISA may lack the sensitivity of a cELISA, its requirement of only a single antigen specific antibody makes it a simple technique for evaluating the relative difference in the level of target protein expression between samples. However, many antibodies that work effectively to detect protein antigens in other immunoassays such as Western blotting or immunohistochemistry fail to work in microplate based iELISA. Although these alternate immunoassay methods are useful for qualitative determination of target antigens, they provide limited quantitative information, limiting the assessment of sample specific differences in protein expression. We hypothesized that protein conformation following adsorption on the plastic surface of microplates impedes antibody epitope binding and this restriction could be overcome by a short chemical denaturation step. In this report we define a rapid method to assess the utility of an antibody for iELISA application and demonstrate a significant improvement in both qualitative and quantitative protein detection after chemical denaturation using defined assay conditions.     

Development of a sensitive ELISA for the quantification of human tumour necrosis factor-alpha using 4 polyclonal antibodies

Despite the availability of many assays to measure concentrations of tumour necrosis factor alpha (TNF-alpha) in body fluids, these assays often lack specificity or sensitivity and are often of questionable reliability, resulting in inconsistent results. Therefore, we have developed an ELISA that is sensitive, reliable and not susceptible to disturbances by interfering substances such as heterophilic antibodies. The assay involves a combination of four polyclonal antibodies. The antibodies, which capture the analyte, were raised in chicken and the trapping anti-analyte antibodies were raised in rabbit. The immobilization of capture antibodies was achieved via a coating antibody raised in a duck against chicken IgY and the recognition of trapping antibodies was achieved by a detection antibody raised in a goat against rabbit IgG and labelled with HRP. The analytical and functional sensitivities of the ELISA are 8 pg/mL and 13 pg/mL, respectively. The assay showed good precision and, in contrast to our in-house RIA, excellent parallelism in serial dilutions. The recovery of TNF-alpha spiked to plasma samples ranged from 97% to 119%. Comparison of the newly developed, sensitive ELISA with our in-house RIA showed that the median TNF-alpha value obtained by RIA (range: 0.095-10.0, median 0.578 ng/mL) was found to be 1.5-2 times higher than that obtained with the ELISA (range 0.008-5.84, median 0.213 ng/mL). Spearman correlation was 0.755 (p < 0.0001). In addition, analysis of the TNF-alpha concentrations in blood from healthy individuals and from patients suffering from tuberculosis, with RIA and ELISA, showed the same differences although TNF-alpha levels obtained with ELISA were lower. We feel that this ELISA is a major improvement compared to the currently available assays for TNF.     

Design and construction of novel molecular conjugates for signal amplification (I): conjugation of multiple horseradish peroxidase molecules to immunoglobulin via primary amines on lysine peptide chains

Immunoconjugates are widely used for indirect detection of analytes (such as antibodies or antigens) in a variety of immunoassays. However, the availability of functional groups such as primary amines or free sulfhydryls in an immunoglobulin molecule is the limiting factor for optimal conjugation and, therefore, determines the sensitivity of an assay. In the present study, an N-terminal bromoacetylated 20 amino acid peptide containing 20 lysine residues was conjugated to N-succinimidyl-S-acetylthioacetate (SATA)-modified IgG or free sulfhydryl groups on 2-mercaptoethylamine (2-MEA)-reduced IgG molecules via a thioether (S---CH₂CONH) linkage to introduce multiple reactive primary amines per IgG. These primary amines were then covalently coupled with maleimide-activated horseradish peroxidase (HRP). The poly-HRP–antibody conjugates thus generated demonstrated greater than 15-fold signal amplification upon reaction with orthophenyldiamine substrate. The poly-HRP–antibody conjugates efficiently detected human immunodeficiency virus (HIV)-1 antibodies in plasma specimens with significantly higher sensitivity than conventionally prepared HRP–antibody conjugates in an HIV-1 solid-phase enzyme immunoassay and Western blot analysis. The signal amplification techniques reported here could have the potential for development of highly sensitive immunodiagnostic assay systems.     

Highly sensitive detection of cocaine using a piezoelectric immunosensor

This paper describes the development of a highly sensitive competitive immunoassay with the piezoelectric sensor. The immobilized derivative of cocaine was benzoylecgonine-1,8-diamino-3,4-dioxaoctane (BZE-DADOO). For the immobilization of BZE-DADOO, the conjugate BZE-DADOO with 11-mercaptomonoundecanoic acid (MUA) was synthesized via 2-(5-norbornen-2,3-dicarboximide)-1,1,3,3-tetramethyluronium-tetrafluoroborate (TNTU), followed by the creation of the conjugate monolayer on the piezosensor electrodes. For the optimization of the competitive assay we used electrodes with rough or smooth gold areas and for the interaction with immobilized antigen different anti-cocaine sheep polyclonal (pAb, either whole IgG or Fab fragment) and mouse monoclonal (mAb, whole IgG) antibodies. The assay of cocaine developed achieved a detection limit (LOD) of 100 pmol/l (34 ng/l) using the sheep antibody (IgG) and piezoelectric sensors with a smooth gold surface. The total time of one analysis was 15 min and the measuring area of the sensor could be used more than 40 times without losing its sensitivity.     

Evaluation of a biosensor immunoassay for simultaneous characterization of isotype and binding region of human anti-tocilizumab antibodies with control by surrogate standards

This article describes the simultaneous Biacore analysis of human anti-human antibodies (HAHAs) with respect to the binding region and the isotype by a combination of 11 single measurements per sample. The multiplexing single assay setup made efficient use of the four parallel flow cells on one biosensor chip by immobilization of full-length antibody and its constant (Fc) and antigen binding (Fab) fragments for differential binding analysis of anti-drug antibodies (ADAs). Thereby, a complete time-specific immunogenicity profile (intensity, isotype, specificity, and kinetics) of a patient could be obtained by assessing the response patterns of serially collected samples analyzed in a single measurement run. The use of functionally active standard conjugates allowed control of the assay performance throughout the whole procedure. The positive control standard conjugates mimicking polyclonal human ADAs of different isotypes were obtained by conjugating polyclonal rabbit antibodies against the therapeutic antibody to human immunoglobulin (Ig) M, IgG, or IgE. In this article, the qualification of the assay is demonstrated and the application of the methodology to six representative rheumatoid arthritis patients treated with the therapeutic humanized IgG1 antibody tocilizumab (anti-IL-6R) is shown to illustrate the versatility of the assay. The presented method allows one to differentiate specific ADAs from drug-unspecific responses (e.g., rheumatoid factors). In addition, the method can be used to discriminate between isotype responses of the IgG, IgM, and IgE types and, thereby, allows one to describe the time course of specific ADA formation and its disappearance on the single patient level.