Benzidine dihydrochloride as a chromogen for single- and double-label light and electron microscopic immunocytochemical studies

Although very sensitive chromogens have been adapted for localization of horseradish peroxidase in anterograde and retrograde tracing studies, they have not been successfully applied in immunocytochemical studies. This report describes a protocol which uses benzidine dihydrochloride (BDHC) as the chromogen for light (LM) and electron microscopic (EM) immunocytochemical studies. The protocol is comparable to that used for tetramethylbenzidine, except that the pH of the reaction is above 6.0. At the LM level, the BDHC reaction product is bluish-green and crystalline. Both the color and form of the product are readily distinguished from the reddish-brown DAB reaction product. LM double-labeling studies are therefore feasible. The use of BDHC also increases significantly the sensitivity of the immunoreaction. Higher fixative concentrations can be used, less detergent is necessary, and higher primary antibody dilutions are possible. By osmicating at 45 degrees C in an s-collidine buffer it is possible to preserve the soluble BDHC reaction product for EM analysis. Immunoreactive cells are particularly well labeled with this new protocol. The BDHC crystals are easily detected at the EM level and can be distinguished from flocculent DAB reaction product. This feature makes EM double-labeling studies possible.     

Microphotometric quantitation of the reaction product of several indirect immunoperoxidase methods demonstrating monoclonal antibody binding to antigens immobilized on nitrocellulose

The nitrocellulose model and microphotometry were used to investigate whether in immunoperoxidase cytochemical methods the amount of final reaction product reflects the amount of cell surface antigen. The results obtained with four cytochemical peroxidase methods, i.e., those using diaminobenzidine/H2O2 (DAB/H2O)2, DAB/H2O2/COCl2, DAB/H2O2/imidazole, and silver intensification of the DAB end product, were compared first. The quantitative DAB/H2O2/imidazole method proved to be the most sensitive and was selected for further studies. Cell surface antigens prepared by solubilization of peritoneal macrophages with octyl-beta-D-glucopyranoside were immobilized on nitrocellulose. Monoclonal antibody binding to these cell antigens was detected by peroxidase immunocytochemistry. Comparison of the sensitivity of the indirect immunoperoxidase and the biotin-(strept)avidin immunoperoxidase methods on the basis of the highest detectable dilution of a cell lysate showed that these methods were equally sensitive. A linear relationship between the absorbance of the peroxidase reaction product and the amount of cell lysate immobilized on nitrocellulose was found for all three indirect immunoperoxidase methods. This proves that the amount of final immunocytochemical peroxidase reaction product is proportional to the amount of antigen in cell lysates. However, the relative expression of antigens in intact cells differs from that in cell lysates. Therefore, the present method to solubilize cells and immobilize cell antigens cannot be used to quantitate the antigen content of cells.     

Immunocytochemical localization of the functional fraction of lipoprotein lipase in the perfused heart

The functional (heparin-releasable) fraction of myocardial lipoprotein lipase (LPL) has been located at the lumen surface of capillary endothelium by means of an indirect immunocytochemical perfusion method for electron microscopy. The primary step immunoreactant was an IgG fraction of goat antiserum directed against LPL from rat heart. The second step antibody, conjugated with horseradish peroxidase, was rabbit IgG directed against goat IgG. Peroxidase reaction product, when present, appeared at the surface an in invaginations of the lumenal plasma membrane of capillary endothelium and also on chylomicrons adherent to that membrane. The highest coverage by such product occurred when the highest heparin-releasable heart LPL activity was attained after fat-feeding of rats. Coverage was low when a low level of heparin-releasable heart LPL activity was induced by carbohydrate-feeding. Coverage was very low in the perfused hearts after heparin-release of functional LPL activity. The positive association between these immunocytochemical results and actual levels of functional LPL activities indicates that functional LPL in the isolated rat heart is at the lumen surface of capillary endothelium.     

Double-label immunocytochemistry: combination of anterograde neuroanatomical tracing with Phaseolus vulgaris leucoagglutinin and enzyme immunocytochemistry of target neurons

By the neuroanatomical tracing technique based on uptake, transport, and immunocytochemical detection of injected Phaseolus vulgaris leucoagglutinin (PHA-L), fiber trajectories of labeled neurons can be followed with great accuracy to their termination areas. To further analyze the connectivity of these fibers, the target neurons must be chemically characterized. In vibratome and frozen sections of rat brain, we tried to visualize PHA-L-labeled fibers and, simultaneously, the target neuron-related antigen. As a model system we used the projection from the pre-frontal cortex to histaminergic neurons in the posterior hypothalamic region. We tested "sequential" and "pooled" immunocytochemical procedures. In the sequential procedure, the two antigens are detected by two successive and complete immunocytochemical staining procedures, with primary antibodies raised in different animal species and with different chromogens for the final visualization. In the pooled procedure, the sections are incubated with mixtures of primary and secondary antibodies, after which the procedure is similar to the sequential procedure. We obtained excellent results on vibratome sections with a sequential procedure using first conventional peroxidase immunocytochemistry (goat anti-PHA-L primary antibody) to visualize the transported PHA-L (brown reaction product), and subsequently alkaline phosphatase immunocytochemistry (rabbit anti-histidine decarboxylase primary antibody) to locate the histaminergic neurons (blue reaction product). The resulting preparations deteriorate, however, after 1-2 months of storage. Good results were also obtained with a double peroxidase procedure on frozen sections, using nickel-enhanced diaminobenzidine to visualize the PHA-L (dark blue reaction product), and diaminobenzidine (brown reaction product) to visualize the second antigen. The quality of these preparations is permanent.     

A double-label pre-embedding immunoperoxidase technique for electron microscopy using diaminobenzidine and tetramethylbenzidine as markers

Techniques for correlative double-label immunocytochemistry (ICC) at light and electron microscopic (EM) level are useful for determining the neurotransmitter phenotype of inputs onto immunocytochemically identified neurons. Tetramethylbenzidine (TMB) has been used as a chromogen at the EM level for horseradish peroxidase tract tracing. We have found that TMB, in combination with diaminobenzidine (DAB), can be used in a double-label immunocytochemical protocol to examine neuropeptide Y inputs onto luteinizing hormone-releasing hormone cells in the sheep preoptic area. At both light and EM levels, TMB reaction product is visibly distinct from DAB reaction product. The ultrastructural preservation we have been able to obtain with our technique is better than that obtained with techniques that use TMB at a lower pH. Furthermore, this technique allows the demonstration of synaptic contacts between neurochemically identified terminals and cells with different neurotransmitter phenotypes.     

The immunohistochemical detection of prostatic acid phosphatase: its possibilities and limitations in tumour histochemistry

Summary The immunological specificity of the Amsterdam rabbit antiserum against human prostatic and phosphatase was studied on paraffin sections of 200 prostatic carcinomas and 330 control tissues using an indirect peroxidase technique. Peripheral blood leucocyte smears were also investigated with a fluorescent technique. In a limited number of cases, the mixed aggregation immunocytochemical method was also applied as post-primary incubation procedure. The diaminobenzidine (DAB) final reaction product of the peroxidase technique, carried out under standard conditions, was quantified in some cases using the Leyden Television Analysis System (LEYTAS) with a built-in standard.A positive reaction was obtained in 96.5% of the prostatic carcinomas. Only 2.1% of the non-prostatic tumour cases (23 types) showed a positive reaction, namely six out of 10 insulomas and one out of 10 carcinoid tumours. The -cells of the normal islet of Langerhans and the leucocytes in the smears showed a positive reaction. The sensitivity of the peroxidase method, judged subjectively, is not only dependent on the circumstances of fixation, embedding and incubation but also on the degree of tumour differentiation. None of the three prostatic carcinomas studied reached the level of DAB staining intensity shown by the hyperplastic prostatic epithelium.     

Identification of glucagon-producing cells (A cells) in dog gastric mucosa

An immunocytochemical technique using specific antiglucagon serum reveals the presence of glucagon-containing cells situated exclusively in the oxyntic glandular mucosa of the dog stomach. Electron microscope examination of the mucosa demonstrated endocrine cells containing secretory granules with a round dense core surrounded by a clear halo, indistinguishable from secretory granules of pancreatic A cells. Like the alpha granules of pancreatic A cells, the granules of these gastric endocrine cells exhibited a peripheral distribution of silver grains after Grimelius silver staining. Moreover, the granules of these cells were found to be specifically labeled with reaction product, using the peroxidase immunocytochemical technique at the ultrastructural level. Accordingly, these cells were named gastric A cells. These data suggest that the gastric oxyntic mucosa contains cells indistinguishable cytologically, cytochemically, and immunocytochemically from pancreatic A cells. It is believed that gastric A cells are responsible for the secretion of the gastric glucagon.     

Immunocytochemical localization of a rhodopsin-like protein in the lipochondria in photosensitive neurons of Aplysia californica

Summary Polyclonal antibodies directed against squid opsin were used in immunocytochemical and immunoblot experiments to identify a rhodopsin-like protein in photosensitive neurons of Aplysia. Aldehyde-fixed abdominal and cerebral ganglia were embedded in paraffin for peroxidase anti-peroxidase analysis or used whole for immunofluorescence studies. Ganglia were embedded in Lowicryl K4M for electron-microscope immunocytochemistry. In both the cerebral and abdominal ganglia, light-microscope immunocytochemical results showed reaction product deposited around the neuronal cell periphery corresponding in position to the lipochondria. In the abdominal ganglion, the giant cell R2, located in the right rostral quarter, and neurons in the right caudal quarter were consistently labeled with anti-opsin. Electron-microscopic studies demonstrated ferritin-labeling of the lipochondria in R2 and other immunoreactive neurons. Immunoblot analysis of R2 and cerebral neuron extracts was used to identify two prominent immunoreactive protein bands at 85000 and 67500 molecular weight.     

A novel tetrazolium method for peroxidase histochemistry and immunohistochemistry.

We developed a new method for the histochemical demonstration of peroxidase. This method, which has a novel reaction mechanism, is based on the oxidation of phenol by peroxidase and coupling of this reaction to the reduction of a tetrazolium salt, with the deposition of an insoluble formazan at sites of enzyme activity. This new method was compared with an established diaminobenzidine (DAB) technique for peroxidase histochemistry and immunohistochemistry. Although both methods identified peroxidase activity in myeloid cells of bone marrow biopsy specimens, there was no interference from red cell pseudoperoxidase activity with the phenol-tetrazolium method, in contrast to the diaminobenzidine method. The detection of cytokeratin using an indirect immunoperoxidase technique was compared with both methods for demonstrating peroxidase activity. The phenol-tetrazolium method gave results similar to that obtained with DAB and appeared to be at least as sensitive as DAB in detecting low amounts of antigen. In addition, the production of a formazan as the final reaction product means that the phenol-tetrazolium method is ideally suited for quantitative peroxidase histochemistry. Therefore, the phenol-tetrazolium method represents a useful alternative method to DAB and for certain applications offers significant advantages over DAB.     

Immunocytochemical localization of soluble protein in the adrenal medulla

Synopsis An indirect immunocytochemical technique (Nakane, 1970) was employed to localize the soluble proteins purified from lysates of catecholamine (CA)-containing vesicles of the bovine adrenal medulla. Antiserum to the proteins, produced in rabbits, was used for incubation of sections of bovine adrenal tissue prepared by fixation in glutaraldehyde and embedding in serum albumin (McLean & Singer, 1970). The site of the antigen-antibody complex was visualized by incubating the sections with anti-rabbit -globulin (goat) conjugated to peroxidase, followed by the deposition of electronopaque reaction product generated by the enzyme. The reaction product, also visible at the level of the light microscope, appeared to have a distribution similar to that of the CA-storage vesicles. Electron microscopic examination revealed that nearly all the reaction product was deposited over the electron-opaque core of the vesicles. The intravesicular localization is consistent with the proposal that these proteins exist primarily in the CA-containing granular vesicle and may function to stabilize the CA-storage complex.     

Immunocytochemical localization of nerve growth factor (NGF) in the submandibular gland of adult mice by light and electron microscopy

Summary Nerve growth factor (NGF) was localized in the submandibular gland of adult male mice by a direct immunocytochemical method using highly purified antibodies against NGF coupled to horseradish peroxidase. In light microscopic sections the reaction product was entirely confined to the cells of the secretory tubules. The acinar part of the gland was free of reaction product. This finding was confirmed by electron microscopy. Within the cells NGF was localized exclusively in the apical secretory granules.No reaction was observed in the rough endoplasmic reticulum, the Golgi region or in the granules of the basal part of the cells. This observation favours the assumption that NGF is derived from a precursor molecule and that the precursor is transformed into immunologically active NGF within the secretory granules during their transport from the basal to the apical part of the tubular cells. Stimulation of the submandibular gland with carbachol (2 mg/kg) led to a massive release of the content of the secretory granules, including NGF, into the salivary duct.We wish to thank Dr. C. Rufener, Geneva, for communicating to us a new method of antibodyperoxidase coupling and Mrs. M. Durand-Wenger for her excellent technical assistance. This study was supported by the Swiss National Foundation for Scientific Research (Grant Nr. 3.432.74)     

Localization of rhodopsin in isolated, osmotically intact rod outer segment discs.

Localization of rhodopsin and its position in the membrane has been the subject of numerous studies. Most recently, immunocytochemical techniques have been employed to localize the opsin component of the molecule in in situ rod outer segments. Due to the problems inherent in localization procedures (penetration and mechanical interference) we have utilized isolated, osmotically intact rod outer segment discs in this study. Specific antibodies to chromatographically pure rhodopsin were prepared and enzymatically digested to their Fab components. The univalent Fab antibodies were conjugated to horseradish peroxidase and used to label the isolated rod outer segment discs. Discs treated with anti-opsin conjugate stained uniformly and heavily on their interdisc surfaces. Reaction product was also present on the intradisc surface in a thinner but still uniformly distributed layer. Controls treated with preimmune Fab - horseradish peroxidase conjugate showed no deposition of reaction product.     

An enzymatic colorimetric method for measuring naringin using 2,2'-azino-bis-(3-ethylbenzthiazoline-6-sulfonic acid)(ABTS) in the presence of peroxidase

A sensitive colorimetric method for naringin estimation using 2,2'-azino-bis-(3-ethylbenzthiazoline-6-sulfonic acid) (ABTS) as peroxidase substrate is described. The method is based on the coupling reaction of an ABTS radical cation with an oxidation product of naringin formed by peroxidase. This coupling reaction leads to the formation of a purple-colored compound with a maximum absorption at 560 nm. A molar absorption coefficient at this wavelength was calculated to be 13,286 +/- 200 M-1 cm-1. The lowest amount of naringin that can be detected is 1 nmol. The application of this method to the quantification of naringin in grapefruit tissues is presented.     

Identification of immunoreactive sites in bovine parathyroid cells to antibodies raised against the NH2-terminal sequence of parathyroid hormone.

The NH2-terminal sequence of bovine parathyroid hormone (1-84) was localized with different immunocytochemical methods on the light and electron microscopic level in bovine parathyroid glands and in isolated bovine parathyroid parenchymal cells. The peroxidase labeled staphylococcal protein A and the peroxidase anti-peroxidase method were found to be advantageous for light and electron microscopic localization, respectively. Reaction product was found light microscopically in the cytoplasma of the parenchymal cells and electron microscopically largely over the secretion granules of the parenchymal cells. The immunoreactive sites were subsequently identified to represent only intact parathyroid hormone (1-84) by gel electrophoresis derived enzyme linked immunosorbent assay.     

Endogenous peroxidase in the lacrimal gland of the rat and its differentiation against injected catalase and horseradish-peroxidase

Summary The localization of endogenous peroxidase was studied in the glandula orbitalis (lacrimalis) externa of the rat by the method of Graham and Karnovsky (1966). Reaction product is visible in all cisternae of the rough endoplasmic reticulum including the perinuclear cisternae, in condensing vacuoles, and in all secretion granules. The Golgi cisternae seldom are peroxidase positive. Intercalated duct cells rarely contain reaction product in a few scattered cisternae of the rough endoplasmic reticulum and in secretion granules.After the injection of beef liver catalase reaction product is found in the capillary lumen. Both the injected catalase and the endogenous peroxidase are completely inhibited by 10^–2M aminotriazole, while the pseudoperoxidatic activity within the erythrocytes persists. After injection of horseradish-peroxidase reaction product is visible within the capillary lumen and also in the intercellular spaces between lacrimal gland cells. 10^–2M aminotriazole completely inhibits the endogenous peroxidase while the exogenous horseradish-peroxidase remains unaffected. The inhibitory effect of aminotriazole is not specific for catalase since lacrimal gland peroxidase is also inhibited.     

Cytochemical localization of peroxidase in soybean suspension culture cells and protoplasts: Intracellular vacuole differentiation and presence of peroxidase in coated vesicles and multivesicular bodies

Summary The ultrastructural localization of peroxidase in soybean (Glycine max L.) suspension culture cells and protoplasts is reported. In cells peroxidase is found primarily in the cell wall and at the tonoplast. Protoplasts and cells contain a vacuolar system which is differentiated with respect to peroxidase content since some vacuoles are found which do not contain peroxidase reaction product. The Golgi dictyosomes, coated and smooth vesicles contain peroxidase. Some of the multivesicular bodies have the reaction product as well. The results are discussed in terms of the pathways of sorting of peroxidase between the cell wall and vacuoles of cultured cells.     

Pt-staining of peroxidatic reaction products at the ultrastructural level

The use of H2PtCl6 is proposed for the selective visualization of the poly-DAB reaction product created, in aldehyde-fixed tissue, with the cytochemical reaction according to Graham and Karnovsky (1966) or to Hoefsmit (1975). At sites known to contain peroxidatic activity, at the ultrastructural level, an electron-dense reaction product is acquired in otherwise unstained ultrathin sections. The presence of the element platinum in these sites has been demonstrated by X-ray microanalysis, for both the endogenous peroxidase and peroxidase conjugated to antibodies. The absolute platinum concentration has been established in erythrocytes and the granules in eosinophils and monocytes by co-embedded, Pt-containing Chelex ion-exchange beads next to the cells. By the application of the method of integrated morphometrical and chemical analysis (de Bruijn and Zeelen 1984; de Bruijn 1985; de Bruijn and Cleton 1985), both the elemental concentration and the area occupied have been calculated for eosinophil granules. The mean Pt net-intensity values of the cytoplasmic areas, known not to contain the enzyme peroxidase has been measured, and compared to the mean net-intensity Pt values of the granules. It was noted that the cytoplasmic Pt net-intensity values were not zero. The two sets of values are expressed as a mean Pt granule/cytoplasm ratio, this ratio creates a value for the "selectivity" of the reaction. The application of a postfixation reaction with OsO4- containing media, at pH 7.4, in addition to the H2PtCl6 reaction, resulted in a contrasted poly-DAB reaction product at all sites known to contain peroxidatic activity. However, X-ray microanalysis revealed that in addition to platinum, osmium was present.(ABSTRACT TRUNCATED AT 250 WORDS)     

Endogeneous peroxidase activity in the frog thyroid gland

Summary The fine structural localization of the endogeneous peroxidase activity in the thyroid of the young frog was studied. The reaction product for peroxidase was observed over the peripheral luminal colloid and apical region of the follicular epithelial cell. Most apical small granules and some parts of Golgi lamellae and a few Golgi vesicles were specifically stained. The cisternae of rough endoplasmic reticulum and the nuclear cisternae did not demonstrate any positive reaction for peroxidase activity with difference from that of various cells of mammalia. In this study, only mature peroxidase seems to be positive for its reaction and the enzyme in the rough endoplasmic reticulum is considered to be too immature to react for DAB method in the frog thyroid cell. The relationship between the localization of peroxidase reaction and the site of the iodination of thyroglobulin was discussed.     

Quantification by image analysis of immunocytochemical reactions: application for determination of lysozyme content in individual smeared cells.

The objective of the present study was to develop a cytophotometric technique to quantitate immunocytochemical reactions. Cell antigens were detected after immunophosphatase alkaline staining procedure. The amount of reaction product was quantitated by computerized scanning cytophotometry. The technical conditions (dilution of primary antibody; incubation time of the three antibodies; volume and pH of the enzyme substrate reaction; storage of the slides) required for optimal cytophotometric determination of the reaction product were determined. Under these optimally defined conditions, a linear relationship between cell protein content (lysozyme) and microdensitometric measure of the colored reaction product was found. This method could be used for other cells, antigens, and enzymatic indicators.