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

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.

Heat-induced retrieval of immunogold labeling for nucleobindin and osteoadherin from Lowicryl sections of bone

The main purpose of this study was to examine whether antigens can be retrieved by heating Lowicryl sections of paraformaldehyde-fixed (PFF) tissues. Thus the intensity of the immunogold signal for two bone proteins (Nucleobindin (Nuc) and osteoadherin (OSAD)) was compared in retrieved and non-retrieved sections of PFF rat bone. As an additional experiment, the effect of antigen retrieval (for Nuc) in sections of tissue primary stabilized by high pressure freezing with subsequent freeze substitution (HPF-FS) was studied. Finally, the tissue distribution patterns of Nuc labeling were compared in non-retrieved HPF-FS sections to that of retrieved and non-retrieved PFF sections. Antigen retrieval in Lowicryl sections of PFF tissues showed significantly enhanced labeling intensity for both proteins in all compartments where they are known to occur. Retrieved PFF Lowicryl sections showed only minor ultrastructural differences compared to non-retrieved ones. Retrieval of HPF-FS sections exhibited no enhancement of labeling but rather a slight reduction, which was significant in the cytoplasm and in cartilage. Furthermore, striking ultrastructural differences were observed in retrieved HPF-FS sections compared to non-retrieved ones with loss of coherence and structure in sections subjected to heating. Comparison of the distribution patterns of Nuc in the sections of PFF and HPF-FS tissues showed discrepancy in most compartments. Antigen retrieval by heating Lowicryl sections of PFF tissues significantly enhances immunogold labeling in all cell compartments where the bone proteins are known to occur. However, the procedure may distort the tissue distribution pattern of bone proteins.

Localization of caveolin 1 in aortic valve endothelial cells using antigen retrieval

Ultrastructural analysis of aortic valve endothelial cells subjected to growth arrest revealed many vesicles defined as caveolae by the localization of caveolin. Translocation of caveolin after exposure to oxidized LDL suggests that the localization of caveolin may be a valuable tool to study models of early atherogenesis. In this study, several antigen retrieval protocols were tested in osmium-fixed and Spurr-embedded cells to determine the optimal method of antigen retrieval in our model system. SDS produced the most consistent labeling pattern. A quantitative evaluation revealed that SDS significantly increased the labeling density in Spurr-embedded cells. The labeling pattern appeared as clusters of gold particles, 15-40 nm in diameter, that were associated with membranes of a similar size which may represent the neck region of the caveolae.

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.

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).