Use of colloidal gold and ruthenium red in stereo high-voltage electron microscopic study of Con A-binding sites in mouse macrophages

Concanavalin A (Con A)-binding sites were labeled with colloidal gold (CG), stained with ruthenium red, and observed under a high-voltage electron microscope. Mouse peritoneal macrophages were labeled by the indirect Con A/CG labeling method at 0 degree C. After washing, some of the cells were incubated in phosphate-buffered saline (PBS) at 37 degrees C. The specimens were then stained with ruthenium red, to enhance the contrast of the cell surface, and embedded in Epon. Sections (0.3 approximately 3 micron thick) were cut and examined by high-voltage electron microscopy at accelerating voltages of 200 approximately 1,000 kV. Staining with ruthenium red provided a strong contrast of the cell surface and the invaginating tubules beneath it against the cytoplasm; in thick sections, both of them were clearly seen by stereomicroscopy. CG particles which represented Con A-binding sites were also sufficiently electron dense to be recognized by high-voltage electron microscopy of thick sections. The two- and three-dimensional distribution of CG particles on the ruthenium-red-positive cell surface was clearly visualized. At 0 degree C, Con A-binding sites were randomly distributed on the cell surface. The redistribution and endocytosis of Con A-binding sites were seen at 37 degrees C. The three-dimensional organization of membrane invagination, which represented the process of endocytosis, was clearly seen by stereomicroscopy. The combination of CG labeling and ruthenium red staining is a useful method for high-voltage electron microscopic analysis of the two- and three-dimensional distribution of CG-labeled ligands on the cell surface in thick sections.     

Whole-cell-mount cytochemistry by the colloidal gold labeling method. Combined transmission and scanning electron microscopic study of ConA binding sites in mouse macrophages

Binding, redistribution, and endocytosis of colloidal gold (CG)-labeled concanavalin A (ConA) were studied by transmission electron microscopy (TEM) and scanning electron microscopy (SEM). Mouse peritoneal macrophages were cultured on Formvar-coated platinum grids. Either fixed or unfixed cells were labeled by the indirect ConA-CG labeling method. Specimens were critical-point-dried and observed by TEM and SEM in the same region. Surface-bound ConA-CG was easily seen by SEM. Stereomicroscopic observation by TEM clearly showed the three-dimensional distribution of ConA on the cell surface as well as in the cytoplasmic vesicles and vacuoles. In the prefixed cells, CG was distributed randomly on the cell surface. When unfixed cells were labeled at 0 degree C, a similar binding pattern was observed, although the density of bound CG was decreased. When cells labeled with ConA-CG at 0 degree C were further incubated at 37 degrees C, redistribution and endocytosis of the label were seen. Endocytosed CG in the cytoplasmic vesicles and vacuoles was clearly seen by TEM. In addition, three-dimensional location and relationship with other organelles were easily observed. Combined TEM and SEM observation of CG-labeled whole-cell-mount specimens is a useful method to study the dynamics of cell-bound ligands.     

Light microscopic localization of silver-enhanced liposome-entrapped colloidal gold in mouse tissues

Silver-enhanced liposome-entrapped colloidal gold was developed for light microscopic localization of liposomes. Preparation of colloidal gold entrapped in liposomes was achieved by a modified method of Hong, et al. (1983) Biochim. Biophys. Acta 732, 320-323). In this report, a gold chloride/citrate solution of low pH (3.4) was used to inhibit the formation of gold granules during the liposome preparation. The diameter of most liposomes ranged from 80 to 100 nm. Following liposome preparation, the pH was adjusted to 6, and the temperature increased to 55 degrees C. The majority of the liposomes contained one to three gold particles. Liposomes were injected into mice via tail vein; 24 h later, tissues were collected. Sections were processed for silver enhancement of the gold particles and examined by light microscopy. Silver-enhanced gold particles were clearly observed in both liver and implanted tumor. Localization was confirmed by electron and fluorescence microscopy. Thus, we have shown that silver enhancement of colloidal gold liposomes is a direct and sensitive method for tracing the fate of liposomes in vivo, providing minimal background interference and a good definition of various cell types.     

Simultaneous electron microscopic detection of colloidal gold labeled ligand and adenylate cyclase

Summary Concanavalin-A-colloidal gold (Con-A-G) complex and adenylate cyclase activity were detected simultaneously in electron microscopic preparations of human fibroblast cultures, by a combined histochemical technique. The colloidal gold particles appeared as round bodies which could be readily differentiated from the amorphous product of the adenylate cyclase enzyme reaction. The combined technique makes possible the simultaneous visualization of the bound ligand (i.e. of its binding site), and of the enzyme activated by the lignad. Treatment of the cells with Con-A accounted for a considerable increase in intracellular adenylate cyclase activity. The activity increase was disproportionally greater than the amount of bound ligand, and it also appeared in localizations showing no indication of ligand binding. Treatment of the fibroblasts with Con-A was followed by internalization of the lignand and the enzyme inside at least seemingly segregated vesicles.     

Receptor-mediated endocytosis of immunoglobulin-coated colloidal gold particles in cultured mouse peritoneal macrophages

Endocytosis of immunoglobulin G (IgG)-coated colloidal gold particles in cultured mouse peritoneal macrophages was studied by scanning and transmission electron microscopy. At 4 degrees C, the tracers adhered to the plasma membrane and accumulated in coated pits located in the bottom of furrows or deep invaginations on the cell surface. In the presence of an excess of unlabeled mouse IgG, cellular binding of the tracer was reduced by 80 to 90%. After warming to 37 degrees C, surface-bound tracer particles were rapidly ingested and transported to small and large vesicles lacking membrane coat. From here, they were then passed over to multivesicular bodies and lysosomes characterized by their content of myelin-like figures and other inclusions. Double-labeling experiments with IgG-coated colloidal gold particles of two different sizes (20 and 5 nm diameter) indicated that the plasma membrane was depleted of binding sites after uptake of a polyvalent ligand. The restoration of the binding capacity was a slow process requiring ongoing protein synthesis. On the basis of these observations, a model for endocytosis of immune complexes in macrophages is presented. It includes the following four steps: IgG-containing macromolecular aggregates bind to specific receptors in the plasma membrane. These appear to be preclustered in coated pits or able to move laterally within the membrane even at 4 degrees C. The receptor-ligand complexes are internalized and transferred sequentially to larger uncoated vesicles or endosomes, multivesicular bodies, and lysosomes with inclusions of varying appearance. Receptors and ligands are degraded within the lysosomes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Scanning electron microscopic investigation of mouse cerebellar macrophages in vitro

Dispersed monolayer cultures of post-natal mouse cerebella were studied using scanning electron microscopy. Special attention was given to the morphology of the brain macrophages and their interaction with neuronal cells. The brain macrophages resemble other macrophages and mononuclear phagocytes in vitro, reported in the literature. Their ability to induce neuronal growth cones to avoid contact, results in areas devoid of neuronal processes (halos) in this culture system; this seems of considerable interest in connection with their possible developmental role in post-natal reshaping of the brain. Scanning electron microscope observations indicate that these halos are not the result of phagolysis of already established neuronal networks, but can only be induced during neuronal growth and process formation. Established, intact neurons are apparently not altered or harmed by contact with brain macrophages.     

Correlative light and electron microscopic immunocytochemistry on the same section with colloidal gold

Ultrastructural localization of growth hormone in rat anterior pituitary and of muscle-specific actin in rabbit arterial smooth muscle cells was accomplished with a post-embedment procedure using colloidal gold. Plastic sections (2 microns) were mounted on slides, deplasticized, immunostained with immunoglobulin-colloidal gold particles, re-embedded in Epon, and sectioned for electron microscopy. This procedure enabled light and electron microscopic localization of these intracellular antigens on the same section. Positive immunostaining was demonstrated with this procedure with a muscle-specific actin antibody which previously failed to localize antigenic sites by EM. The procedure described yielded staining of high specificity, with minimal background and well-preserved ultrastructure. This re-embedding technique is useful in situations where problems with post-embedding EM immunostaining exist and where correlative LM and EM immunostaining is essential.     

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.     

Positive colloidal thorium dioxide as an electron microscopical contrasting agent for glycosaminoglycans, compared with ruthenium red and positive colloidal iron

In electron microscopy Thorotrast has been used as a specific contrasting agent for acid glycosaminoglycans. Because of its high atomic number, thorium (Z=90) gives good contrast in the electron microscope, but at present it is less frequently used for this purpose. We prepared a positive colloidal solution of ThO2 without stabilizers to compare its properties with those of ruthenium red and positive colloidal iron for contrasting fetal mouse epiphyseal cartilage. The results indicate that colloidal ThO2, which is easy to prepare in any laboratory, gives better results than ruthenium red and colloidal iron do in this kind of cartilage. Furthermore, as judged from data in the literature and obtained in our laboratory, it penetrates this tissue better than Thorotrast does, probably because of the absence of stabilizers.     

Positive colloidal thorium dioxide as an electron microscopical contrasting agent for glycosaminoglycans,compared with ruthenium red and positive colloidal iron

Summary In electron microscopy Thorotrast has been used as a specific contrasting agent for acid glycosaminoglycans. Because of its high atomic number, thorium (Z=90) gives good contrast in the electron microscope, but at present it is less frequently used for this purpose. We prepared a positive colloidal solution of ThO₂ without stabilizers to compare its properties with those of ruthenium red and positive colloidal iron for contrasting fetal mouse epiphyseal cartilage. The results indicate that colloidal ThO₂, which is easy to prepare in any laboratory, gives better results than ruthenium red and colloidal iron do in this kind of cartilage. Furthermore, as judged from data in the literature and obtained in our laboratory, it penetrates this tissue better than Thorotrast does, probably because of the absence of stabilizers.     

An electron microscopic study of mouse foldback DNA.

Foldback DNA is defined by its rapid, concentration-independent renaturation, consistent with intramolecular base pairing of inverted repeat sequences. Foldback DNA, isolated from renatured mouse main band DNA by hydroxyapatite chromatography, is spread for electron microscopy by the formamide isodenaturing technique. A large fraction of the molecules can be recognized as intramolecular "hairpins"--structures in which complementary sequences on a single DNA strand form base-paired "stem" regions analogous to tRNA stems. The stem regions of the hairpins have a wide distribution of lengths, averaging about 1000 base pairs. About 60% of the stem regions terminate in single-stranded loops, ranging from 400 to many thousands of nucleotides in length, while 40% of the hairpins do not have discernible loops. There are about 40,000 hairpin-forming sequences in the main band portion of the mouse haploid genome. They appear to be either clustered in groups or confined to about one third of the DNA, rather than uniformly or randomly distributed. Another large fraction of the molecules seen in foldback DNA consists of linear structures, some of which are probably also hairpins. The electron microscopic results, along with simple theoretical considerations, make possible a better interpretation of our previous studies of the yield and S1 nuclease resistance of mouse foldback DNA.     

Use of colloidal gold in diagnostic surgical pathology

Colloidal gold immuno-electron microscopy is a powerful tool for defining antigenicity at the subcellular level. Such studies permit correlation with cell fractionation studies. They also allow one to assess the specificity of a particular antibody. The most useful reagent for immuno-electron microscopy is colloidal gold stabilized by a binding protein, either staphylococcal protein A or immunoglobulin. This method permits highly discrete labeling, and the system is useful for most antibodies used in diagnostic pathology.     

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.     

Inflammation with restricted lysosomal proteolysis during early ascites carcinoma invasion of mouse parietal peritoneum. A medium and high-voltage electron microscopic and cytochemical study

A carcinoma invasion system (Krebs-2 and Ehrlich tetraploid ascites tumors invading mouse peritoneum) was studied by high-voltage electron microscope (HVEM) stereoscopy, conventional (medium voltage) electron microscopy (MVEM), and cytochemistry. Tumor cells entered areas of peritoneum (mainly parietal) only where mesothelial cells were damaged and where there was inflammation of the underlying stroma. The initial invasion was different from that of most other invading carcinomas in that there was minimal breakdown of basal lamina and collagen. Neither tumor cells, inflammatory leukocytes nor peritoneal fibroblasts showed significant secondary lysosome production or release of intracellular or extracellular acid phosphatase. Morphological and cytochemical criteria suggest that in some invading carcinomas, as with non-tumor migrating cells such as leukocytes, widespread proteolysis due to diffusion of proteases is not a prerequisite for invasion of stromal connective tissue.     

Use of colloidal gold cytochemistry in the study of the basic cell biology of cancer

We are currently investigating the morphologic aspects of two areas of the basic cell biology of cancer: tumor-specific surface antigens as targets for immunotoxins, and the phenomenon of multidrug resistance in chemotherapy of human tumors. Colloidal gold cytochemistry has provided a useful method for the electron-microscopic cytochemical detection of materials endocytosed by cells in culture. This technique has been used to study the internalization pathway of ligands bound to the surface of cancer cells, particularly antibodies for use as immunologic targeting reagents for the construction of immunotoxins. These colloidal gold conjugates with monoclonal antibodies have demonstrated the internalization of these immunologic reagents through coated pits and receptosomes, which is a necessary step in the delivery of immunotoxins into the cell where they can mediate their cell-killing functions. Morphologic methods have been employed for the screening and selection of monoclonal antibodies reactive with the surface of human ovarian cancer cells for use as immunotoxins and have demonstrated the in vivo activity of immunotoxins made with these antibodies and Pseudomonas exotoxin in a nude mouse model system. In other studies, we have employed such reagents for the immunocytochemical detection of the surface expression of P170, the cell-surface efflux pump protein responsible for the phenotype of multidrug resistance in tumor cells, and to investigate the distribution of this protein by using immunocytochemistry in normal human tissues. These results have suggested a role for P170 in normal cell membrane transport of metabolites in various organ systems.     

Receptor-mediated pinocytosis of IgG and immune complex in rat peritoneal macrophages: an electron microscopic study

The uptake mechanism of homologous IgG and immune complex, and the participation of coated vesicles in this process were studied in rat peritoneal macrophages. Peroxidase-antiperoxidase (PAP) immune complex produced in rat, and purified rat IgG adsorbed to gold particles (IgG-Au) were used as ligands. Freshly collected peritoneal macrophages were preincubated with the ligands at 4 degrees C, washed, warmed up to 37 degrees C, maintained in a serum-free culture medium for 5 sec to 30 min and subsequently fixed for electron microscopy. In the IgG-Au experiments, acid phosphatase reaction was also applied to identify lysosomes, and ruthenium red to trace membranes exposed to the extracellular space. At the end of the preincubation period PAP and IgG were found randomly distributed on the external surface of the plasma membrane. After warming up the cells to 37 degrees C, the ligands bound to the plasma membrane showed a tendency to move towards deep labyrinthic invaginations of the cell surface from where they were internalized via coated pits and coated vesicles. In the initial period, these structures seemed to be the primary carriers of the ligands. In the period between 5 and 10 min, ligands were concentrated in vacuoles (endosomes) located in the deeper cytoplasm, while after 30 min, they were present in large lysosome-like or multivesicular bodies, which were found to be acid phosphatase positive.