Improved technique for immunoelectron microscopy. How to prepare epoxy resin to obtain approximately the same immunogold labeling for epoxy sections as for acrylic sections without any etching

Heat-induced Antigen Retrieval in Conventionally Processed Epon-embedded Specimens: Procedures and Mechanisms

We studied the effectiveness of heat-induced antigen retrieval (HIAR) in conventionally processed, epon-embedded specimens and the mechanisms of HIAR in the specimens. Frozen sections were first immunostained to examine the possibility of using HIAR for 18 antigens to avoid the effects of epoxy resin embedment. The antigenicity of 7 out of 18 antigens was retrieved with glutaraldehyde fixation followed by osmium tetroxide treatment whereas none were retrieved with glutaraldehyde fixation without post-osmication. Six antigens also exhibited positive immunostaining in semi-thin epon sections when the sections were deplasticized with sodium ethoxide followed by autoclaving. In the immunoelectron microscopy with the post-embedding method, positive reactions with fine ultrastructures were obtained using HIAR without deplasticization. These results suggested that osmium tetroxide binds to ethylene double bonds (which are introduced into protein crosslinks by glutaraldehyde) and forms an extremely stable resonance interaction with the Schiff bases, thus destabilizing the protein crosslinks. Heating also further degrades these crosslinks. The present study demonstrated that archival epon blocks can be useful resources for immunohistochemical studies for both light and electron microscopy.

State of the art in antigen retrieval for immunohistochemistry

The masking effects of antigens by chemical fixation, processing, embedding media interactions, represent a serious problem for immunohistochemical purposes. Fortunately, different approaches in antigen retrieval exist. These techniques are relatively recent and continuously expanding. This review focuses on the present state of the art in antigen retrieval methods for immunohistochemistry in light and electron microscopy. Moreover, a brief discussion on the chemical aspects of fixation, mechanism of retrieval, as well as its efficacy, is given.

Heat-induced antigen retrieval: mechanisms and application to histochemistry

Since the introduction of the fluorescence-labeled antibody method by Coons et al. [Immunological properties of antibody containing a fluorescent group. Proc Soc Exp Biol Med 47, 200-2002], many immunohistochemical methods have been refined to obtain high sensitivity with low background staining at both light and electron microscopic levels. Heat-induced antigen retrieval (HIAR) reported by Shi et al. in the early 1990s has greatly contributed to immunohistochemical analysis for formalin-fixed and paraffin-embedded (FFPE) materials, particularly in the field of pathology. Although antigen retrieval techniques including enzyme digestion, treatment with protein denaturants and heating have been considered tricky and mysterious techniques, the mechanisms of HIAR have been rapidly elucidated. Heating cleaves crosslinks (methylene bridges) and add methylol groups in formaldehyde-fixed proteins and nucleic acids and extends polypeptides to unmask epitopes hidden in the inner portion of antigens or covered by adjacent macromolecules. In buffers having an appropriate pH and ion concentration, epitopes are exposed without entangling the extended polypeptides during cooling process, since polypeptides may strike a balance between hydrophobic attraction force and electrostatic repulsion force. Recent studies have demonstrated that HIAR is applicable for immunohistochemistry with various kinds of specimens, i.e., FFPE materials, frozen sections, plastic-embedded specimens, and physically fixed tissues at both the light- and electron-microscopic levels, and have suggested that the mechanism of HIAR is common to aldehyde-fixed and aldehyde-unfixed materials. Furthermore, heating has been shown to be effective for flow cytometry, nucleic acid histochemistry (fluorescein in situ hybridization (FISH), in situ hybridization (ISH), and terminal deoxynucleotidyl transferase-mediated nick labeling (TUNEL)), and extraction and analysis of macromolecules in both FFPE archive materials and specimens processed by other procedures. In this article, we review mechanism of HIAR and application of heating in both immunohistochemistry and other histochemical reactions.

Increased level of immunogold labeling of epoxy sections by rising the temperature significantly beyond 100 degrees C in the antigen retrieval medium

The purpose of this study was to compare the level of immunogold labeling of epoxy sections when the sections were subjected to antigen retrieval at different temperatures. Renal swine tissue with glomerular immune complex deposits with reactivity against IgG and C3 was embedded in epoxy resin. Sections from these blocks were exposed to antigen retrieval by heating in citrate solution at temperatures in the range of 25-135 degrees C. Immunogold labeling with anti-IgG and anti-C3 was performed on the heated sections. The level of immunogold labeling increased significantly in the direction of increased heat. Interestingly, the level of immunogold labeling was significantly higher when exposed to heating in the autoclave (121 and 135 degrees C) than at temperatures just below the normal boiling point. Sections stained with anti-C3 turned from almost negative labeling when heated at 95 degrees C to strong positive labeling when heated at 135 degrees C (11 times increased). The intensity of the immunogold labeling with anti-IgG increased almost three times when raising the temperature in the retrieval medium from 95 to 135 degrees C. The practical significance of these results is that antigen retrieval of epoxy sections should be performed by heating in aqueous solutions at 135 degrees C or higher to obtain maximum immunolabeling.

Amplification methods for the immunolocalization of rare molecules in cells and tissues

The needs to precisely assign macromolecules to specific locations and domains within tissues and cells and to reveal antigens which are present in low or even in trace amounts, led to the elaboration of a wide spectrum of immunocytochemical amplification procedures. These arise from the successive improvements of tissue preparation techniques, of antigen retrieval procedures and of immunological or non-immunological detection systems. Improvement of detection systems may be the most active in the development of amplification techniques. Since the early work of Coons, in which by the introduction of the indirect technique has started amplifying the signal, different systems have succeeded in increasing the sensitivity of antigens detection. Indeed, amplification techniques such as the multiple antibody layers, the multiple bridges, the enzyme complexes, the avidin-biotin, the silver intensification, and the numerous variations and combinations among these have increased the sensitivity for the detection of scarce tissue antigens. However, as shown by the recent progress carried out with new approaches such as the catalyzed reporter deposition (CARD) and the enhanced polymer one-step staining (EPOS), more efficient methods are still needed. In electron microscopy, few techniques have reached the resolution afforded by the post-embedding immunogold approach. In spite of this and in order to further increase its sensitivity, new probes and novel approaches are allowing combination of the gold marker with the amplification capacity of enzymes afforded by the CARD technique. Immunogold amplification strategies, such as the multiple incubations with the primary antibody and the use of an anti-protein A antibody have also led to enhanced signals displaying the advantages in terms of resolution and possibilities of quantification inherent to the colloidal gold marker.

Deplasticizing or etching of epoxy sections with different concentrations of sodium ethoxide to enhance the immunogold labeling

The study's purpose was to obtain improved "deplasticizing" of epoxy sections for immunoelectron microscopy. Epoxy-embedded renal swine tissue with immune complex deposits was used. Ultrathin sections were mounted on uncoated grids or on carbon-stabilized formvar grids. The sections were exposed to different concentrations of sodium ethoxide, and they were subjected to immunogold labeling with anti-IgG. Etching with > or =8% of saturated solution gave completely deplasticized sections. Sections etched with 2-4% solution were only partly deplasticized, but these sections were detached if mounted on uncoated grids, and the yields of immunolabeling were significantly decreased compared with the deplasticized ones. Sections exposed to < or =1% solution were not detached from the uncoated grids. Double-sided labeling of uncoated sections etched with 1% solution yielded approximately the same immunolabeling as for the completely deplasticized formvar-supported sections, and they gave better ultrastructural preservation of the tissue. We have established that etching epoxy sections on non-supported grids with a diluted solution of sodium ethoxide may be preferable for immunoelectron microscopy.

A comparative study of the immunogold labeling on H(2)O(2)-treated and heated epoxy sections

The purpose of this study was to compare the intensity of the immunogold labeling of H(2)O(2)-treated and heated epoxy sections. Renal swine tissue with glomerular immune complex deposits with reactivity against IgG was embedded in epoxy resin. Immunogold labeling with anti-IgG was performed on sections from these blocks. Some of these sections were treated by H(2)O(2), others were heated in a citrate solution, while some were not treated at all. Some epoxy sections, which had been exposed to both H(2)O(2) and heat, were also exposed to the same immunolabeling. The heated epoxy sections obtained an yield of specific immunogold labeling, which was twice as large as the labeling of the H(2)O(2)-treated sections. The yield of immunolabeling of the sections that had been exposed to both H(2)O(2) and heat was not significantly different from the sections that were only exposed to heat. The non-treated sections were very weakly labeled with anti-IgG. We believe that both H(2)O(2) and heat have the ability to break some chemical bonds between the epoxy resin and the antigens, but heating in citrate buffer has a larger potential in this respect than H(2)O(2). We interpret the results from the combined treatment with H(2)O(2) and heat in the following way; the bonds that are broken by H(2)O(2) will also be broken by heating in citrate solution. The practical significance of these results is that heating in citrate buffer is a more convenient method for enhancing the immunolabeling of epoxy sections than treatment with H(2)O(2).

Increased yield of immunogold labeling of epoxy sections by adding para-phenylendiamine in the tissue processing

The purpose of this study was to examine if the presence of para-phenylendiamine (PPD) in the tissue processing could increase the yield of immunogold labeling of the epoxy sections. Renal swine tissue with glomerular immune complex deposits with reactivity against IgG was embedded in epoxy resin. PPD was added (1) at the beginning of the dehydration, (2) in the first step with propylene oxide, (3) in the beginning of the dehydration and in all steps with propylene oxide included the infiltration step where propylene oxide and epoxy resin are mixed, or (4) PPD was totally avoided. The tissue was embedded with two different combinations of accelerator. Immunogold labeling with anti-IgG was performed on both non-heated and heated ultrathin sections. The immunogold labeling on the heated sections which were based on processing with PPD in all steps (3) was about 55-65% higher than the corresponding labeling for epoxy sections processed in total absence of PPD (4). The immunolabeling was not significantly increased when the tissue was processed with PPD only in the start of the dehydration (1) or in the first step with propylene oxide (2). We believe that tissue processing with sufficient PPD contributes to reduce the co-polymerization between the antigens and the epoxy polymer in the same way as excess of accelerator does (Brorson and Skjørten, 1996a). The practical significance of this study provides better opportunities for increasing the immunogold labeling of epoxy sections by adding PPD in the tissue processing, and our result may inspire other researchers to develop even more efficient methods for controlling the copolymerization between antigens and epoxy resin.

Fixative-dependent increase in immunogold labeling following antigen retrieval on acrylic and epoxy sections

We examined the increase in immunogold labeling of variably fixed, resin embedded tissue sections following antigen retrieval by heating in citrate solution. Fibrin clots and porcine renal tissue were fixed in glutaraldehyde, paraformaldehyde or ethanol, and specimens were embedded in LR-White or epoxy resin. Immunogold labeling was performed on ultra-thin sections with anti-fibrinogen for the fibrin clots and anti-IgG for the porcine renal tissue. Immunogold labeling increased greatly after heating epoxy sections regardless of the fixative used. The ratio labeling(retrieved)/labeling(nonretrieved) (Lr/Ln) was 2.8 or higher, and the largest increases were obtained for anti-IgG. Heating induced a large increase of immunolabeling for LR-White sections only when the specimens had been fixed in paraformaldehyde (Lr/Ln = 2.2 for anti-IgG and 1.4 for antifibrinogen). LR-White sections showed decreased, insignificant or weakly increased immunolabeling of ethanol or glutaraldehyde fixed tissues following antigen retrieval. Disruption of aldehyde cross-links is not the only mechanism for antigen retrieval when epoxy sections are heated in citrate solution since large increases in immunolabeling were obtained on ethanol fixed tissue. The large heat-induced increases in immunolabeling on epoxy sections are probably caused by the disruption of chemical bonds between the epoxy resin and side groups of proteins.

Comparison of the immunolabeling of heated and deplasticized epoxy sections on the electron microscopical level

The purpose of this study was to compare the yield of immunogold labeling of heated epoxy sections with the yield of labeling of deplasticized epoxy sections, and to compare the immunolabeling of deplasticized high-accelerator epoxy sections and deplasticized low-accelerator epoxy sections. Renal swine tissue and human thyroid tissue were embedded in both high- and low-accelerator epoxy resin and also in LR-White resin. Immunogold labeling was performed on deplasticized (ethoxide-treated), heated and non-treated ultrathin sections from these specimens. The renal tissue was immunolabeled with anti-IgG, and the thyroid tissue was immunolabeled with anti-thyroglobulin. The ethoxide treatment of the epoxy sections induced complete deplasticizing. The immunogold labeling with anti-IgG on deplasticized epoxy sections of renal tissue demonstrated significantly more intense immunolabeling of immune complex deposits than the corresponding epoxy sections which were exposed to heat in citrate buffer. The results for labeling areas of thyroglobulin substance with anti-thyroglobulin showed no significant differences between deplasticized and heated epoxy sections, probably because the sodium ethoxide partly destroys the antigenicity. Deplasticized high-accelerator epoxy sections showed significantly higher yield of immunolabeling than deplasticized low-accelerator epoxy sections and LR-White sections both for anti-IgG and anti-thyroglobulin. This can be explained by the reduced tendency for the knife to cleave proteins when cutting high-accelerator epoxy sections. High-accelerator epoxy sections which were exposed to heat in citrate buffer were more intensely immunolabeled than similarly treated low-accelerator epoxy sections, in agreement with previous results. The ultrastructural preservation of the tissues of deplasticized epoxy sections was inferior compared with the other sections. This study shows that the choice between deplasticizing technique or heating of epoxy sections has to be considered with respect to the nature of the antigen and to the requirement for ultrastructural preservation.

A new immunoelectron microscopy approach for the detection of immunoglobulin and complement deposits in epoxy-embedded renal biopsies

The purpose of this study was to examine the diagnostic value of a new immunoelectron microscopy technique (IEM) for detection of immunoglobulin and complement deposits in epoxy-embedded renal biopsies. Twenty-four renal biopsies were embedded in epoxy resin following a tissue processing involving moderately increased amount of accelerator, DMP-30 (Tri(Dimethyl Amino Methyl) Phenol), in the infiltration steps. Following antigen retrieval by heating in citrate buffer, immunogold labeling was performed on ultrathin sections from these epoxy blocks with antibodies against immunoglobulins and complement. The sections were counterstained with urnayl acetate and lead citrate without any enhancing procedures. The preservation of the ultrastructure with this method was similar to that usually seen in epoxy embedded material. The immunogold labeling was intense and distinct. Immunofluorescence (IF) for light microscopy was carried out on frozen sections of parallel tissue samples. The correspondence between IF and IEM were good, but in some cases higher sensitivity for IgA with IEM than IF was observed in the sense that smaller amounts of antigen were detectable with IEM. The combination of moderately increased amount of accelerator and antigen retrieval is superior to previous methods with respect to ease of use, ultrastructural preservation, and intensity of the immunolabeling. Moreover, the renal tissue can be processed in an automatic ultraprocessor together with other specimens which are to be prepared for routine electron microscopy.

The combination of high-accelerator epoxy resin and antigen retrieval to obtain more intense immunolabeling on epoxy sections than on LR-white sections for large proteins

The purpose of this study was to examine how antigen retrieval affected the yield of immunogold labeling on epoxy sections based on embedding with different amounts of accelerator. The concentration of accelerator DMP-30 (tri(dimethyl amino methyl) phenol) was varied in the range of 0-8% in the processing of the tissue for epoxy embedding. Immunogold labeling was performed on epoxy sections and LR-White sections of fibrin clots and renal tissue with IgG-deposits, and the antibodies used were anti-fibrinogen anti-IgG and, respectively. For some of the sections antigen retrieval was performed by heating the sections in citrate buffer. In all cases, the yield of immunogold labeling increased following antigen retrieval. The increase (%) in the yield of immunogold labeling as a result of antigen retrieval was larger for epoxy sections than for LR-White sections. The immunolabeling on high-accelerator epoxy sections exposed to antigen retrieval was about 20% more intense than on untreated LR-White sections both for IgG and fibrinogen. In addition to breaking fixations bonds introduced by the chemical fixation, we believe that the antigen retrieval also breaks bonds between the epoxy resin and the embedded tissue. The combination of increased amount of accelerator during tissue processing for epoxy embedding and antigen retrieval by heating in citrate buffer is a potent method for increasing specific immunolabeling on epoxy sections.

Bovine serum albumin (BSA) as a reagent against non-specific immunogold labeling on LR-White and epoxy resin

The purpose of this study was to examine how different incubation times with different concentrations of bovine serum albumin (BSA) affect the amount of non-specific immunogold labeling on epoxy sections and LR-White sections. Immunogold labeling was performed on epoxy sections and LR-White sections of renal tissue with IgG-deposits and fibrin clots, and the antibodies used were anti-IgG and anti-fibrinogen, respectively. The sections were incubated with different concentrations of BSA prior to application of primary antibodies, and the length of this pre-incubation step varied between 0 and 4 h. During the incubation with primary antibodies, BSA was added in the same concentration as in the pre-incubation step. The results showed that the non-specific labeling on the resin decreased significantly when the concentration of BSA or the length of the preincubation step was increased. The non-specific labeling was usually higher on the epoxy resin than on the LR-White resin when using the same conditions with respect to BSA. But, when the preincubation step with BSA lasted 4 h, the non-specific labeling was somewhat lower on epoxy resin than on the acrylic LR-White resin, without respect to the concentration of BSA. The specific labeling for both fibrinogen and IgG decreased slightly when the concentration of BSA and incubation time increased, probably due to the steric hindrance performed by BSA molecules on the section. Blocking procedures with at least 1 h incubation time for the blocking step with at least 5% BSA are recommended for both epoxy and LR-White sections.

Immunoelectron microscopy on epoxy sections without deplasticizing to detect glomerular immunoglobulin and complement deposits in renal diseases

Twenty renal biopsies were studied by immunoelectron microscopy (IEM) after embedding in epoxy resin. Immunogold labeling for immunoglobulins and complement C3 was performed on the epoxy sections, which were not subjected to any kind of etching or deplasticizing prior to the immunolabeling. The concentration of accelerator, DMP-30 (Tri (Dimethyl Amino Methyl) Phenol), was increased in the infiltration and embedding steps far beyond the values normally used to make immunolabeling of these antigens possible on epoxy sections. The sections were stained with tannic acid accompanied by uranyl acetate and lead citrate. Immunofluorescence (IF) for light microscopy was carried out on frozen sections of parallel tissue samples. Some cases with IgA-nephritis demonstrated a higher sensitivity for IEM than IF, in the sense that smaller amounts of antigen were detectable with IEM. Ultrastructural preservation with this method was approximately the same as that usually seen on epoxy-embedded material. By combining excellent immunolabeling with nearly optimal ultrastructural morphology in one procedure, this method is useful particularly in situations where the material available is limited, such as in studies of renal biopsies. As far as we know, this is the first time that immunoglobulins have been satisfactorily immunolabeled on epoxy sections without etching or deplasticizing.

Improved immunogold labeling of epoxy sections by the use of propylene oxide as additional agent in dehydration, infiltration and embedding

The purpose of this study was to examine how the intensity of the immunogold labeling on epoxy sections was affected by the use of propylene oxide as an agent in addition to ethanol in the dehydration and infiltration, and also to examine the effect on the immunogold labeling by adding small amounts of propylene oxide to the embedding mixture. Increased knowledge of the mechanism for antigen detection on resin sections was another aim. Thyroid tissue, kidney tissue, and fibrin were embedded in epoxy resin; some with ethanol as the only dehydration agent and others with propylene oxide as an additional agent in dehydration, infiltration or embedding steps in different ways. Immunogold labeling was performed with anti-thyroglobulin, anti-IgG, and anti-fibrinogen, respectively. A higher degree of immunogold labeling was achieved by increasing the concentration of accelerator during infiltration and embedding (Brorson and Skjørten, 1996a, Micron, 27, 211-217). The immunogold labeling of the sections that were based on additional dehydration and infiltration with propylene oxide showed significantly more intense labeling than the sections of tissues that had only been exposed to ethanol in the dehydration and infiltration steps. The embedding of tissues in a mixture of epoxy resin and 5-10% propylene oxide gave higher yields of immunogold labeling than if pure epoxy resin was used for the embedding. The improved labeling is explained by higher amplitudes of protruding antigens on the surface of the sections because antigens are less tightly incorporated in the polymer network when using propylene oxide as additional agent in dehydration, infiltration or embedding. These results illustrate the advantage of using propylene oxide as an additional agent when preparing specimens for immunoelectron microscopy with epoxy resin embedding.