A simple enhancement method for the silver-gold-intensified diaminobenzidine reaction in the light microscopic immunoperoxidase technique.

We describe a simple and sensitive method for enhancement of the silver-gold-intensified 3,3'-diaminobenzidine (DAB) reaction demonstrating peroxidase activity. After completing silver-gold intensification of the preparations immunostained by the avidin-biotin-peroxidase method with DAB as the chromogen, the preparations were immersed in a solution containing uranyl nitrate. This new method appeared to increase the sensitivity by at least one order of magnitude as compared with silver-gold intensification alone.     

Silver-enhanced colloidal gold probes as markers for scanning electron microscopy

Summary Silver enlargement of small colloidal gold particles has been extensively used for the light microscopical visualization of gold probes. Very recently, a few investigators have employed physical developers in electron microscopy (both pre-embedding and on-grid staining methods). We now demonstrate that physical development of small colloidal gold particles advantageously can be exploited for labelling biological surfaces in scanning electron microscopy. This novel application of silver enhancement of colloidal gold particles is characterized by a high detection efficiency. Thus, specimens are labelled with small gold probes affording high immunocytochemical efficiency but being impossible to detect with the present scanning microscopes. These particles are subsequently scanning electronmicro-scopically visualized by silver enhancement.Presented in part at the International Symposium on Biological Regulation of Cell Proliferation, 9th International Chalone Conference, Milano, Italy, March 3–6, 1986     

Silver-enhanced colloidal gold probes as markers for scanning electron microscopy

Silver enlargement of small colloidal gold particles has been extensively used for the light microscopical visualization of gold probes. Very recently, a few investigators have employed physical developers in electron microscopy (both pre-embedding and on-grid staining methods). We now demonstrate that physical development of small colloidal gold particles advantageously can be exploited for labelling biological surfaces in scanning electron microscopy. This novel application of silver enhancement of colloidal gold particles is characterized by a high detection efficiency. Thus, specimens are labelled with small gold probes affording high immunocytochemical efficiency but being impossible to detect with the present scanning microscopes. These particles are subsequently scanning electronmicroscopically visualized by silver enhancement.     

A light and electron microscopic procedure for sequential double antigen localization using diaminobenzidine and benzidine dihydrochloride

Very few double-antigen staining methods are available that are applicable to both light and electron microscopy. The objective of this study was to develop for localization of two neural antigens simultaneously a procedure which would be sensitive, simple to perform, offer permanent reaction products, and permit correlated light and ultrastructural analysis. The method employs sequential immunoperoxidase staining without antibody elution, in which the first sequence of antibodies is visualized with 3,3'-diaminobenzidine (DAB) and the second with benzidine dihydrochloride (BDHC). The DAB reaction product (brown and diffuse) was easily distinguishable from the BDHC deposit (blue, granular, and more electron-dense) by both light and electron microscopy. The procedure was used to simultaneously localize choline acetyltransferase-and either substance P or tyrosine hydroxylase in rat brain at both light and ultrastructural levels. Control experiments demonstrated the absence of both color mixing and antibody crossreactions, even when both primary antibodies were from the same species. This study demonstrates the usefulness of BDHC as a chromogen for immunoperoxidase staining either alone or in combination with DAB, and describes a double method which should have wide applicability for detailed studies of most pairs of antigens at both light and ultrastructural levels.     

A pre-embedding immunolabeling technique for basal lamina and extracellular matrix molecules

We have developed a pre-embedding immunolabeling technique to identify basal lamina and extracellular matrix molecules in embryos at various stages of development. The technique works for both fluorescence optical microscopy (1-2.5-micron sections) and for transmission electron microscopy, and enables straigthforward correlation between the two. An additional advantage is the easy preparation of well-oriented serial sections, facilitating detailed studies of development.     

Substance P-containing axon terminals in the mucosa of the human urinary bladder: pre-embedding immunohistochemistry using cryostat sections for electron microscopy

The ultrastructure of substance P (SP)-containing axon terminals in the mucosa of the human urinary bladder was studied. Numerous SP-immunoreactive varicose nerve fibers were seen in the lamina propria, and most of them ran freely in the connective tissue. Many SP-immunoreactive nerve fibers were observed beneath the epithelium, and perivascular SP-immunoreactive nerves were also found in the submucosal layer. We observed a total of 305 SP-immunoreactive (IR) axon terminals, of which most (89.6%) were free nerve endings at the ultrastructural level; the rest of the SR-IR axon terminale were seen in the vicinity of the epithelium and blood vessels in the lamina propria. Varicose regions of SP-IR axon terminals contained large granular and small agranular synaptic vesicles, and most of them partially lacked a Schwann cell sheath. In some SP-IR varicosities, synaptic vesicles were concentrated in the region without any Schwann cell sheath. Long storage (for more than 1 month) of fixed-tissue pieces in sucrose before freezing has improved the ultrastructure of cryostat sections in pre-embedding immunohistochemistry. Trypsin digestion for the purpose of exposing antigenic sites was also employed before applying the first antiserum.     

A technique for preserving aerial fungal structures for scanning electron microscopy

A technique is described that employs vapor fixation and a simple vapor diffusion dehydration apparatus to minimize the disturbance of delicate fungal structures during preparation for scanning electron microscopy. The technique is applicable to fungi grown on agar media or on natural substrates.     

A replication technique for scanning electron microscopy: Applications for anthropologists

Scanning electron microscopy has become an increasingly useful tool for anthropologists, particularly because of the development of improved methods of replicating specimens. One of the best replication techniques involves silicone-based dental impression materials to make negative impressions, in conjunction with epoxy resins, which are used to make positives or casts. The technique outlined here is particularly useful for anthropologists. Using this technique allows the examination of bone surfaces, teeth, and fossils for taphonomic, microwear, and experimental studies. Reproduction of detail is faithful at magnifications of × 1,500 to × 2,000, routinely giving resolutions of .1 to .25 μm.     

Derivatized silica spheres as immunospecific markers for high resolution labeling in electron microscopy

For high resolution labeling of influenza virus cell surface antigens on HeLa cells, an immunospecific marker is used with silica sphere cores of 13--14 nm average diameter. These markers are formed using commercially available silica sphere sols. Two other size ranges are available, 7--8 nm and 22--25 nm. The steps for chemical derivatization are described in detail. Amino and aldehyde functions are covalently introduced onto the sphere surface. Sols of these derivatized silica spheres (DSS) are physicochemically stable and therefore usable for years. Coupling of IgG to DSS followed by permeation chromatography on controlled pore glass results in size-defined immunospecific silica sphere markers (DSS-markers). Saturation labeling of cell surface antigens on HeLa cells on cover slips is obtained with the final sphere concentration of 10(14) DSS-marker/cm3 within 20 min. With usual protective conditions, the marker stability and labeling ability are preserved for months. The visibility and the fine structure of the DSS-marker on cell surfaces are shown by using transmission electron microscopy (TEM) with stereo replicas and ultrathin sections.     

A rapid technique for preparing microorganisms for transmission electron microscopy.

A rapid and efficient method of preparing microorganisms for transmission electron microscopy is reported. In developing the method Salmonella, streptococcal, and protozoal specimens were fixed with glutaraldehyde. After fixation cells are collected on a membrane filter, washed with buffer, postfixed with osmium tetroxide, then washed with distilled water and stained en bloc with uranyl acetate. Specimens are dehydrated using a graded series of acetone and then infiltrated with graded mixtures of acetone and Spurr embedding medium. Finally the membrane filter is cut into small pieces and embedded in fresh embedding medium polymerized in polyethylene capsules. By collecting and processing the specimens on membrane filters, numerous centrifugations are eliminated from standard procedures. The use of a low viscosity embedding medium allows for rapid infiltration and embedding of the specimen. Using this technique microbial specimens can be sectioned after less than 4 hours preparation.     

A simple and direct pre-embedding technique for ultrastructure of scarce biological specimens

A simple and rapid technique for pre-embedding scarce biological specimens for Transmission electron microscopy (TEM) is reported. It is based on pre-embedding biological samples in bovine serum albumin (BSA) and bis-acrylamide (BA), cross-linked and polymerized with paraformaldehyde, glutaraldehyde, ammonium persulfate and Temed. Pre-embedding in BSA and BA offers several advantages over traditional pre-embedding techniques for TEM including the ability to visualize the sample and a more resistant matrix. This results in more reproducible and consistent analysis. It can be applied to tissues, cells, and subcellular structures handled as pellets or suspensions. In addition, use of the pre-embedding matrix for light microscopy is reported. The ability to pre-embed scarce biological specimens efficiently and reproducibly provides a valuable way to study and characterize cytological tissues such as biopsies or cystic and amniotic fluid cells.     

The use of markers for correlative light electron microscopy

Bioimaging: the visualisation, localisation and tracking of movement of specific molecules in cells using microscopy has become an increasing field of interest within life science research. For this, the availability of fluorescent and electron-dense markers for light and electron microscopy, respectively, is an essential tool to attach to the molecules of interest. In recent years, there has been an increasing effort to combine light and electron microscopy in a single experiment. Such correlative light electron microscopy (CLEM) experiments thus rely on using markers that are both fluorescent and electron dense. Unfortunately, there are very few markers that possess both these properties. Markers for light microscopy such as green fluorescent protein are generally not directly visible in the electron microscopy and vice versa for gold particles. Hence, there has been an intensive search for markers that are directly visible both in the light microscope and in the electron microscope. Here we discuss some of the strategies and pitfalls that are associated with the use of CLEM markers, which might serve as a “warning” that new probes should be extensively tested before use. We focus on the use of CLEM markers for the study of intracellular transport and specifically endocytosis.     

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.     

Localization of the fibronexus at the surface of granulation tissue myofibroblasts using double-label immunogold electron microscopy on ultrathin frozen sections

An intimate transmembrane complex of fibronectin-containing extracellular fibers and actin microfilaments termed the fibronexus has been observed at the adhesive surface of fibroblasts in vitro [19] and along the plasmalemma of myofibroblasts in vivo [22]. Although the observation of coincident actin and fibronectin immunofluorescence patterns in the latter work strongly suggested that the fibronexus is localized at the myofibroblast surface, we only obtained morphological evidence for its existence with electron microscopy. Therefore, in the present study, we have utilized a double-label immunoelectron microscopic technique to localize fibronectin and actin simultaneously in the putative fibronexuses of myofibroblasts within guinea pig granulation tissue, formed 7 to 9 days after skin wounding. This method employed rabbit antifibronectin and mouse anti-actin antibodies, followed by species-specific secondary antibodies conjugated to colloidal gold particles of different sizes. These probes were applied to the surfaces of ultrathin frozen sections mounted on grids. We found that fibronectin and actin were specifically localized on the respective external and internal components of myofibroblast fibronexuses. Our results suggest that specific transmembranous fibronectin-cytoskeletal complexes play an important role in the cohesion of granulation tissue.