Immunogold signal amplification: Application of the CARD approach to electron microscopy.

Catalyzed reporter deposition (CARD) is a technique that allows amplification of routine immunolabeling in light microscopy. This procedure takes advantage of the horseradish peroxidase (HRP) from an HRP-avidin complex to catalyze the accumulation of reporter-conjugated tyramine (a phenolic compound) onto a surface displaying biotinylated antigen-antibody complexes. The large amount of labeled tyramine deposited allows the detection of an antigenic site with multiple reporter molecules. In this study we modified this amplification protocol to combine it with the immunogold technique for the ultrastructural localization of antigens in electron microscopy. We constructed various tyramide conjugates that permit the combination of this amplification method with a particulate colloidal gold marker. The new probes yield results of high specificity and enhanced intensity. Assessment of the level of resolution of the labeling has demonstrated that, in spite of the amplification, the resolution remains very good. Therefore, once associated, the immunogold and the CARD techniques lead to specific, high-resolution, sensitive and amplified signals that exhibit the advantages of both approaches.(J Histochem Cytochem 47:421-429, 1999)     

Introduction of a novel HRP substrate-Nanogold probe for signal amplification in immunocytochemistry.

Amplification of immunological signals with catalyzed reporter deposition (CARD) allows improved detection of scarce tissue antigens in light and electron microscopy. The technique takes advantage of the oxidation ability of horseradish peroxidase (HRP), in the presence of hydrogen peroxide, to yield the accumulation of one of its specific reporter-tagged substrates. This immunocytochemical approach continues to be improved by the introduction of new reporter molecules tagged to tyramine or to other HRP substrates. In this study we introduced a novel HRP substrate tagged to Nanogold particles. The amplification protocol is based on the application of a specific primary antibody, a biotinylated secondary antibody, streptavidin-HRP, and an HRP substrate coupled to Nanogold, followed by silver intensification. In addition to amplification of immunological signals of high resolution, direct accumulation of Nanogold particles at target sites by enzymatic activity of HRP improves the efficiency of the technique compared to other amplification protocols. Moreover, this approach combines the CARD amplification potentials with the ultrasmall gold probe and the silver intensification method. Immunolabeling obtained by light and electron microscopy, as well as immunodot assay using this new amplification strategy, appear to be highly sensitive, specific, and of enhanced intensity.     

A review of the potential and versatility of colloidal gold cytochemical labeling for molecular morphology.

In the present article we review several postembedding cytochemical techniques using the colloidal gold marker. Owing to the high atomic number of gold, the colloidal gold particles are electron dense. They are spherical in shape and can be prepared in sizes from 1 to 25 nm, which renders this marker among the best for electron microscopy. In addition, because it can be bound to several molecules, this marker has the advantage of being extremely versatile. Combined to immunoglobulins or immunoglobulin-binding proteins (protein A), it has been applied successfully in immunocytochemistry. Colloidal gold particles 5-15 nm in size are excellent for postembedding cytochemistry. Particles of smaller size, such as 1 nm, must be silver enhanced to be visualized by transmission electron microscopy. We have elected to review the superiority of indirect immunocytochemical approaches using IgG-gold or protein A-gold (protein G-gold and protein AG-gold). Lectins or enzymes can be tagged with colloidal gold particles, and the corresponding lectin-gold and enzyme-gold techniques have specific advantages and great potential. Using an indirect digoxigenin-tagged nucleotide and an antidigoxigenin probe, colloidal gold technology can also be used for in situ hybridization at the electron microscope level. Affinity characteristics lie behind all cytochemical techniques and several molecules displaying high affinity properties can also be beneficial for colloidal gold electron microscopy cytochemistry. All of these techniques can be combined in various ways to produce multiple labelings of several binding sites on the same tissue section. Colloidal gold is particulate and can easily be counted; thus the cytochemical signal can be evaluated quantitatively, introducing further advantages to the use of the colloidal gold marker. Finally, several combinations and multiple step procedures have been designed to amplify the final signal which renders the techniques more sensitive. The approaches reviewed here have been applied successfully in different fields of cell and molecular biology, cell pathology, plant biology and pathology, microbiology and virology. The potential of the approaches is emphasized in addition to different ways to assess specificity, sensitivity and accuracy of results.     

A Review of the Potential and Versatility of Colloidal Gold Cytochemical Labeling for Molecular Morphology

In the present article we review several postembedding cytochemical techniques using the colloidal gold marker. Owing to the high atomic number of gold, the colloidal gold particles are electron dense. They are spherical in shape and can be prepared in sizes from 1 to 25 nm, which renders this marker among the best for electron microscopy. In addition, because it can be bound to several molecules, this marker has the advantage of being extremely versatile. Combined to immunoglobulins or immunoglobulin-binding proteins (protein A), it has been applied successfully in immunocytochemistry. Colloidal gold particles 5–15 nm in size are excellent for postembedding cytochemistry. Particles of smaller size, such as 1 nm, must be silver enhanced to be visualized by transmission electron microscopy. We have elected to review the superiority of indirect immunocytochemical approaches using IgG-gold or protein A-gold (protein G-gold and protein AG-gold). Lectins or enzymes can be tagged with colloidal gold particles, and the corresponding lectin-gold and enzyme-gold techniques have specific advantages and great potential. Using an indirect digoxigenin-tagged nucleotide and an antidigoxigenin probe, colloidal gold technology can also be used for in situ hybridization at the electron microscope level. Affinity characteristics lie behind all cytochemical techniques and several molecules displaying high affinity properties can also be beneficial for colloidal gold electron microscopy cytochemistry. All of these techniques can be combined in various ways to produce multiple labelings of several binding sites on the same tissue section. Colloidal gold is particulate and can easily be counted; thus the cytochemical signal can be evaluated quantitatively, introducing further advantages to the use of the colloidal gold marker. Finally, several combinations and multiple step procedures have been designed to amplify the final signal which renders the techniques more sensitive. The approaches reviewed here have been applied successfully in different fields of cell and molecular biology, cell pathology, plant biology and pathology, microbiology and virology. The potential of the approaches is emphasized in addition to different ways to assess specificity, sensitivity and accuracy of results.     

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.     

Immunofluorescence signal amplification by the enzyme-catalyzed deposition of a fluorescent reporter substrate (CARD)

Progress has been made in improving the immunohistochemical detection of antigens for imaging and flow cytometry. We report the synthesis of a novel fluorescent horseradish peroxidase substrate, Cy3.29-tyramide, and its application in an enzyme-based signal amplification system, catalyzed reporter deposition (CARD). The catalyzed deposition of Cy3.29-tyramide was used to detect cell surface markers such as CD8 and CD25 on tonsil tissue and human lymphocytes. We compared the fluorescence CARD method to standard indirect immunofluorescence detection methods and found that an amplification of up to 15-fold was possible with CARD. The detection of the intracellular protein myosin II in fibroblastic cells and rabbit serum proteins blotted onto nitrocellulose was also improved. Thus, fluorescent CARD is a simple modification that can be made to standard immunofluorescence staining protocols to enhance significantly the detection of antigens.     

Amplification methods to increase the sensitivity of in situ hybridization: play card(s).

In situ hybridization (ISH) has proved to be an invaluable molecular tool in research and diagnosis to visualize nucleic acids in their cellular environment. However, its applicability can be limited by its restricted detection sensitivity. During the past 10 years, several strategies have been developed to improve the threshold levels of nucleic acid detection in situ by amplification of either target nucleic acid sequences before ISH (e.g., in situ PCR) or the detection signals after the hybridization procedures. Here we outline the principles of tyramide signal amplification using the catalyzed reporter deposition (CARD) technique, present practical suggestions to efficiently enhance the sensitivity of ISH with CARD, and discuss some applications and possible future directions of in situ nucleic acid detection using such an amplification strategy.     

Amplification of antigen-antibody interactions based on biotin labeled protein-streptavidin network complex using impedance spectroscopy.

Antibody was covalently immobilized by amine coupling method to gold surfaces modified with a self-assembled monolayer of thioctic acid. The electrochemical measurements of cyclic voltammetry and impedance spectroscopy showed that the hexacyanoferrate redox reactions on the gold surface were blocked due to the procedures of self-assembly of thioctic acid and antibody immobilization. The binding of a specific antigen to antibody recognition layer could be detected by measurements of the impedance change. A new amplification strategy was introduced for improving the sensitivity of impedance measurements using biotin labeled protein-streptavidin network complex. This amplification strategy is based on the construction of a molecular complex between streptavidin and biotin labeled protein. This complex can be formed in a cross-linking network of molecules so that the amplification of response signal will be realized due to the big molecular size of complex. The results show that this amplification strategy causes dramatic improvement of the detection sensitivity of hIgG and has good correlation for detection of hIgG in the range of 2-10 microg/ml.     

Post-embedding double-labeling of antigen-retrieved ultrathin sections using a silver enhancement-controlled sequential immunogold (SECSI) technique.

In electron microscopy, the post-embedding immunogold technique provides a high degree of resolution and the possibility of quantitation owing to the intrinsic characteristics of the colloidal gold marker. Application of this technique to the subcellular localization of multiple antigens by differential labeling using gold markers of different sizes, or to double labeling using the same primary antibody isotype with serial silver enhancement, has been reported. We have incorporated this double labeling technique into a modified procedure that produces excellent labeling and ultrastructural preservation, even after exposure of ultrathin sections large enough to cover a 300- micro m-diameter single-hole grid to hot antigen retrieval solutions and prolonged labeling protocols.     

Biotin amplification of biotin and horseradish peroxidase signals in histochemical stains.

A procedure is described for intensifying histochemical reactions by amplification of biotinylated sites. This is achieved by deposition of biotinylated tyramine on the tissue through the enzymatic action of horseradish peroxidase (HRP). The amplified biotin sites are subsequently visualized by binding them to avidin, to which a marker is attached. This amplification greatly increases the sensitivity of staining procedures that employ HRP (and/or biotin) in tissue. For neuroanatomical pathway tracing methods, the procedure greatly increases the detectability of the injected tracer. For lectin histochemistry and immunohistochemistry, the amplification requires that the lectin or primary antibody be greatly diluted. This dilution results in less background staining and yet strong signals are produced even when very dilute reagents are used. Alternatively, the amplification permits much shorter incubations in primary antibodies when dilutions are used that would ordinarily be used with conventional bridge techniques. The procedure is also useful for amplifying very weak signals, such as those of immunoreactions in glutaraldehyde-fixed tissue. The amplification procedure, together with the availability of avidin probes labeled with fluorochromes, colloidal gold, or enzyme systems other than HRP, provides a means of greatly increasing the versatility of a variety of histochemical reactions, including those for detecting in situ hybridization probes, in addition to increasing the sensitivity of the reactions.     

Cytochemical detection systems for in situ hybridization, and the combination with immunocytochemistry. ‘Who is still afraid of red, green and blue?’

Summary An overview is given of the different non-radioactive cytochemical detection methodologies that are currently utilized to localize nucleic acid sequences in chromosomes, cells and tissue sections. Dependent on the reporter molecule (fluorochrome, enzyme or hapten) that is used to modify the appropriate nucleic acid probe, and the sensitivity that is required, the in situ hybridized sequences can be detected either directly after hybridization or indirectly, using cytochemical detection and amplification layers. These may then contain antibody and/or avidin molecules conjugated to fluorochromes, enzymes or colloidial gold particles. Since the choice of a suitable probe-labelling method in combination with a fluorescence, enzyme cytochemical or immunogold-silver detection procedure is often determined by the user's own practical experience and applications, the different detection methodologies are compared with each other in detail with respect to sensitivity, resolution, applicability for multiple probe detection, and signal evaluation. Furthermore, procedures are reviewed for the combination of in situ hybridization with immunocytochemical detection of proteins and/or incorporated bromodeoxyuridine, which allow the simultaneous visualization of genomic phenotypic and/or cell cycle parameters in the same sample. Possible improvements with respect to sensitivity, specificity and multiplicity of the detection methods, which may be interesting for one's own experimental design, are finally being discussed.     

Nanoparticle labels in immunosensing using optical detection methods

Efforts to improve the performance of immunoassays and immunosensors by incorporating different kinds of nanostructures have gained considerable momentum over the last decade. Apart from liposomes, which will not be discussed here, most groups focus on artificial, particulate marker systems, both organic and inorganic. The underlying detection procedures may be based either on electro-magnetical or optical techniques. This review will be confined to the latter only, comprising nanoparticle applications generating signals as diverse as static and time-resolved luminescence, one- and two-photon absorption, Raman and Rayleigh scattering as well as surface plasmon resonance and others. In general, all endeavors cited are geared to achieve one or more of the following goals: lowering of detection limits (if possible, down to single-molecule level), parallel integration of multiple signals (multiplexing), signal amplification by several orders of magnitude and prevention of photobleaching effects with concomitant maintenance of antigen binding specificity and sensitivity. Inorganic nanoparticle labels based on noble metals, semiconductor quantum dots and nanoshells appear to be the most versatile systems for these bioanalytical applications of nanophotonics.     

Application of the FITC-anti-FITC-gold system to ultrastructural localization of antigens

We report the application of a fluorescein isothiocyanate (FITC)-anti-FITC method to localize antigens at the ultrastructural level. In the systems studied, the anti-FITC-based detection method displays high specificity and sensitivity. These observations, combined with ease of production and with availability of FITC-protein conjugates, suggest that the FITC-anti-FITC method is a good alternative to presently used methods and is widely applicable to immunochemical and immunocytochemical procedures. The same preparation and protocol can be used for light and electron microscopic studies, thereby reducing possible artifacts introduced if different procedures are used. In the present study, two systems were used to test the method. One system used an FITC-labeled monoclonal antibody (MAb) to schistosome circulating cathodic antigen. In this system, the label was detected in the gut of adult Schistosoma mansoni by an anti-FITC MAb conjugated to 10-nm gold particles. The second system used human IgM antibodies pooled from patients infected with Schistosoma mansoni. In this system detection was accomplished using an anti-human IgM-FITC conjugate followed by the anti-FITC-Au antibody conjugate.     

Ferrocenemonocarboxylic-HRP@Pt nanoparticles labeled RCA for multiple amplification of electro-immunosensing

A multiple amplification immunoassay was proposed to detect alpha-fetoprotein (AFP), which was based on ferrocenemonocarboxylic-HRP conjugated on Pt nanoparticles as labels for rolling circle amplification (RCA). Firstly, the capture antibody (anti-AFP) was immobilized on glass carbon electrode (GCE) deposited nano-sized gold particles. After a typical immuno-sandwich protocol, primary DNA was immobilized by labeling secondary antibody, which acted as a precursor to initiate RCA. The products of RCA provide large amount of sites to link detection DNAs, which were labeled by signal probes (ferrocenemonocarboxylic) and horseradish peroxidase (HRP). Moreover, the enzymatic amplification signals could be produced by the catalysis of HRP and Pt nanoparticles with the addition of H?O?. These lead to multiple amplification signals monitoring by electrochemical instrument and further resulted in high sensitivity of the immunoassay with the detection limit of 1.7 pg/mL.     

New techniques in rapid viral diagnosis

Abstract The development of new diagnostic techniques in immunology and molecular biology during the last two decades has opened up new possibilities for rapid viral diagnosis. Solid phase immunoassays for antigen and antibody detection are now widely used in diagnostic settings. Several novel techniques have been introduced and have led to commercially available tests. Diagnostic methods using nucleic acid amplification procedures are already applied in research laboratories and will be commercialized soon. Biosensor-based diagnostic techniques have the potential of generating a result nearly instantaneously and it has become possible to monitor kinetic processes. Automatization and simplified procedures are needed to allow diagnostic tests to be performed soon after the sample has been obtained from the patient. In order to evaluate the new procedures and avoid false results, rigorous quality control in diagnostic virology will have to be instituted.     

Immunosensor with a controlled orientation of antibodies by using NeutrAvidin-protein A complex at immunoaffinity layer

The orientation of antibody was controlled by using NeutrAvidin-protein A complex on the gold surface of SPR biosensor. The surface density of receptor antibody (anti-hIgG) was compared by treatment of receptor antibody to the layer of avidin, NeutrAvidin, protein A, NeutrAvidin-protein A complex and bare gold surface of SPR biosensor. The ligand antibody (hIgG) was injected to each IA layer and the binding ratio of ligand antibody per unit receptor was estimated as a parameter of orientation control. The NeutrAvidin-protein A complex on gold surface of SPR biosensor showed the highest surface density of receptor antibody as well as the binding ratio of ligand antibody per receptor antibody. The NeutrAvidin-protein A complex was also prepared on biotin-labelled SAM, and the binding ratio of ligand per receptor was found to be significantly improved in comparison to the IA layer prepared by chemical coupling of receptor antibody to the SAM layer. The NeutrAvidin-protein A complex which showed the highest efficiency for the binding of ligand antibodies, was applied for the detection of a cancer marker called CEA. By using NeutrAvidin-protein A complex and sandwich assay for signal amplification, sensitivity was improved to be 1.5-fold higher than bare gold surface and the detection of CEA with the detection limit of 30 ng/ml was achieved.     

Dual signal amplification of surface plasmon resonance imaging for sensitive immunoassay of tumor marker

Surface plasmon resonance imaging (SPRi) is an intriguing technique for immunoassay with the inherent advantages of being high throughput, real time, and label free, but its sensitivity needs essential improvement for practical applications. Here, we report a dual signal amplification strategy using functional gold nanoparticles (AuNPs) followed by on-chip atom transfer radical polymerization (ATRP) for sensitive SPRi immunoassay of tumor biomarker in human serum. The AuNPs are grafted with an initiator of ATRP as well as a recognition antibody, where the antibody directs the specific binding of functional AuNPs onto the SPRi sensing surface to form immunocomplexes for first signal amplification and the initiator allows for on-chip ATRP of 2-hydroxyethyl methacrylate (HEMA) from the AuNPs to further enhance the SPRi signal. High sensitivity and broad dynamic range are achieved with this dual signal amplification strategy for detection of a model tumor marker, α-fetoprotein (AFP), in 10% human serum.     

High and intermediate grade ductal carcinoma in-situ of the breast: a comparison of pathologic features in core biopsies and excisions and an evaluation of core biopsy features that may predict a close or positive margin in the excision

It has been more than 50 years since antinuclear antibodies were first discovered and found to be associated with connective tissue diseases. Since then different methods have been described and used for their detection or confirmation. For many decades immunofluorescent antinuclear antibody test has been the "gold standard" in the diagnosis of these disorders. However to increase the sensitivity and specificity of antinuclear antibody detection further approaches were explored. Today a battery of newer techniques are available some of which are now considered better and are competing with the older methods. This article provides an overview on advancement in antinuclear antibody detection methods, their future prospects, advantages, disadvantages and guidelines for use of these tests.     

Gold nanoparticle probe-based gene expression analysis with unamplified total human RNA

Microarray-based gene expression analysis plays a pivotal role in modern biology and is poised to enter the field of molecular diagnostics. Current microarray-based gene expression systems typically require enzymatic conversion of mRNA into labeled cDNA or cRNA. Conversion to cRNA involves a target amplification step that overcomes the low sensitivity associated with commonly used fluorescent detection methods. Herein, we present a novel enzyme-free, microarray-based gene expression system that uses unamplified total human RNA sample as the target nucleic acid. The detection of microarray-bound RNA molecules is accomplished by targeting the poly-A tail with an oligo-dT₂₀ modified gold nanoparticle probe, signal amplification by autometallography, and subsequent measurement of nanoparticle-mediated light scattering. The high sensitivity afforded by the nanoparticle probes allows differential gene expression from as little as 0.5 μg unamplified total human RNA in a 2 h hybridization without the need for elaborate sample labeling steps.     

Sensitive Immunofluorescent Staining of Cells via Generation of Fluorescent Nanoscale Polymer Films in Response to Biorecognition

Immunofluorescent staining is central to nearly all cell-based research, yet only a few fluorescent signal amplification approaches for cell staining exist, each with distinct limitations. Here, the authors present a novel, fluorescent polymerization-based amplification (FPBA) method that is shown to enable similar signal intensities as the highly sensitive, enzyme-based tyramide signal amplification (TSA) approach. Being non-enzymatic, FPBA is not expected to suffer from nonspecific staining of endogenous enzymes, as occurs with enzyme-based approaches. FPBA employs probes labeled with photopolymerization initiators, which lead to the controlled formation of fluorescent polymer films only at targeted biorecognition sites. Nuclear pore complex proteins (NPCs; in membranes), vimentin (in filaments), and von Willebrand factor (in granules) were all successfully immunostained by FPBA. Also, FPBA was demonstrated to be capable of multicolor immunostaining of multiple antigens. To assess relative sensitivity, decreasing concentrations of anti-NPC antibody were used, indicating that both FPBA and TSA stained NPC down to a 1:100,000 dilution. Nonspecific, cytoplasmic signal resulting from NPC staining was found to be reduced up to 5.5-fold in FPBA as compared to TSA, demonstrating better signal localization with FPBA. FPBA’s unique approach affords a combination of preferred attributes, including high sensitivity and specificity not otherwise available with current techniques.