Standardization of various applications of methacrylate embedding and silver methenamine for light and electron microscopy immunocytochemistry

The use of butyl-methyl-methacrylate embedding and the application of the silver methenamine (SM) method as a poststaining of the immunoperoxidase-DAB (IP) procedure led to the standardization of several useful methods for the visualization of tissue antigens at the light and electron microscope level. These procedures included: 1) Standardization of the actual methacrylate embedding; 2) The IP-SM method with and without periodic acid oxidation, which provided 100% intensification of the IP staining; 3) The IP-SM method made it possible to stain semithin sections (0.5 micron), and this in turn, permitted a) clear visualization under the light microscope of the intracellular distribution of antigens and, b) staining, in several adjacent sections, of roughly the same cytoplasmic region of the same cell with different primary antisera; 4) a double immunostaining whereby the first antigen in the sequence was revealed by the IP-SM method and the second by the IP procedure; 5) standardization of the IP and the IP-SM methods for post-embedding staining of ultrathin methacrylate sections. The combined application of methacrylate embedding and the IP-SM, and the use of an appropriate fixative, resulted in an ultrastructural immunocytochemical procedure characterized by a good immunoreactivity of the tissue sections, a strong and selective immunoreaction and a well preserved ultrastructure.     

Immuno gold staining (IGS) for electron microscopical demonstration of glial fibrillary acidic (GFA) protein in LR white embedded tissue

Post-embedding immunocytochemical staining methods using gold have so far failed to label intermediate filament antigens in situ in epon or araldite embedded tissue. We have now applied the post-embedding immuno gold staining (IGS) technique for LR White embedded tissue. Glial fibrillary acidic (GFA) protein immunoreactivity was clearly demonstrated electron microscopically on astrocytic filaments of rat cerebellum in situ.     

Fc-mediated nonspecific staining of the porcine brain with rabbit antisera in immunocytochemistry is prevented by pre-incubation of the sera with proteins A and G.

Nonspecific staining was detected in immunocytochemical procedures on the porcine hypothalamus with rabbit antisera, irrespective of the antigen specificity of the sera, in magnocellular neurons of the paraventricular (PVN) and supraoptic nuclei (SON), and in the vasopressin- and oxytocin-containing nucleus (VON). The present study was designed to test the hypothesis that this staining is mediated by the Fc portion of rabbit immunoglobulins. Rabbit antisera against neuropeptides localized predominantly outside the PVN, SON, and VON were employed in combination with different detection methods. The intensity of the nonspecific staining varied depending on the antiserum and persisted after pre-absorption of the antisera with their homologous peptides. Nonspecific staining and antigen-specific staining were differentially affected by the method of tissue fixation. The nonspecific staining could be prevented by preincubation of the antisera with proteins A and G, which left the antigen-specific staining intact, whereas additional preabsorption with homologous peptide abolished all staining. These observations suggest that the Fc region of IgGs is indeed involved in the nonspecific staining. On press-blots of homogenates from SON tissue subjected to isoelectric focusing, one band in the low-pH region was found with all antisera. Pre-incubation of the antisera with protein A abolished the staining of this band but did not affect staining of antigen-specific bands. Pre-incubation with proteins A and G is proposed as a routine control to check for nonspecific staining mediated by the Fc region of IgGs in immunocytochemical procedures, particularly those that employ rabbit sera in porcine brain.     

Amplification methods for the immunolocalization of rare molecules in cells and tissues

The needs to precisely assign macromolecules to specific locations and domains within tissues and cells and to reveal antigens which are present in low or even in trace amounts, led to the elaboration of a wide spectrum of immunocytochemical amplification procedures. These arise from the successive improvements of tissue preparation techniques, of antigen retrieval procedures and of immunological or non-immunological detection systems. Improvement of detection systems may be the most active in the development of amplification techniques. Since the early work of Coons, in which by the introduction of the indirect technique has started amplifying the signal, different systems have succeeded in increasing the sensitivity of antigens detection. Indeed, amplification techniques such as the multiple antibody layers, the multiple bridges, the enzyme complexes, the avidin-biotin, the silver intensification, and the numerous variations and combinations among these have increased the sensitivity for the detection of scarce tissue antigens. However, as shown by the recent progress carried out with new approaches such as the catalyzed reporter deposition (CARD) and the enhanced polymer one-step staining (EPOS), more efficient methods are still needed. In electron microscopy, few techniques have reached the resolution afforded by the post-embedding immunogold approach. In spite of this and in order to further increase its sensitivity, new probes and novel approaches are allowing combination of the gold marker with the amplification capacity of enzymes afforded by the CARD technique. Immunogold amplification strategies, such as the multiple incubations with the primary antibody and the use of an anti-protein A antibody have also led to enhanced signals displaying the advantages in terms of resolution and possibilities of quantification inherent to the colloidal gold marker.     

Detection of Cell Surface Antigens in Tissue Sections by Means of Pre-Embedding Immunogold Staining

The immunogold technique has been used in electron microscopy to detect cytoplasmic and extracellular antigens by postembedding techniques. It has also been used to detect plasma-membrane-associated molecules on suspended cells and, recently, to visualise cell surface antigens in ultrathin sections of Lowicryl embedded specimens. In the present study, cell surface antigens of rat kidney and human skin were identified in tissue sections by using pre-embedding immunogold labeling. Brush border microvillar antigens and dermal lymphocyte antigens both bound numerous gold particles. The immunogold staining described here has the advantage over immunoperoxidase procedures that it is not subject to diffusion or reabsorption artifacts, and allows estimation of the antigen density on labeled cells. Furthermore, this pre-embedding immunogold technique is ideally suited to detecting cell surface-associated antigens since it preserves antigenicity, allows gold particle penetration and enhances cell membrane profiles.     

Detection of cell surface antigens in tissue sections by means of pre-embedding immunogold staining

The immunogold technique has been used in electron microscopy to detect cytoplasmic and extracellular antigens by postembedding techniques. It has also been used to detect plasma-membrane-associated molecules on suspended cells and, recently, to visualize cell surface antigens in ultrathin sections of Lowicryl embedded specimens. In the present study, cell surface antigens of rat kidney and human skin were identified in tissue sections by using pre-embedding immunogold labeling. Brush border microvillar antigens and dermal lymphocyte antigens both bound numerous gold particles. The immunogold staining described here has the advantage over immunoperoxidase procedures that is not subject to diffusion or reabsorption artifacts, and allows estimation of the antigen density on labeled cells. Furthermore, this pre-embedding immunogold technique is ideally suited to detecting cell surface-associated antigens since it preserves antigenicity, allows gold particle penetration and enhances cell membrane profiles.     

Sensitivity and nonspeicific staining of various immunoperoxidase techniques

Optimally fixed paraffin enbedded tissue sections and cytocentrifuged cell smears were used to test the sensitivity and nonspecific staining with the enzyme-bridge, PAP, indirect and direct immunoperoxidase methods using human immunoglobulins and lysozyme as antigens. With the enzyme-bridge method positive staining was seen with primary antiserum dilutions up to 1:20,000. The least background staining was observed with this method. The PAP method was equally sensitive, although false-negative results with low primary antiserum dilutions were seen. Some nonspecific background staining always persisted using the PAP method even with high primary antiserum dilutions. The indirect method was not as sensitive as the enzyme-bridge method and some nonspecific staining always persisted. The direct method was too insensitive with paraffin embedded tissue sections.     

Combined use of immunoperoxidase and radioimmunocytochemistry for double immunocytochemical labeling of neurons at light and electron microscopic level

Complexes formed by binding 125I- or 3H-labeled neuropeptides to one of the two binding sites of their specific antibodies allowed specific and sensitive labeling of various peptidergic neurons, which could be detected by classical autoradiographic methods. To visualize two neuronal antigens on the same material at both light and electron microscopic level, we used a new technique of double immunocytochemical labeling, combining immunoperoxidase and radioimmunocytochemistry. The main steps of the process included: (a) indirect labeling of the first antigen by its specific antibody and by a peroxidase-labeled Fab immunoglobulin fragment directed against the primary antibody; (b) direct labeling of the second antigen by a radiolabeled peptide-antibody complex; (c) revealing of the first label in the presence of peroxidase substrate; and (d) revealing of the second label by autoradiographic treatment of tissue sections. Compared with other known techniques of double immunostaining, this technique offers major advantages for combined visualization of two neuronal antigens at the electron microscopic level: (a) two neuron types can be labeled by a pre-embedding approach, allowing highly sensitive detection of neuronal antigens throughout the 50-microns thickness of vibratome sections; (b) two primary antibodies obtained in the same species can be used to label the two antigens without any risk of crossreactions between the two successive labelings; and (c) the two labels can easily be differentiated, even when they are co-localized within the same neuron structures. Application of this double immunostaining technique is illustrated by data obtained in rat hypothalamus concerning the relationships among a variety of identified neurons and the co-localization of different neuropeptides within the same neuron system.     

Immunocytochemical localization of nuclear antigens in the unicellular green alga,Chlamydomonas reinhardtii,processed by cryofixation and freeze-substitution

Summary We describe the preparation of monoclonal antibodies to nuclear antigens in the green alga,Chlamydomonas reinhardtii, and their localization at the light and electron microscope level. Supernatants from hybridomas were screened by the ELISA method and the four antibodies giving the strongest signal were subjected to further analysis. At the LM level immunogold silver staining was used on semi-thick resinless sections. We have examined at the EM level the distribution of these antigens by post-embedding immunocytochemical techniques on sections of conventionally fixed specimens compared to cryofixed and freeze-substituted ones. Enhanced ultrastructural preservation was observed in cells which were cryofixed, freeze-substituted and embedded at –35°C in Lowicryl K4M. Different preparative procedures involving cryofixation and substitution are described. Of the four antibodies three were localized under light and electron microscopy. All three were distributed in the interchromatin space. One of these antigens (QUL4D2, 54 kDa) is also found in the dense fibrillar component and fibrillar centers of the nucleolus.Abbreviations DFC dense fibrillar component - EM electron microscope - FC fibrillar center - GAM5 goat anti-mouse IgM coupled to 5 nm colloidal gold - Ig immunoglobulin - LM light microscope - MAb monoclonal antibody - PAG protein A-gold - PBS phosphate buffered saline - PEG polyethylene glycol     

Postembedding immunocytochemical localization of paramyxovirus antigens by light and electron microscopy

A postembedding method is described to localize antigens specific for various paramyxoviruses in sections of cells and tissues that have been fixed and embedded in epoxy resins for conventional electron microscopy. Viral antigens were localized in CV-1 cell cultures infected with simian virus 5 (SV5), brains of suckling hamsters inoculated with either neuroadapted mumps virus or hamster-adapted measles virus, and brains of adult mice infected with Sendai (parainfluenza I) virus. Both 1-micrometer-thick and thin (gold) tissue sections were etched with alcoholic sodium hydroxide-solution and then treated following either the unlabeled antibody peroxidase-antiperoxidase or the biotinylated protein A:avidin peroxidase procedure. Primary reagents included immunoglobulin isolated from hyperimmune rabbit sera with specificity to the major viral components of SV5 or SV5 hemagglutinin-neuraminidase, to whole mumps virus or mumps virus nucleocapsids, and to whole Sendai virus. Crude rabbit anti-Sendai virus antiserum and whole human subacute sclerosing panencephalitis (SSPE) sera were used in parallel. The results indicate that tissues processed for conventional evaluation by electron microscopy may be suitable, within limits, for postembedding immunocytochemical staining of paramyxovirus antigens.     

Sequential use of the PAP and immunogold staining methods for the light microscopical double staining of tissue antigens: Its application to the study of regulatory peptides in the gut

Double immunoperoxidase staining using different couplers can give various combinations of colours on a single tissue section to achieve a comparable picture of different antigens. However, the colour combinations achieved to date are not entirely satisfactory.A double immunostaining procedure is introduced here, combining the peroxidase anti-peroxidase (PAP) and immunogold staining (IGS) methods. The IGS method is a new, simple, sensitive and reliable approach to immunostaining at the light microscopic level. It was carried out in three ways. Firstly, a two-step method was used in which the second layer was goat anti-rabbit IgG adsorbed onto gold particles (GAR/Au20). Secondly, a three-step method was employed where the second layer was unlabelled goat anti-rabbit IgG and the third layer was a rabbit antibody to peroxidase adsorbed onto the gold particles (RAP/Au20) and acting as a gold-labelled IgG antigen. The third method combined the first two methods using GAR/Au20 as the second layer and RAP/Au20 as the third layer which increased the amount of bound gold and enhanced the red colour, providing a better picture.The use of gold-labelled antibodies in double immunostaining has great potential value for many studies including that of the diffuse neuroendocrine system of the gut.     

Enhancement of Antigenic Site Detection with Gold Labeled Secondary and Tertiary Antibodies Using the Immunogold-Silver Staining Method

We report a modification of the immunogold-silver staining method (IGSS) for localizing hepatic phosphoenolpyruvate carboxykinase (PEPCK) in tissue sections, and we compare the efficacy of localizing the primary antibody with either a 5 nm gold labeled secondary antibody or 5 nm gold labeled secondary and tertiary antibodies. Light microscope examination of 10 μm frozen sections demonstrated that the use of combined secondary and tertiary gold labeled antibodies was superior to using a secondary gold labeled antibody alone. The increased labeling density (number of colloidal gold particles/antigenic site/cell) achieved by combined gold labeled antibodies was confirmed by electron microscopy. The increased labeling density resulted in a two-thirds reduction in the time needed for the IGSS physical development of the silver shells and less background. We achieved intense specific staining of hepatocytes expressing PEPCK while minimizing background staining. The use of combined secondary and tertiary gold labeled antibodies enhances the signal-to-noise ratio, achieves high resolution and is a suitable method for use in both light and electron microscopy.     

Sensitivity and nonspecific staining of various immunoperoxidase techniques

Summary Optimally fixed paraffin embedded tissue sections and cytocentrifuged cell smears were used to test the sensitivity and nonspecific staining with the enzyme-bridge, PAP, indirect and direct immunoperoxidase methods using human immunoglobulins and lysozyme as antigens. With the enzyme-bridge method positive staining was seen with primary antiserum dilutions up to 1:20,000. The least background staining was observed with this method. The PAP method was equally sensitive, although false-negative results with low primary antiserum dilutions were seen. Some nonspecific background staining always persisted using the PAP method even with high primary antiserum dilutions. The indirect method was not as sensitive as the enzyme-bridge method and some nonspecific staining always persisted. The direct method was too insensitive with paraffin embedded tissue sections.Supported by the Sigrid Jusélius Foundation and Finska Läkaresällskapet     

Standardization of various applications of methacrylate embedding and silver methenamine for light and electron microscopy immunocytochemistry

Summary The use of butyl-methyl-methacrylate embedding and the application of the silver methenamine (SM) method as a poststaining of the immunoperoxidase-DAB (IP) procedure led to the standardization of several useful methods for the visualization of tissue antigents at the light and electron microscope level. These procedures included: 1) Standardization of the actual methacrylate embedding; 2) The IP-SM method with an without periodic acid oxidation, which provided 100% intensification of the IP staining; 3) The IP-SM method made it possible to stain semithin sections (0.5 m), and this in turn, permitted a) clear visualization under the light microscope of the intracellular distribution of antigens and, b) staining, in several adjacent sections, of roughly the same cytoplasmic region of the same cell with different primary antisera; 4) a double immunostaining whereby the first antigen in the sequence was revealed by the IP-SM method and the second by the IP procedure: 5) standardization of the IP and the IP-SM methods for post-embedding staining of ultrathin methacrylate sections.The combined application of methacrylate embedding and the IP-SM, and the use of an appropriate fixative, resulted in an ultrastructural immunocytochemical procedure characterized by a good immunoreactivity of the tissue sections, a strong and selective immunoreaction and a well preserved ultrastructure.Supported by Grant RS-82-18 from Dirección de Investigaciones, Universidad Austral de Chile, Chile     

Colloidal gold probes in immunocytochemistry. An optimization of their application in light microscopy by use of silver intensification procedures

Colloidal gold particles are the markers of choice for ultrastructural localization of antigens. By reducing gold chloride with tannic acid and trisodium citrate, a broad range of narrowly determined particle sizes can be obtained. Such particles can easily be coupled to a number of proteins and the resulting conjugates are conveniently purified on a gel-chromatography column. Their application in light microscopy requires an amplification step with a silver physical developer. Silver-intensified colloidal gold probes can advantageously be used for immunostaining of cryostat, paraffin and plastic sections. Moreover, permeabilized cultured cells and whole-mount preparations can also be stained with gold-silver techniques. Silver intensification does not affect reactivity of a number of tissue antigens, thus permitting double staining combinations with immunoperoxidase or immunofluorescence methods.     

Enhanced immunocytochemical staining sensitivity in formalin-fixed and paraffin-embedded material by simultaneous use of PAP and ABC

The simultaneous use of two immunoperoxidase (IP) methods; e.g. the PAP (Peroxidase-antiperoxidase) and ABC (Avidin-Biotin) to localize a single antigen enhances the sensitivity of polyclonal antibodies (FVIII/RAg and laminin) or monoclonal antibodies (MABs) (against human B-, T-cells and macrophages) in routinely formalin fixed and in paraffin embedded material. The increased sensitivity was not accompanied by loss of specificity. With antibodies against Factor VIII related antigen (FVIII/RAg) and laminin the increased staining intensity of blood vessels were demonstrated in experimental rat transplantation tumors. The similar enhancement of immunocytochemical reactions was observed with biopsies of human brain tumors, where the monoclonal antibodies against white blood cells were used. The staining results were of comparable intensity as in snapfrozen tissue or after special embedding procedure for immunocytochemical purposes acc. to Bolton and Mesnard formol sucrose gum, sucrose paraffin; FSGSP).     

A modification of the unlabeled antibody enzyme method using heterologous antisera for the light microscopic and ultrastructural localization of insulin, glucagon and growth hormone.

The requirement of using homologous antisera (primary antiserum and peroxidase-antiperoxidase (PAP) complex raised in the same species) in the unlabeled antibody enzyme method has been investigated at the light and electron microscopic level using the localization of insulin, glucagon and growth hormone as model systems. Optimum immunocytochemical staining for all three antigens was observed when sheep or goat antirabbit gamma-globulin (S-ARgammaG or G-ARgammaG) were used to couple rabbit peroxidase-antiperoxidase complex with either guinea pig antisera to insulin (GP-AIS) or glucagon (GP-AGS), or monkey antisera to rat growth hormone (M-ARGH). The cross-reactivity between S-ARgammaG or G-ARgammaG and immunoglobulins in these primary antisera were substantiated by immunoelectrophoresis and radioimmunoassay. S-ARgammaG was shown to produce precipitation arcs with GP-AIS and M-ARGH that were similar to those seen when the latter were reacted with rabbit antiguinea pig gamma-globulin antiserum and goat antimonkey gamma-globulin antiserum, respectively. Radioimmunoassay results revealed that immunoprecipitation of 6-10% as compared to homologous antisera controls yielded excellent staining localization when S-ARgammaG was used for immunocytochemistry. Thus, heterologous antisera (primary antiserum and PAP complex raised in different species) may be used in the unlabeled antibody enzyme method as long as the coupling antiserum shows cross-reactivity with immunoglobulins of the primary antiserum and the PAP complex.     

Localization of hepatitis A antigen in liver tissue by peroxidase-conjugated antibody method: light and electron microscopic studies.

Hepatitis A antigen (HAAG) was localized in liver tissue from marmosets inoculated with human hepatitis A virus (HAV) by light and electron microscopy by using a peroxidase-conjugated antibody method. The fine granular peroxidase staining was scattered throughout the cytoplasm of liver cells when viewed with the light microscope. The distribution of HAAg-positive cells was focal. Virus-like particles, 24 to 27 nm in diameter, were observed in the cytoplasm of hepatocytes and smaller cells, resembling Kupffer cells, by standard thin-section electron microscopy (thin section EM). By immunoperoxidase electron microscopy (immunoperoxidase EM), HAAg was detected on the particles, which were aggregated within cytoplasmic vesicles of the hepatocyte. The surrounding membrane of the vesicles was also HAAg- positive. Similar HAAg particles were observed in the cytoplasm of smaller cells adjacent to hepatocytes as well. Thus, immunoperoxidase EM revealed that the 24- to 27-nm virus-like particles in the cytoplasm of liver cells obtained from marmosets were infected with HAV contained HAAg.     

Detection of polysaccharide, teichoic acid, and protein antigens in bacterial colonies on an agar surface

An improved method of using fluorescein-labeled antibody for the detection of polysaccharide, protein, and teichoic acid antigens synthesized by streptococcal colonies on an agar surface is described. The bacteria were grown on the surface of an agar medium contained in the shallow well of an immunodiffusion slide. An agar overlay containing the fluorescein antiserum was dispensed over the colonies, excess antiserum was washed out of the overlay agar, and the fluorescent colonies were observed under an ultraviolet microscope. The shallow well in the immunodiffusion slide prevented the agar from floating loose during washing, and the agar overlay prevented the fragmentation and loss of colonies. The thin layer of agar facilitated microscopic examination and the counting of fluorescent and nonfluorescent colonies. Colonies producing an antigen against which the antiserum was directed could readily be distinguished from colonies not producing the antigen. The specificity of the method was shown by using mixtures of streptococci representing six serological groups and five types. Those not known to possess cross-reacting antigens were specific in their reaction to the fluorescein antibody. Cross-reactions between the group antigens of A, C, and G, as reported previously by fluorescent staining of streptococcal suspensions, were also seen. Group A colonies reacted weakly with fluorescent E antibody and vice versa. The extraction of this antigen with cold trichloroacetic acid indicates it was related to the teichoic acids. Colonies possessing polysaccharide, protein, and teichoic acid antigens gave equally strong fluorescent reactions. This procedure permits detection of the synthesis of antigen which could not be observed by the use of a selective medium; it also eliminates the necessity for subculture of each colony and testing by appropriate serological means. Such a technique has value for studies in classification and biochemical genetics, and should be applicable to other genera of bacteria.