Glucose oxidase as label in histological immunoassays with enzyme-amplification in a two-step technique: coimmobilized horseradish peroxidase as secondary system enzyme for chromogen oxidation

A sensitive staining procedure for glucose oxidase (GOD) as marker in immunohistology is described. The cytochemical procedure involves a two-step enzyme method in which GOD and horseradish peroxidase (HRP) are coimmobilized onto the same cellular sites by immunological bridging or by the principle of avidin-biotin interaction. In this coupled enzyme technique, H2O2 generated during GOD reaction is the substrate for HRP and is utilized for the oxidation of chromogens such as 3,3'-diaminobenzidine or 3-amino-9-ethylcarbazole. Due to the immobilization of the capture enzyme HRP in close proximity to the marker enzyme (GOD), more intense and specific staining is produced than can be obtained with soluble HRP as coupling enzyme in the substrate medium. Indirect antibody labelled and antibody bridge techniques including the avidin (streptavidin)-biotin principle have proven the usefulness of this GOD labelling procedure for antigen localization in paraffin sections. Antigens such as IgA in tonsil, alpha-fetoprotein in liver and tissue polypeptide antigen in mammary gland served as models. The immobilized two-step enzyme procedures have the same order of sensitivity and specificity as comparable immunoperoxidase methods. The coupled GOD-HRP principle can be superior to conventional immunoperoxidase labelling for the localization of biomolecules in tissue preparations rich in endogenous peroxidase activities.     

Paired indirect immunoenzyme staining with primary antibodies from the same species. Application of horseradish peroxidase and alkaline phosphatase as sequential labels

Summary Paired indirect immunoenzyme staining based on primary antisera from the same species was performed sequentially without intermediate antibody elution. The first antigen was labelled brown by an immunoperoxidase procedure (either the two-stage indirect method, the unlabelled antibody peroxidase-antiperoxidase method, or the avidin-biotin bridge method using diaminobenzidine (DAB) and hydrogen peroxide as the substrates. The second antigen was labelled blue by applying a two-stage indirect immuno-alkaline phosphatase procedure using naphthol AS phosphate and Fast Blue BB salt as the substrate. In this way, polyclonal mucosal immunocytes were revealed in distinctly contrasting colours when stained for and light chains. Glucagon and somatostatin (D) cells in human pancreatic islets, and gastrin and D cells in human gastric antral glands, were likewise clearly differentiated. Conversely, a mixed colour appeared in some immunocytes after staining for and chains. However, unbalanced colour mixing was sometimes difficult to interpret, and additional experiments demonstrated that unwanted interactions could take place between the two sequences of reagents if the density of the DAB deposits was insufficient. These pitfalls were incompatible with unequivocal double staining in the same cell. Nevertheless, paired staining could be conveniently applied with the described procedures when prior knowledge had established that the antigens in question were located in separate cells.     

Direct immunocytochemistry with a horseradish peroxidase-conjugated monoclonal antibody against substance P

The procedure for the isolation and conjugation of the anti-substance P monoclonal antibody NC1/34 with the enzyme horseradish peroxidase (HRP) is described. This resulted in a molecular complex of monoclonal antibody/HRP of 1:1. This conjugate was of approximately 400,000 daltons, as estimated by gel chromatography. Practically all the isolated antibody was coupled to HRP. The conjugate was tested both in a model system where CNBr-activated Sepharose beads were coupled to substance P and on fixed tissue preparations from the rat spinal cord and medulla oblongata. The conjugate revealed staining in nerve fibers in areas known to contain substance P. The best immunohistochemical results were obtained by prolonged incubations at 12 degrees C in the presence of 0.1% Triton X-100. The preabsorption of the conjugate with substance P obliterated the reaction.     

Method for Whole Mount Antibody Staining in Chick

The chick embryo is a valuable tool in the study of early embryonic development. Its transparency, accessibility and ease of manipulation, make it an ideal tool for studying antibody expression in developing brain, neural tube and somite. This video demonstrates the different steps in whole-mount antibody staining using HRP conjugated secondary antibodies; First, the embryo is dissected from the egg and fixed in paraformaldehyde. Second, endogenous peroxidase is inactivated; The embryo is then exposed to primary antibody. After several washes, the embryo is incubated with secondary antibody conjugated to HRP. Peroxidase activity is revealed using reaction with diaminobenzidine substrate. Finally, the embryo is fixed and processed for photography and sectioning. The advantage of this method over the use of fluorescent antibodies is that embryos can be processed for wax sectioning, thus enabling the study of antigen sites in cross section. This method was originally introduced by Jane Dodd and Tom Jessell ¹.Open in a separate windowClick here to view.^{(64M, flv)}     

Simultaneous ultrastructural demonstration of retrogradely transported horseradish peroxidase and choline acetyltransferase immunoreactivity

Summary In order to study the synaptic connections of neurons identified by their projection target and neurotransmitter content, we have adapted a method of combining retrograde tracing of horseradish peroxidase (HRP) and immunocytochemistry at the electron microscopic level. HRP was injected into the rat amygdala. Sections from the rostral forebrain were processed according to the 3,3-diaminobenzidine/glucose oxidase reaction followed by choline acetyltransferase (ChAT) localization. Neurons in the ventral pallidum which contained both the diffuse immunoperoxidase reaction product (ChAT) and large electron dense bodies characteristic of retrogradely transported HRP were defined as double labeled, i.e. cholinergic neurons that project to the amygdaloid body.     

The labeled antigen method of immunoenzymatic staining.

A two stage immunohistological technique (the "labeled antigen" procedure) has been assessed for the detection of a variety of human and animal cytoplasmic constituents in tissue sections. In this method specific antiserum is followed by antigen complexed to horseradish peroxidase or to alkaline phosphatase. The primary antibody acts bivalently, linking the labeled antigen to antigen in the tissue section. The major advantage of this technique is that nonantigen specific antibody in the primary antiserum cannot cause nonspecific staining since it has no affinity for the antigen:enzyme complex. Consequently the specificity of the reaction is assured, background staining is minimized and the total staining time (from wax section to mounted slide) can be reduced to as little as 30 min. Further advantages include the possibility of labeling Ig allotypes and the high efficiency of enzyme utilization. Covalent human IgG:horseradish peroxidase complexes can also be used in a triple sandwich in conjunction with human anti-viral or autoimmune antibodies.     

A modified immunohistochemical procedure for the detection of estrogen receptor in mouse tissues

Summary A horseradish peroxidase (HRP) labeled antibody method was developed for use with a monoclonal antibody to detect estrogen receptor (ER) in mouse tissue. Combined use of HRP labeled F(ab)₂ fragment absorbed with mouse liver protein to minimize background staining and imidazol-DAB reaction gave the most reliable and sensitive immunostaining.The method was applied to uterine, vaginal, pituitary and liver tissues in ovariectomized adult mice. In uterus and vagina, ER was recognized in nuclei of epithelial cells, stromal cells and smooth muscle cells of the muscle layer and blood vessels. Liver tissue showed positive nuclear immunostaining in parenchymal cells; however, no reaction was present in endothelial cells, Kupffer cells, bile ductal cells, and smooth muscle cells of blood vessels. ER was localized in the nuclei of anterior pituitary cells while weak reaction was also recognized in cells of the intermediate lobe. No staining was detected in the posterior pituitary.Results demonstrate that both occupied and unoccupied ER are localized in the cell nucleus from several target tissues. Weak immunostaining in samples could not be enhanced by multiple procedures. It is suggested that nuclear ER is partially hidden by nuclear components such as nuclei acid and chromatin proteins.     

A new homogeneous enzyme immunoassay. Its application to measurement of alpha-fetoprotein

A rapid and sensitive homogeneous enzyme immunoassay (homogeneous EIA) was developed for determination of serum proteins such as alpha-fetoprotein (AFP). There are two assay systems, one is a competitive system including horseradish peroxidase (HRP)-labeled antigen, antibody and substrate, and the other is a non-competitive system including HRP-labeled antibody and substrate. When the aggregate was formed through the binding of HRP-labeled AFP and anti-AFP antibody or through the binding of HRP-labeled anti-AFP antibody and AFP, HRP of the aggregates, as compared with HRP of free conjugates, exhibited marked activity in the presence of 35 mM H2O2. The extent of stimulation of HRP activity depended on the amount of AFP. This new assay method is very simple and sensitive, and can be used for the determination of any kind of protein, hormone, or drug.     

Ultrastructural localization of the maltose-binding protein within the cell envelope of Escherichia coli

Logarithmically growing cells of Escherichia coli were fixed with glutaraldehyde and incubated with antimaltose-binding protein F_ab coupled to horseradish peroxidase (molecular weight of the complex 80,000). The position of this complex within the cell envelope was determined by reacting with diaminobenzidine-H₂O₂, staining with osmium tetroxide and processing for thin section electron microscopy. The following observations were made: (i) induction of the maltose-binding protein resulted in swelling and staining of the outer membrane; (ii) the swelling and staining was more prominent in short cells, less prominent or absent in long cells; (iii) rare examples exhibited granular staining in the space between the plasma membrane and the peptidoglycan layer. These stainings were observable mainly in pole caps; (iv) a mutant lacking the receptor for phage showed altered staining pattern. Treatment of glutaraldehyde-fixed cells with EDTA-lysozyme prevented the specific labelling of the maltose-binding protein.Lists of Non Common Abbreviations MBP maltose-binding protein - MBP-F_ab)-HRPO F_ab fragments against maltose-binding, protein coupled to horseradish peroxidase - IgG immunoglobulin - PBS pnosphate buffered saline     

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.     

A reliable method combining horseradish peroxidase histochemistry with immuno-beta-galactosidase staining

A sensitive combination of horseradish peroxidase (HRP) tracing and immunohistochemistry was used by Rye et al. [J Histochem Cytochem (1984) 32:1145] in a search for the origins of neurotransmitter- and neuromodulator-containing nerve fibers in brain. In this combination, peroxidase as a marker in immunohistochemistry was thought to yield a homogeneous brown immunoreaction product of diaminobenzidine, different from the black granular reaction product of retrogradely transported HRP, which is visualized by the tetramethylbenzidine (TMB) reaction and subsequent stabilization. A neuron that exhibits both kinds of reaction products in its cytoplasm in sections subjected to combination staining is referred to as a double-labeled cell. With a combined HRP and corticotropin-releasing factor (CRF) immunoperoxidase-antiperoxidase (PAP) method, the first set of experiments showed "false" double-labeled cells in the pyramidal cell layer of rat cerebral cortex, but only rarely in the subcortical areas, possibly because of the use of one enzyme system in two different histochemical procedures. This limitation of the double-staining technique prompted us to demonstrate an alternate combination of HRP tracing and immunohistochemistry in the second set of experiments by employing two previously described independent enzyme systems: HRP as a retrograde tracer and beta-galactosidase as a marker for immunohistochemical demonstration of CRF. A homogeneous blue reaction product indicated immuno-beta-galactosidase staining, and a granular black or brown reaction product labeled retrogradely transported HRP in double-labeled cells in subcortical regions. Neither double labeling nor "false" double labeling was seen in pyramidal cells of cerebral cortex. These findings suggest that application of two independent enzyme systems in a combined HRP and immunohistochemical method may be useful for investigating in origins of peptidergic fibers in brain when the combination of HRP histochemistry and the PAP method appears to be inappropriate.     

Localization of tartrate-resistant acid phosphatase in human placenta

Summary Tartrate-resistant acid phosphatase is an inducible marker of cell differentiation and activation expressed by specialized cells of macrophage lineage and some activated lymphocytes. Clinically, this phosphatase is a diagnostic marker for hairy cell leukaemia and osteoclast activity. The cDNA for this enzyme has been cloned from a placental expression library, yet the cell(s) expressing the enzyme protein has not been determined with certainty. Our laboratories have developed a monoclonal antibody, 9C5, suitable for immunohistochemical localization of tartrate-resistant acid phosphatase in paraffin sections. The purpose of this study was to use antibody 9C5 to identify cells expressing tartrate-resistant acid phosphatase in sections of paraffin-embedded, normal, full-term placenta and to determine if those cells expressed other macrophage markers including CD68(PG-M1 antibody), LN5, lysozyme ₁-antitrypsin and ₁-antichymotrypsin. Histochemical localization of activity in frozen sections was compared with immunohistochemical localization in paraffin sections of the same tissue specimens. The activity and antigenicity of this enzyme were detected in decidual cells, syncytiotrophoblast, and some macrophages distributed throughout maternal and embryonic tissues, but not in neutrophils. Unlike other tissues previously examined, placenta contains significant numbers of the phosphate-positive cells that are not of macrophage origin.     

Sensitivity and efficiency of four immunohistochemical methods as defined by staining of artificial sections

Direct (DIF) and indirect (IIF) immunofluorescence, indirect immunoperoxidase conjugate (IPC) and unlabelled antibody peroxidase antiperoxidase (PAP) staining was performed on sections of artificial substrate containing different concentrations of human immunoglobulin (Ig)A or IgG. Detection sensitivity, in terms of the lowest amount of discernible antigen, was evaluated by direct microscopy and by microphotometry. Staining efficiency (signal-to-noise ratio) was evaluated by microphotometry. Only minor differences in antigen detection sensitivity were found when IPC and PAP were compared with DIF and IIF under appropriate conditions. The sensitivity of DIF was only marginally improved by raised conjugate concentration and prolonged incubation time. Microphotometry of DIF on ethanol-fixed IgA substrate revealed that the staining intensity increased proportionally with the antigen concentration whereas on formaldehyde-fixed substrate a progressive masking of the antigen was indicated which, however, could be overcome by applying raised conjugate concentration and prolonged incubation time. Such antigenic self masking was of relatively little importance to IPC and PAP staining, probably because of the inherent amplification in these methods. An additional masking effect due to extraneous protein was revealed by DIF when ethanol-fixed sections had been soaked in bovine serum albumin and postfixed with formaldehyde; unmasking was achieved by proteolytic treatment of the sections.     

A Double Staining Technique using 5-Bromo,4-chloro-3-indolyl-β-D- galactopyranoside (X-gal) and Immunoperoxidase in Whole Drosophila Embryos

We have developed a double staining method using 5-bromo,4-chloro-3-indolyl-β-D-galactopyranoside X-gal and immunoperoxidase for whole Drosophila embryos. The dechorionated embryos are fixed in heptane saturated with 4% formaldehyde, then in heptane and 50% methanol. Fixed embryos are devitellinized with a tungsten needle and processed for immunoperoxidase staining immediately prior to peroxidase color development. The embryos are stained with X-gal, then peroxidase staining is resumed. This procedure enables us to observe cells stained with both X-gal and a specific antibody in whole embryos.     

Double-enzyme conjugates, producing an intermediate color, for simultaneous and direct detection of three different intracellular immunoglobulin determinants with only two enzymes

A new double-enzyme conjugate was synthesized by coupling alkaline phosphatase (AP) to horseradish peroxidase (HRP). After AP (blue) and subsequent HRP (red) cytochemistry, this new conjugate produced a stable intermediate-colored (violet) product. By coupling this double-enzyme conjugate to an antigen (trinitrophenyl, TNP) or an antibody (anti-mouse immunoglobulin G2a), anti-TNP or -IgG2a-producing cells could be demonstrated as violet cells in spleen sections. This led to the development of a rapid one-step incubation--two-step cytochemical procedure for simultaneous detection of three different determinants in a single tissue section. To demonstrate this novel triple staining method, we coupled three different antigens to, respectively, AP, HRP, and AP-HRP. When spleen sections of immunized animals were incubated with a mixture of these three antigen-enzyme conjugates, we could distinguish antibody-forming cells against each of these three antigens simultaneously as red (HRP), blue (AP), and violet (AP-HRP) cells. The simultaneous detection of three different classes of intracellular antibodies in a single section also proved to be possible with this method. With this study we provide a new direct method for detection of three different intracellular immunoglobulins after a one-step incubation and a two-step standard cytochemical procedure.     

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.     

Sensitivity and efficiency of four immunohistochemical methods as defined by staining of artificial sections

Summary Direct (DIF) and indirect (IIF) immunofluorescence, indirect immunoperoxidase conjugate (IPC) and unlabelled antibody peroxidase antiperoxidase (PAP) staining was performed on sections of artificial substrate containing different concentrations of human immunoglobulin (Ig)A or IgG. Detection sensitivity, in terms of the lowest amount of discernible antigen, was evaluated by direct microscopy and by microphotometry. Staining efficiency (signal-to-noise ratio) was evaluated by microphotometry. Only minor differences in antigen detection sensitivity were found when IPC and PAP were compared with DIF and IIF under appropriate conditions. The sensitivity of DIF was only marignally improved by raised conjugate concentration and prolonged incubation time. Microphotometry of DIF on ethanol-fixed IgA substrate revealed that the staining intensity increased proportionally with the antigen concentration whereas on formaldehyde-fixed substrate a progressive masking of the antigen was indicated which, however, could be overcome by applying raised conjugate concentration and prolonged incubation time. Such antigenic self masking was of relatively little importance to IPC and PAP staining, probably because of the inherent amplification in these methods. An additional masking effect due to extraneous protein was revealed by DIF when ethanol-fixed sections had been soaked in bovine serum albumin and postfixed with formaldehyde; unmasking was achieved by proteolytic treatment of the sections.This work was supported by the Norwegian Cancer Society, the Norwegian Research Council for Science and the Humanities, and Anders Jahres Foundation     

An ultrastructural double-labelling method: immunohistochemical localization of cell adhesion molecule L1 on HRP-labelled developing corticospinal tract axons in the rat

A double electronmicroscopical (EM) staining was developed which enabled the ultrastructural localization of cell adhesion molecules on the outer axonal membrane of horseradish peroxidase (HRP)-labelled axons in the developing central nervous system (CNS). HRP was used to anterogradely trace outgrowing corticospinal tract (CST) axons in ten-day-old rats. After visualization of HRP using tetramethylbenzidine (TMB) as a chromogen and ammoniumheptamolybdate (AHM) as a stabilizer at pH 6.0 as described previously (Joosten et al. 1987, J Histochem Cytochem 35: 623-626) an additional diaminobenzindine (DAB)-Ni incubation was carried out for further stabilization. Subsequently a preembedding immunoperoxidase (DAB) staining was executed for detection of cell adhesion molecule L1. Using this procedure anterogradely HRP-labelled CST axons were recognizable by a granular black TMB-AHM-DABNi reaction product at the light microscopic (LM) level, which clearly contrasts to the relatively homogeneous brown L1-immunostaining. Electronmicroscopically HRP-labelled CST axons were characterized by the presence of an intracellular crystaloid TMB-AHM-DABNi reaction product which made identification of CST axons rather easy, whereas the L1-DAB precipitate could be noted on the outer axonal membrane of the HRP-labelled CST axons, marking the presence of the L1 cell adhesion molecule. In addition the procedure described in this report preserves ultrastructural details of developing neural tissue. In conclusion, the method presented can be employed in combined HRP-tracing and immunohistochemical electronmicroscopic studies.     

Characterisation of the anti-bladder-cancer monoclonal antibody BLCA-8: Identification of its antigen as a neutral glycolipid

A monoclonal antibody, BLCA-8, was raised against the human bladder cancer cell line, UCRU-BL-17CL. By flow cytometry and immunoperoxidase staining, this antibody was found to possess high specificity for bladder tumours, some reactivity with fetal tissues, and no reactivity with normal bladder, or any normal or malignant tissue. This high specificity and the stability of the antigen to the urinary environment suggest that BLCA-8 may have potential for use as an anti-bladder-cancer therapeutic agent. By thin-layer chromatography and autoradiography, BLCA-8 was found to bind four components within the neutral lipid fraction of a bladder cancer cell line, UCRU-BL-17/23. These components hadR _F values of 0.22, 0.16/0.15 (doublet), 0.12 and 0.08, and migrated below globoside, indicating the presence of more than four sugars. By enzyme-linked immunosorbant assay and thin-layer chromatography it was found that the binding of BLCA-8 to the lipid extract was increased by both mild alkaline hydrolysis and enzymatic treatments, indicating that adjacent phospholipids and glycolipids interfere with the accessibility of the antibody-binding site. Full biochemical characterisation of the BLCA-8 antigen is currently underway.     

An ultrastructural double-labelling method: immunohistochemical localization of cell adhesion molecule L1 on HRP-labelled developing corticospinal tract axons in the rat

Summary A double electronmicroscopical (EM) staining was developed which enabled the ultrastructural localization of cell adhesion molecules on the outer axonal membrane of horseradish peroxidase (HRP)-labelled axons in the developing central nervous system (CNS). HRP was used to anterogradely trace outgrowing corticospinal tract (CST) axons in ten-day-old rats. After visualization of HRP using tetramethylbenzidine (TMB) as a chromogen and ammoniumheptamolybdate (AHM) as a stabilizer at pH 6.0 as described previously (Joosten et al. 1987, J Histochem Cytochem 35:623–626) an additional diaminobenzindine (DAB)-Ni incubation was carried out for further stabilization. Subsequently a pre-embedding immunoperoxidase (DAB) staining was executed for detection of cell adhesion molecule L1. Using this procedure anterogradely HRP-labelled CST axons were recognizable by a granular black TMB-AHM-DABNi reaction product at the light microscopic (LM) level, which clearly contrasts to the relatively homogeneous brown L1-immunostaining. Electronmicroscopically HRP-labelled CST axons were characterized by the presence of an intracellular crystaloid TMB-AHM-DABNi reaction product which made identification of CST axons rather easy, whereas the L1-DAB precipitate could be noted on the outer axonal membrane of the HRP-labelled CST axons, marking the presence of the L1 cell adhesion molecule. In addition the procedure described in this report preserves ultrastructural details of developing neural tissue. In conclusion, the method presented can be employed in combined HRP-tracing and immunohistochemical electronmicroscopic studies.