Conjugated avidin binds to mast cell granules

The glycoprotein, avidin, conjugated either to the enzyme horseradish peroxidase, or to the fluorochrome dyes, fluorescein or rhodamine, identifies the granules of mast cells in both tissues and cell suspensions. In the absence of prior fixation, mast cells were not identified with conjugated avidin; however, granules released from these cells were stained with this labeled glycoprotein. The specificity of avidin for mast cells was confirmed by the absence of conjugated avidin-positive cells in the skin of mice (S1/S1d) deficient in mature dermal mast cells. Electron microscopic studies confirmed that avidin binds specifically to individual mast cell granules rather than to other cellular structures. Rodent and human mast cells were readily stained with avidin conjugated to horseradish peroxidase or to either of the fluorochrome dyes. The conjugated avidin staining technique is a reliable and simple method for identifying rodent and human mast cells, one that is useful as both an investigative and a clinical tool.     

An alkaline-phosphatase staining method in avidin-biotin immunohistochemistry

An avidin-biotin alkaline-phosphatase (ABAP) staining method has been developed for the labeling of tissue sections and cell smears. The introduction of alkaline phosphatase as a marker enzyme through an avidin bridge results in excellent immunocytochemical labeling of different antigens using poly- and monoclonal antibodies. This technique avoids problems with endogenous peroxidase activity that sometimes occur using peroxidase staining procedures. The introduction of a preformed avidin-biotin alkaline-phosphatase complex (ABAPC) makes the presented technique as simple to handle as the widely used avidin biotin-peroxidase complex method (ABC). The ABAPC technique could be combined with other enzymatic labelings for double immunoenzymatic staining.     

The use of avidin-gold complex for light microscopic localization of lectin receptors

Summary In the present study, we have investigated the use of avidin-gold complex (AG) as a possible cytochemical marker for visualizing and identifying lectin receptors in deparaffinized tissue sections. Monodispersed gold sols of 15 nm average diameter were prepared by sodium citrate reduction. The AG complex was prepared with highly purified egg-white avidin (avidin-D).Deparaffinized sections of cat duodenum were labeled with five different biotinylated lectins, then were washed and stained for 1–2 h with AG. Intensification of the gold staining was achieved by a modification of the silver-enhancement method. For each lectin, the labeling properties of the avidin-gold-silver (AGS) were compared with those of the avidin-biotin-peroxidase (ABC) and the lectin-gold (LG) methods. We found the lectin binding pattern demonstrated by the AG method to be similar to that of the ABC. The AG localization of the carbohydrate residues is more precise, compared to the peroxidase reaction due to lack of diffusion of the gold marker. Labeling with AGS resulted in improved staining over the AG method, similar to the staining intensity of the ABC. In addition, the two-step AG method provided more intense staining than the direct one-step procedure of the lectin-gold labeling.In conclusion, the use of the AGS method for histochemical visualization of lectin receptors requires a simple two-step procedure which allows highly accurate localization of tissue glycoconjugates. It entails using only a single gold-ligand complex applicable to any biotinylated lectin regardless of its biochemical nature. It can also be easily adapted for use with other biotinylated ligands such as antibodies, hormones, toxins, etc.     

The use of avidin-gold complex for light microscopic localization of lectin receptors

In the present study, we have investigated the use of avidin-gold complex (AG) as a possible cytochemical marker for visualizing and identifying lectin receptors in deparaffinized tissue sections. Monodispersed gold sols of 15 nm average diameter were prepared by sodium citrate reduction. The AG complex was prepared with highly purified egg-white avidin (avidin-D). Deparaffinized sections of cat duodenum were labeled with five different biotinylated lectins, then were washed and stained for 1-2 h with AG. Intensification of the gold staining was achieved by a modification of the silver-enhancement method. For each lectin, the labeling properties of the avidin-gold-silver (AGS) were compared with those of the avidin-biotin-peroxidase (ABC) and the lectin-gold (LG) methods. We found the lectin binding pattern demonstrated by the AG method to be similar to that of the ABC. The AG localization of the carbohydrate residues is more precise, compared to the peroxidase reaction due to lack of diffusion of the gold marker. Labeling with AGS resulted in improved staining over the AG method, similar to the staining intensity of the ABC. In addition, the two-step AG method provided more intense staining than the direct one-step procedure of the lectin-gold labeling. In conclusion, the use of the AGS method for histochemical visualization of lectin receptors requires a simple two-step procedure which allows highly accurate localization of tissue glycoconjugates. It entails using only a single gold-ligand complex applicable to any biotinylated lectin regardless of its biochemical nature.(ABSTRACT TRUNCATED AT 250 WORDS)     

Suppression of nonspecific binding of avidin-biotin complex (ABC) to proteins electroblotted to nitrocellulose paper

Nitrocellulose blots of cell extracts reacted in sequence with biotinylated lectins and horseradish peroxidase-labeled avidin-biotin complex (ABC) often show considerable nonspecific staining of protein bands. Experiments were performed to determine which of the components of the ABC were responsible for this and whether or not the nature and ionic strength of the buffer used could alter this binding. Furthermore, as powdered non-fat milk has been proposed as a possible blocking agent for nonspecific binding of ABC, we sought to determine if it would adequately block that binding in our system. The initial experiments showed that nonspecific binding of ABC to proteins transferred to nitrocellulose membranes was due to the avidin component of the ABC; little, if any, binding was seen if biotin alone was incubated with these blots. The spurious binding was shown to be primarily due to the high affinity of avidin to proteins electroblotted to nitrocellulose, when incubated in low-salt buffers. Low-fat milk added to the buffer reduced overall nonspecific reactivity but produced additional artifacts in the form of bands that were not seen in other preparations. Nonspecific avidin binding to proteins transferred to nitrocellulose can therefore be effectively reduced by adding extra salt to buffers, whereas the addition of non-fat dry milk does not seem suitable for this purpose.     

Use of avidin-biotin-peroxidase complex (ABC) in immunoperoxidase techniques: a comparison between ABC and unlabeled antibody (PAP) procedures

The use of avidin-biotin interaction in immunoenzymatic techniques provides a simple and sensitive method to localize antigens in formalin-fixed tissues. Among the several staining procedures available, the ABC method, which involves an application of biotin-labeled secondary antibody followed by the addition of avidin-biotin-peroxidase complex, gives a superior result when compared to the unlabeled antibody method. The availability of biotin-binding sites in the complex is created by the incubation of a relative excess of avidin with biotin-labeled peroxidase. During formation of the complex, avidin acts as a bridge between biotin-labeled peroxidase molecules; and biotin-labeled peroxidase molecules, which contains several biotin moieties, serve as a link between the avidin molecules. Consequently, a "lattice" complex containing several peroxidase molecules is likely formed. Binding of this complex to the biotin moieties associated with secondary antibody results in a high staining intensity.     

The effect of avidin-biotin interactions in detection systems for in situ hybridization.

The effect of avidin-biotin interactions in several detection systems for the non-radioactive in situ hybridization (ISH) technique was studied in a model system using a transitional cell carcinoma line and a biotinylated DNA probe. We performed fluorescence ISH to unravel the individual steps in a sensitive and frequently used amplification method which makes use of the alternating cytochemical detection layers of fluorescein isothiocyanate-conjugated avidin (AvFITC) and biotinylated goat anti-avidin (BioGAA) antibodies to detect the hybridized and biotinylated probe. Our experiments revealed that BioGAA antibodies bind with their antigen binding sites and not with their biotin moieties to avidin molecules that have already interacted with the DNA probe. The probable working mechanism of this amplification method is presented in a model. Furthermore, we used a peroxidase staining technique to compare with each other the sensitivity of several other detection systems in which avidin-biotin interactions play an important role, e.g., the avidin-biotinylated peroxidase complex (ABC) system. The experiments show that avidin molecules can not be efficiently used to interconnect two biotinylated molecular layers, since their introduction leads to firmly closed cytochemical networks. Such a closed network is already formed between the hybridized and biotinylated DNA probe and a first detection layer of avidin molecules, as appears from the finding that biotinylated molecules could hardly be coupled to these avidin molecules in a following detection layer. Therefore, the results presented here provide us with new insight into the molecular basis of cytochemical network formation. This will enable us to choose the proper procedures for increasing the sensitivity of ISH detection systems.     

Elimination of the non-specific binding of avidin to tissue sections

Summary A simple procedure is described for eliminating non-specific staining with avidin—peroxidase conjugates. Murine ovaries were embedded in either paraffin wax or epoxy resin and, after blocking endogenous peroxidase activity, were treated with 10 µg/ml biotinylatedPisum sativum agglutinin. Avidin—peroxidase conjugates (5 µg/ml), diluted in standard 0.05m tris-buffered saline, pH 7.6, containing 0.139m NaCl, produced considerable background coloration and intense mast cell staining in controls without the lectin. This background diminished as the ionic strength of the buffer was raised. At 0.125m Tris-buffered saline (containing 0.347m NaCl) the background was completely unstained, with elimination of all binding to mast cells and only minimal loss of specific lectin binding.     

Cytochemical observations on mannose-specific binding sites for horseradish peroxidase in liver sinusoidal cells

Paraformaldehyde-fixed, frozen sections of the liver of rats were processed for the detection of mannose-specific binding sites of horseradish peroxidase (HRP) by a method reported previously, with some modifications resulting in a more intense binding reaction. Before staining for peroxidase activity, the sections were held in buffered solutions of physiological saline at different temperatures and pH's, and in the presence or absence of added Ca2+, mannose or galactose. The gradual decrease and final disappearance of the binding reaction were observed. The release of HRP from the binding sites as determined by the disappearance of the cytochemical reaction was 50-100 times faster at 22 degrees C than at 4 degrees C and was 5-10 times faster at 37 degrees C than at 22 degrees C. The release was approximately twice as fast at pH 7.0 than at pH 9.0 and 20-30 times faster at pH 6.0 than at pH 7.0. The release of HRP was 10-15 times faster in the absence of 1 mM Ca2+ in the buffer solution and was approximately 100 times faster in the presence of 0.1 M D-mannose as compared to 0.1 M D-galactose. Pretreatment of the sections with trypsin abolished the binding reaction whereas neuraminidase, phospholipases A2 and C, and chondroitinase ABC were without effect. An acidic isoenzyme of HRP, Sigma type VIII, was bound more intensely and more widely to liver sinusoidal cells than another acidic isoenzyme, Sigma type VII, a basic isoenzyme, Sigma type IX, and the routinely used preparation, Sigma type VI. The effect of the temperature on the binding reaction was re-examined with an improved procedure. In contradistinction to the previous finding, strong binding of HRP after 2-4 h incubation at 4 degrees C was observed.     

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.     

Disintegration of layer-by-layer assemblies composed of 2-iminobiotin-labeled poly(ethyleneimine) and avidin

A layer-by-layer thin film composed of avidin and 2-iminobiotin-labeled poly(ethyleneimine) (ib-PEI) was prepared and their sensitivity to the environmental pH and biotin was studied. The avidin/ib-PEI multilayer assemblies were stable at pH 8-12, whereas the assemblies were decomposed at pH 5-6 due to the low affinity of the protonated iminobiotin residue to avidin. The avidin/ib-PEI assemblies can be disintegrated upon addition of biotin and analogues in the solution as a result of the preferential binding of biotin or analogues to the binding site of avidin. The decomposition rate was arbitrarily controlled by changing the type of stimulant (biotin or analogues) and its concentration. The avidin/ib-PEI assemblies were disintegrated rapidly by the addition of biotin or desthiobiotin, whereas the rate of decomposition was rather slow upon addition of lipoic acid or 2-(4'-hydroxyphenylazo)benzoic acid. The present system may be useful for constructing the stimuli-sensitive devices that can release drug or other functional molecules.     

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.     

Dolichos biflorus agglutinin (DBA) reacts selectively with mast cells in human connective tissues

Dolichos biflorus agglutinin (DBA) binds to N-acetyl-D-galactosamine (GalNAc) residues in glycoconjugates and agglutinates erythrocytes carrying blood group antigen A. In cryostat sections of various tissues from blood group-specified humans, fluorochrome-coupled DBA bound preferentially to fusiform connective tissue cells and to certain epithelial cells. The connective tissue cells were identified as mast cells by their typical metachromasia in consecutive staining with toluidine blue. Double labeling with DBA and conjugated avidin revealed two distinct populations of mast cells. In several tissues the DBA-reactive cells likewise displayed uniform avidin reactivity. In intestinal mucosa, however, morphologically distinct DBA-binding mast cells were found, which were labeled with the avidin conjugates only in specially fixed paraffin sections. DBA did not bind to vascular endothelial cells, which could be identified by double staining with antibodies to factor VIII-related antigen. Labeling with Helix pomatia agglutinin (HPA), another blood group A-reactive lectin, resulted in distinct blood group-dependent fluorescence of the endothelia. Sophora japonica agglutinin (SJA), a blood group B-reactive lectin, labeled vascular endothelial cells in tissues from blood group A, AB, and B donors. HPA and SJA reacted with small mast cells in the gastrointestinal mucosa but failed to label large mast cells in any of the tissues. These results indicate that the blood group reactivity of lectins, as determined by erythroagglutination, is not necessarily consistent with their reactivity with blood group determinants in tissue sections. Moreover, DBA conjugates appear to be a reliable probe for detection of mast cells in various human connective tissues.     

Selection of a simple protease procedure for identifying mast cells in routinely processed human tissues

Proteases present in mast cell granules have been harnessed to demonstrate mast cells in human tissues. A number of substrate mixtures were tested. D-Val-Leu-Arg-4-methoxy-2-naphthylamide (MNA) plus Fast Blue B was the best for identifying human mast cells, yielding the most specific and complete staining. The procedure is simple and the results are permanent. Cryostat sections of aldehyde-fixed routine preparations or paraffin sections of Carnoy-fixed tissues give the most satisfactory results. Mast cells are stained a strong red color that stands out distinctly from the surrounding tissues, so that they can be easily identified by simple microscopy. A double-staining technique, first for protease and subsequently using Alcian Blue, showed that as progressive protease staining occurs, the alcianophilia of mast cells is lost. This procedure demonstrated that mast cells in the mucosa of human gut generally required longer incubations to develop protease staining than in other connective tissue sites. In post-mortem tissues, mast cells retain their protease activity well and so can be demonstrated in cryostat sections of aldehyde-fixed material, giving a more complete picture than with Alcian Blue. The synthetic substrate D-Val-Leu-Arg-MNA can be recommended for routine identification of mast cells in human tissues.     

Controlled Staining of Autoradiographs

The preparation of autoradiographs in which the tissue and the emulsion are in permanent register is often complicated by staining after the photographic image has been developed and fixed. While general oversight methods can be satisfactory, controlled, specific staining can be obtained with most basic dyes when the pH is properly regulated. The reactivity of the gelatin is suppressed at a pH of 4 or slightly below whereas nuclei, ergastoplasm, cartilage, mast cells, mucus, etc. stain readily. Basic fuchsin, .05% at pH 3.5-4.0 in dilute (1:10) McLlvaine buffer, is recommended. The final preparation contrasts in color and transparency with the black, opaque silver grains.     

Lectin Histochemistry on Glycoconjugates of the Epidermis and Dermal Glands of Xenopus laevis (Daudin, 1802)

We performed an investigation at the light microscopical level of the differential distribution of lectin-binding sites among cells of the epidermis and glandular domains of the African clawed frog Xenopus laevis. Using a panel of biotinylated lectins (Con-A. PSA, LCA, UEA-I, DBA, SBA, SJA, RCA-I, BSL-I, WGA, s-WGA, PHA-E and PHA-L) and an avidin–biotin–peroxidase complex (ABC), we have identified specific binding patterns. The results show that expression of saccharide moieties in Xenopus epidermal keratinocytes is related to the stage of cellular differentiation, different cell layers expressing different sugar residues. Moreover, oliogosaccharides with “identical” biochemically defined sugar compositions can be distinguished. The method allowed further characterization of complex glycoconjugates of dermal glands. In view of these results, the ABC technique and the biotinylated lectins employed in the present study are believed to be a reliable method for the precise localization of saccharide residues of glycoconjugates present in ectothermic vertebrates.     

Localization of avidin in virus-transformed and damaged chicken embryo fibroblasts by immunofluorescence and the avidin-biotin-peroxidase complex (ABC) technique

Avidin, a high-affinity biotin-binding protein of chicken oviduct, was recently found to be synthesized and secreted by damaged or virus-transformed chicken embryo fibroblasts and by chicken macrophages. We have now localized avidin in fibroblasts that were transformed by Rous sarcoma virus. The cells released to the culture medium up to 12 micrograms avidin per 10(6) cells, as judged by the [14C] biotin-binding method. In immunofluorescence microscopy, avidin was localized to the cytoplasm of transformed and of untransformed damaged cells. Treatment with the ionophore monensin was used to determine whether avidin is processed through the Golgi region, which was localized using rhodamine-labeled wheat germ agglutinin. Under these conditions avidin was largely confined to the Golgi region. At the electron microscopic level avidin could be localized to the endoplasmic reticulum of transformed cells, using anti-avidin antibodies and the avidin-biotin-peroxidase complex (ABC) technique. Biotinyl peroxidase did not stain the endogenous avidin in cell layers processed for light or electron microscopy indicating that its biotin-binding sites were either saturated or denaturated. The possibility that endogenous avidin in tissues or cell cultures may bind biotinylated reagents should be controlled for in techniques involving the avidin-biotin interaction.     

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

Summary 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-feroprotein in liver and tissue polypeptide antigen in mainmary gland served as models. The immobilized twostep 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.     

Histochemical method for demonstrating quail mast cell types simultaneously

Abstract

The development and application of selective staining methods for routine detection of mast cells are of considerable interest, because these cells play an important role in health and disease. The composition of cytoplasmic mast cell granules depends on the species and type of mast cell. The study reported here was conducted to investigate the combined use of aldehyde fuchsin (AF) and the Alcian blue-critical electrolyte concentration (AB-CEC) (pH 5.8, 0.3 M MgCl₂) techniques for differentiating avian mast cell subtypes. Tissue samples from skin, intestines, and lungs of six healthy adult quail and two control rats were fixed in Carnoy's solution and 10% formolin for routine histological processing. To determine the staining properties of sulfated glycosaminoglycans (GAGs), a three-step staining technique was applied using berberine sulfate, AF, and AB-CEC. In quail, AF positivity following application of the AB-CEC technique was found only in the lungs, mostly in cells that gave a berberine sulfate-positive reaction, and this positivity was determined to be localized particularly in the nucleus and perinuclear cytoplasm. In other regions, the pale AF staining of cells that did not emit fluorescence when stained with berberine sulfate was determined to be replaced by a blue color after application of AB-CEC. The AF/AB-CEC (pH 5.8, 0.3 M MgCl₂) technique demonstrated that rat and quail mast cells varied in both GAG types and their distribution within the cell. Especially in avian species, this technique can be applied to distinguish mast cells according to their GAG content. It can be used as an alternative to the AB/safranin O staining procedure for differentiating mast cells that contain and lack heparin.     

Improved avidin-biotin-peroxidase complex (ABC) staining

Summary A considerable intensification of the avidin—biotin—peroxidase complex staining system (ABC) was obtained by sequentially overlaying the sections to be immunostained with an avidin-rich and a biotin-rich complex. Each sequential addition contributed to the deposition of horseradish peroxidase on the immunostained site and allowed the subsequent binding of a complementary complex. With this technique a higher dilution of the antisera could be used and minute amounts of antigen masked by the fixative could be demonstrated on paraffin sections.