One-step double immunolabeling of mouse interdigitating reticular cells: simultaneous application of pre-formed complexes of monoclonal rat antibody M1-8 with horseradish peroxidase-linked anti-rat immunoglobulins and of monoclonal mouse anti-Ia antibody with alkaline phosphatase-coupled anti-mouse immunoglobulins

A novel one-step double immunolabeling method was elaborated on the basis of the simultaneous application of preformed molecular complexes of two primary antibodies with their specific secondary antibodies labeled with different enzymes. Treatment with a rat monoclonal antibody (MAb), M1-8, pre-coupled with horseradish peroxidase-linked sheep anti-rat immunoglobulins, and enzyme reaction revealed by the 3-amino-9-ethylcarbazole/hydrogen peroxide reaction, resulted in red-brown intracytoplasmic staining of interdigitating reticular cells in the lymph nodes of Balb/c mice. Another molecular complex, made of mouse anti-Ia MAb with alkaline phosphatase-linked rabbit anti-mouse immunoglobulins, applied at the same time and then developed with naphthol AS-BI-phosphate/fast blue BB as substrate, yielded blue surface staining of this cell type in addition to labeling of B-lymphocytes. The method described provides the possibility of relatively rapid double antigen detection where the binding sites of the secondary antibodies are saturated by the specific primary immunoglobulins. This approach seems to avoid nonspecific binding of primary antibodies to Fc receptors, and the unwanted binding of secondary antibodies with cell surface immunoglobulins on B-lymphocytes or with crossreactive primary antibodies used in the other sequence, if the primary antibodies and the tissue are the same or crossreactive animal species.     

Simultaneous detection of B-cells and T-cells by a double immunohistochemical technique using immunogold-silver staining and the avidin-biotin-peroxidase complex method

A new double immunohistochemical technique for the simultaneous detection of B-cells and T-cells was investigated, using tissue preparations obtained from human axillary lymph nodes and rejected renal allografts. The specimens were immunostained first for the demonstration of B-cells, by the immunogold-silver staining (IGSS) method using Leu-12 monoclonal antibody, and then for T-cells by the avidin-biotin-peroxidase complex (ABC) method using Leu-1 monoclonal antibody. With the present methods, both B-cells and T-cells were clearly detected and distinctively identified without cross-linking of antibodies or double reaction of enzymes.     

Direct immunoenzyme double staining applicable for monoclonal antibodies

Summary A novel method for immunoenzymatic double staining was developed, using primary antibodies directly labeled with either horseradish peroxidase or alkaline phosphatase. The enzyme-antibody conjugates were applied simultaneously on sections of human tonsil. Intracytoplasmic antigens like immunoglobulins and light chains could easily be detected simultaneously in the same tissue section. With antibodies against cell surface antigens like IgM and T cell antigens areas containing B and T cells could be clearly distinghuished. This method opens the possibility to perform double staining with two monoclonal antibodies.     

Sensitive detection of immunogold-silver staining with darkfield and epi-polarization microscopy

We evaluated the contribution of darkfield and epi-polarization microscopy to the detection of leukocyte cell surface antigens with immunogold-silver staining (IGSS). Lymphocyte cell surface differentiation antigens were labeled with monoclonal antibodies and IGSS as described for brightfield microscopy. In darkfield and epi-polarization microscopy the labeling appeared as bright spots on a dark background. The sensitivity of detection was much higher than that of brightfield microscopy. Sixteenfold higher dilutions of the monoclonal antibody could be used to detect all cells expressing the antigen in the cell suspension. However, non-specific staining was also better visualized. The latter could be reduced to a level comparable to that of brightfield microscopy only by use of weaker labeling conditions. A 25% reduction of the silver enhancement time was necessary for this purpose. However, these weaker labeling conditions also reduced the intensity of the specific staining. Therefore, the efficiency of IGSS, as detected with darkfield and epi-polarization microscopy, was only fourfold greater than that found with brightfield microscopy or that of an immunofluorescence procedure. Especially in combination with transmitted light, to improve cell identification, epi-polarization microscopy is a reliable and sensitive method for detection of immunogold-silver-labeled cell surface antigens for diagnostic and research purposes.     

An alkaline-phosphatase staining method in avidin-biotin immunohistochemistry

An avidin-biotin alkaline-phosphatase (ABAP) staining method has been developed for the labeling of tissue sections and cell smears. The introduction of alkaline phosphatase as a marker enzyme through an avidin bridge results in excellent immunocytochemical labeling of different antigens using poly- and monoclonal antibodies. This technique avoids problems with endogenous peroxidase activity that sometimes occur using peroxidase staining procedures. The introduction of a preformed avidin-biotin alkaline-phosphatase complex (ABAPC) makes the presented technique as simple to handle as the widely used avidin biotin-peroxidase complex method (ABC). The ABAPC technique could be combined with other enzymatic labelings for double immunoenzymatic staining.     

Double and triple immunocytochemical labelling at the light microscope level in histopathology

Summary Double and triple immunocytochemical detection methods for routine use in histopathology were investigated. For double immunostaining, the combinations of immunogold-silver staining (IGSS, black) with an immunoperoxidase method (3-amino-9-ethylcarbazole, red-brown) or with an immunoalkaline phosphatase method (Fast Red TR, red) proved very useful. These were followed by a Haematoxylin counterstain. An alternative approach using immunoperoxidase (red-brown) and immunoalkaline phosphatase (Fast Blue, BB, blue) methods was also successful, particularly for frozen sections of unfixed tissue and for the establishment of intermediate filament coexpression in tumours. The coexistence of desmin with vimentin in rhabdomyosarcoma, and of glial fibrillary acidic protein with vimentin in ependymoma, could be demonstrated directly by means of non-crossreacting murine and rabbit antibodies in the above combinations. The black (IGSS), red-brown (immunoperoxidase) and blue )immunoalkaline phosphatase) colours gave excellent contrast in triple immunostaining. The side-by-side demonstration of helper and suppressor T lymphocytes during renal allograft rejection, of kappa and lambda light chains in B-immunoblastic lymphoma, and of T and B lymphocyte populations in non-Hodgkin's lymphomas provided immediate information on the topography and cellular organization of the tissues.     

Antibodies against neuroactive amino acids and neuropeptides. II. Simultaneous immunoenzymatic double staining with labeled primary antibodies of the same species and a combination of the ABC method and the hapten-anti-hapten bridge (HAB) technique.

In the present study we developed an immunoenzymatic double staining technique allowing the simultaneous detection of two neuroactive substances with primary antibodies of the same species and their simultaneous visualization in semithin sections of epoxy-embedded material. For this purpose, primary antibodies against glutamate, GABA, and serotonin were either biotinylated or labeled with the trinitrophenyl (TNP) group. The latter was visualized by a detection system here referred to as the hapten-anti-hapten bridge (HAB) technique. The HAB technique consists of anti-TNP antibodies, serving as bridges between the TNP-ylated primary antibody, and a TNP-ylated marker enzyme, such as alkaline phosphatase. The single components of the HAB technique were optimized by use of a dot-blot assay and an "artificial tissue" system. The optimal staining sequence consisted of TNP-ylated primary antibody with a molar TNP:antibody ratio of 12:1, followed by anti-TNP antibody and TNP-ylated alkaline phosphatase (molar TNP:enzyme ratio of 20:1). No further improvement of detection sensitivity could be obtained when soluble immunocomplexes between anti-TNP antibody and TNP-ylated alkaline phosphatase on the side of phosphatase excess were prepared and used instead of simple TNP-ylated alkaline phosphatase. When compared with other established procedures, such as avidin-conjugated alkaline phosphatase or the ABC method, the HAB technique revealed a similar detection sensitivity. The TNP-ylated primary antibody, however, had to be used at higher concentration than the corresponding unlabeled primary antibody. The suitability of the HAB technique in combination with a modified three-step ABC technique for the simultaneous demonstration of glutamate-like and GABA-like immunoreactivity in the rat brain was demonstrated. The advantages of the new technique in comparison with existing double staining methods are discussed.     

Enhancement of Antigenic Site Detection with Gold Labeled Secondary and Tertiary Antibodies Using the Immunogold-Silver Staining Method

We report a modification of the immunogold-silver staining method (IGSS) for localizing hepatic phosphoenolpyruvate carboxykinase (PEPCK) in tissue sections, and we compare the efficacy of localizing the primary antibody with either a 5 nm gold labeled secondary antibody or 5 nm gold labeled secondary and tertiary antibodies. Light microscope examination of 10 μm frozen sections demonstrated that the use of combined secondary and tertiary gold labeled antibodies was superior to using a secondary gold labeled antibody alone. The increased labeling density (number of colloidal gold particles/antigenic site/cell) achieved by combined gold labeled antibodies was confirmed by electron microscopy. The increased labeling density resulted in a two-thirds reduction in the time needed for the IGSS physical development of the silver shells and less background. We achieved intense specific staining of hepatocytes expressing PEPCK while minimizing background staining. The use of combined secondary and tertiary gold labeled antibodies enhances the signal-to-noise ratio, achieves high resolution and is a suitable method for use in both light and electron microscopy.     

Multiple epitope labeling by the exclusive use of alkaline phosphatase conjugates in immunohistochemistry

 Here we demonstrate a simple and reliable multiple epitope labeling technique based exclusively on the alkaline phosphatase (AP) enzyme-linked visualization method. AP is functionally blocked by ethylenediaminetetraacetic acid (EDTA), which allows the repeated use of AP conjugates in immunohistochemistry with different substrates. We found that reactivation of AP function following EDTA incubation is dependent on EDTA concentration and incubation time. While incubation times of up to 2 h in 0.25 M EDTA, pH 6, exhibit a resumption of AP enzyme function, more than 2 h of incubation irreversibly blocks AP enzyme activity. Surprisingly, EDTA incubation also results in considerable but not complete inhibition of antibody crossreactivity during immunohistochemistry. Thus, this technique is suitable for single-layer, multiple-staining experiments with AP-linked primary antibodies or multilayer labeling with antibodies of various species for sequential staining rounds. We demonstrate the applicability of this technique in immunohistochemistry by double-labeling experiments using the monoclonal antibodies anti-glial fibrillary acidic protein, anti-leucocyte common antigen, anti-CD43/CD45RA (pan-human leucocyte), and anti-migration inhibitory factor-related protein-8 in combination with an in situ nick translation assay to characterize differentiating antigens of apoptotic cells in human glioblastoma paraffin sections. Accepted: 2 April 1998     

Evaluation of histochemical observations of activity of acid hydrolases obtained with semipermeable membrane techniques. 3. The substrate specificity of isoenzymes of acid phosphatase in m.gastrocnemius of rabbits.

Three distinct isoenzymes of acid phosphatase have been separated from extracts of m.gastrocnemius of normal and of vitamin E deficient rabbits by gel filtration and polyacrylamide gel electrophoresis. These isoenzymes, termed I, II and III, have molecular weights of: 110,000--130,000, 60,000--78,000 and 12,500--14,500. Isoenzymes I and II split the substrates 4-methylumbelliferyl phosphate and naphthol AS-BI phosphate and the activity is strongly increased in the muscles of vitamin E deficient rabbits. Isoenzyme III splits only 4-methylumbelliferyl phosphate and the activity is not increased in the muscles of vitamin E deficient rabbits. The pH-optimum for isoenzymes I and II is 4.8 and for isoenzyme III 5.5. It has been shown that the histochemical semipermeable membrane technique, using substrate naphthol AS-BI phosphate, is a very reliable technique for demonstrating activity of the isoenzymes I and II in tissue sections. On the other hand, activity of isoenzyme III cannot be demonstrated with this histochemical technique. In pathologically altered muscles, the activity of the isoenzymes I and II is greatly increased whilst the activity of isoenzyme III is not significantly altered.     

The presence of a low molecular weight acid phosphatase in liver tissue that cannot be demonstrated with the histochemical substrate naphthol AS-BI phosphate

Summary Three distinct isoenzymes of acid phosphatase have been separated from extracts of liver tissue of rats by gel filtration. These isoenzymes have molecular weights of 180,000±35,000; 74,000±11,000 and 13,000±2,500. High molecular weight isoenzymes and a low molecular weight isoenzyme of acid phosphatase (molecular weight 13,000±2,100) were also present in extracts of normal human and mouse liver tissue, and of pathologically altered liver tissue of mice in which the activity of acid phosphatase was strongly increased as a result of intraperitoneal injections of dextran solutions. Activity of acid phosphatase was determined with three substrates. The isoenzymes showed different conversion rates for the three substrates. The high molecular weight isoenzymes split the substrates 4-methylumbelliferyl phosphate, p-nitrophenyl phosphate and naphthol AS-BI phosphate. The activity was sensitive to the inhibitors fluoride and L(+)tartrate. In the pathologically altered liver tissue, which had stored dextran, the activity of these isoenzymes was strongly increased. The low molecular weight isoenzyme split 4-methylumbelliferyl phosphate and p-nitrophenyl phosphate but not naphthol AS-BI phosphate. Therefore this isoenzyme cannot be demonstrated with histochemical techniques using the substrate naphthol AS-BI phosphate. In contrast to the activity of the high molecular isoenzymes the activity of the low molecular isoenzyme was not changed in the pathologically altered liver tissue of mice and was not sensitive to the inhibitors fluoride and L(+)tartrate.This study was supported by a grant from the Prinses Beatrix Fonds, s'Gravenhage     

Double immunoenzymatic staining for the simultaneous detection of Epstein-Barr virus induced antigens

Summary A double indirect immunoenzymatic staining was developed for the simultaneous visualization of Epstein-Barr virus-induced early antigens and virus capsid antigens in P3HR1 lymphoblastoid cell line.The double immunocytochemical staining was performed with a four-stage and a two-stage procedure employing human sera and monoclonal antibodies against Epstein-Barr virus-induced antigens, followed by the addition of specific alkaline phosphatase and peroxidase labeled antisera.The selection of substrates yielding reaction products of contrasting colours enabled the observer to distinguish cells expressing Epstein-Barr virus capsid antigens (blue) from cells expressing Epstein-Barr virus early antigens (brown).     

Double immunoenzymatic staining for the simultaneous detection of Epstein-Barr virus induced antigens

A double indirect immunoenzymatic staining was developed for the simultaneous visualization of Epstein-Barr virus-induced early antigens and virus capsid antigens in P3HR1 lymphoblastoid cell line. The double immunocytochemical staining was performed with a four-stage and a two-stage procedure employing human sera and monoclonal antibodies against Epstein-Barr virus-induced antigens, followed by the addition of specific alkaline phosphatase and peroxidase labeled antisera. The selection of substrates yielding reaction products of contrasting colours enabled the observer to distinguish cells expressing Epstein-Barr virus capsid antigens (blue) from cells expressing Epstein-Barr virus early antigens (brown).     

An investigation of optimal gold particle size for immunohistological immunogold and immunogold-silver staining to be viewed by polarized incident light (EPI polarization) microscopy

We investigated the optimal gold particle size for use with polarized incident light (epi polarization) microscopy with immunogold immunohistological preparation in both immunogold indirect (IGS) and silver-enhanced immunogold-silver staining (IGSS) techniques. A range of gold particle sizes from 5 nm-40 nm was used along with tissue of known immunoreactivity with a well-characterized primary monoclonal antibody. Checkerboard titrations were carried out for each technique and for each particle size. The preparations were viewed using a standard polarized incident light microscope and assessed in a semi-quantitative manner. Adequate visualization of gold particles was achieved using the indirect staining method only with a particle size of 40 nm. With silver enhancement (IGSS), particles of all sizes were clearly seen. However, 5-nm particles were considered optimal for this method because of reduced background staining, high titration of antisera possible, and crisp localization of the visual signal.     

Immunological Determination of Labeling Index on Human Tumor Tissue Sections Using Monoclonal Anti-Brdurd Antibody

The use of a monoclonal antibody against the thymidine analogue bromodeoxyuridine together with an in vitro labeling technique allowed rapid determination of the labeling index in human tumors. The labeling index estimated by these relatively simple immunofluorexence or immunoenzymatic staining methods was equivalent to that obtained by autoradiography. The interpretation of the preparations is easy since there is a minimum of background staining. This immunohistochemical technique combined with in vitro labeling provides a suitable alternative for determining the labeling index of human tumors.     

Acid hydrolases in HeLa cells: comparison of methods for light microscopy

To distinguish lysosome populations of HeLa cells, acid phosphatase, beta-glucuronidase, arylsulfatase and esterase were demonstrated using various substrates and couplers with different fixations, pHs and inhibitors. The substrates chosen were for acid phosphatase, naphthol AS-BI phosphate with fast red violet LB at pH 4.6; for beta-glucuronidase, naphthol AS-BI beta-D-glucuronide with fast red violet LB at pH 4.4; for arylsulfatase, p-nitrocatechol sulfate, with lead as the capturing ion, at pH 4.8 and 5.6; and for esterase, naphthol AS-D acetate with fast blue BB at pH 6.5. In the azo-dye methods, the coupling was always simultaneous and results were satisfactory with unfixed cells. For optimal demonstration of arylsulfatase, cells were fixed in glutaraldehyde in 0.1 M cacodylate buffer pH 7.2, 2% for 24 hr or 6.25% for 2 hr, and washed for 1-9 days in 0.1 M veronal acetate buffer pH 7.2, 7.5% with respect to sucrose. Two groups of lysosomes were distinguished. One comprised small bodies, probably primary lysosomes, which lay in a cluster near the nucleus. They had quite stable membranes and were mostly acid phosphatase-positive. They sometimes contained beta-glucuronidase or esterase, but rarely arylsulfatase. The other group included all the acid hydrolase-positive bodies scattered throughout the rest of the cytoplasm. They were mostly larger, with more labile membranes, and contained beta-glucuronidase, esterase or arylsulfatase, but rarely acid phosphatase.     

Immunological determination of labeling index on human tumor tissue sections using monoclonal anti-BrdUrd antibody

The use of a monoclonal antibody against the thymidine analogue bromodeoxyuridine together with an in vitro labeling technique allowed rapid determination of the labeling index in human tumors. The labeling index estimated by these relatively simple immunofluorescence or immunoenzymatic staining methods was equivalent to that obtained by autoradiography. The interpretation of the preparations is easy since there is a minimum of background staining. This immunohistochemical technique combined with in vitro labeling provides a suitable alternative for determining the labeling index of human tumors.     

A trinitrophenyl(TNP)-poly-L-lysine-horseradish peroxidase conjugate for the detection of anti-TNP antibodies in vivo

A new conjugate for the detection of anti-trinitrophenyl(TNP) antibodies was developed to study the localization pattern of specific antibody containing cells and extracellular antibody in vivo. By means of a bridging molecule, poly-L-lysine, nine TNP groups and six horseradish peroxidase (HRP) groups were joined in one conjugate. Thus a higher specificity (more hapten) was united with a higher staining intensity (more enzyme) in the same conjugate. This conjugate made possible the simultaneous detection of anti-TNP antibody containing cells and establishment of their class (immunoglobulin M (IgM) and IgG). It was also used for the demonstration of anti-TNP antibodies in tissues where a TNP-alkaline phosphate (AP) conjugate could not be used due to high AP (endogenous) background staining. Thus we demonstrated anti-TNP antibody containing cells in gut associated lymphoid tissue and anti-TNP-(TNP-ovalbumin) immune complexes in the glomeruli of the kidney. We suggest that poly-L-lysine is a suitable bridging molecule for the preparation of hapten-HRP conjugates.     

Immunogold-silver staining method for light and electron microscopic detection of lymphocyte cell surface antigens with monoclonal antibodies

We used the immunogold-silver staining method (IGSS) for detection of lymphocyte cell surface antigens with monoclonal antibodies in light and electron microscopy and compared this procedure with the immunogold staining method. Two different sizes of colloidal gold particles (5 nm and 15 nm) were used in this study. Immunolabeling on cell surfaces was visualized as fine granules only by IGSS in light microscopy. The labeling density (silver-gold complexes/cell) and diameters of silver-enhanced gold particles on cell surfaces were examined by electron microscopy. Labeling density was influenced not by the enhancement time of the physical developer but by the size of the gold particles. However, the development of shells of silver-enhanced gold particles correlated with the enhancement time of the physical developer rather than the size of the colloidal gold particles. Five-nm gold particles enhanced with the physical developer for 3 min were considered optimal for this IGSS method because of reduced background staining and high specific staining in the cell suspensions in sheep lymph. Moreover, this method may make it possible to show the ultrastructure of identical positive cells detected in 1-micron sections counterstained with toluidine blue by electron microscopy, in addition to the percentage of positive cells by light microscopy.     

Ultrastructural localization of intracellular immunoglobulins in Epon-embedded human lymph nodes. An immunoelectron microscopic investigation using the immunogold staining (IGS) and the avidin-biotin-peroxidase complex (ABC) methods

The ultrastructural localization of intracellular immunoglobulins on ultrathin sections of glutaraldehyde-fixed, postosmicated, and Epon-embedded human lymph nodes has been achieved using such highly sensitive immunocytochemical techniques as immunogold staining and avidin-biotin-peroxidase complex. These immunoelectron microscopic techniques allow the identification of intracellular immunoglobulins without affecting the ultrastructural morphology of the tissue, since they do not require any pretreatment of the sections with proteolytic enzymes or deresinating agents. Therefore, immunoglobulins can be precisely localized in the cell organelles; structures whose morphology is well preserved. The availability of a reliable postembedding staining procedure for the ultrastructural localization of immunoglobulins is of definite value for investigations on human lymphoid tissue, both normal and pathological.