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 as a cell surface marker for photoelectron microscopy

Colloidal gold labeling in conjunction with silver enhancement was investigated as a labeling technique for photoelectron microscopy (PEM). PEM uses UV-stimulated electron emission to image uncoated cell surfaces, and markers for cell surfaces need to be sufficiently photoemissive to be clearly visible against this background. Label contrast provided by 6 nm or 20 nm colloidal gold markers alone was compared to that provided by 6 nm markers after silver enhancement, using both direct and indirect labeling methods for fibronectin on human fibroblast cell surfaces. In all cases, details of the fibrillar fibronectin labeling distribution which were barely discernible before silver enhancement became highly visible against the cellular surface features. Two factors evidently contribute to the pronounced increase in label contrast with silver enhancement: (1) Increased particle size, which was documented by transmission electron microscopy, and (2) increased photoemission resulting from a silver coating on the enhanced gold markers, compared with the protein coating on the unenhanced gold markers. These data demonstrate that silver enhancement of colloidal gold labeling patterns in PEM images is a highly effective method for localization of specific sites on cell surfaces.     

Chitosan-colloidal gold complexes as polycationic probes for the detection of anionic sites by transmission and scanning electron microscopy

Summary A new cationic colloidal gold complex has been developed for ultrastructural localization of cell surface anionic sites by transmission and scanning electron microscopy. The marker is prepared by labelling gold particles of suitable sizes (6 to 70 nm in diameter) with chitosan, a polymer of (14)-linked d-glucosamine. Using human red blood cells as a model, chitosan-gold complexes were shown to be specific for anionic sites and at pH 2 for sialic acid residues. The binding capacity of complexes of different sizes with carboxymethyl and phosphorylated celluloses was examined as a function of pH and ionic strength. The results indicated that these complexes can be used under acidic conditions as well as in physiological buffers. The complexes were further tested by transmission and scanning electron microscopy in detecting anionic sites on cells of various origins such as Escherichia coli, Lactobacillus maltaromicus, Lactobacillus reuteri, Saccharomyces cerevisiae, Saccharomyces rouxii, Schizosaccharomyces pombe, Fusarium oxysporum, Catharantus roseus.     

Chitosan-colloidal gold complexes as polycationic probes for the detection of anionic sites by transmission and scanning electron microscopy

A new cationic colloidal gold complex has been developed for ultrastructural localization of cell surface anionic sites by transmission and scanning electron microscopy. The marker is prepared by labelling gold particles of suitable sizes (6 to 70 nm in diameter) with chitosan, a polymer of beta (1----4)-linked D-glucosamine. Using human red blood cells as a model, chitosan-gold complexes were shown to be specific for anionic sites and at pH 2 for sialic acid residues. The binding capacity of complexes of different sizes with carboxymethyl and phosphorylated celluloses was examined as a function of pH and ionic strength. The results indicated that these complexes can be used under acidic conditions as well as in physiological buffers. The complexes were further tested by transmission and scanning electron microscopy in detecting anionic sites on cells of various origins such as Escherichia coli, Lactobacillus maltaromicus, Lactobacillus reuteri, Saccharomyces cerevisiae, Saccharomyces rouxii, Schizosaccharomyces pombe, Fusarium oxysporum, Catharantus roseus.     

DNA probes on chip surfaces studied by scanning force microscopy using specific binding of colloidal gold

Single-stranded DNA was covalently bound on chip surfaces using two different silanization procedures. The resulting surfaces were characterized by fluorescence and scanning force microscopy using sequence-complementary DNA molecules with labels. Colloidal gold (30 nm) was used as the topographic label. Scanning force microscopy revealed the individual labels on the surface and their distribution. Steps of silane layers or DNA-modified surfaces prepared using an elastomeric mask provided internal controls for comparison of modified with unmodified surfaces.     

Fluorescent colloidal gold: A cytochemical marker for fluorescent and electron microscopy

Summary The gold method was further developed for fluorescent microscopy. Gold granules (12 nm in size) were labelled with rhodamine conjugates of Concanavalin A and avidin. The fluorescent markers were used to mark cell wall mannan on the yeast Saccharomyces cerevisiae either by the one-step, or by the two-step method via a biotinyl derivative of ConA. By fluorescence or transmission electron microscopy, the two-step method was found to achieve a higher density of marking.     

Scanning electron microscopy of cell surface antigens labeled with colloidal gold

A method is described and discussed that permits the specific labeling of the surface of prefixed cells with the colloidal gold marker viewed with the scanning electron microscope. Its value depends exclusively on the use of backscattered electron imaging. Its advantages include the possibility of preserving the surface features of the labeled cells, the ease with which specificity can be established, the possibility of making total counts of the labeled surface antigenic sites, and the possibility of achieving distinct labeling for two different antigens expressed on the surface of the same cell.     

Fluorescent colloidal gold: a cytochemical marker for fluorescent and electron microscopy.

The gold method was further developed for fluorescent microscopy. Gold granules (12 nm in size) were labelled with rhodamine conjugates of Concanavalin A and avidin. The fluorescent markers were used to mark cell wall mannan on the yeast Saccharomyces cerevisiae either by the one-step, or by the two-step method via a biotinyl derivative of ConA. By fluorescence or transmission electron microscopy, the two-step method was found to achieve a higher density of marking.     

Distribution and movement of membrane-associated platelet glycoproteins: use of colloidal gold with correlative video-enhanced light microscopy, low-voltage high-resolution scanning electron microscopy, and high-voltage transmission electron microscopy

Scanning electron microscopy (SEM), especially low-voltage (1 KeV) high-resolution SEM, can be used in conjunction with stereo pair high-voltage (1 MeV) transmission electron microscopy (HVEM) of whole spread cells or thick sections effectively to correlate surface structure with internal structure. Surface features such as microvilli, pits, pseudopodia, ruffles, attached virus, and other surface-related morphologic characteristics can be identified using SEM, while underlying cytoskeletal structure and organelle organization can be viewed by HVEM of the same preparation. However, the need to "prepare" cells for electron microscopy precludes observation in the living state. The use of several types of video-enhanced light microscopy (VLM) permits observation of living cells such that certain surface and internal features can be observed at a relatively high level of resolution or detection. Thus, changes in living cells can be followed, and at appropriate times the cells may be chemically fixed or rapidly frozen and prepared for ultrastructural examination by electron microscopy. We have utilized VLM in conjunction with SEM and HVEM to correlate changes in shape and surface structure with changes in the internal structure of platelets. In addition, we have found it advantageous to use colloidal gold-labeling procedures, because these markers are detectable by all three forms of microscopy. Using this approach we have labeled platelet membrane GPIIb/IIIa, a receptor for RGD-containing adhesive proteins, with gold-fibrinogen or gold-anti-IIb/IIIa. The initial binding and subsequent movement of gold-fibrinogen-IIb/IIIa complexes in living platelets was followed by VLM. The movement of individual labels could be mapped. Subsequent observation by low-voltage (1 KeV) high-resolution SEM and HVEM permits visualization of the same individual receptors tracked by LM. The final position on the membrane or the position-in-transit when fixative was added was determined relative to surface ultrastructure (SEM) and internal, particularly cytoskeletal, ultrastructure (HVEM).     

Colloidal gold, a useful marker for transmission and scanning electron microscopy.

Electron dense markers of a size suitable for transmission electron microscopy and scanning electron microscopy have been prepared with gold granules labeled with a monolayer of specific macromolecules. The optimum conditions for preparing the markers have been ascertained. The method is simple, rapid and seems to be general since gold granules have been labeled with polysaccharides and proteins. As homogeneous populations of gold granules having different sizes can be prepared, the method is also suitable for double marking experiments. The gold technique is illustrated by the localization of polysaccharides and glycoproteins on yeast cell walls and erythrocyte membranes by transmission electron microscopy and on yeast cells and intact erythrocytes by scanning electron microscopy. Good spatial resolution of the marker was achieved in all cases. The method is also suitable for marking thin sections. Spectrophotometric measurements were used to determine the number of gold granules adsorbed per cell.     

Concatenated metallothionein as a clonable gold label for electron microscopy

Localization of proteins in cells or complexes using electron microscopy has mainly relied upon the use of heavy metal clusters, which can be difficult to direct to sites of interest. For this reason, we would like to develop a clonable tag analogous to the clonable fluorescent tags common to light microscopy. Instead of fluorescing, such a tag would initiate formation of a heavy metal cluster. To test the feasibility of such a tag, we exploited the metal-binding protein, metallothionein (MT). We created a chimeric protein by fusing one or two copies of the MT gene to the gene for maltose binding protein. These chimeric proteins bound many gold atoms, with a conservative value of 16 gold atoms per copy of metallothionein. Visualization of gold-labeled fusion proteins by scanning electron microscopy required one copy of metallothionein while transmission electron microscopy required two copies. Images of frozen-hydrated samples of simple complexes made with anti-MBP antibodies hint at the usefulness of this method.     

Microwave processing for scanning electron microscopy

The normal processing of biological samples for Scanning Electron Microscopy, includes treatment with aldehyde (1 to 2 hours), postfixation with Osmium (1 hour), followed by dehydration in a ascending grade of ethanol (30 a 100%), 10 to 15 minutes in each step, and finally drying. This procedure takes at least 8 hours. In this work, samples of mosquitoes (Aedes), protozoa (Tritrichomonas muris), bacteria (Clostridium oceanicum), murine liver, and small intestine were processed in the same manner in a domestic microwave oven for two minutes at 20% of its maximum power. The complete procedure from the initial fixation to dehydration in 100% ethanol was reduced to one hour with good preservation of the ultrastructural details of the specimens.     

Demonstration and cytochemical analysis of anionic sites on ejaculated boar spermatozoa: a scanning electron microscopy study using cationised colloidal gold

The plasmalemma of spermatozoa bears negative charges as is the case for most mammalian cells. This has been concluded from the sperm cell's electrophoretic behaviour and from labelling experiments with various cationic probes followed by transmission electron microscopy of ultrathin sections. An overall view of the cell surface, however, is necessary in order to assess the distribution and density of the anionic sites adequately. We, therefore, used scanning electron microscopy in combination with cationised colloidal gold labelling to analyse the presence of anionic sites on ejaculated boar spermatozoa. Incubations were performed at pH 3.5, 2.5 and 1.0. Labelling was specific and bound gold particles were unequivocally identified using the backscattered electron signal. The chemical nature of the anionic sites involved was investigated by treating spermatozoa with pronase, phosphatase and neuraminidase as well as by methylation, acid hydrolysis and beta-elimination prior to cationised gold labelling. Our results suggest that besides phosphates, carboxyl groups are predominantly accountable for the binding of cationised colloidal gold. Presumptive macromolecules bearing these anionic sites are phospholipids and sialic acid residues. The combination of methods presented herewith should be of value in order to elucidate charge interactions which have been shown to play a role in cellular recognition events and adhesion.     

Simplified purification and testing of colloidal gold probes

Summary A novel efficient method for purifying and testing colloidal gold probes has been developed. The method consists of concentrating colloidal gold particles conjugated to IgG or protein A in dialysis bags over silica gel and purifying them by gel chromatography on small columns of Sephacryl S-400. Fractions collected are tested by paper immunocytochemical models. Comparisons to gold probes purified by conventional ultracentrifugation documents that ultrastructural staining intensities and total yield of gold probes is the same, but that the chromatographically purified gold probes are less prone to aggregation or clumping. The method has been extensively used for preparing conjugates of 5, 10 or 15 nm gold particles with antirabbit immunoglobulins but has also been exploited for preparing streptavidin-gold conjugates, protein A-gold conjugates and antirabbit immunoglobulin-silver conjugates.     

Simplified purification and testing of colloidal gold probes

A novel efficient method for purifying and testing colloidal gold probes has been developed. The method consists of concentrating colloidal gold particles conjugated to IgG or protein A in dialysis bags over silica gel and purifying them by gel chromatography on small columns of Sephacryl S-400. Fractions collected are tested by paper immunocytochemical models. Comparisons to gold probes purified by conventional ultracentrifugation documents that ultrastructural staining intensities and total yield of gold probes is the same, but that the chromatographically purified gold probes are less prone to aggregation or clumping. The method has been extensively used for preparing conjugates of 5, 10 or 15 nm gold particles with antirabbit immunoglobulins but has also been exploited for preparing streptavidin-gold conjugates, protein A-gold conjugates and antirabbit immunoglobulin-silver conjugates.     

New immunolatex spheres: visual markers of antigens on lymphocytes for scanning electron microscopy

New immunochemical reagents consisting of antibodies bound to small latex spheres were used as visual markers for the detection and localization of cell surface antigens by scanning electron microscopy. Cross-linked latex spheres of various sizes from 300 to 3,4000 A in diameter were synthesized by aqueous emulsion copolymerization of methacrylate derivatives containing hydroxyl and carboxyl functional groups. Proteins and other molecules containing primary amino groups were covalently bonded to the acrylic spheres under a variety of mild conditions by the aqueous carbodiimide, cyanogen bromide, and glutaraldehyde methods. For use in the indirect immunochemical-labeling technique, goat antibodies directed against rabbit immunoglobulins were bonded to the spheres. These immunolatex reagents were shown to bind only to cells (red blood and lymphocytes) which had previously been sensitized with rabbit antibodies against cell surface antigens. Mouse spleen lymphocytes with exposed immunoglobulins on their surface (B cells) were labeled with these spheres and distinguished from unlabeled or T lymphocytes by scanning electron microscopy. The distribution of Ig receptors on lymphocytes was also studied using the spheres as visual markers. When lymphocytes were fixed with glutaraldehyde and subsequently labeled with the immunolatex reagents, a random distribution was observed by scanning electron microscopy; a patchy distribution was observed when unfixed lymphocytes were used. These results are consistent with studies using ferritin-labeled antibodies (S. De Petris and M. Raff. 1973. Nature [Lond.]. 241:257.) and support the view that Ig receptors on lymphocytes undergo translational diffusion. In addition to serving as visual markers for scanning electron microscopy, these latex spheres tagged with fluorescent or radioactive molecules have applications as highly sensitive markers for fluorescent microscopy and as reagents for quantitative studies of cell surface antigens and other receptors.     

Ultrastructural localization of neutral DNAse in hepatocytes by immune electron microscopy using colloidal gold

A method for obtaining of the colloidal gold with particles 20 nm in diameter is described. The use of conjugate of colloidal gold-specific antibodies to the neutral DNAase is shown to determine the DNAase localization on ultrathin epontic sections of rat liver fixed by glutaraldehyde. The conditions of fixation, filling and immune reactions are described. The neutral DNAase has been found to localize mainly in heterochromatin.     

In situ localization of antigens of Histoplasma capsulatum using colloidal gold immune electron microscopy

Histoplasma capsulatum contains multiple antigens, among them the H antigen and M antigen, which are useful in serologic testing for histoplasmosis. We prepared 7 mouse monoclonal antibodies (5 IgG, 2 IgM) to histoplasmin, and compared these with polyclonal histoplasmin antibodies raised in rabbits and mice. Both monoclonal and polyclonal antibodies were high titered by ELISA. Colloidal gold immune electron microscopy (CGIEM) showed that polyclonal antibodies to histoplasmin or H antigen bound at multiple sites in the cell wall, cytoplasm, and nucleus of Histoplasma yeast cells. In contrast, antibodies to M antigen selectively label the cell membrane and antibodies to alkali soluble cell wall antigen label only the cell wall. Polyclonal antibodies cross reacted extensively with other fungi, both by ELISA and CGIEM. Monoclonal antibodies stained only cytoplasmic epitopes, but also cross reacted with other fungi by electron microscopy. Only periodate treated H antigen elicited polyclonal antibodies which were more specific than those of untreated H antigen or histoplasmin.