Use of anti-horseradish peroxidase antibody-gold complex in the ABC technique.

We report a modification of the avidin-biotin-peroxidase complex (ABC) technique for the light and electron microscopic detection of antigens in tissue sections. An immunological approach was used instead of the DAB reaction to reveal ABC bound to antigen-antibody complexes. Affinity-purified polyclonal antibodies against horseradish peroxidase were complexed to particles of colloidal gold and applied for reaction with the horseradish peroxidase molecules of the ABC. For light microscopic immunolabeling, the signal produced by the anti-horseradish peroxidase antibody-gold complex required silver intensification. The ABC immunogold reaction as compared with the standard ABC technique, in particular with silver intensification of the DAB reaction product, provided superior resolution in paraffin sections. Furthermore, section pre-treatment to block endogenous peroxidase activity could be omitted and no potentially hazardous substrate was used. The ABC immunogold reaction was successfully applied for electron microscopic immunolabeling on Lowicryl K4M thin sections. We propose that the ABC immunogold reaction is a useful alternative to the standard ABC technique and can be equally well applied to light and electron microscopy.     

Prevention of non-specific interactions of gold-labeled reagents on tissue sections

The protein A-gold technique is amongst the most useful labeling techniques available for light and electron microscopic immunolabeling. Some electron microscopic studies, however, have suggested that protein A-gold, and other protein-gold complexes as well, may bind non-specifically to certain tissue structures, particularly in skin, creating a specious pattern of labeling. We utilized the protein A-gold technique with antiserum to both involucrin and keratin under a variety of conditions to document the specificity of labeling. When the standard conditions were followed, the protein A-gold technique produces highly specific results. These conditions include: 1. the blocking of unreacted aldehyde groups by amination; 2. the blocking of non-specific binding sites on tissue sections by preincubation with inert proteins; and 3. the use of proper concentration of the protein A-gold complex. However, non-specific labeling could be produced if the three components of the standard protocol were omitted. In particular, the use of too concentrated protein A-gold lead to non-specific labeling. We report here also updated working protocols for antigen detection with protein A-gold on semithin Lowicryl K4M and paraffin sections which provide optimal staining results.     

Light microscopical detection of antigens and lectin binding sites with gold-labelled reagents on semi-thin Lowicryl K4M sections: Usefulness of the photochemical silver reaction for signal amplification

Summary In the present study, we have investigated the applicability of semi-thin sections from low temperature Lowicryl K4M-embedded tissues for cytochemical labelling with protein A—gold and lectin—gold complexes. In order to ensure the best possible signal-to-noise ratio antibodies, protein A—gold and lectin—gold were applied in concentrations used for labelling at the electron microscope level. Furthermore, due to the lack of an appropriate chemical procedure for resin removal, untreated semi-thin sections were incubated. Under such conditions, semi-thin sections displayed either no visible staining or only a faint incomplete staining. However, following photochemical silver reaction, the latent or faint incomplete staining was rendered visible in most cases. It is concluded that the same block of Lowicryl K4M-embedded tissue and the same labelling reagents can be used for both light and electron microscopical cytochemical studies. At the light microscopical level, a high degree of structural and specific staining information is obtained. The reactivity of cellular components with antibodies or lectins is preserved even after years of storage of the blocks or slides containing semi-thin sections.     

High-resolution immunogold localization of Giardia cyst wall antigens using field emission SEM with secondary and backscatter electron imaging

We describe here the ultrastructural localization of Giardia cyst antigens in the filaments associated with the outer portion of intact cysts and on developing cyst wall filaments in encysting trophozoites. Post-embedding immunogold labeling of thin sections of intact Giardia cysts with polyclonal and monoclonal antibodies specific for cyst wall antigens (major protein bands of approximately 29, 75, 88, and 102 KD on Western blots) showed strong labeling of the filamentous cyst wall, whereas no labeling was seen on the membranous portion. High-resolution field emission scanning electron microscopy (FESEM) of Giardia cysts revealed that the cyst wall-specific polyclonal rabbit antisera and monoclonal mouse antibody produced gold labeling of 20-nm filaments in the cyst wall as detected with secondary electron imaging (SEI) and backscatter electron imaging (BEI) at 10 kV, despite coating of the cells with platinum by ion sputtering. FESEM studies of encysting Giardia trophozoites demonstrated that immunostaining with antibodies to cyst wall antigens produced colloidal gold labeling of developing cyst wall filaments on the cell surface; however, the intervening membrane domains were unlabeled. Substitution of normal serum for cyst wall-specific antibodies, or preabsorption of specific antibodies with Giardia cysts, eliminated immunolabeling of the filaments.     

Heparan sulfate proteoglycan is present in basement membrane as a double-tracked structure

Basement membranes contain 4.5-nm wide sets of two parallel lines, along which short prongs called "spikes" occur at regular intervals. The nature of this structure, referred to as "double tracks," was investigated in Lowicryl sections of mouse kidney and rat Reichert's membrane immunolabeled for basement membrane components using secondary antibodies conjugated to 5-nm gold particles. When the mouse glomerular basement membrane and rat Reichert's membrane were exposed to antibodies directed to the core protein of heparan sulfate proteoglycan, 95% or more of the gold particles were over double tracks, whereas after exposure of Reichert's membrane to antisera against laminin, collagen IV, or entactin, labeling of the double tracks remained at the random level. When heparan sulfate proteoglycan was incubated in Tris buffer, pH 7.4, at 35 degrees C for 1 hr, a precipitate resulted which, on electron microscopic examination, was found to consist of 5- to 6-nm wide sets of two parallel lines along which densities were observed. Immunolabeling confirmed the presence of the proteoglycan's core protein in the sets. Since double tracks were closely similar to this structure and were labeled with the same antibodies, they were likely to be also composed of heparan sulfate proteoglycan.     

Re-evaluation of epoxy resin sections for light and electron microscopic immunostaining.

Epoxy resins provide optimal tissue morphology at both the light and the electron microscopic level and therefore enable correlative studies on semithin and thin sections from the same tissue block. Here we report on an approach to retain these advantages for immunolabeling studies by adapting and combining well-known techniques, i.e., surface etching with sodium ethoxide and heat-mediated antigen retrieval. We propose a simple procedure for immunostaining semithin and thin epoxy resin sections. To check its applicability, well characterized, commercially available antibodies (against E-cadherin, alpha-catenin, and beta-catenin) were used on sections of human small intestine. By light microscopy, the immunostaining efficiency was compared on cryo-, paraffin, and epoxy semithin sections processed in parallel. The most detailed results were obtained on semithin sections, where the labeling precisely delineated the lateral plasma membrane of the enterocytes. At the electron microscopic level the procedure did not damage the structures and allowed an efficient, reproducible immunogold labeling extending homogeneously over exceptionally wide tissue areas. The three antibodies specifically labeled the zonula adherens of the junctional complex between epithelial cells and, in agreement with light microscopic observations, the lateral plasma membrane.     

Immunohistochemical study of basement membrane reconstruction by an epidermis-dermis recombination experiment using cultured chick embryonic skin: induction of tenascin.

The production of extracellular matrix components such as laminin, Type IV collagen, fibronectin, and tenascin during the formation of basement membrane in cultured epidermis-dermis recombinant skin of 13-day-old chick embryo was analyzed immunohistochemically. The epidermis and dermis were separated from each other by treatment with EDTA and/or dispase. The basal lamina of the basement membrane was thus removed from both epidermis and dermis. The isolated epidermis was overlaid onto the isolated dermis, i.e., recombined, and then cultured for 1-7 days in a chemically defined medium (BGJb) on a Millipore filter. Immunofluorescence labeling was used for light microscopy and HRP or colloidal gold labeling for electron microscopy. In specimens from 2-day cultures, positive sites of anti-laminin and anti-fibronectin reaction were observed light microscopically as patches which, at the electron microscopic level, corresponded to fragments of the basal lamina located immediately beneath and in the vicinity of the attachment plaques of the hemidesmosomes. The staining pattern became continuous 7 days after recombination. Fluorescence labeling of laminin and fibronectin appeared somewhat earlier than that of Type IV collagen and tenascin. All of the four components were found localized primarily in the basal lamina. Furthermore, fibronectin and tenascin were also distributed in the extracellular matrix of the dermis. The expression of tenascin, which does not exist in the basement membrane of 13-day-old intact embryonic skin, was induced in vitro. These results suggest that hemidesmosomes may play an important role in the reconstruction of the basement membrane and that various components of the basement membrane appeared at different times during the reconstruction.     

Evaluation of immunoelectron microscopic techniques in the study of basement membrane antigens

 Recent technical advances in immunoelectron microscopy (IEM), including methods of pre- and postembedding IEM and cryoultramicrotomy, have helped to elucidate the precise ultrastructural localization of various basement membrane-related molecules. Our objective was to evaluate the advantages and disadvantages of several different techniques for studying the ultrastructural organization of basement membrane components. We found that, while ”on-surface” immunolabeling of postembedding IEM and cryoultramicrotomy with anti-type IV collagen or anti-laminin-5 antibody clearly demonstrated dense labeling on the lamina densa, preembedding IEM with a 1-nm ultra-small gold probe showed labeling only on the epidermal and/or dermal surfaces of the lamina densa, with no specific gold particles being seen within the lamina densa itself. These results indicate that even ultra-small colloidal gold-labeled antibody fails to penetrate the lamina densa in preembedding IEM. However, labeling with a GB3 monoclonal antibody against laminin-5 was demonstrable with preembedding IEM and cryoultramicrotomy, but not with post-embedding IEM, probably due to a loss of antigenicity. These results confirm the advantages and limitations of these techniques of IEM and emphasize the importance of using different techniques of IEM in determining the precise ultrastructural distribution of basement membrane antigens. Accepted: 30 January 1998     

Prevention of non-specific interactions of gold-labeled reagents on tissue sections

Summary The protein A-gold technique is amongst the most useful labeling techniques available for light and electron microscopic immunolabeling. Some electron microscopic studies, however, have suggested that protein A-gold, and other protein-gold complexes as well, may bind non-specifically to certain tissue structures, particularly in skin, creating a specious pattern of labeling.We utilized the protein A-gold technique with antiserum to both involucrin and keratin under a variety of conditions to document the specificity of labeling. When the standard conditions were followed, the protein A-gold technique produces highly specific results. These conditions include: 1. the blocking of unreacted aldehyde groups by amination; 2. the blocking of non-specific binding sites on tissue sections by preincubation with inert proteins; and 3. the use of proper concentration of the protein A-gold complex. However, non-specific labeling could be produced if the three components of the standard protocol were omitted. In particular, the use of too concentrated protein A-gold lead to non-specific labeling.We report here also updated working protocols for antigen detection with protein A-gold on semithin Lowicryl K4M and paraffin sections which provide optimal staining results.Part of this work was presented at the 17th World Congress of Dermatology, Berlin (West), May 24–29, 1987     

Localization of immunoreactive tyrosine hydroxylase in the goldfish retina with pre-embedding immunolabeling with one-nanometer colloidal gold particles and gold toning.

The goal of this study was to develop an alternative to silver intensification for visualizing small colloidal gold particles by light and electron microscopy. The isolated goldfish retina was labeled with rabbit antiserum to tyrosine hydroxylase and 1-nm colloidal gold-conjugated goat anti-rabbit IgG. The gold particles were enlarged by toning with gold chloride, followed by reduction in oxalic acid. Dopaminergic interplexiform cells were clearly visible by light microscopy and, in lightly-fixed material treated with detergent, they were labeled in their entirety. Labeling was qualitatively similar, although less extensive, in material fixed and processed for electron microscopy. The labeled processes were apparent in ultra-thin sections viewed at low magnification, but the gold-toned particles were not so large that they obscured subcellular structures. The procedure apparently had no deleterious effects on the tissue, since the ultrastructural preservation was comparable to that seen with other pre-embedding immunolabeling methods. The technique was simple, reliable and, since the gold solutions were so dilute, relatively inexpensive.     

In situ hybridization at the electron microscope level: localization of transcripts on ultrathin sections of Lowicryl K4M-embedded tissue using biotinylated probes and protein A-gold complexes

A technique has been developed for localizing hybrids formed in situ on semi-thin and ultrathin sections of Lowicryl K4M-embedded tissue. Biotinylated dUTP (Bio-11-dUTP and/or Bio-16-dUTP) was incorporated into mitochondrial rDNA and small nuclear U1 probes by nick-translation. The probes were hybridized to sections of Drosophila ovaries and subsequently detected with an anti-biotin antibody and protein A-gold complex. On semi-thin sections, probe detection was achieved by amplification steps with anti-protein A antibody and protein A-gold with subsequent silver enhancement. At the electron microscope level, specific labeling was obtained over structures known to be the site of expression of the appropriate genes (i.e., either over mitochondria or over nuclei). The labeling pattern at the light microscope level (semi-thin sections) was consistent with that obtained at the electron microscope level. The described nonradioactive procedures for hybrid detection on Lowicryl K4M-embedded tissue sections offer several advantages: rapid signal detection: superior morphological preservation and spatial resolution; and signal-to-noise ratios equivalent to radiolabeling.     

The molecular organization of myosin in stress fibers of cultured cells

Antibodies to chicken gizzard myosin, subfragment 1, light chain 20, and light meromyosin were used to visualize myosin in stress fibers of cultured chicken cells. The antibody specificity was tested on purified gizzard proteins and total cell lysates using immunogold silver staining on protein blots. Immunofluorescence on cultured chicken fibroblasts and epithelial cells exhibited a similar staining pattern of antibodies to total myosin, subfragment 1, and light chain 20, whereas the antibodies to light meromyosin showed a substantially different reaction. The electron microscopic distribution of these antibodies was investigated using the indirect and direct immunogold staining method on permeabilized and fixed cells. The indirect approach enabled us to describe the general distribution of myosin in stress fibers. Direct double immunogold labeling, however, provided more detailed information on the orientation of myosin molecules and their localization relative to alpha-actinin: alpha-actinin, identified with antibodies coupled to 10-nm gold, was concentrated in the dense bodies or electron-dense bands of stress fibers, whereas myosin was confined to the intervening electron-lucid regions. Depending on the antibodies used in combination with alpha-actinin, the intervening regions revealed a different staining pattern: antibodies to myosin (reactive with the head portion of nonmuscle myosin) and to light chain 20 (both coupled to 5-nm gold) labeled two opposite bands adjacent to alpha-actinin, and antibodies to light meromyosin (coupled to 5-nm gold) labeled a single central zone. Based on these results, we conclude that myosin in stress fibers is organized into bipolar filaments.     

Macromolecular organization of bovine lens capsule

Rabbit antisera to type IV collagen, laminin, entactin, heparan sulfate proteoglycan and fibronectin were used to localize these proteins in cross-sections of bovine anterior lens capsule. The antisera were exposed to (a) 10-micron frozen-thawed sections of formaldehyde-fixed tissue for examination in the light microscope by the indirect immunofluorescence method and (b) formaldehyde-fixed and L. R. White plastic-embedded thin sections for electron microscopic examination by the protein A-gold technique. The intensity of immunofluorescence was both uniform and strong throughout for type IV collagen, laminin and entactin, but patchy and weak for fibronectin. Electron microscopic immunolabeling with protein A-gold showed that all five components were distributed throughout the full thickness of the membrane, albeit the density of gold particles was not identical for all basement membrane proteins. In general, the number of particles per micron2 was greatest for type IV collagen and entactin, moderate for laminin and heparan sulfate proteoglycan and low for fibronectin. The ultrastructure of the lens capsule as examined by the electron microscope revealed a relatively uniform parallel alignment of filaments, thought to be collagenous. Since the distribution of the filaments corresponds well with the observed immunocytochemical pattern it is concluded that type IV collagen, laminin, entactin, heparan sulfate proteoglycan and fibronectin co-localize throughout the cross-section of the anterior lens capsule.     

Ultrastructural immunogold labeling of glial filaments in osmicated and unosmicated epoxy-embedded tissue

On-grid (post-embedding) immunolabeling methods with epoxy resins have been difficult to apply to thin structures such as intermediate filaments, which may remain inaccessible within the plastic. In this study, glial fibrillary acidic protein (GFAP), the major protein of astrocyte intermediate filaments, was localized with a post-embedding immunogold method, using both unosmicated and osmicated material embedded in epoxy resin. The tissue studied was from a diagnostic brain biopsy on a child with Alexander's disease. This disorder is characterized by proliferation of astrocyte intermediate filaments and formation of Rosenthal fibers. With unosmicated tissue, as in a previous study, extensive labeling of the glial filaments was achieved only when ultra-thin sections were pre-treated with dilute sodium ethoxide, an agent that dissolves plastic. Fifteen-nm gold could be used. With osmicated tissue, localization to glial filaments required pre-treatment with sodium ethoxide and with the oxidizing agent sodium metaperiodate, followed by the use of small (5 nm) colloidal gold. That 5-nm gold was required for labeling filaments in osmicated material suggested that osmication increases problems of penetrability and antigen accessibility within ultra-thin sections. The large Rosenthal fibers were labeled by 15-nm gold in both unosmicated and osmicated material. The methods employed may be useful for electron immunolocalizations to other thin structures in material embedded in epoxy resin.     

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.     

Preembedding colloidal gold immunostaining of hypothalamic neurons: light and electron microscopic localization of beta-endorphin-immunoreactive perikarya

A preembedding immunogold staining (IGS) procedure was developed to identify beta-endorphin/adrenocorticotropic hormone immunoreactive neurons at the light and electron microscopic levels. Colchicine-treated rats were perfused with Nakane's periodate-lysine-paraformaldehyde fixative. Vibratome sections were incubated in primary antisera followed by goat anti-rabbit immunoglobulin G coupled to 16 nm colloidal gold, and, in some cases, rabbit immunoglobulin G coupled to gold. The appearance to pink to light red perikarya, corresponding to colloidal gold deposition at antigenic sites, was monitored under the light microscope. Positive cell bodies in the arcuate region sometimes extended lateral to the nucleus. Only proximal portions of neuronal processes were stained. At the ultrastructural level, colloidal gold labeled the periphery of 90-110 nm dense neurosecretory granules in the perikaryal cytoplasm and a few proximal axons. Clusters of gold particles, appearing free in the neuroplasm, actually labeled secretory granules in adjacent thin sections. Granules associated with the Golgi apparatus were not stained. Colloidal gold labeling of mature beta-endorphin granules, but not progranules, in rat hypothalamic neurons was confirmed using the peroxidase-antiperoxidase technique. The results correlate well with data on the intracellular processing of pro-opiomelanocortin in pituitary cells and prepropressophysin in the paraventricular nucleus. These data demonstrate the first application of the preembedding colloidal gold staining method for the identification of intracellular antigens within the central nervous system. The IGS method provides a definitive marker for single or double labeling of nervous tissue at both the light and electron microscopic levels.     

Routine use of backscattered electron imaging to visualize cytochemical and autoradiographic reactions in semi-thin plastic sections.

The scanning electron microscope (SEM) was used to examine cytochemical and autoradiographic reactions in 2-microns semi-thin sections of tissues conventionally fixed and embedded in various resins. The sections were examined using both the secondary and backscatter modes of the SEM at magnifications within the range attainable with the light microscope. Both modes allowed the imaging of phosphatase reaction product using cerium and lead capture, lectin-gold, and immunogold labeling, with and without silver enhancement, and autoradiography. Backscattered electron imaging (BEI), however, provided images with more contrast and structural details. This approach allows examination of large sections, with more contrast and resolution than the light microscope, and visualization of reactions not visible with this instrument. The improved imaging and the simple and conventional preparation of specimens indicate that BEI can be used routinely to examine tissue organization, cell structure, and the content of the various cell compartments with a resolution approaching that of transmission electron microscopy.     

The silver anniversary of gold: 25 years of the colloidal gold marker system for immunocytochemistry and histochemistry

Since 1971, when W.P. Faulk and G.M. Taylor published “An immunocolloid method for the electron microscope”, colloidal gold has become a very widely used marker in microscopy. It has been used to detect a huge range of cellular and extracellular constituents by in situ hybridization, immunogold, lectin-gold, and enzyme-gold labeling. Besides its use in light microscopic immunogold and lectin-gold silver staining, colloidal gold remains the label of choice for transmission electron microscopy studying thin sections, freeze-etch, and surface replicas, as well as for scanning electron microscopy. The year 1996 is the 25th anniversary of the introduction of colloidal gold as a marker in immunoelectron microscopy and this overview outlines some of the major milestones in the development of the colloidal gold marker system.     

Detection of hepatopancreatic parvovirus (HPV) of penaeid shrimp by in situ hybridization at the electron microscope level

A post-embedding in situ hybridization procedure was developed to detect hepatopancreatic parvovirus (HPV) of penaeid shrimp at the ultrastructural level. The procedure was optimized using sections of resin-embedded hepatopancreas from HPV-infected juvenile Penaeus monodon and postlarval P. chinensis. The hepatopancreata were fixed using various fixatives, dehydrated, and embedded in the hydrophilic resin Unicryl. A 592 bp HPV-specific DNA probe, labeled with DIG-11-dUTP, was tested both on semi-thin and ultra-thin sections and examined by light and electron microscopy, respectively. Hybridized probe was detected by means of an anti-DIG antibody conjugated to 10 nm gold particles and subsequent silver enhancement. Hybridization signal intensities were similar with all fixatives tested, but ultrastructure was best preserved with either 2 or 6% glutaraldehyde. Post-fixation with 1% osmium tetroxide improved ultrastructure but markedly decreased hybridization signal and induced non-specific deposition of gold and silver. Under optimized conditions, this technique was used to successfully follow the development of HPV from absorption and transport through the cytoplansm to nuclear penetration, replication and release by cytolysis. The probe signal was consistently observed among necrotic cell debris within the lumen of hepatopancreatic tubules, within the microvillous border of tubule epithelial cells, within the cytoplasm, and within diagnostic HPV intranuclear inclusion bodies. The nucleolus and karyoplasm of patently infected cells (i.e., showing HPV intranuclear inclusion bodies) were almost devoid of signal. Electron-lucent structures, known as intranuclear bodies, commonly found within the virogenic stroma, showed only weak labeling. This is the first use of in situ hybridization to detect HPV nucleic acids with the electron microscope. The technique should be useful for studying the pathogenesis of HPV.