Quantification of protein A-gold staining for peroxisomal enzymes by confocal laser scanning microscopy.

The protein A-gold technique has been widely applied for visual localization and quantification of various antigens by electron microscopy. Observation of specimens stained by the protein A-gold technique with conventional light microscopy is difficult because of insufficient sensitivity of the staining. Light microscopic visualization and quantification of the reaction products were attempted employing a confocal laser scanning microscope (CLSM). Liver tissues of normal and peroxisome proliferator-treated rats were fixed and embedded in Lowicryl K4M resin. Ultrathin and thin sections were stained for catalase and a peroxisome-specific beta-oxidation enzyme by the protein A-gold technique. Ultrathin sections were observed by electron microscopy and the labeling density for each enzyme was analyzed with an image analyzer. Thin sections were observed with a CLSM in the reflection mode and the intensity of the light reflection was analyzed under the same conditions for all specimens. A comparison of these two observation procedures was also attempted using liver tissues stained with various concentrations of the antibody for catalase. The intensity of the reflection for each, as observed by CLSM, correlated well with the labeling density observed by electron microscopy. CLSM made it possible to quantify and to directly observe protein A-gold staining at the light microscopic level.(J Histochem Cytochem 47:1343-1349, 1999)     

Characterization of AL amyloid protein identified by immunoelectron microscopy: a simple method using the protein A-gold technique

The classification of amyloidosis depends on the chemical nature of the specific amyloid protein involved. Because AL amyloid protein consists mainly of variable regions of light chain (LC), immunohistochemical staining with conventional anti-LC antisera cannot identify its protein. We were able to classify three cases of AL amyloidosis, including one case of AL-kappa LC and two cases of AL-lambda LC, using post-embedding protein A-gold immunoelectron microscopy on autopsy-derived tissues. We describe here our procedure in which a protein A-gold staining apparatus was used. The main advantage of this method is that many sections can be stained and washed simultaneously under the same conditions. These results suggest that the post-embedding protein A-gold technique using conventional kappa or lambda LC may be useful in diagnosing AL amyloidosis.     

Prevention of non-specific interactions of gold-labeled reagents on tissue sections

The protein A-gold technique is amongst the most useful labeling techniques available for light and electron microscopic immunolabeling. Some electron microscopic studies, however, have suggested that protein A-gold, and other protein-gold complexes as well, may bind non-specifically to certain tissue structures, particularly in skin, creating a specious pattern of labeling. We utilized the protein A-gold technique with antiserum to both involucrin and keratin under a variety of conditions to document the specificity of labeling. When the standard conditions were followed, the protein A-gold technique produces highly specific results. These conditions include: 1. the blocking of unreacted aldehyde groups by amination; 2. the blocking of non-specific binding sites on tissue sections by preincubation with inert proteins; and 3. the use of proper concentration of the protein A-gold complex. However, non-specific labeling could be produced if the three components of the standard protocol were omitted. In particular, the use of too concentrated protein A-gold lead to non-specific labeling. We report here also updated working protocols for antigen detection with protein A-gold on semithin Lowicryl K4M and paraffin sections which provide optimal staining results.     

The detection of substructures within proteoglycan molecules. Electron-microscopic immuno-localization with the use of Protein A-gold.

Proteoglycan monomers from pig laryngeal cartilage were examined by electron microscopy with benzyldimethylalkylammonium chloride as the spreading agent. The proteoglycans appeared as extended molecules with a beaded structure, representing the chondroitin sulphate chains collapsed around the protein core. Often a fine filamentous tail was present at one end. Substructures within proteoglycan molecules were localized by incubation with specific antibodies followed by Protein A-gold (diameter 4 nm). After the use of an anti-(binding region) serum the Protein A-gold (typically one to three particles) bound at the extreme end of the filamentous region. A small proportion of the labelled molecules (10-15%) showed the presence of gold particles at both ends. A monoclonal antibody specific for a keratan sulphate epitope (MZ15) localized a keratan sulphate-rich region at one end of the proteoglycan, but gold particles were not observed along the extended part of the protein core. This distribution was not changed by prior chondroitin AC lyase digestion of the proteoglycan. Localization with a different monoclonal antibody to keratan sulphate (5-D-4) caused a change in the spreading behaviour of a proportion (approx. 20%) of the proteoglycan monomers that lost their beaded structure and appeared with the chondroitin sulphate chains projecting from the protein core. In these molecules the Protein A-gold localized antibody (5-D-4) along the length of the protein core whereas in those molecules with a beaded appearance it labelled only at one end. Labelling with either of the monoclonal antibodies was specific, as it was inhibited by exogenously added keratan sulphate. The differential localization achieved may reflect structural differences within the proteoglycan population involving keratan sulphate and the protein core to which it is attached. The results showed that by this technique substructures within proteoglycan molecules can be identified by Protein A-gold labelling after the use of specific monoclonal or polyclonal antibodies.     

Prevention of non-specific interactions of gold-labeled reagents on tissue sections

Summary The protein A-gold technique is amongst the most useful labeling techniques available for light and electron microscopic immunolabeling. Some electron microscopic studies, however, have suggested that protein A-gold, and other protein-gold complexes as well, may bind non-specifically to certain tissue structures, particularly in skin, creating a specious pattern of labeling.We utilized the protein A-gold technique with antiserum to both involucrin and keratin under a variety of conditions to document the specificity of labeling. When the standard conditions were followed, the protein A-gold technique produces highly specific results. These conditions include: 1. the blocking of unreacted aldehyde groups by amination; 2. the blocking of non-specific binding sites on tissue sections by preincubation with inert proteins; and 3. the use of proper concentration of the protein A-gold complex. However, non-specific labeling could be produced if the three components of the standard protocol were omitted. In particular, the use of too concentrated protein A-gold lead to non-specific labeling.We report here also updated working protocols for antigen detection with protein A-gold on semithin Lowicryl K4M and paraffin sections which provide optimal staining results.Part of this work was presented at the 17th World Congress of Dermatology, Berlin (West), May 24–29, 1987     

Immunolabeling efficiency of protein A-gold complexes

A systematic study of the adsorption of protein A on colloidal gold particles varying in size from 5-16 nm was performed at different protein concentrations. The number of protein A molecules bound per colloidal particle was evaluated and the Scatchard analysis of the adsorption parameters was applied for each size of the colloid. The binding of protein A to the colloidal gold surface exhibited the same affinity pattern for all of the particle sizes. At low concentrations of stabilizing protein, adsorption took place with high affinity (Kd 1.96-3.3 nM) and the maximum number of protein A molecules attached with this affinity correlated well with the surface of the particle. At higher concentrations of protein A, adsorption exhibited a significantly lower affinity (Kd 530-800 nM), and no saturation was recorded. Competition by albumin did not reveal a preferential removal of the "low-affinity" bound protein A molecules, contradicting the model of successive shells of stabilizing protein around the colloidal particle. The immunolabeling efficiency of conjugates having the same size of gold nucleus but carrying different numbers of protein A molecules was comparatively investigated by quantitative post-embedding immunocytochemistry. Protein A-gold formed with 5-10-nm colloids gave the highest intensity of labeling when carrying the maximum number of protein A molecules that could be adsorbed with high affinity. Overloading as well as underloading these complexes resulted in a significant decrease of their immunoreactivity. The most efficient conjugates were obtained when stabilization was performed with 6 micrograms protein A/ml gold sol of 5 and 10 nm particle diameter, and 15 micrograms protein/ml of 15-nm colloid.     

Modification of the protein A-gold immunocytochemical technique for the enhancement of its efficiency

A modification in the protein A-gold immunocytochemical technique has been introduced for amplification of the labeling. This modification consists of performing additional incubation steps with an anti-protein A antibody and the protein A-gold complex. The original antigen-antibody-protein A-gold complex was further incubated with an antibody directed against protein A and then, in a fourth step, again with protein A-gold. This multiple-step protocol results in significant enhancement of the original signal. The modified technique can be applied to either light or electron microscopy protein A-gold immunocytochemistry. The advantage of such an approach is double: it allows for either amplification of the labeling when the original signal is of low intensity or use of highly diluted antibody solutions. The modification introduced was thus found to significantly enhance the efficiency of the technique.     

Calcitonin and chromogranin A localization in medullary carcinoma of the thyroid by immunoelectron microscopy

We used a post-embedding immunoelectron microscopy method, using protein A-gold, to detect calcitonin and chromogranin A immunoreactivity in three cases of human medullary thyroid carcinoma. Because the epoxy-embedded tissue had been fixed (glutaraldehyde or formaldehyde) and osmicated before embedment, the proteins were identified in optimally preserved tissue. Uranyl and lead staining was used after immunolabeling, so that the tissue was also optimally contrasted. The morphological advantage provided by osmication was tested by labeling rat thyroid gland C-cells for calcitonin. The protein A-gold technique allowed localization of both antigens to the contents of membrane-bound secretory granules in the tumor cells. In one case, labeling density for each antigen was measured over several intercellular compartments and the interstitium. Calcitonin, but not chromogranin A, reactivity was also identified in intracellular amyloid fibrils in two cases, showing that the constant region of calcitonin is preserved in amyloid deposits related to the tumor cells.     

Applications of immunocolloids in light microscopy. III. Demonstration of antigenic and lectin-binding sites in semithin resin sections

Previous studies have demonstrated that antigens or lectin-binding sites can be localized in sections from paraffin-embedded tissues with protein A or lectins bound to colloidal gold or colloidal silver (Roth J: J Histochem Cytochem 30:691, 1982 and 31:547, 1983). In the present study the protein A-gold technique and lectin-gold complexes have been applied to semithin sections (0.5-1.5 micron) of Epon- or low temperature Lowicryl K4M-embedded rat pancreas, kidney and submandibular gland. The results show that an increase in resolution and, therefore, in amount of information can be obtained. The optimal mode of imaging was determined on sections without counterstaining. Bright-field illumination gives the maximum information about the staining signal, while phase-contrast and Nomarski differential interference contrast give predominantly structural and, to a lesser extent, staining information. Polarization epi- and transillumination microscopy is inferior in all aspects. The application of a battery of lectin-gold complexes to rat submandibular gland revealed a specific staining pattern for each lectin in acinar and excretory duct cells.     

A double protein A-gold-silver staining method for tissue antigens in light microscopy

Summary A double staining method has been developed for light microscopic immunohistochemistry. The technique consists of a sequence of protein A-gold-silver procedures, in which the reaction products are visualized in black and brown colours. The results obtained in the rat pancreatic islets and adenohyophysis, in combination with a variety of histochemical controls, substantiate both the specificity and reliability of this method. The double staining method is simple and economical, since the two differently coloured reaction products are obtained by a common mechanism of colouration (physical development) using a single probe, protein A-gold.     

Applications of immunocolloids in light microscopy. IV. Use of photochemical silver staining in a simple and efficient double-staining technique

We report the development of a new light-microscopic double-staining technique using colloidal gold as sole marker. The contrasting color to the red of colloidal gold is achieved by the application of photochemical silver reaction. The silver reaction, which is principally performed at the end of the first staining sequence, converts the red color of a gold-labeled reagent into black. This contrasts clearly with the red coloration that results from the second incubation sequence without silver reaction. For antigen double staining, the same protein A-gold complex can be used to provide the black and the red color, thus rendering the technique very economical. Alternatively, combination of protein A-gold immunolocalization and lectin-gold staining is possible, as is combined lectin-gold staining.     

卵泡刺激素和表皮生长因子对小鼠精原细胞增殖的影响

利用生殖细胞-体细胞体外无血清共培养模型研究了卵泡刺激素(FSH)和表皮生长因子(EGF)对小鼠A型精原细胞增殖的影响。精原细胞在ITS培养液(添加胰岛素、转铁蛋白和亚硒酸钠的DMEM)中培养24h后进行c-kit免疫细胞化学鉴定和EGF及其受体(EGFR)免疫细胞化学检测,72h后测定其形成集落数的情况。结果表明:ITS培养液能维持生殖细胞的活性,增殖细胞核抗原(PCNA)的表达增高。A型精原细胞呈c-kit阳性,EGF和EGFR主要表达于精原细胞。单独的FSH(1～100ng/ml)或EGF(1～10ng/ml)显著促进精原细胞集落数的增加。此外,EGF(0.1ng/ml)联合FSH(10ng/ml)具有加性效应,但更高剂量的EGF(1～10ng/ml)则降低了FSH的刺激作用。结果说明FSH可联合适量的EGF促进精原细胞的增殖。     

Morphological and immunological evidence of a unique selective production and endoplasmic reticular accumulation of interleukin-1alpha in rat peritoneal macrophages induced by Pseudomonas aeruginosa exotoxin A

The immunotoxicity of Pseudomonas aeruginosa exotoxin A (ETA) on macrophages was evaluated by incubating rat peritoneal macrophages (RPM) with 1-100 ng/ml ETA for 3-60 h. Although the overall changes in cell viability and DNA, RNA, and protein synthesis of the ETA-treated RPM (E-RPM) were reduced in a dose- and time-dependent manner, there was a transient but evident rebound in RNA and/or protein synthesis at 24-36 h post-incubation (HPI) at 1-50 ng/ml ETA. However, a more apparent enhancement appeared in RNA and protein synthesis at 36-48 HPI in 10 and 50 ng/ml E-RPM after normalized on the basis of viable cell. Most 50-100 ng/ml E-RPM underwent necrosis/apoptosis before 24 HPI. By 36 HPI, 41% of 10 ng/ml E-RPM remained viable but were full of cytoplasmic granules due to the accumulation of glycoprotein in segmentally dilated endoplasmic reticulum. Immunological staining of the granules revealed strong IL-1alpha but weak or no signals for IL-1beta, IL-1 receptor antagonist, IL-6, and TNF-alpha. A time-dependent increase in IL-1alpha but no IL-1beta was detected in cell lysate of 10 ng/ml E-RPM; however, neither IL-1alpha nor IL-1beta was detected in culture supernatant. Thus, besides cytopathic and functional effects, ETA could induce a unique selective production and endoplasmic reticular accumulation of IL-1alpha in RPM.     

Ultrastructural localization of immunoreactive neurophysins using monoclonal antibodies and protein A-gold

Using three different monoclonal antibodies against rat neurophysins (5), with protein A-gold as immunocytochemical marker (27), the murid hypothalamoneurohy-pophysial system was studied at the ultrastructural level. Postembedding staining was done on epoxy-embedded sections of supraoptic nuclei and posterior pituitaries. Specific immunolabeling of vasopressinergic and oxytocinergic neurosecretory granules was observed in tissues fixed with glutaraldehyde or glutaraldehyde mixtures (containing paraformaldehyde and picric acid), with or without osmium tetroxide postfixation and with or without sodium metaperiodate oxidation. Some autophagic vacuoles containing lysed neurosecretory granules were also neurophysin immunoreactive. Nonspecific background staining was extremely low. An attempt was made to appraise labeling intensities semiquantitatively by counting gold particles in relation to number of secretory granules per axonal varicosity. Immunoreactivity was measurably influenced by the mode of fixation, sodium metaperiodate oxidation, and titer and affinity of the antibody. The protein A-gold technique using monoclonal antibodies against neurophysins provides a superior means of ultrastructural analysis of the hypothalamoneurohypophysial system, both visually and morphometrically.     

"Brilliant Blue G" and "Membrane Blue Dual" assisted vitrectomy for macular hole

The aim of this study is to evaluate vital dyes "Brilliant Blue G" (BBG) and "Membrane Blue Dual" (MBD) for intraoperative staining of the inner limiting membrane (ILM) during vitrectomy for macular hole (MH). Retrospective, comparative case series on 18 eyes with macular holes who underwent "23 and 25 gauge" pars plana vitrectomy. Main outcome measurements were staining intensity and characteristics, visual acuity, visual field, OCT measurements and complications over a period of 6 months. With the help of BBG and MBD successfully was removed complete ILM in 14 eyes. Postoperative visual acuity was improved in 12 patients, unchanged in 2 patients and worse in 4 patients. Central retinal thickness showed significant postoperative reduction with closure of macular hole. OCT values range were from -10 to -250 microm. No visual field defects and no adverse effects were found. BBG and MBD successfully identificate internal limiting membrane during vitrectomy for MH. Good anatomical and functional results are achieved with the use of both vital dyes.     

Advantages and disadvantages of silver staining of proteins in polyacrylamide gel

Sensitivity of protein staining with Serva blue G-250 (Coomassie brilliant blue G-250 analogue) in polyacrylamide gel was determined. It has been shown that protein staining with 0.1% Serva blue G-250 results in the recovery of 80 to 35 ng of single protein, that is almost 10 times higher than reported previously for Coomassie brill. blue G-250 (or R-250) staining. The comparison of the sensitivity of Serva blue G-250 protein staining in PAAG and AgNO3 has shown that AgNO3 staining was approximately 18-30 (but not 100 times, as it had been thought before) times more effective for the majority of proteins under study. Silver staining of some proteins, for instance ribonuclease and a number of retrovirus-specific structural proteins, was of lower efficacy. Thus, to obtain reliable results protein electrophoresis in PAAG should be followed by both staining procedures.     

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.     

Protein G-gold complex: comparative evaluation with protein A-gold for high-resolution immunocytochemistry

We combined the protein G-gold complex with several polyclonal and monoclonal antibodies for localization of various antigenic sites. The labelings were compared with those obtained using the protein A-gold complex. The results from either the immunodot experiment or immunoelectron microscopy have demonstrated that, for rabbit and guinea pig antibodies, both protein G-gold and protein A-gold complexes label several different specific antibodies with similar efficiency. However, with antibodies raised in goats or in mice, and particularly with mouse monoclonal antibodies, protein G-gold yielded intense and specific labeling, whereas protein A-gold yielded intense and specific labeling, whereas protein A-gold was very variable; it either gave weaker signals or failed to reveal any specific site or, as with one monoclonal, both protein G and protein A gave similar results. The higher affinity and versatility of protein G over protein A, established by the immunochemical approach, was confirmed by immunocytochemistry. Because of its enhanced reactivity with monoclonal antibodies and its broader affinity for polyclonal antibodies, protein G-gold complex appears to be a better and more versatile probe for high-resolution immunocytochemistry.     

Subcellular distribution of cardiac fatty acid-binding protein in bovine heart muscle and quantitation with an enzyme-linked immunosorbent assay

Several types of the 14-15 kDa fatty acid-binding proteins (FABPs) are known to occur in the cytosol of mammalian cells. With antibodies raised against the cardiac-type protein from bovine heart, immunoblots indicated a more widespread distribution of the cardiac FABP in subcellular fractions, such as mitochondria and nuclei. A detailed view was obtained when the post-embedding protein A-gold labeling method was applied to cross-sections of heart cells and isolated subcellular fractions. Cardiac FABP in myocytes was associated with myofibrils and localized within mitochondria and nuclei. After subfractionation of mitochondria, the binding protein was recovered with matrix proteins only. A non-competitive enzyme-linked immunosorbent assay (ELISA) of the direct type was developed specifically for bovine cardiac FABP. This assay was sensitive in the range of 0.05 to 1 ng, and concentrations of cardiac FABP per mg protein were found for cytosol, matrix and nuclei to be around 3.18, 0.18 and 0.03 micrograms, respectively. The newly found compartmentation of cardiac FABP in the heart cell must be considered when the true functions of the protein, yet to be defined, are studied.     

The importance of tissue fixation for light microscopic immunohistochemical localization of peroxisomal proteins: the superiority of Carnoy's fixative over Baker's formalin and Bouin's solution

We have compared the effects of fixation with three commonly used fixatives upon preservation of the antigenicity of six peroxisomal proteins in rat liver using both immunohistochemical staining and Western blotting of fixed tissue extracts. The immunoreactivity of all six peroxisomal proteins was well preserved and peroxisomes were clearly identified in material fixed in Carnoy's fixative. Moreover, the corresponding proteins stained well in Western blots prepared from extracts of Carnoyfixed material. The intensity of the immunohistochemical staining was reduced at different rates for individual peroxisomal proteins after fixation in Baker's formalin, but peroxisomes were still well visualized with antibodies to catalase and some -oxidation enzymes. No evidence of immunohistochemical staining for any peroxisomal antigens was obtained after fixation in Bouin's fluid. For detection of the antibody binding sites in Carnoy's fixed material, the avidin-biotin-peroxidase complex (ABC) with aminoethyl carbazole as chromogen was found to be superior to the methods of peroxidase-antiperoxidase/diaminobenzidine and protein A-gold with silver intensification. Using Carnoy-fixative and the ABC-method, we demonstrate light microscopic immunohistochemical localization of peroxisomal antigens in several rat tissues as well as in human post-mortem liver.