Enzyme histochemical investigation of glycol methacrylate embedded chick embryonic tissue

Synopsis The advantages of the water-soluble glycol methacrylate (GMA) embedding procedure make it highly applicable for use with fragile early embryonic material. Not only can one obtain tissue sections containing excellent histological detail, but numerous enzymes are retained for subsequent histochemical localization. For the purpose of establishing a methodology whereby concomitant histology and histochemistry could be obtainable, various fixatives and fixation times have been evaluated on GMA embedded chick embryonic mesonephros and gonad. It was found that fixing the tissues for 1 h in a solution of 95% ethanol, 5% acetic acid and 10% neutralbuffered formalin resulted in the retention of not only excellent histology but also alkaline and acid phosphatase. Thus, with this procedure, more specific investigations of early embryonic tissue can be performed.     

A New Method for Flat Embedding in Glycol Methacrylate

Glycol methacrylate (GMA) is a useful polymer for embedding tissue because of its stability, hydrophilic properties, and resistance to many solvents (Feder a d O'Brien 1968, Bennett et a/. 1976). Undue solvent extraction is also avoided as GMA contains water, making complete dehydration unnecessary (Cole and Sykes 1974). This property shows some evidence that GMA embedded sections may be useful in energy dispersive analysis by X-ray for some elements (DeNee et al. 1977). GMA also does not exclude water soluble dye molecules and has thus become a useful medium for histochemical studies (Bennett et al. 1976).     

Demonstration of tartrate-resistant acid phosphatase in un-decalcified, glycolmethacrylate-embedded mouse bone: a possible marker for (pre)osteoclast identification

Fixed, undecalcified mouse long bones were embedded in glycol methacrylate (GMA), sectioned, and incubated for acid phosphatase in the presence or absence of tartrate, to investigate the feasibility of tartrate-resistant acid phosphatase as a histochemical marker for osteoclast identification. Naphthol AS-BI phosphate was used as the substrate and hexazonium pararosanaline as coupler. Cytocentrifuge preparations of mouse, rat, and quail bone marrow or frozen and GMA sections of mouse splenic tissue were used as controls to specify acid phosphatase activity. After adequate fixation, acid phosphatase activity sensitive to tartrate inhibition (TS-AP) was demonstrated in macrophages from spleen, bone marrow, and loose connective tissue surrounding bone rudiments. Acid phosphatase activity resistant to tartrate inhibition (TR-AP), was detected in multi-nuclear osteoclasts and in some mononuclear cells from bone marrow and periosteum. In cytocentrifuge preparations and frozen sections of mouse spleen, TR-AP was demonstrated after simultaneous incubation with substrate and tartrate. In GMA sections, however, TR-AP could only be demonstrated after pre-incubation with tartrate before application of substrate. We suggest that histochemical demonstration of TR-AP versus TS-AP on GMA-embedded bone sections by means of a pre-incubation method can be used as an identification marker of (pre)osteoclasts. Plastic embedding is recommended for its excellent preservation of morphology and enzyme activity.     

Enhanced in situ detection of beta-glucuronidase activity in murine tissue.

We outline here a protocol for high-resolution in situ localization of beta-glucuronidase in murine tissues processed in glycol methacrylate (GMA). Murine tissues were first stained with 5-bromo-4-chloro-3-indolyl-beta-d-glucuronic acid (x-gluc), followed by histological processing in GMA. Retention of the blue indigo reaction product after overnight incubations in x-gluc allowed high-resolution localization of beta-glucuronidase activity by brightfield microscopy. When illuminated under darkfield, the x-gluc signal was enhanced, permitting detection even in cells with low-level enzyme activity. This technique offers for the first time a more sensitive enzyme histochemical method of detecting beta-glucuronidase activity in animal tissues and also the opportunity to examine expression at high magni-fication.     

Glycol Methacrylate in Light Microscopy a Routine Method for Embedding and Sectioning Animal Tissues

Glycol methacrylate (GMA), a water and ethanol miscible plastic, was introduced to histology as an embedding medium for electron microscopy. This medium may be made soft enough for cutting thick sections for routine light microscopy by altering its composition. A procedure for the infiltration, polymerization, and sectioning of animal tissues in GMA for light microscopy is presented which is no more complex than paraffin techniques and which has a number of advantages: (I) The GMA medium is compatible with both aqueous fixatives (formaldehyde, glutaraldehyde, Bouin's, and Zenker's) and non-aqueous fixatixes (Carnoy's, Newcomer's, ethanol, and acetone). (2) Undue solvent extraction of the tissue is avoided because adequate dehydration occurs during infiltration of the embedding medium. Separate dehydration and clearing of the tissue prior to embedding is eliminated. (3) When polymerized, the supporting matrix is firm enough that hard and soft tissues adjacent to one another may be sectioned without distortion. (4) Thermal artifact is reduced to a minimum during polymerization because the temperature of the tissue may be maintained at 0-4 C from fixation through ultraviolet light polymerization of the embedding medium. (5) Shrinkage during polymerization of the embedding medium is minimized by prepolymerization of the medium before use. (6) Sections may be easily cut using conventional steel knives and rotary microtomes at a thickness of 0.5 to 3.0 microns, thus improving resolution compared with routinely thicker paraffin sections. (7) The polymerized GMA medium is porous enough so that staining, auto radiography, and other histological procedure are done without removal of the embedding medium from the sections. A list of these stains and related procedures are included. (8) Enzyme digestion of ultra thin sections of tissue embedded in GMA is common in electron microscopic cyto chemistry. me same digestion techniques appear compatible with the thicker seaions used in light microscopy.     

Immunohistochemistry on Resin Sections: A Comparison of Resin Embedding Techniques for Small Mucosal Biopsies

We have modified resin embedding methods to provide optimal information from en-doscopic biopsies. Mucosal biopsies were fixed either in buffered formalin and processed for embedding in Araldite or in acetone containing protease inhibitors and embedded in glycol meth-acrylate (GMA). GMA embedding generated an im-munophenotypic profile similar to that obtained in frozen sections while yielding far superior morphology and greater numbers of sections from small biopsies. The phenotypic markers included those for T cells, macrophages, mast cells, eosin-ophils and neutrophils. We have also demonstrated collagens, cell adhesion molecules and integrin molecules. Sections of similar quality were obtained with Araldite but the repertoire of antibodies was restricted to those which can be applied to formalin fixed, paraffin embedded tissues. We suggest that for optimal results, small biopsies to be subjected to immunochemistry are fixed in acetone at -20 C with the inclusion of protease inhibitors and embedded in GUIA with careful temperature control.     

Glycol Methacrylate Embedding of Algmate-Polylysine Microencapsulated Pancreatic Islets

A method for processing and embedding alginate-polylysine microencapsulated pancreatic tissue in glycol methacrylate resin (GMA) is described. Fixation in 4% phosphate buffered formaldehyde, processing in ascending concentrations of glycol methacrylate monomer and embedding in Technovit 7100 results in well preserved morphological details of hydrogels, hydrogel-cell interfaces, and encapsulated pancreatic tissue. Routine staining with Loeffler's methylene blue, hematoxylin and eosin, and Romanovsky-Giemsa gave excellent images of the GMA embedded alginate polylysine membrane and tissues allowing cells on the outside of the capsule to be analyzed effectively as part of the foreign body reaction against the capsule membrane.     

Glycol Methacrylate Embedding of Algmate-Polylysine Microencapsulated Pancreatic Islets

A method for processing and embedding alginate-polylysine microencapsulated pancreatic tissue in glycol methacrylate resin (GMA) is described. Fixation in 4% phosphate buffered formaldehyde, processing in ascending concentrations of glycol methacrylate monomer and embedding in Technovit 7100 results in well preserved morphological details of hydrogels, hydrogel-cell interfaces, and encapsulated pancreatic tissue. Routine staining with Loeffler's methylene blue, hematoxylin and eosin, and Romanovsky-Giemsa gave excellent images of the GMA embedded alginate polylysine membrane and tissues allowing cells on the outside of the capsule to be analyzed effectively as part of the foreign body reaction against the capsule membrane.     

Identification of carrageenan in mammalian tissues: An analytical and histochemical study

Synopsis Methods have been developed for the analytical estimation and histochemical demonstration of carrageeman in the granuloma induced in rats and guinea-pigs by subcutaneous injection of degraded carrageenan.The analytical method for the determination of carrageenan in tissues involved a preliminary clean-up procedure. The tissues were defatted by solvent extraction and incubated with papain and trypsin to remove proteins. Carrageenan and naturally occurring acid mucopolysaccharides were isolated using cetyl pyridinium chloride. The subsequent separation and estimation of carrageenan was carried out by electrophoresis on cellulose acetate paper. Following electrophoresis the cellulose acetate strips were incubated with hyaluronidase to remove acid mucopolysaccharides, and stained with Toluidine Blue. The stained band corresponding to pure degraded carrageenan was quantitated on a scanning densitometer. The method was capable of detecting 0.25 g of degraded carrageenan in tissue.The most suitable method for the histochemical demonstration of carrageenan in paraffin embedded tissues was found to be Alcian Blue at either pH 1 or a CEC (critical electrolyte concentration) of 1.0 M MgCl₂ (pH 5.8). At this pH or CEC, both the carrageenan and the strongly acidic glycosaminoglycans were stained. Prior digestion with hyaluronidase and neuraminidase eliminated the staining of the tissue polysaccharides so that the carrageenan could be visualized within macrophages and in the extracellular space. Mast cell granules retained their staining properties after mucolytic digestion; but morphologically, mast cells could be distinguished from macrophages containing carrageenan.     

A rapid connective tissue stain for glycol methacrylate embedded tissue

No reliable connective tissue stains for GMA sections were available until recently. However, the use of toluidine blue in combination with basic fuchsin appeared to be a rapid and reliable connective tissue stain for glycol methacrylate (GMA) embedded tissue.     

Ia antigens in plastic-embedded tissues: a post-embedding immunohistochemical study

The aim of the present study was to establish a plastic embedding technique that makes possible the immunohistochemical demonstration of class II major histocompatibility complex (MHC) antigens (Ia antigens) in undecalcified joint tissues. Therefore a series of fixatives and dehydrating agents was tested for saving Ia immunoreactivity by post-embedding immunostaining of thin sections (2 microns) of rat tissues that had been embedded in glycol methacrylate (GMA), and by comparing with cryostat sections. An indirect immunoperoxidase and the avidin-biotin complex (ABC) technique were used. Combined with fixation by 4% formaldehyde, dehydration with GMA was found to give the best preservation of Ia antigenicity, followed by dehydration with ethylene glycol. The thinness of tissue sections facilitated the association of Ia antigens with different subcellular compartments in distinct cell populations. These various patterns are described.     

Thionin Staining of Paraffin and Plastic Embedded Sections of Cartilage

The usefulness of thionin for staining cartilage sections embedded in glycol meth-acrylate (GMA) and the effect of decalcification on cartilage sections embedded in paraffin and GMA were assessed. Short decalcification periods using 5% formic acid or 10% EDTA did not influence the staining properties or the morphology of cartilage matrix and chondrocytes. The standard stain safranin O-fast green for differential staining of cartilage was used as control in these experiments. Prolonged exposure of safranin P stained sections to fast green resulted in disappearance of the safranin O stained matrix, thereby hampering the quantitative measurement of negatively charged glycosaminoglycans (GAG). Thionin stained evenly throughout all cartilage layers, independent of the staining times. In contrast to safranin 0, thionin did not show meta-chromasia in nondehydrated cartilage sections, which made it more suitable for assessing cartilage quality in GMA embedded cartilage. To evaluate the selectivity of thionin staining in cartilage, chondroitinase ABC and trypsin digestions were carried out. Thionin staining was prevented by these enzymes in the territorial matrix, representing the interlacunar network and the chondrocyte capsule. Staining with thionin of the interterritorial matrix was only slightly reduced, possibly representing keratan sulfate and hyaluronic acid in cartilage of elderly patients. Comparison of thionin stained GMA embedded cartilage with safranin O stained paraffin embedded sections showed significant similarity in optical densitometry, indicative of the specificity of thionin bound to negatively charged GAG in cartilage. In GMA embedded cartilage morphology was relatively intact compared to paraffin embedded sections due to less shrinkage of chondrocytes and the interlacunar network.     

Thionin Staining of Paraffin and Plastic Embedded Sections of Cartilage

The usefulness of thionin for staining cartilage sections embedded in glycol meth-acrylate (GMA) and the effect of decalcification on cartilage sections embedded in paraffin and GMA were assessed. Short decalcification periods using 5% formic acid or 10% EDTA did not influence the staining properties or the morphology of cartilage matrix and chondrocytes. The standard stain safranin O-fast green for differential staining of cartilage was used as control in these experiments. Prolonged exposure of safranin P stained sections to fast green resulted in disappearance of the safranin O stained matrix, thereby hampering the quantitative measurement of negatively charged glycosaminoglycans (GAG). Thionin stained evenly throughout all cartilage layers, independent of the staining times. In contrast to safranin 0, thionin did not show meta-chromasia in nondehydrated cartilage sections, which made it more suitable for assessing cartilage quality in GMA embedded cartilage. To evaluate the selectivity of thionin staining in cartilage, chondroitinase ABC and trypsin digestions were carried out. Thionin staining was prevented by these enzymes in the territorial matrix, representing the interlacunar network and the chondrocyte capsule. Staining with thionin of the interterritorial matrix was only slightly reduced, possibly representing keratan sulfate and hyaluronic acid in cartilage of elderly patients. Comparison of thionin stained GMA embedded cartilage with safranin O stained paraffin embedded sections showed significant similarity in optical densitometry, indicative of the specificity of thionin bound to negatively charged GAG in cartilage. In GMA embedded cartilage morphology was relatively intact compared to paraffin embedded sections due to less shrinkage of chondrocytes and the interlacunar network.     

A Fresh Mount Method for Cytochrome Oxidase Histochemistry

A simple modification of cytochrome oxidase histochemistry was undertaken to prevent the artifactual condensation of reaction product. The quality and reliability of the histochemical method were greatly improved by mounting the tissue after reaction.     

A new polychrome stain and simultaneous methods of histological, histochemical and immunohistochemical stainings performed on semithin sections of Bioacryl-embedded human tissues

Summary We describe a new polychrome stain and simultaneous methods of histological, histochemical and immunocytochemical staining performed on sections from human tissues embedded in the new hydrophilic resin Bioacryl. The polychrome stain involves the sequential use of Harris' Haematoxylin, silver methenamine, Light Green and Eosin or Safranin dyes and provides a highly specific visualization of the overall cytological tissue architecture. When histochemical, immunocytochemical, and polychrome stains are performed together on the same section, crisp images are obtained, yielding simultaneous data of histochemical and immunological reactivities with clear tissue architecture.     

Histochemical Demonstration of Enzyme Activities in Plastic and Paraffin Embedded Tissue Sections

Histochemical staining for enzymes is usually performed on frozen sections. This report lists the longer incubation times required to demonstrate esterase, acid phosphatase, β-galactosidase, and cytochrome oxidase in plastic embedded and routine paraffin embedded tissues. The sections embedded in plastic, i.e. water soluble methacrylate (Polyscience's JB-4) and cut at 2 μm, were far superior to frozen Sections and paraffin embedded sections both in tissue detail and in the localization of the histochemical reaction product.     

Glycol methacrylate embedding in enzyme histochemistry: Application to arthropode tissue incubated for demonstration of unspecific esterase and succinic dehydrogenase activity

Summary The final products of unspecific esterase and succinic dehydrogenase were demonstrated in 1–2 m sections of tick salivary glands embedded in glycol methacrylate (GMA). In the esterase experiments, the tissue specimens were incubated after fixation in glutaraldehyde or acroleïn, and then embedded in GMA. For demonstration of succinic dehydrogenase activity, the specimens were incubated prior to glutaraldehyde fixation followed by embedding in GMA. In sections of all preparations intense enzymatic reaction was observed. High resolution light microscopy could efficiently be used for precise locating of the enzymic products, due to excellent morphologic reference in semithin GMA sections.Supported by the Deutsche Forschungsgemeinschaft. Presented in part at the 4th International Congress on Protozoology, Clermont-Ferrand (France), 2.–9. September 1973.The author was fellow of the Deutsche Forschungsgemeinschaft at the Department of Anatomy, Medical School Hannover, Federal Republic of Germany, during part of this study.     

A numerical procedure for choosing effective, low toxicity plasticizers for glycol methacrylate embedding

Summary A numerical method for selecting low toxicity plasticizers for glycol methacrylate (GMA) embedding mixtures is described. It involves use of various numerical parameters, namely; molecular weight, melting point, solubility parameter, and toxicity data. On the basis of these parameters, nine plasticizers were selected. Their effects on microtomy and tissue processing, and also their influence on tissue morphology and staining, were investigated. For tissue processed at low temperatures into GMA, using ethanol dehydration, the following compounds were as satisfactory as 2-butoxyethanol whilst being less toxic: 2-isopropoxyethanol, 2-(2-methoxyethoxy)ethanol, 2-(2-ethoxyethoxy)ethanol, 2-(n-butoxyethoxy)ethanol. However for tissues processed using the plasticizer as dehydrating agent, the optimum plasticizers were 2-isopropoxyethanol, 2-(2-methoxyethoxy)ethanol and 2-(2-ethoxyethoxy)ethanol. It is possible to give a numerical specification of the preferred plasticizers, and for the first procedure this is: a solubility parameter in the range 21–26 J^0.5 cm^–1.5 or higher, a melting point well below 0°C, and a rat oral LD₅₀>12.52 mmol kg^–1. It was also possible to analyse the differential effects of the dehydrating agents on histochemical and enzyme histochemical staining on a numerical basis, using a structure-activity relations approach.     

Ultrastructural histochemical localization of acid phosphatase in salivary glands of Drosophila melanogaster.

The ultrastructural histochemical localization of acid phosphatase in salivary glands of third instar larvae of Drosophila melanogaster has been studied. Using Gomori's lead phosphate method for acid phosphatase detection, the optimal incubation time in the reaction medium was determined to be 30 min. When glands having wild-type acid phosphatase activity are incubated for this time, deposition of the final reaction product is observed in essentially every lysosome and artifactual staining is minimal.     

Development of a Plastic Embedding Method for Large-Volume and Fluorescent-Protein-Expressing Tissues

Fluorescent proteins serve as important biomarkers for visualizing both subcellular organelles in living cells and structural and functional details in large-volume tissues or organs. However, current techniques for plastic embedding are limited in their ability to preserve fluorescence while remaining suitable for micro-optical sectioning tomography of large-volume samples. In this study, we quantitatively evaluated the fluorescence preservation and penetration time of several commonly used resins in a Thy1-eYFP-H transgenic whole mouse brain, including glycol methacrylate (GMA), LR White, hydroxypropyl methacrylate (HPMA) and Unicryl. We found that HMPA embedding doubled the eYFP fluorescence intensity but required long durations of incubation for whole brain penetration. GMA, Unicryl and LR White each penetrated the brain rapidly but also led to variable quenching of eYFP fluorescence. Among the fast-penetrating resins, GMA preserved fluorescence better than LR White and Unicryl. We found that we could optimize the GMA formulation by reducing the polymerization temperature, removing 4-methoxyphenol and adjusting the pH of the resin solution to be alkaline. By optimizing the GMA formulation, we increased percentage of eYFP fluorescence preservation in GMA-embedded brains nearly two-fold. These results suggest that modified GMA is suitable for embedding large-volume tissues such as whole mouse brain and provide a novel approach for visualizing brain-wide networks.