Recent advances in the detection and characterization of specific antibody-forming cells in tissue sections

Summary A new general approach has been developed for the detection of one or more different specific antibody producing cells and the simultaneous determination of their Ig isotype in tissue sections, after immunization of animals. Specificity of intracellular antibodies is demonstrated after incubation of the sections with an antigen-enzyme conjugate and the isotype of the antibodies is determined using an anti-immunoglobulin (Fc chain-specific)-enzyme conjugate followed by histochemical revelation of the two different enzymes. The principles of the method, the required antigen— and antibody—enzyme conjugates and their application in single, double or triple staining studies are reviewed.The method allows the detection of specific antibody-forming cells against protein antigens as well as against haptens. By means of haptens such as trinitrophenyl (TNP), immune responses against thymus dependent, thymus independent, and particulate antigens can be studied. In a limited number of cases the method can also be used to study the localization of antigen—antibody complexes.     

Simultaneous application of in situ DNA hybridization and immunohistochemistry on one tissue section

Summary Combined application of a non-radioactivein situ DNA hybridization procedure and the immunoperoxidase technique on one tissue section is described. Of six potential protocols, only one proved to be successful. First, the immunohistochemical procedure including visualization of enzyme activity is performed; thein situ DNA hybridization protocol is then applied. Using this protocol, several antigens, detected with monoclonal antibodies, and target DNAs, detected by using biotinylated human cytomegalovirus or human papilloma virus type 16 DNA probes, could be distinguished by their peroxidase activity (brown precipitate) and alkaline phosphatase activity (purple—blue precipitate) respectively. The method allows immunophenotyping of virus-infected cells as well as simultaneous visualization of two viral parameters. This technique has important implications for research and diagnostic purposes.     

Freeze-drying of bone tissue: immunocytochemistry and enzyme histochemistry on paraffin embedded and low-temperature resin embedded specimens

A simple protocol of tissue preparation was sought, which would enable marker enzymes of bone cells and extracellular matrix antigens to be localized in the same tissue section with high optical resolution. For this purpose, snap-frozen samples of rat fetal skeletal tissues were dried in a FDU 010 freeze-drying unit (Balzers) for 8–12 h at –50 to –40°C and 0.02 bar. Freeze-dried tissues were either vacuum-infiltrated at 45°C and embedded undemineralized in Paraplast, or vacuum-infiltrated overnight at 4°C and embedded undemineralized in glycol methacrylate. These procedures enabled enzyme cytochemistry for alkaline phosphatase and tartrate-resistant acid phosphatase, and immunocytochemical staining for collagen types I, III, and laminin to be performed on the same sections. No pretreatment of the sections was necessary to reveal collagen antigenicity. This study reveals the possibility of complementing immunocytochemical studies of extracellular matrix with enzyme cytochemistry and, above all, with the excellent tissue preservation and high resolution afforded by plastic embedding.     

Freeze-drying of bone tissue: immunocytochemistry and enzyme histochemistry on paraffin embedded and low-temperature resin embedded specimens.

A simple protocol of tissue preparation was sought, which would enable marker enzymes of bone cells and extracellular matrix antigens to be localized in the same tissue section with high optical resolution. For this purpose, snap-frozen samples of rat fetal skeletal tissues were dried in a FDU 010 freeze-drying unit (Balzers) for 8-12 h at -50 to -40 degrees C and 0.02 bar. Freeze-dried tissues were either vacuum-infiltrated at 45 degrees C and embedded undemineralized in Paraplast, or vacuum-infiltrated overnight at 4 degrees C and embedded undemineralized in glycol methacrylate. These procedures enabled enzyme cytochemistry for alkaline phosphatase and tartrate-resistant acid phosphatase, and immunocytochemical staining for collagen types I, III, and laminin to be performed on the same sections. No pretreatment of the sections was necessary to reveal collagen antigenicity. This study reveals the possibility of complementing immunocytochemical studies of extracellular matrix with enzyme cytochemistry and, above all, with the excellent tissue preservation and high resolution afforded by plastic embedding.     

Enzyme histochemistry on freeze-substituted glycol methacrylate-embedded tissue

We developed a method for histochemical demonstration of a wide range of enzymes in freeze-substituted glycol methacrylate-embedded tissue. Tissue specimens were freeze-substituted in acetone and then embedded at low temperature in glycol methacrylate resin. All enzymes studied (oxidoreductases, hydrolases) were readily demonstrated. The enzymes displayed high activity and were accurately localized without diffusion when tissue sections were incubated in aqueous media, addition of colloid stabilizers to the incubating media not being required. Freeze-substitution combined with low-temperature glycol methacrylate embedding permits the demonstration of a wide range of enzymes with accurate enzyme localization, maintenance of enzyme activity, and excellent tissue morphology.     

Enzyme histochemistry on freeze-dried, resin-embedded tissue

We have developed a method for histochemical demonstration of a wide range of enzymes in freeze-dried, resin-embedded tissue. Freeze-dried tissue specimens were embedded without fixation at low temperature (4 degrees C or -20 degrees C) in glycol methacrylate resin or LR Gold resin. Enzyme activity was optimally preserved by embedding the freeze-dried tissue in glycol methacrylate resin. All enzymes studied (oxidoreductases, esterases, peptidases, and phosphatases), except for glucose-6-phosphatase, were readily demonstrated. The enzymes displayed high activity and were accurately localized without diffusion when tissue sections were incubated in aqueous media, addition of colloid stabilizers to the incubating media not being required. Freeze-drying combined with low-temperature resin embedding permits the demonstration of a wide range of enzymes with accurate enzyme localization, high enzyme activity, and excellent tissue morphology.     

Gelatin In Situ Zymography on Fixed, Paraffin-embedded Tissue: Zinc and Ethanol Fixation Preserve Enzyme Activity

In situ zymography is a method for the detection and localization of enzymatic activity in tissue sections. This method is used with frozen sections because routine fixation of tissue in neutral-buffered formalin inhibits enzyme activity. However, frozen sections present with poor tissue morphology, making precise localization of enzymatic activity difficult to determine. Ethanol- and zinc-buffered fixative (ZBF) are known to preserve both morphological and functional properties of the tissue well, but it has not previously been shown that these fixatives preserve enzyme activity. In the present study, we show that in situ zymography can be performed on ethanol- and ZBF-fixed paraffin-embedded tissue. Compared with snap-frozen tissue, ethanol- and ZBF-fixed tissue showed stronger signals and superior morphology, allowing for a much more precise detection of gelatinolytic activity. Gelatinolytic enzymes could also be extracted from both ethanol- and ZBF-fixed tissue. The yield, as analyzed by SDS-PAGE gelatin zymography and Western blotting, was influenced by the composition of the extraction buffer, but was generally lower than that obtained from unfixed tissue. (J Histochem Cytochem 58:29–39, 2010)     

Radioimmunochemical methods for the quantitative autoradiographic determination of antigens in brain and other tissues

1. We have used horseradish peroxidase-conjugated protein A- and 125I-protein A to develop immunohistochemical and radioimmunohistochemical methods for the localization of antigens in brain and other tissues of the rat. 2. We visualized methionine-enkephalin fibers in the rat brain by incubating tissue sections with a specific polyclonal antibody and peroxidase-conjugated protein A. The method is simple, fast, and less expensive and more sensitive than classical immunohistochemical techniques and the principle could be used to visualize many other tissue antigens. 3. Incubation of tissue samples with specific polyclonal antibodies and 125I-protein A, followed by autoradiography, allows the permanent recording of the radioimmunohistochemical localization of brain methionine-enkephalin, tyrosine hydroxylase, and angiotensin-converting enzyme and of pituitary vasopressin and could be applied to the localization of many other tissue antigens. 4. A new quantitative radioimmunohistochemical technique for methionine-enkephalin allows the determination of the endogenous peptide content in discrete brain nuclei from 16-microns-thick sections. The method is based on the quantitative determination of the amount of 125I-protein A bound to specific tissue areas after incubation with a specific polyclonal antibody, followed by autoradiography and computerized microdensitometry. To quantify the endogenous peptide content, the values obtained are interpolated into a methionine-enkephalin internal standard curve. This standard curve was constructed by measuring endogenous concentrations of methionine-enkephalin by radioimmunoassay in specific brain regions and correlating these values with quantitative autoradiographic determinations in homologous areas of adjacent sections. Similar methods can be developed for other tissue antigens. 5. These new methods allow for the localization and quantification of tissue antigens in very discrete areas of the brain and other tissues and have a wide application in neurobiology and pathology.     

Colloidal gold immunostaining on deplasticized ultra-thin sections

We localized tissue antigens on ultra-thin sections by deplasticizing the sections while on the grid, incubating in primary antiserum followed by immunoglobulin-conjugated colloidal gold, and ultimately re-embedding in dilute Epon. This procedure permitted ultrastructural localization of tissue antigens that were previously masked by the embedding plastic surrounding tissue components. In addition, replacement of the plastic matrix on the thin section after immunostaining prevented development of the drying artifacts that occur in unsupported tissue sections. Optimal preservation of components in the tissue sections was achieved despite extensive steps involved in plastic removal and immunostaining. This method may be useful in situations where the number of exposed epitopes on the surface of a thin section is low. The procedure also allows the use of antisera at greater dilutions and provides enhanced immunostaining specificity with low background.     

Microwave incubation improves lipolytic enzyme preservation for ultrastr uctural cytochemistry

Standard methods for the ultrastructural detection of lipase and sphingomyelinase activities in the skin result in considerable loss of structural preservation, often interfering with accurate delineation of enzyme localization in association with specific organelles. Moreover, poor preservation occurs, even after extensive aldehyde prefixation, owing to the prolonged incubation times needed to detect residual enzyme activity, which often require non- physiological conditions. A modified incubation protocol is described here, which uses microwave irradiation in conjunction with drastically shortened incubation times, resulting in both superior ultrastructural preservation and excellent localization in mammalian epidermis. This method should be useful generally not only for the study of lipase localization in skin, but also in conjuction with the cytochemical detection of a variety of enzymes in various types of tissue. This revised version was published online in November 2006 with corrections to the Cover Date.     

ENZYME-LABELED ANTIBODIES FOR THE LIGHT AND ELECTRON MICROSCOPIC LOCALIZATION OF TISSUE ANTIGENS

Enzymes, either acid phosphatase or horseradish peroxidase, were conjugated to antibodies with bifunctional reagents. The conjugates, enzymatically and immunologically active, were employed in the immunohistochemical localization of tissue antigens utilizing the reaction product of the enzymatic reaction as the marker. Tissues reacted with acid phosphatase-labeled antibodies directed against basement membrane were stained for the enzyme with Gomori's method, and those reacted with peroxidase-labeled antibody were stained with Karnovsky's method. The reaction products of the enzymes localized in the basement membrane. Unlike the preparations of the fluorescent antibody technique, enzyme-labeled antibody preparations were permanent, could be observed with an ordinary microscope, and could be examined with the electron microscope. In the latter, specific localization of antibody occurred in the basement membrane and in the endoplasmic reticulum of cells known to synthesize basement membrane antigens. The method is sensitive because of the amplifying effect of the enzymatic activity. The ultrastructural preservation and localization were better with acid phosphatase-labeled antibody than with peroxidase-labeled antibody, but acid phosphatase conjugated antibody was unstable and difficult to prepare. Peroxidase-antibody conjugates were stable and could be stored for several months at 4°C, or indefiniely in a frozen state.     

ULTRATHIN FROZEN SECTIONS : II. Demonstration of Enzymic Activity

Endogenous enzyme activity can be readily and routinely demonstrated in ultrathin, frozen sections for electron microscopy. The procedure employed to obtain the best structural preservation as well as enzyme activity in thin sections involved fixation in glutaraldehyde, embedding in thiolated gelatin or pure gelatin, partial dehydration in glycerol, and sectioning in a cryostat at -35°C with a slightly modified Porter-Blum microtome on which the tissue is maintained at -70°C and the knife at -23°C. Kidney cortex was used as test tissue, but a few other organs were occasionally used. Thin sections were floated on the surface of several incubation media routinely employed for enzyme cytochemistry. Positive, specific reactions were obtained for alkaline phosphatase in kidney brush border, for adenosine triphosphatase in brush border and in basal membranes of distal tubules, for acid phosphatase and esterase in lysosomes, and for NADH diaphorase in mitochondria. Mitochondrial ATPase was sporadically evident only in the distal tubule of the kidney. Localizations of enzyme activity reported by other technical approaches were confirmed and in some cases somewhat improved.     

Immunocytochemical localization of neuronal antigens: tyrosine hydroxylase, substance P, [Met5]-enkephalin.

Neuronal antigens can be demonstrated histologically by numerous direct and indirect immunocytochemical techniques in which a specific antibody is identified by a marker compound such as fluorescein isothiocyanate, ferritin, or horseradish peroxidase. One of the more sensitive methods for the light and electron microscopic localizations of antigens in sections of tissue is the peroxidase-antiperoxidase (PAP) technique. The experimental procedures and the results obtained using this technique for the localization of the catecholamine synthesizing enzyme, tyrosine hydroxylase, are described. The cellular and ultrastructural localization of the enzyme is demonstrated in perikarya, processes, and terminals of catecholaminergic neurons in rat brain. The immunocytochemical localization of tyrosine hydroxylase is compared to the localization of two peptides, substance P and [Met5]-enkephalin, in the A2 region of the medulla. These studies suggest that a synaptic interaction exists between the catecholaminergic neurons and neurons showing positive immunoreactivity for the peptides. The limitations of the PAP immunocytochemical technique are also discussed in relation to the immunocytochemical localization of tyrosine hydroxylase and other antigens.     

Dehydrogenase enzyme histochemistry on freezedried or fixed resin-embedded tissue

Summary A method has been developed for the histochemical demonstration of a variety of dehydrogenases in freeze-dried or fixed resin-embedded tissue. Seven dehydrogenases were studied. Lactate dehydrogenase, NADH dehydrogenase and NADPH tetrazolium reductase were all demonstrable in sections of paraformaldehyde-fixed resin-embedded tissue. Freeze-dried specimens were embedded, without fixation, in glycol methacrylate resin or LR Gold resin at either 4°C or –20°C. All the dehydrogenases except succinate dehydrogenase retained their activity in freeze-dried, resin-embedded tissue. Enzyme activity was maximally preserved by embedding the freeze-dried tissue specimens in glycol methacrylate resin at –20°C. The dehydrogenases were accurately localized without any diffusion when the tissue sections were incubated in aqueous media. Addition of a colloid stabilizer to the incubating medium was not required. Freeze-drying combined with low-temperature resin embedding permits accurate enzyme localization without diffusion, maintenance of enzyme activity and excellent tissue morphology.     

Electron microscopical demonstration of glucose-6-phosphatase in native cryostat sections fixed with glutaraldehyde through semipermeable membranes.

The cytochemical demonstration of glucose-6-phosphatase (G6Pase) activity in native cryostat sections fixed with glutaraldehyde through semipermeable membranes is superior to conventional methods with regard to exact localization and lack of inactivation and diffusion of the enzyme, together with simultaneous excellent preservation of the tissue fine structure. In rat liver not only hepatocytes but also many bile duct epithelia and endothelia of arterioles and venules show a marked G6Pase activity in the membranes of the endoplasmic reticulum including the nuclear envelope.     

Histochemical localization of mushroom tyrosinase in whole tissue sections on nitrocellulose

Mushrooms were cut into vertical and horizontal sections. These sections were blotted onto nitrocellulose sheets and the sheets were then stained for tyrosinase using L-dopa. Tyrosinase was localized throughout the mushroom tissues but more enzyme was located in the epidermis of the cap, the gill region, and the stipe. Preincubation of the nitrocellulose sheets in specific inhibitors of tyrosinase completely blocked enzyme staining, suggesting that the enzyme stained areas on the nitrocellulose blots were regions of tyrosinase activity. Immunochemical localization of tyrosinase was similar to that observed by histochemical staining. Nitrocellulose blotting of mushrooms allows localizations of enzyme at the whole tissue level and may be useful for other enzymes in mushrooms as well.     

A new method for flat-embedding large native cryostat sections for targeting small preneoplastic lesions in comparative ultrastructural and ultracytochemical investigations

 Ultrastructural studies of rare and small cellular lesions in pathologically altered tissue are difficult to perform by applying conventional electron microscopic preparation. The search for lesions, often consisting of only a few cells in randomly obtained small specimen blocks, is time consuming and often without success. The methodological requirements for comparative enzyme cytochemical and morphological studies, i.e., preservation of both enzyme activity and ultrastructure, are divergent. By processing large native cryostat sections for electron microscopy, small preneoplastic focal lesions were successfully targeted in liver and kidney. Glucose-6-phosphatase, alkaline phosphatase, acid phosphatase, catalase, and cytochrome c oxidase activities were distinctly localized to endoplasmic reticulum, canalicular membrane, lysosomes, peroxisomes, and mitochondria, respectively, in the morphologically altered cells. Fixation of serial cryostat sections and enzyme reactions were both carried out through a semipermeable membrane except those for cytochrome c oxidase, which was demonstrated after fixation through the membrane by floating the section in incubation medium containing cytochrome c. Thereafter, the sections were flat embedded and polymerized between epoxy resin disks and aluminum dishes fitting exactly together. The objects of interest were identified in the light microscope, cut out, and reembedded in reversed gelatine capsules. By using this technique an ultrastructural preservation was achieved similar to that seen after immersion fixation. The enzyme activities were clearly localized without diffusion of the reaction product or unspecific deposits. The procedure permits precise targeting and complex studies of rare and small lesions, and opens new perspectives for the use of cryo-preserved tissue. Accepted: 10 March 1998     

Malignant growth in relation to enzyme activity

Conclusion In this paper the recent work on the various phases of oxidation enzymes, glycolysis and metabolic radiation are coordinated.The cumulative evidence of this study as well as that of the specific functions of vitamins and hormones — all support the conception that malignant growth characterised by abnormal glycolysis and absence of mitogenetic radiation is primarily due to a protracted inhibition of the oxidation enzyme activity.This enzyme inhibition is brought about by (A) the depletion of the enzyme source and (B) environmental conditions suppressing normal enzyme activity.This dualism is however but apparent as in both cases the resulting abnormal metabolism leads to the synthesis of suboxidised glycolytic products, analogous, if not identical, to carcinogenic substances obtained by the pyrogenic dehydrogenation of sterols and sexual hormones.These active unsaturated compounds appear to disturb the sulphydryl equilibrium, connected with the glutathione function and essential to normal cell proliferation.The uniformity in the type of cancerous cell metabolism irrespective of the variety of external causes and applicable to both spontaneous and synthetic cancer — in other words regardless whether the carcinogenic bodies are introduced or producedin situ — supports this conception.     

QUANTITATIVE ESTIMATION OF LYO- AND DESMOENZYMES IN TISSUE SECTIONS WITH AND WITHOUT FIXATION

1. Tissue sections eight microns thick were exposed to various experimental conditions used in histochemistry, and the effect upon the activities of esterase, the phosphatases, leucine aminopeptidase, β-glucuronidase, and arylsulfatase was determined colorimetrically. 2. Significant differences were found in the amounts of the lyo and desmo fractions of these enzymes. The desmo components were found to be for esterase, alkaline phosphatase, leucine aminopeptidase, acid phosphatase, β-glucuronidase, and arylsulfatase, ⅓, 2/3, 2/3, ½, ⅛, and ⅛ of the total enzymatic activity respectively. 3. Variations in the time and in the temperature at which diffusion was studied and of the pH and salt concentration of the solution into which the sections were placed, resulted in differences in the amount of enzymatic activity which remained in the tissue section. Some enzyme loss by diffusion was noted even after fixation of the tissue section. 4. The significance of the findings with respect to some of the concepts of localization of enzymes in tissue sections was discussed.