Colour development of immunogold-labelled antibodies for light microscopy

Summary We describe an improvement of the immunogold technique, which is based on the colour development of silver-intensified immunogold signals. This method (referred to as the coloured-SIG technique) was found to be as sensitive as the silver-intensified immunogold method and more sensitive (in two of the three tested systems) than immunoenzymatic procedures, such as the peroxidase/antiperoxidase technique or the avidin-biotin system. The coloured SIG-method results in either a magneta-red or a cyan-blue final reaction product. Therefore, this new improvement of the immunogold technique should be useful in (1) double-staining methods, (2) immunoblot methods and (3) conventional immunostaining methods.Supported by the Robert-Bosch-Foundation, Stuttgart     

Colored silver-intensified gold technique for light microscopy

The development of silver-intensified immunogold-labeled antibodies for light microscopy described by Fritz et al. (4) has been investigated. Principles and chemistries used in color photographic science have been applied to immunogold enhancement. In this technique, colloidal gold acts as the catalytic center for the reduction of silver ions to metallic silver with subsequent color development in the presence of hydroquinone. Silver ions and hydroquinone are adsorbed onto the surface of colloidal gold. The reduction of silver ions to metallic silver is further catalyzed by autometallography. The colored-SIG technique offers several advantages. It has sensitivity comparable to the silver-intensified gold (SIG) method and greater sensitivity than immunoenzymatic procedures, takes approximately one hour, results in one of three color reaction products (magenta, cyan, or yellow), and produces better contrast between the reaction products and the background (Figure 1). Thus, this method should prove useful in double- and even triple-staining procedures.     

Increased sensitivity in immunocytochemistry. Effects of double application of antibodies and of silver intensification on immunogold and peroxidase-antiperoxidase staining techniques

Sensitivity and detection efficiency of immunocytochemical methods were tested on cytochemical models and tissue material, respectively. Use of silver intensification procedures revealed that staining with immunogold reagents could be rendered equally or even more sensitive than the standard peroxidase-antiperoxidase (PAP) method. Further increases in sensitivity with both methods could be obtained by double application of the primary antiserum. Combined use of the immunogold techniques and the PAP method with development in diaminobenzidine and subsequent silver intensification resulted in the most sensitive procedures. The procedures were applied to a wide variety of tissue preparations, including whole mount preparations of the external longitudinal muscle layer of the gut wall and were found not to produce any unspecific staining in any tissue tested. Use of immunogold-silver and, particularly of the combined immunogold-silver-PAP methods may be valuable for analyzing tissues and tumours containing small amounts of antigen, for testing the quality of immunogold staining procedures intended for ultrastructural studies and for electroblotting techniques.     

Immunogold silver staining for light microscopy

 The immunogold silver staining method (IGSS) is widely used as a sensitive and specific immunohistochemical visualisation technique. IGSS involves the specific deposition of metallic silver at the site of immunogold labelling and provides a means of visualisation at low magnification by light or electron microscopy. Silver developers for IGSS rapidly deposit metallic silver only at the site of heavy metals, including gold and silver, because of their catalytic activity. The developing solution contains the silver ions and reducing agent necessary for this reaction. Using different silver salts as ion donors and by selecting an appropriate temperature and pH, visible amounts of silver can be deposited in a few minutes at the site of colloidal gold labelling while little non-specific background deposition occurs. Inclusion of protective colloids in the solution can also be used to control the reaction. Although studies of the chemical basis of silver deposition around unlabelled colloidal gold date back to 1939, immunogold enhancement by silver was established in 1983. The IGSS method evolved from the combination of disparate photographic, histochemical and immunogold techniques which have been effectively combined and optimised over the last 10 years to provide a visualisation system which is well suited to many immunohistochemical studies. Accepted: 29 April 1996     

The application of a biotin-anti-biotin gold technique providing a significant signal intensification in electron microscopic immunocytochemistry: a comparison with the ultrasmall immunogold silver staining procedure

 A three-step biotin-anti-biotin gold-detection system (method A) has been applied for ultraimmunocytochemistry using ultrasmall colloidal gold (0.8 nm) linked to anti-biotin antibodies which were visualized and enhanced by silver reduction. The reactivity for glucagon in human pancreatic islets and for cytochrome-c oxidase in heart mitochondria has been compared to a two-step ultrasmall immunogold technique (method B). For both antigens, method A provided significantly higher labelling indices (P<0.001): the labelling density for cytochrome-c oxidase was 223/μm² using method A and 78/μm² using method B. For glucagon, the labelling density was 1455/μm² with method A and 322/μm² with method B. The results demonstrate that the silver-intensified biotin-anti-biotin gold-detection system is a valuable immunocytochemical method for signal enhancement. The method utilizes biotinylated antibodies from different species, allowing its broad application at the electron microscopic level. Accepted: 24 June 1997     

Applications of immunogold and lectin-gold labeling in tumor research and diagnosis

Immunohistochemistry and carbohydrate histochemistry have had an enormous impact on both tumor research and diagnosis. In particular, immunogold labeling has provided significant advantages over classical fluorescence and enzyme-based techniques. In light microscopy, the silver-intensified gold labeling has proven highly sensitive and precise in localization. In electron microscopy, the gold particle marker was a prerequisite for succesful and unequivocal antigen detection in electron-dense cellular structures such as secretory granules. In this review we demonstrate the usefulness of light and electron microscopiaal gold labeling techniques as applied in tumor research and diagnosis. The examples include expression of β-1,6 branches and specific sialoglycoconjugates in colon carcinoma, b-12 carbohydrate epitope in breast carcinoma, polysialic acid in neuroendocrine tumors of lung, adrenal and thyroid, as well as studies on proinsulin to insulin conversion in insulinomas. In addition, practical hints for prevention of background taining, tissue fixation, and silver intensification of gold labeling are given.     

Native Immunogold Labeling of Cell Surface Proteins and Viral Glycoproteins for Cryo-Electron Microscopy and Cryo-Electron Tomography Applications

Numerous methods have been developed for immunogold labeling of thick, cryo-preserved biological specimens. However, most of the methods are permutations of chemical fixation and sample sectioning, which select and isolate the immunolabeled region of interest. We describe a method for combining immunogold labeling with cryo-electron microscopy (cryo-EM) and cryo-electron tomography (cryo-ET) of the surface proteins of intact mammalian cells or the surface glycoproteins of assembling and budding viruses in the context of virus-infected mammalian cells cultured on EM grids. In this method, the cells were maintained in culture media at physiologically relevant temperatures while sequentially incubated with the primary and secondary antibodies. Subsequently, the immunogold-labeled specimens were vitrified and observed under cryo-conditions in the transmission electron microscope. Cryo-EM and cryo-ET examination of the immunogold-labeled cells revealed the association of immunogold particles with the target antigens. Additionally, the cellular structure was unaltered by pre-immunolabeling chemical fixation and retained well-preserved plasma membranes, cytoskeletal elements, and macromolecular complexes. We think this technique will be of interest to cell biologists for cryo-EM and conventional studies of native cells and pathogen-infected cells.     

Development and validation of a sensitive immunohistochemical oestrogen receptor assay for use on archival breast cancer tissue

In a preliminary paper (Teasdale et al. 1987) comparing the oestrogen receptor (ER) content of breast cancers by the biochemical dextran coated charcoal (DCC) method and by two histochemical methods, peroxidase immunocytochemistry (ERICA) and immunogold-silver staining (IGSS), it was indicated that ERICA is more sensitive than DCC and that IGSS is as specific as ERICA but less sensitive. This paper describes the comparison of the above three assay methods with two other biochemical methods, iso-electric focusing (IEF) and an enzyme immuno-assay (EIA) on a larger number of cancers. All methods gave statistically comparable results except that IGSS remained less sensitive than the rest. Various modifications to IGSS showed that an immunogold streptavidin enhancement method (IG-SAM) produced sensitivity and specificity equal to that of ERICA. Since IGSS and its modifications are the only methods which can be used on archival paraffin-embedded cancers and IG-SAM gives results highly comparable to ERICA, retrospective studies can be performed on patients whose outcome and response to various treatments are known. Most recent studies have shown that ER positive results can be obtained from 10-year-old paraffin blocks.     

Reflection contrast microscopy of ultrathin sections in immunocytochemical localization studies: a versatile technique bridging electron microscopy with light microscopy

Reflection contrast microscopy (RCM) of ultrathin sections was recently introduced as a sensitive technique for visualization with enhanced definition in immunogold histochemistry. Experience of using RCM as a major tool in immunocytochemical research in different fields is summarized, e.g. oncology, nephrology and embryology. The sensitive visualization of immunocytochemical labels, gold particles or peroxidase-diaminobenzidine deposits in or on ultrathin sections, by RCM instead of electron microscopy is demonstrated. RCM of ultrathin sections is an adequate light microscopical alternative for immunoelectron microscopy, since an overview of both label and tissue is obtained with a high image definition and high contrast of label. In the studies presented, RCM is shown to provide a better gradation in staining intensity and staining pattern than other light microscopical methods. Moreover, a precise localization of multiple labels is obtained with this method. Besides the applications shown, ultrathin section visualization by RCM is very useful for correlative light- and electron microscopical studies of fine structures. Commercially available fluorescence microscopes can be adapted for proper RCM functioning; an adaptation scheme and list of microscopes tested is provided.     

Development and validation of a sensitive immunohistochemical oestrogen receptor assay for use on archival breast cancer tissue

Summary In a preliminary paper (Teasdale et al. 1987) comparing the oestrogen receptor (ER) content of breast cancers by the biochemical dextran coated charcoal (DCC) method and by two histochemical methods, peroxidase immunocytochemistry (ERICA) and immunogold-silver staining (IGSS), it was indicated that ERICA is more sensitive than DCC and that IGSS is as specific as ERICA but less sensitive. This paper describes the comparison of the above three assay methods with two other biochemical methods, iso-electric focusing (IEF) and an enzyme immuno-assay (EIA) on a larger number of cancers. All methods gave statistically comparable results except that IGSS remained less sensitive than the rest. Various modifications to IGSS showed that an immunogold streptavidin enhancement method (IG-SAM) produced sensitivity and specificity equal to that of ERICA. Since IGSS and its modifications are the only methods which can be used on archival paraffin-embedded cancers and IG-SAM gives results highly comparable to ERICA, retrospective studies can be performed on patients whose outcome and response to various treatments are known. Most recent studies have shown that ER positive results can be obtained from 10-year-old paraffin blocks.     

Microwave-stimulated incubation in immunoelectron microscopy: A quantitative study

Summary Microwave irradiation has been applied to reduce the immunogold staining time of ultrathin sections of Lowicryl embedded specimens. Labelling has been stimulated by microwave irradiation during incubation with 10nm colloidal gold particls coated with either goat anti-mouse antibodies (GaM-gold) or goat anti-rabbit antibodies (GaR-gold) and has been compared with control incubations. Quantification has been performed on cytoplasmic membranes or lysosomes labelled with a primary antibody. Counting the gold particles over specific and non-specific sites in electron micrographs and electron microscopic images by IBAS 2000 revealed that irradiation of 25 l droplets both at 80W and 150 W resulted in an accelerated immunogold labelling, while the non-specific background levels were not increased. A plateau level in immunogold labelling intensity was reached after 25 min incubation under microwave irradiation at 150W as compared to 120 min incubation without microwaves. No improvement in localization sharpness of immunogold labelling on membranes was achieved by microwave irradiation. The microwave-mediated acceleration of immunogold staining may be considered as an example of a staining method with a restricted thermal action on microvolumes as indicated by direct temperature measurements using a fibre-optic thermometer.     

Versatility of anti-horseradish peroxidase antibody-gold complexes for cytochemistry and in situ hybridization: preparation and application of soluble complexes with streptavidin-peroxidase conjugates and biotinylated antibodies.

In previous studies we have employed a gold-labelled, affinity-purified polyclonal antibody against horseradish peroxidase (anti-HRP--gold) in the avidin-biotin peroxidase complex (ABC) technique and indirect labelled avidin-biotin methods. The gold-labelled antibody was used as final revealing reagent to replace the 3,3'-diaminobenzidine (DAB) reaction by immunogold silver staining. The anti-HRP--gold reagent proved to be advantageous since blocking of endogenous peroxidase activity in the tissue sections was not further required and staining of superior contrast and resolution could be achieved in paraffin sections. In the present study we have optimized this technique by combining the last two incubation steps, i.e. HRP-conjugated streptavidin and anti-HRP--gold. Different ratios of the two reagents were tested empirically to establish the conditions for the formation of a soluble complex with optimal staining properties. Quantitative evaluation by densitometry of the staining intensity showed that the soluble streptavidin-HRP/anti-HRP--gold complex and the indirect labelled avidin-biotin method employing the gold-labelled anti-HRP antibody performed equally well. Thus, the availability of this complex simplifies the streptavidin-biotin immunogold technique for immunohistochemistry, lectin histochemistry and in situ hybridization and further demonstrates the versatility of anti-HRP--gold complexes.     

应用免疫金电镜技术鉴定动物病毒方法的探讨

本文提出了一种改进的免疫金电镜技术,即,离心法,快速鉴定动物病毒。发现了离心法比混合法和滴附法较为理想,非特异性反应较小,灵敏度高,可做为常规快速鉴定动物病毒方法。     

Use of immunoperoxidase and immunogold methods in studying prolactin secretion and application of immunogold labelling for pituitary hormones and neuropeptides

Two immunocytochemical methods, immunoperoxidase and immunogold (IG), were used in an attempt to study the dynamic process of prolactin release from stimulated rat pituitary mammotrophs. The immunogold method was also used to localize other pituitary hormones including growth hormone, follicle-stimulating hormone, luteinizing hormone, and the neuropeptides substance P, neuropeptide tyrosine, leu-enkephalin, and atrial natriuretic factor in peripheral nerves. Light-microscopic immunoperoxidase staining of prolactin revealed a unique distribution of immunoreactive mammotrophs. Two groups of cells were seen, one centrally located and one forming a narrow peripheral rim on the gland. The two groups were separated by a zone of nonimmunoreactive cells. In addition, the distribution of immunoperoxidase-stained material was not uniform in all mammotrophs. In some, prolactin immunoreactive material was clumped near the nucleus (in the Golgi cisternae); in others it was more diffused within the cytoplasm (but immediately surrounding the cisternae of rough endoplasmic reticulum). After stimulation of mammotrophs, via suckling, prolactin-immunoreactive material was visualized in extracellular spaces. With immunogold methods, prolactin labelling was seen mainly in secretory granules; but some labelling of Golgi cisternae and rough endoplasmic reticulum also occurred. Immunogold labelling revealed that material immunoreactive for leu-enkephalin and atrial natriuretic factor was present in nerve terminals in the rat paracervical ganglion. Material immunoreactive for substance P and neuropeptide tyrosine was present in nerve terminals in the guinea pig heart. Thus, in some situations the immunoperoxidase technique was useful and helped to visualize "grossly" the presence of specific antigens, but it was inadequate for fine ultrastructural localization of these antigens. The immunogold technique was excellent for precise localization of antigens and especially for the detection of colocalization of different antigens. This method can be used in very different structures, such as the adenohypophysis and peripheral nervous tissue, without any modification except for the nature of the antibodies.     

Immunogold signal amplification: Application of the CARD approach to electron microscopy.

Catalyzed reporter deposition (CARD) is a technique that allows amplification of routine immunolabeling in light microscopy. This procedure takes advantage of the horseradish peroxidase (HRP) from an HRP-avidin complex to catalyze the accumulation of reporter-conjugated tyramine (a phenolic compound) onto a surface displaying biotinylated antigen-antibody complexes. The large amount of labeled tyramine deposited allows the detection of an antigenic site with multiple reporter molecules. In this study we modified this amplification protocol to combine it with the immunogold technique for the ultrastructural localization of antigens in electron microscopy. We constructed various tyramide conjugates that permit the combination of this amplification method with a particulate colloidal gold marker. The new probes yield results of high specificity and enhanced intensity. Assessment of the level of resolution of the labeling has demonstrated that, in spite of the amplification, the resolution remains very good. Therefore, once associated, the immunogold and the CARD techniques lead to specific, high-resolution, sensitive and amplified signals that exhibit the advantages of both approaches.(J Histochem Cytochem 47:421-429, 1999)     

Use of immunogold preembedding technique to detect hepatitis A viral antigen in infected cells

Localization of virus and viral antigen in cell cultures infected with a rapidly replicating isolate of strain HM-175 of hepatitis A virus (HAV; pHM-175) was accomplished by using immunogold probes. Cells infected under one-step growth curve conditions were prefixed with 2% paraformaldehyde and 0.1-0.001% saponin at appropriate times postinfection for detection of maximum virus and viral antigen. An indirect labeling technique was employed using monoclonal antibody to HAV followed by 5 nm gold-antimouse IgG conjugate. Cells were then fixed by standard electron microscopy techniques and thin sectioned. This prefixation technique allowed penetration of the immunogold probes and moderate preservation of ultrastructure. Within infected cell cytoplasm, numerous antigenic sites were labeled with six to 200 gold particles. Two types of cells were infected with HAV and somewhat different results were obtained with the two cell types. In BS-C-1 cells, where a cytopathic effect (CPE) was not observed, myelin figures were immunogold labeled or frequently were located near immunogold-labeled sites. Vesicles containing viruslike particles (14-22 nm) were also observed. A significant observation in infected FRhK-4 cells was the presence of multivesicular bodies labeled with immunogold. Microfilaments were commonly seen near the multivesicular bodies. Our results demonstrate that the choice of prefixation method for immunogold labeling should be empirically determined for the cell type and condition.     

Immunoelectron microscopic localization of chlamydial lipopolysaccharide (LPS) in McCoy cells inoculated with Chlamydia trachomatis.

Interactions between Chlamydia trachomatis, host cells, and the immune system are believed to involve lipopolysaccharide (LPS). We used immunogold techniques to study the distribution of chlamydial LPS in cultured cells infected with C. trachomatis LGV-L1. McCoy cells inoculated with C. trachomatis were cultured and then fixed and embedded in situ with acrylic resins. Sections were immunolabeled with a protein A-gold method using antisera to the genus-specific, periodate-sensitive epitope on chlamydial LPS. Pre-embedding immunogold labeling on permeabilized cells was also done. By post-embedding methods, labeling for LPS was equally abundant over the outer membranes of elementary (EB) and reticulate bodies (RB). By post-embedding labeling, the sub-surface side of the EB outer membrane was more heavily labeled than the surface side. By pre-embedding labeling, LPS was found to be less abundant on the surface of EBs than RBs. Labeling for LPS was found over apparent lysosomes in McCoy cells and over electron-dense blebs on or near the surface of the plasma membranes of McCoy cells. These results indicate that the concentration of LPS in chlamydial membranes is constant during development but that with development its location changes from being mostly cell-surface to sub-surface. These results show that the post-embedding immunogold technique can be a useful approach for the cell culture-based study of chlamydial LPS.     

The localization of estrogen receptors on human osteoblasts

Attempts to identify estrogen target cells in bone by immunocytochemistry using antibodies to the receptor have proved to be controversial. The aim of this study was therefore to determine whether immunogold labeling can be used as a technique for the localization of estrogen receptors (ER) on a human osteoblast-like cell line. The aim was also to determine the distribution of ER on the cell surface by using a scanning electron microscope (SEM) and intracellularly by using a transmission electron microscope (TEM). Labeling of the cytoplasmic material was seen around areas that appeared to be a disrupted plasma membrane. No nuclear or perinuclear labeling could be detected. The conclusion can be made that SEM immunogold labeling combined with TEM can be regarded as a practical technique for localizing ER on human osteoblasts. This article clearly demonstrated that osteoblast-like cells do express ER at low levels and that, although cytoplasmic immunoreactivity could be detected, no, nuclear or perinuclear labeling was found.     

Versatility of anti-horseradish peroxidase antibody-gold complexes for cytochemistry and in situ hybridization: preparation and application of soluble complexes with streptavidin-peroxidase conjugates and biotinylated antibodies

Summary In previous studies we have employed a gold-labelled, affinity-purified polyclonal antibody against horseradish peroxidase (anti-HRP — gold) in the avidinbiotin peroxidase complex (ABC) technique and indirect labelled avidin-biotin methods. The gold-labelled antibody was used as final revealing reagent to replace the 3,3-diaminobenzidine (DAB) reaction by immunogold silver staining. The anti-HRP — gold reagent proved to be advantageous since blocking of endogenous peroxidase activity in the tissue sections was not further required and staining of superior contrast and resolution could be achieved in paraffin sections. In the present study we have optimized this technique by combining the last two incubation steps, i.e. HRP-conjugated streptavidin and anti-HRP — gold. Different ratios of the two reagents were tested empirically to establish the conditions for the formation of a soluble complex with optimal staining properties. Quantitative evaluation by densitometry of the staining intensity showed that the soluble streptavidin-HRP/anti-HRP — gold complex and the indirect labelled avidin-biotin method employing the gold-labelled anti-HRP antibody performed equally well. Thus, the availability of this complex simplifies the streptavidin-biotin immunogold technique for immunohistochemistry, lectin histochemistry and in situ hybridization and further demonstrates the versatility of anti-HRP — gold complexes.     

Comparative study of three proteomic quantitative methods, DIGE, cICAT, and iTRAQ, using 2D gel- or LC-MALDI TOF/TOF

A comparative study on the three quantitative methods frequently used in proteomics, 2D DIGE (difference gel electrophoresis), cICAT (cleavable isotope-coded affinity tags) and iTRAQ (isobaric tags for relative and absolute quantification), was carried out. DIGE and cICAT are familiar techniques used in gel- and LC-based quantitative proteomics, respectively. iTRAQ is a new LC-based technique which is gradually gaining in popularity. A systematic comparison among these quantitative methods has not been reported. In this study, we conducted well-designed comparisons using a six-protein mixture, a reconstituted protein mixture (BSA spiked into human plasma devoid of six abundant proteins), and complex HCT-116 cell lysates as the samples. All three techniques yielded quantitative results with reasonable accuracy when the six-protein or the reconstituted protein mixture was used. In DIGE, accurate quantification was sometimes compromised due to comigration or partial comigration of proteins. The iTRAQ method is more susceptible to errors in precursor ion isolation, which could be manifested with increasing sample complexity. The quantification sensitivity of each method was estimated by the number of peptides detected for each protein. In this regard, the global-tagging iTRAQ technique was more sensitive than the cysteine-specific cICAT method, which in turn was as sensitive as, if not more sensitive than, the DIGE technique. Protein profiling on HCT-116 and HCT-116 p53 -/- cell lysates displayed limited overlapping among proteins identified by the three methods, suggesting the complementary nature of these methods.