Electrochemical antigen-retrieval of formaldehyde fixed and paraffin-embeddedarchived leprosy skin biopsies

Summary While formaldehyde fixation preserves tissue morphology, it often hinders immunodetection of antigens in paraffin-embedded tissue because the antigens are masked. Antigen unmasking can be achieved with treatments such as microwave irradiation but they often lead to excessive tissue damage. Therefore, an electrochemical antigen-retrieval method (EAR) was devised in which an alternating electric current is passed through the tissue in a chamber containing an electrolyte buffer. The results obtained with this method were compared to those after microwave irradiation using archived samples of formaldehyde-fixed and paraffin-embedded lepromatous leprosy skin. The efficacy of the two unmasking procedures was assessed by the immunodetectability of several marker antigens using 24 antibodies. Fifteen antibodies that were directed against transmembrane proteins (CD), and the remaining 9 against cytokeratins 18.6 and 19, laminin, vimentin, S100a, BCG,Ulex europaeus lectin, PCNA, and P21^ras. Simple and double immunohistochemistry was performed using the universal ENVISION and LSAB + AP detection systems. After unmasking with the EAR method, immunoreactivity was clearly detected with 22 of the 24 antibodies in single labeling reactions. They include the critical antigens CD3 and CD4 for identifying the T lymphocyte lineages. In contrast, only 20 of the antibodies reacted after microwave irradiation. After double immunolabeling, immunoreactivity was quantitatively similar with both methods. However, the EAR unmasking produced a stronger labeling reaction. Thus, with double labeling immunohistochemistry, EAR made it possible to use higher antibody dilutions and shorter incubation times. Heat damage was also prevented. In conclusion, EAR treatment produces better staining results than microwave irradiation treatment.     

The use of avidin-biotin interaction in immunoenzymatic techniques.

Biotin was covalently attached to antibodies, antigens and enzymes, and the effects of this labeling on the antigen and antibody binding capacity and on enzymatic activity were tested. Based on avidin-biotin interaction, the labeled proteins were used in quantitative enzyme-immunoassay and enzyme-immunohistochemical staining procedures. Two procedures were developed. In the first procedure, named the Bridged Avidin-Biotin (BRAB) technique four steps were used sequentially in order to quantify or detect an immobilized antigen: 1) incubation with biotin-labeled antibody; 2) incubation with avidin; 3) incubation with biotin-labeled enzyme; 4) measurement or histochemical staining of the enzyme. The technique is based on the observation that avidin possesses four active sites. In the second procedure, named the Labeled Avidin-Biotin (LAB) technique, biotin-labeled antibody and enzyme-labeled avidin are used sequentially. Enzyme-associated antigen is then quantified or revealed immunohistochemically. The optimal conditions for enzyme-immunoassay and enzyme-immunohistochemical staining using BRAB and LAB procedures were established.     

Site-specific labeling of cell surface proteins with biophysical probes using biotin ligase

We report a highly specific, robust and rapid new method for labeling cell surface proteins with biophysical probes. The method uses the Escherichia coli enzyme biotin ligase (BirA), which sequence-specifically ligates biotin to a 15-amino-acid acceptor peptide (AP). We report that BirA also accepts a ketone isostere of biotin as a cofactor, ligating this probe to the AP with similar kinetics and retaining the high substrate specificity of the native reaction. Because ketones are absent from native cell surfaces, AP-fused recombinant cell surface proteins can be tagged with the ketone probe and then specifically conjugated to hydrazide- or hydroxylamine-functionalized molecules. We demonstrate this two-stage protein labeling methodology on purified protein, in the context of mammalian cell lysate, and on epidermal growth factor receptor (EGFR) expressed on the surface of live HeLa cells. Both fluorescein and a benzophenone photoaffinity probe are incorporated, with total labeling times as short as 20 min.     

A reliable method for simultaneous demonstration of two antigens using a novel combination of immunogold-silver staining and immunoenzymatic labeling.

We have developed a reliable and sensitive immunohistochemical staining technique which allows the simultaneous demonstration of two different antigens expressed in or on the same cell (referred to as mixed labeling), together with the evaluation of the general histopathological appearance of the tissue. The staining procedure combines a three-step (streptavidin-biotin) immunogold-silver staining (IGSS) with a three-step immunoenzymatic labeling. For this purpose, we investigated the compatibility of IGSS with various substrates of peroxidase or alkaline phosphatase (AP). Highly reliable and discernible mixed labeling was achieved only after initial labeling with IGSS followed by AP labeling using the substrates naphthol AS-MX phosphate/Fast Blue or naphthol AS-BI phosphate/New Fuchsin, respectively. To ensure utmost specificity, we applied FITC-conjugated mouse monoclonal antibodies and rabbit anti-FITC immunoglobulins visualized by AP-labeled immunoglobulins and the respective substrate in a final step. This novel approach provides an excellent means for demonstration of immunocompetent cells and unequivocal determination of the percentage of specific cell subsets in infiltrated tissue. The advantages of this method, as compared with double immunofluorescence or double immunoenzymatic labeling, were investigated and are discussed.     

Tyramide Signal Amplification Method in Multiple-Label Immunofluorescence Confocal Microscopy

The tyramide signal amplification (TSA) method has recently been introduced to improve the detection sensitivity of immunohistochemistry. We present three examples of applying this method to immunofluorescence confocal laser microscopy: (1) single labeling for CD54 in frozen mouse brain tissue; (2) double labeling with two unconjugated primary antibodies raised in the same host species (human immunodeficiency virus type 1 p24 and CD68) in paraffin-biopsied human lymphoid tissue; and (3) triple labeling for brain-derived neurotrophic factor, glial fibrillary acidic protein, and HLA-DR in paraffin-autopsied human brain tissue. The TSA method, when properly optimized to individual tissues and primary antibodies, is an important tool for immunofluorescence microscopy. Furthermore, the TSA method and enzyme pretreatment can be complementary to achieve a high detection sensitivity, particularly in formalin-fixed paraffin-embedded archival tissues. Using multiple-label immunofluorescence confocal microscopy to characterize the cellular localization of antigens, the TSA method can be critical for double labeling with unconjugated primary antibodies raised in the same host species.     

Conjugate formation in urea: coupling of insoluble peptides to alkaline phosphatase for ELISA and in situ detection of antibody-forming cells

We report here a new method to produce synthetic peptide/alkaline phosphatase (AP) conjugates in the presence of urea. The method allows the use of peptides that are not soluble to a sufficient degree in aqueous buffers. The presence of 8 M urea during the construction of the synthetic peptide/AP conjugates does not influence enzyme activity nor the affinity of the anti-peptide antibodies for the conjugated peptide. We demonstrate that these synthetic peptide/AP conjugates can be used for detection of specific antipeptide antibody-forming cells (AFC) in vivo. This method for constructing enzyme conjugates with insoluble proteins or peptides suggest not only new possibilities for detection of specific AFC in vivo but also for applications in receptor-ligand studies, ELISA (enzyme-linked immunosorbent assay), and spot ELISA for detection of antibody-secreting cells in vitro.     

A reliable method combining horseradish peroxidase histochemistry with immuno-beta-galactosidase staining

A sensitive combination of horseradish peroxidase (HRP) tracing and immunohistochemistry was used by Rye et al. [J Histochem Cytochem (1984) 32:1145] in a search for the origins of neurotransmitter- and neuromodulator-containing nerve fibers in brain. In this combination, peroxidase as a marker in immunohistochemistry was thought to yield a homogeneous brown immunoreaction product of diaminobenzidine, different from the black granular reaction product of retrogradely transported HRP, which is visualized by the tetramethylbenzidine (TMB) reaction and subsequent stabilization. A neuron that exhibits both kinds of reaction products in its cytoplasm in sections subjected to combination staining is referred to as a double-labeled cell. With a combined HRP and corticotropin-releasing factor (CRF) immunoperoxidase-antiperoxidase (PAP) method, the first set of experiments showed "false" double-labeled cells in the pyramidal cell layer of rat cerebral cortex, but only rarely in the subcortical areas, possibly because of the use of one enzyme system in two different histochemical procedures. This limitation of the double-staining technique prompted us to demonstrate an alternate combination of HRP tracing and immunohistochemistry in the second set of experiments by employing two previously described independent enzyme systems: HRP as a retrograde tracer and beta-galactosidase as a marker for immunohistochemical demonstration of CRF. A homogeneous blue reaction product indicated immuno-beta-galactosidase staining, and a granular black or brown reaction product labeled retrogradely transported HRP in double-labeled cells in subcortical regions. Neither double labeling nor "false" double labeling was seen in pyramidal cells of cerebral cortex. These findings suggest that application of two independent enzyme systems in a combined HRP and immunohistochemical method may be useful for investigating in origins of peptidergic fibers in brain when the combination of HRP histochemistry and the PAP method appears to be inappropriate.     

Activation of Pyrococcus furiosus alkaline phosphatase by divalent metal ions

Treatment of a hyperthermophilic enzyme, alkaline phosphatase from Pyrococcus furiosus (PfuAP), with EDTA completely deactivated PfuAP, indicating that the presence of one or more divalent metal ions is essential for its catalytic activity. Subsequent addition of various divalent metal ions to the apoprotein recovered the enzymatic activity and, in particular, the addition of Co(II) resulted in an over 50-fold increase in activity compared with PfuAP before EDTA treatment. Intriguingly, PfuAP with Co(II) exhibited weaker stability toward heat treatment, suggesting that Co²⁺ destabilizes the tertiary structure of PfuAP at high temperature.     

The known purified mammalian 2,4-dienoyl-CoA reductases are mitochondrial isoenzymes

The aim of this work was to determine the subcellular location of mammalian 2,4-dienoyl-CoA reductase, a key enzyme for degradation of polyunsaturated fatty acids by beta-oxidation. The enzyme was purified according to Kimura et al. (J Biochem 96:1463, 1984), and antibodies were raised in rabbits. Monospecific antibodies were obtained via purification on an affinity column. Immunoblotting of isolated rat liver mitochondria and peroxisomes with the monospecific reductase antibody showed that the antigen was located only in mitochondria. Immunocytochemical experiments with liver tissue, using the protein A-gold labeling technique, confirmed this result. The similarity of their characteristics suggests that the purified reductases described in the literature are the same isoenzyme. Consequently, since the rat enzyme was localized here to the mitochondria, purification and characterization of peroxisomal mammalian reductases remain to be achieved in the future. In addition, a significant induction also of mitochondrial reductase by clofibrate was observed in the immunoblotting experiments.     

Double-enzyme conjugates, producing an intermediate color, for simultaneous and direct detection of three different intracellular immunoglobulin determinants with only two enzymes

A new double-enzyme conjugate was synthesized by coupling alkaline phosphatase (AP) to horseradish peroxidase (HRP). After AP (blue) and subsequent HRP (red) cytochemistry, this new conjugate produced a stable intermediate-colored (violet) product. By coupling this double-enzyme conjugate to an antigen (trinitrophenyl, TNP) or an antibody (anti-mouse immunoglobulin G2a), anti-TNP or -IgG2a-producing cells could be demonstrated as violet cells in spleen sections. This led to the development of a rapid one-step incubation--two-step cytochemical procedure for simultaneous detection of three different determinants in a single tissue section. To demonstrate this novel triple staining method, we coupled three different antigens to, respectively, AP, HRP, and AP-HRP. When spleen sections of immunized animals were incubated with a mixture of these three antigen-enzyme conjugates, we could distinguish antibody-forming cells against each of these three antigens simultaneously as red (HRP), blue (AP), and violet (AP-HRP) cells. The simultaneous detection of three different classes of intracellular antibodies in a single section also proved to be possible with this method. With this study we provide a new direct method for detection of three different intracellular immunoglobulins after a one-step incubation and a two-step standard cytochemical procedure.     

Labeling and stability of radiolabeled antibody fragments by a direct 99mTc-labeling method

The in vitro labeling and stability of ^99mTc-labeled antibody Fab′ fragments prepared by a direct labeling technique were evaluated. Eight antibody fragments derived from murine IgG1 (N = 5), IgG2a (N = 2) and IgG3 (N = 1) isotypes were labeled with a preformed ^99mTc-d-glucarate complex. No loss of radioactivity incorporation was observed for all the ^99mTc-labeled antibody fragments after 24 h incubation at 37 °C. The ^99mTc-labeled antibody fragments (IgG1, N = 2; IgG2a, N = 2; IgG3, N = 1) were stable upon challenge with DTPA, EDTA or acidic pH. Furthermore, using the affinity chromatography technique, two of the ^99mTc-labeled antibody fragments displayed no loss of immunoreactivity after prolonged incubation in phosphate buffer up to 24 h at 37 °C. The bonding between ^99mTc and antibody fragments was elucidated by challenging with a diamide ditholate (N₂S₂) compound. The Fab′ with IgG2a isotype displayed tighter binding to ^99mTc in comparison to the Fab′ from IgG1 and IgG3 isotype in N₂S₂ challenge and incubation with human plasma. The in vivo biodistribution of five ^99mTc-labeled fragments were evaluated in normal mice. In conclusion, the direct labeling method allows stable ^99mTc labeling of antibody fragments from three of the major murine isotypes.     

Direct flow cytometric quantification of alkaline phosphatase activity in rat bone marrow stromal cells.

Cell preparations in cytochemistry are conventionally analyzed with transmitted light after fixation and reaction with agents such as azo-coupling dyes. With cell suspensions stained with fluorescent cytochemical dyes, cells can also be analyzed and sorted by flow cytometry. We have exploited the intense red fluorescence of Fast Red Violet LB generated in cytochemical reactions to perform flow cytometric analyses of alkaline phosphatase (AP) expression in rat bone marrow stromal cells. By modifying staining protocols of single-cell suspensions, we demonstrate that in comparison to staining with Fast Red TR, the method is specific, can distinguish among various levels of enzyme expression within the whole population, and permits enzyme kinetic studies of heterogeneous cell populations. The method was applied to study the effect of the glucocorticoid dexamethasone (Dx) on cell proliferation and AP expression. In low AP-expressing cells, Dx treatment at 10(-8) M increased the [3H]-thymidine labeling index from 3.85% to 5.24% (p less than 0.01). In contrast, high AP-expressing cells were unlabeled by [3H]-thymidine. The staining and analytical methods reported here facilitate the detection, isolation, and quantification of subpopulations of bone marrow stromal cells that express alkaline phosphatase activity. These experiments demonstrate the value of flow cytometry as an adjunct to conventional cytochemical methods.     

Control of alkaline phosphatase activity in C3H10T1/2 cells: role of retinoic acid and cell density.

The enzyme alkaline phosphatase (AP) has been shown to be lost or inappropriately expressed during carcinogenesis in some tissues. Because retinoic acid (RA) appears to play a role in the normal regulation of the enzyme (RA up-regulates AP in a variety of cell types) we have suggested that altered AP expression in some cancers may be caused by a defect in the ability of the cells to respond normally to retinoid. We have begun to use the chemically transformable mouse embryo fibroblast cell, C3H10T1/2, to investigate this possibility. In this initial study we characterized AP regulation in normal C3H10T1/2 cells and show that: (1) 10(-7) M RA increases AP activity within 3-4 h in serum-free medium; (2) serum inhibits short-term induction (0-8 h) in a concentration-dependent manner (10% serum causes complete inhibition); (3) during long-term RA exposure (24 h and 48 h), induction can be detected in serum-containing medium; (4) AP induction is dose related at RA concentrations from 10(-10) M to 10(-6) M in serum-free medium; (5) 10(-5) M RA is ineffective at inducing AP in serum-free medium during 8 h but is the most effective concentration in serum-containing medium during 24 h and 48 h exposures; (6) AP inducibility by RA requires near-confluent cell densities; and (7) when cultures become confluent, cells become constitutive for AP and no longer require RA for enzyme expression. The effects of serum and cell density on AP inducibility by RA and implications of the RA up-regulation of AP for teratogenesis are discussed.     

Labeling of antibodies by in situ modification of thiol groups generated from selenol-catalyzed reduction of native disulfide bonds

A new method for labeling antibodies which involves selenol-catalyzed reduction of native disulfide bonds in antibodies to generate thiol groups, which then are labeled using thiol-reactive reagents, is described. The reduction and labeling steps of this rapid procedure are carried out in one vessel, without requiring any separation step to remove the reductant before labeling. It results in a quantitative and homogenous incorporation of about seven labeled groups per antibody molecule in less than 5 min. All reagents used are commercially available-selenocystamine (catalyst precursor), dithiothreitol or tris(2-carboxyethyl)phosphine (reductant), and thiol-reactive labeling reagents such as biotin-poly(ethylene oxide)-maleimide. This method is broadly applicable for labeling proteins such as immunoglobulins with reducible disulfide bonds, whose reduction and labeling does not result in a significant loss of activity. Biotinylated murine antibodies (anti-phosphotyrosine and anti-EGF receptor) prepared by this reduced-disulfide labeling method perform comparably or better than amino-group biotinylated antibodies in applications such as enzyme-linked immunosorbent assay, immunohistochemistry, and immunoprecipitation. This reduced-disulfide labeling method is superior to amino-group labeling methods because it is not inhibited by the presence of amines in solution, as demonstrated by the biotinylation of an antibody in a hybridoma culture supernatant containing amino acids and serum proteins.     

Studies on the incubation mixtures for the in vitro mutagenesis test with metabolic activation (microsomal assay). Behaviour of mixed function oxidase and lipid peroxidation in the presence of some xenobiotics.

The effect of some xenobiotics on microsomal mixed function oxidase and lipid peroxidation, in mice, in incubation mixtures for the in vitro mutagenesis test with metabolic activation was studied. Aniline 1 or 2 mM and aminopyrine 0.38 or 8.33 mM completely inhibited the lipid peroxidation with small protection of the monooxygenase. Styrene 50 or 100 mM inhibited to a lesser extent the lipid peroxidation with marked increase in the inactivation of the monooxygenase. By a technique based on successive additions of fresh microsomes it was possible to evaluate the part of the inactivation due to enzyme denaturation and that due to inhibition. EDTA 40 mM was not able to protect from inactivation in the presence of aniline 1mM. Data of this type could be utilized to obtain more reliable results of in vitro mutagenesis tests with metabolic activation by suitably managing the enzyme activity in the incubation mixtures in order to keep it as constant as possible.     

Generation of monoclonal antibodies to prostatic acid phosphatase isoenzyme 2 and application in solid-phase enzyme immunoassay

Monoclonal antibodies specific to prostatic acid phosphatase (PAP) isoenzyme 2 were generated by using an improved hybridoma technique. After three subcutaneous immunizations and three intravenous boosters, cell fusion experiments were performed. The hybrid cells were first cultured in a semisolid medium containing methylcellulose and later transferred to a liquid medium for further subculture. Out of a total of 600 colonies recovered after two cell fusion experiments, 13 were shown to exhibit affinity to PAP isoenzyme 2 by radioimmunoassay. Nine hybrid cell lines which showed high affinity and specificity were established for further evaluation. Their immunoglobulin subclass was determined to be immunoglobulin G. The association constants between PAP isoenzyme 2 and each monoclonal antibody were determined by titration curve in radioimmunoassay (RIA). Three of them (PAP 1, PAP 03, and PAP 019) were shown to be over 1 X 10(9) M-1. From the results of a matrix cross-matching procedure, a pair of antibodies (PAP 03 and PAP 1) reacting with discrete antigenic determinants were identified for preparing a solid phase sandwich enzyme immunoassay (EIA) kit. The designed EIA procedure could be performed within 40 min in a one-stage incubation protocol. The assay time was shorter than that of other commercial RIA or EIA kits, and the sensitivity was 0.4 ng/ml which was comparable to that of RIA kits. The EIA kit was shown not to cross-react with human thyroid stimulating hormone, alpha-fetoprotein, carcinoembryonic antigen, and acid phosphatases derived from tissues other than prostate. Therefore, this design was a simple and rapid method with high sensitivity and specificity for determining PAP isoenzyme 2 in human serum.     

Alkaline phosphatase from the hyperthermophilic bacterium T. maritima requires cobalt for activity

The hyperthermophilic bacterium Thermotoga maritima encodes a gene sharing sequence similarities with several known genes for alkaline phosphatase (AP). The putative gene was isolated and the corresponding protein expressed in Escherichia coli, with and without a predicted signal sequence. The recombinant protein showed phosphatase activity toward the substrate p-nitrophenyl-phosphate with a k(cat) of 16 s(-1) and a K(m) of 175 microM at a pH optimum of 8.0 when assayed at 25 degrees C. T. maritima phosphatase activity increased at high temperatures, reaching a maximum k(cat) of 100 s(-1), with a K(m) of 93 microM at 65 degrees C. Activity was stable at 65 degrees C for >24 h and at 90 degrees C for 5 h. Phosphatase activity was dependent on divalent metal ions, specifically Co(II) and Mg(II). Circular dichroism spectra showed that the enzyme gains secondary structure on addition of these metals. Zinc, the most common divalent metal ion required for activity in known APs, was shown to inhibit the T. maritima phosphatase enzyme at concentrations above 0.3 moles Zn: 1 mole monomer. All activity was abolished in the presence of 0.1 mM EDTA. The T. maritima AP primary sequence is 28% identical when compared with E. coli AP. Based on a structural model, the active sites are superimposable except for two residues near the E. coli AP Mg binding site, D153 and K328 (E. coli numbering) corresponding to histidine and tryptophan in T. maritima AP, respectively. Sucrose-density gradient sedimentation experiments showed that the protein exists in several quaternary forms predominated by an octamer.     

Caspase-2 is not required for thymocyte or neuronal apoptosis even though cleavage of caspase-2 is dependent on both Apaf-1 and caspase-9

We have generated rat monoclonal antibodies that specifically recognise caspase-2 from many species, including mouse, rat and humans. Using these antibodies, we have investigated caspase-2 expression, subcellular localisation and processing. We demonstrate that caspase-2 is expressed in most tissues and cell types. Cell fractionation and immunohistochemistry experiments show that caspase-2 is found in the nuclear and cytosolic fractions, including a significant portion present in the Golgi complex. We found that caspase-2 is processed in response to many apoptotic stimuli but experiments with caspase-2 deficient mice demonstrated that it is not required for apoptosis of thymocytes or dorsal root ganglia (DRG) neurons in response to a variety of cytotoxic stimuli. Caspase-2 processing does not occur in thymocytes lacking Apaf-1 or caspase-9, suggesting that in this cell type, activation of caspase-2 occurs downstream of apoptosome formation.