Immunoelectron microscopic localization of thiolases, beta-oxidation enzymes of an n-alkane-utilizable yeast, Candida tropicalis.

The location of acetoacetyl-CoA thiolase (T-I) and 3-ketoacyl-CoA thiolase (T-III), enzymes of the fatty acid beta-oxidation system, was studied in n-alkane-grown Candida tropicalis cells by immunoelectron microscopy using a post-embedding method with colloidal gold conjugated IgG. The deposition of gold particles for T-I was detected in the microbodies and cytoplasm and that of gold particles for T-III specifically in the microbodies. The double labeling technique confirmed that T-I and T-III occurred concurrently in a microbody and T-I also in cytoplasm. These results were consistent with the biochemical data based on subcellular fractionation and indicated that the yeast beta-oxidation system operates efficiently only in the microbodies.     

The Determination of Comparable Labeling Densities in Quantitative Immunoelectron Microscopic Double Labeling Studies

In quantitative ultrastructural studies using colloidal gold immunocytochemical techniques, labeling intensities vary according to the size of the probe used. Using postembedded indirect two-sided double labeling and single labeling protocols, the labeling characteristics of four antigens were studied using two probe sizes commonly used in double labeling studies. It was determined that the labeling intensity variation resulting from the use of different probe sizes was unpredictable after correcting for the increased probe size alone. It was possible, however, to obtain comparable labeling densities by first determining the labeling intensities for each probe size with its antigen in single label studies on serial sections and using the same procedure as the double labeling studies. A probe size correction factor for each antigen was calculated from these data. This factor was used to obtain comparable measurements of the relative abundance of each label.     

Double immunocytochemical labeling applying the protein A-gold technique

In the present study we report the modifications and the different steps of the protein A-gold (pAg) technique that allow the simultaneous demonstration of two antigenic sites on the same tissue section. The labeling is carried out in the following manner: face A of the tissue section is incubated with an antiserum followed by a pAg complex prepared with large gold particles; face B of the same tissue section is then incubated with a second antiserum followed by a pAg complex prepared with small gold particles. Each of the pAg complexes reveals a different antigenic site on opposite faces of the tissue section. The transparency of the section in the electron beam allows the visualization of the gold particles present on both faces. The double labeling pAg technique was applied for the simultaneous demonstration of two secretory proteins in the same Golgi, condensing vacuoles, and zymogen granules of the rat pancreatic acinar cells.     

A novel procedure for pre-embedding double immunogold-silver labeling at the ultrastructural level.

Pre-embedding double immunogold-silver labeling using two ultrasmall gold conjugates has not been attempted previously because a means of distinguishing labels by conjugates of identical sizes was lacking. This study investigated the feasibility of creating a particle size segregation between two ultrasmall gold conjugates through sequential immunogold incubations and silver enhancements. Two primary antibodies, mouse anti-synaptophysin and rabbit anti-glial fibrillary acidic protein (GFAP), were used in the model system. Differentiation of the double labeling was achieved by incubating with one ultrasmall gold conjugate, followed by silver enhancement, and then incubating with the second ultrasmall gold conjugate, followed by additional silver enhancement. This resulted in two groups of silver-enhanced particles: smaller particles enhanced once and larger particles enhanced twice. Electron microscopic examination revealed two readily distinguished populations of gold-silver particles within the appropriate structures, with very little size overlap. The quality of the ultrastructure permitted identification of most subcellular organelles. This procedure provides for the first time a pre-embedding immunogold-silver labeling protocol that allows the precise subcellular co-localization of multiple antigens.     

Immunocytochemistry and in situ hybridization in the electron microscope: combined application in the study of virus-infected cells

The present review evaluates methods for electron microscopic immunocytochemistry and in situ hybridization, using post-embedding techniques and colloidal gold as a label. Special emphasis is given to double labeling immunocytochemistry and double in situ hybridization and to their combined application on the same specimen. Brief guidelines are presented for fixation, embedding media, the use of polyclonal and monoclonal antibodies and nucleic acid probes. Conditions for labeling and binding of antibody and nucleic acid probes to the target and protocols for direct and indirect immunodetection are discussed. Combinations of direct and indirect immunodetections in multiple labeling experiments are summarized.     

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.     

Combination of diaminobenzidine staining and immunogold labeling: a novel technical approach to identify lysozyme in human neutrophil cells

In this study, a combination of the diaminobenzidine staining procedure for myeloperoxidase and the immunogold labeling technique was successfully used to show that lysozyme is indeed found in both the primary and secondary type granules of human neutrophils. Following the systematic selection of processing conditions by light microscopic peroxidase anti-peroxidase cytochemistry, on slide preparations, consistent gold labeling was obtained over both types of granules. The combination of myeloperoxidase and immunogold cytochemical procedures permitted the lysozyme-labeling pattern of the small-sized granules to be studied in isolation, thereby confirming the existence of lysozyme in secondary granules. In addition, myeloperoxidase was observed in the large-sized, lysozyme-positive, granules by both cytochemical and immunocytochemical methods, thereby confirming that these labeled structures were primary granules. Morphometrical analysis confirmed that there was a significant difference in mean size between the lysozyme-positive, myeloperoxidase-positive, granules and the lysozyme-positive, myeloperoxidase-negative, granules. The former were significantly larger in size than the latter. In conclusion, although the localization of lysozyme in human neutrophils by the immunogold technique is confirmatory, the combination of enzyme cytochemistry and immunocytochemistry is a novel technical approach that permits the lysozyme-labeling patterns of granule types to be studied in isolation. This double labeling technique is relatively straightforward and, as such, consistent immunostaining can be routinely obtained using intact cells.     

Electron microscopic immunocytochemistry. Silver enhancement of colloidal gold marker allows double labeling with the same primary antibody

Electron microscopic sections, immunocytochemically labeled with colloidal gold, can be prepared for double labeling by applying the "EM-silver enhancement" procedure. This method, a photographic, so-called physical, development, increases the size of the gold marker to a predeterminable value and thereby inactivates the anti-species antibody present on the gold grain, thus allowing the labeling of a second antigen with antibody raised in the same species.     

Topography and dynamics of receptors for acetylated and malondialdehyde-modified low-density lipoprotein in the plasma membrane of mouse peritoneal macrophages as visualized by colloidal gold in conjunction with surface replicas

The topography and dynamics of receptors for acetylated (acetyl) and malondialdehyde-modified (MDA) low-density lipoprotein (LDL) in the plasma membrane of cultured mouse peritoneal macrophages were investigated using a new technique. Modified LDL labeled with gold particles was used to visualize LDL receptors in the plane of the plasma membrane in platinum-carbon surface replicas of critical point-dried cells. It was found that the native distribution of unoccupied acetyl-LDL receptors is diffuse, whereas unoccupied MDA-LDL receptors are preclustered in the plasma membrane. Competition and double labeling experiments suggest the existence of two distinct classes of receptor sites for acetyl-LDL and MDA-LDL.     

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.     

Coloidal gold, ferritin and peroxidase as markers for electron microscopic double labeling lectin techniques

Three markers, colloidal gold, ferritin and peroxidase, were checked for usefulness in double labeling of lectin-binding sites. The amount of various lectins for the stabilization of good sols of a different particle size was evaluated. Several lectin-gold complexes were prepared for electron microscopic labeling purposes, and the optimal amount of various lectins needed for stabilization of gold solutions of a different particle size was determined. The following combinations were investigated for their usefulness in labeling two different lectin-binding sites: lectin-gold and lectin-gold (different particle size), lectin-gold and lectin-ferritin, as well as lectin-ferritin and lectin-peroxidase. Of these combinations the latter did not give satisfactory results for double labeling. In all single and double labeling techniques with the above mentioned markers the quantitative evaluation of the number of lectin-binding sites is not feasible, but these techniques will be of considerable value for the investigation of the dynamics of different lectin-binding sites on the cell surface.     

Differential Silver Enhanced Double Labeling in Immunoelectron Microscopy

A two-sided double labeling method using protein A gold was used to demonstrate the presence of two hormones within the same anterior pituitary cell granule. A single probe size was used for both section faces but one side of the grid was silver enhanced. The use of a single probe size reduced the cost of the study and eliminated the variations in labeling efficiency that result from the use of different probe sizes.     

Flow cytometric DNA content of fresh tumor specimens using keratin-antibody as second stain for two-parameter analysis.

Studies concerning flow cytometric assessed DNA content reveal problems in interpretating DNA histograms of tumor specimens. The main problems are histograms with a broad coefficient of variation in the G0/G1 fraction; a high G2M fraction and samples with a low percentage of tumor cells. Therefore, in the present study, 382 fresh tumor specimens of carcinomas were analysed routinely, double labeled with, on the one hand, propidium-iodide for assessing DNA content and, on the other, a monoclonal keratin-antibody for marking epithelial and tumor cells. Of the 311 tumor samples, using single parameter analysis 165 (54%) were classified as DNA aneuploid and 146 (46%) as DNA "euploid." By double parameter analysis, 224 (72%) samples were keratin positive and 87 (27%) keratin negative and, of the 224 keratin positive tumors, 175 (78%) were DNA aneuploid and 49 (22%) DNA euploid. The DNA histograms of single and double parameter analysis were compared and it was concluded that in 24 cases (11%) keratin labeling was necessary to recognize DNA aneuploidy. In another 23 (10%) cases, keratin labeling was helpful in assessing DNA aneuploidy. Finally when the results of the 311 samples were combined, 215 (68%) were scored as DNA aneuploid and 99 (32%) DNA euploid. Thus the overall gain in assessing DNA aneuploidy using the double labeling technique is 14%. In conclusion, it is shown that keratin labeling on fresh tumor cell suspensions of epithelial tumors is of additional value in establishing DNA content. Because single parameter DNA assessment is adequate in approximately 60% of the tested samples, the double labeling technique can be performed routinely, or after initial single parameter DNA assessment. Histograms having a broad CV and/or a high G2M are good candidates for the double labeling technique. Using this technique, DNA-content assessment becomes more reliable.     

One antigen, one gold? A quantitative analysis of immunogold labeling of plasma membrane 5'-nucleotidase in frozen thin sections

We present an evaluation of the efficiency of immunogold labeling for a low abundance plasma membrane protein. Several independent methods were used to determine the density of 5'-nucleotidase on the plasma membrane of the Fao cell. These methods include morphometry in combination with either enzymology or cell surface radiometric assay. Immunocytochemistry of frozen thin sections with either single or double layers of antibody and visualized with protein A complexed with 5 nm colloidal gold was used to estimate the same density. The application of a balance sheet to immunogold labeling demonstrates that the labeling is never quantitative. For example, labeling of the cell surface is always greater than labeling on the section. We show that departures from the "one antigen, one gold" ideal are systematic, so that an efficiency can be calculated and quantitative results can be obtained. The ability to obtain reliable quantitative results from immunogold labeling extends the utility of this already powerful technique.     

Immunocytochemical localization of serine: pyruvate aminotransferase in peroxisomes of the human liver parenchymal cells

The localization of serine:pyruvate aminotransferase (SPT) in human liver was investigated by indirect immunoenzyme and protein A-gold techniques. By light microscopy, diaminobenzidine reaction product was present in cytoplasmic granules of the parenchymal cells. By electron microscopy, gold particles indicating the antigenic sites for SPT were exclusively confined to peroxisomes but not to mitochondria. By double labeling technique, both peroxisomal marker enzyme, catalase and SPT were detected in the same peroxisomes. Quantitative analysis of the labeling density showed that SPT is contained only in peroxisomes. The results indicate that in human liver most of SPT is contained in the peroxisomes.     

Immunocytochemical localization of serine: pyruvate aminotransferase in peroxisomes of the human liver parenchymal cells

Summary The localization of serine:pyruvate aminotransferase (SPT) in human liver was investigated by indirect immunoenzyme and protein A-gold techniques. By light microscopy, diaminobenzidine reaction product was present in cytoplasmic granules of the parenchymal cells. By electron microscopy, gold particles indicating the antigenic sites for SPT were exclusively confined to peroxisomes but not to mitochondria. By double labeling technique, both peroxisomal marker enzyme, catalase and SPT were detected in the same peroxisomes. Quantitative analysis of the labeling density showed that SPT is contained only in peroxisomes. The results indicate that in human liver most of SPT is contained in the peroxisomes.     

A colloidal gold labeling technique for the direct determination of the surface area of eukaryotic cells

We have developed a colloidal gold labeling technique for the direct quantitation of the cell surface area. The method is based on coating the cell surface with [195Au] colloidal gold-protein complexes followed by morphometric determination of the labeling density (gold particles/micron2 cell surface) and radiometric determination of the total number of gold particles bound per cell. The ratio of both values directly gives the cell surface area. The accuracy of the method was shown using Staphylococcus aureus cells as a model system, where the cell surface area determined with our assay (4.0 microns2) corresponded well to the value calculated from the radius of the cells (3.6 microns2). In a more complex model system J-774 mouse macrophages were labeled with different amounts of [195Au] gold-protein complexes to show that the assay is independent of the degree of saturation of the cell surface binding sites. Both high (135 Au/microns2) and low (65 Au/microns2) labeling densities resulted in a surface area of about 1200 microns2. The technique finally was applied to L-929 fibroblasts to determine the increase of the cell surface area when the cells change from a spherical to a flat monolayer state. We found that the cell surface area increased 3-fold during the spreading process. The results show that the colloidal gold labeling technique allows the direct determination of the surface area of complex eukaryotic cells. The technique is suitable for the quantitation of changes in the surface architecture known to occur in different functional states of eukaryotic cells.     

Gold probe choice in simultaneous detection of human lymphocyte surface antigens at the ultrastructural level

A double immunogold-labeling method in immunoelectron microscopy was used for simultaneous detection of two antigens by monoclonal antibodies [OKT 8 (CD 8), anti-Leu-7, anti-Leu-11b (CD 16)] on lymphocytes in suspension. The combination of gold probe size (5 nm and 15 nm) and monoclonal antibody was found to be decisive for detecting double-labeled cells with the OKT 8+, Leu-11b+ phenotype. The combinations of OKT 8 labeled with the 5-nm gold probe (OKT 8(5] and anti-Leu-11b with the 15-nm gold probe (Leu-11b15) gave double-labeled cells; the reverse situation, using OKT 8 with a 15-nm gold probe (OKT 8(15] and anti-Leu-11b with a 5-nm gold probe (Leu-11b5), did not. Double-labeled OKT 8+, Leu-7+ cells were detected irrespective of which gold probe combination was applied. Our findings indicate that although the double immunogold-labeling method is well suited for study of lymphocyte subsets, it is important to determine suitable combinations of gold probe sizes and monoclonal antibodies for the lymphocyte subset under study, taking into account surface antigen density, so that double labeling ensues.     

Ultrastructural localization of nuclei acids by the use of enzyme-gold complexes

A cytochemical technique for the ultrastructural localization of substrates using enzyme-gold complexes is reported. RNase A and DNase I have been labeled with gold particles. The RNase-gold and dNase-gold complexes obtained were applied on thin sections of glutaraldehyde-fixed and Epon-embedded tissues. Different cellular compartments were labeled by these enzyme-gold complexes. Using the RNase-gold complex the rough endoplasmic reticulum appeared decorated with gold particles. The gold marker was also present over the nucleus, especially over the nucleolus; mitochondria were weakly labeled. Using the DNase-gold complex, gold particles were concentrated over the euchromatin of the nucleus and the mitochondria. The heterochromatin and the nucleolus showed a less intense labeling. For both enzyme-gold complexes, the Golgi area, the secretory granules and the extracellular space appeared free of label. In those control conditions where the substrates were added to the enzyme-gold complexes a major reduction in the labeling was observed. A quantitative evaluation of the labeling was performed. This evaluation confirmed the qualitative observations and the marked reduction of labeling occurring under the control conditions. The combination of the specificity of the enzyme-substrate interactions with the size and electron density of the gold particles and the good ultrastructural preservation of the tissues resulted in a very specific labeling with high resolution. These results demonstrate the possibility of detecting substrates by means of enzyme-gold complexes at the electron microscope level.     

The use of silver-enhanced 1-nm gold probes for light and electron microscopic localization of intra- and extracellular antigens in skin.

We used colloidal gold (1-nm diameter) with silver enhancement, in conjunction with a low-temperature post-embedding immunolabeling technique, to localize several antigens in normal skin at both the light and the electron microscopic level within the same tissue blocks. Normal skin subjected to cyrofixation and cryosubstitution and embedded in Lowicryl K11M was used as a substrate. Semi-thin sections (1 micron) were incubated in primary antibody (against epidermal basement membrane zone associated antigens and two keratin sub-types), biotinylated secondary antibodies, and then in 1-nm gold-conjugated streptavidin. Finally, the 1-nm gold label was enhanced using silver staining. Labeling of both basement membrane and keratin antigens was well demonstrated, and the area in the semi-thin sections showing the best structural preservation and the greatest intensity of immunolabeling was used to identify the part of the block to be used for ultra-thin sectioning. Ultra-thin sections were treated using a similar procedure to that employed for semi-thin sections. The labeling with silver-enhanced 1-nm gold probes was intense and readily visible by electron microscopy, even at low magnification. We have found this technique to have a high degree of specificity and sensitivity for labeling both intra- and extracellular antigens in skin, with the added advantage of providing the means for studies at both light microscopic and electron microscopic level.