Standardization of various applications of methacrylate embedding and silver methenamine for light and electron microscopy immunocytochemistry

The use of butyl-methyl-methacrylate embedding and the application of the silver methenamine (SM) method as a poststaining of the immunoperoxidase-DAB (IP) procedure led to the standardization of several useful methods for the visualization of tissue antigens at the light and electron microscope level. These procedures included: 1) Standardization of the actual methacrylate embedding; 2) The IP-SM method with and without periodic acid oxidation, which provided 100% intensification of the IP staining; 3) The IP-SM method made it possible to stain semithin sections (0.5 micron), and this in turn, permitted a) clear visualization under the light microscope of the intracellular distribution of antigens and, b) staining, in several adjacent sections, of roughly the same cytoplasmic region of the same cell with different primary antisera; 4) a double immunostaining whereby the first antigen in the sequence was revealed by the IP-SM method and the second by the IP procedure; 5) standardization of the IP and the IP-SM methods for post-embedding staining of ultrathin methacrylate sections. The combined application of methacrylate embedding and the IP-SM, and the use of an appropriate fixative, resulted in an ultrastructural immunocytochemical procedure characterized by a good immunoreactivity of the tissue sections, a strong and selective immunoreaction and a well preserved ultrastructure.     

Immunocytochemistry of contractile and cytoskeletal proteins in smooth muscle: Lowicryl,LR White,and polyvinylalcohol compared

Summary Three embedding media have been compared with respect to post-embedding immunolabeling of contractile and cytoskeletal antigens in aldehyde-fixed smooth muscle tissue: the methacrylate derivates lowicryl K4M (cured at –35 or 60°C) and LR White (cured at 0 or 60°C) and the water soluble resin, polyvinylalcohol (dried at 60°C). Measurements of intensity of labeling of ultrathin sections in the fluorescence microscope showed that five antigens (actin, myosin light chain, tropomyosin, filamin and vinculin) reacted more or less equally with their respective antibodies in all the embedding media, including those cured at 60°C. One antibody (anti-light meromyosin) reacted well only with polyvinylalcohol-embedded tissue. In contrast to the relative invariance of antibody reactivity between media clear differences in the preservation of ultrastructural integrity were observed. Embedding in polyvinylalcohol (dried at 60°C) and in Lowicryl (cured at –35°C) resulted in superior preservation as compared to Lowicryl or LR White cured at 60°C. Examples of uitrastructural immunocytochemistry with the antibodies against filamin and myosin light chain, using the immunogold staining procedure are presented: the sites of localization by these antibodies were the same with all the media tried. The relative merits of the different methods are discussed.Abbreviations EGTA Ethyleneglycol-bis(-amino ethyl ether)N,N,N,N-tetra acetic acid - PIPES 1,4-Piperazinediethanesulfonic acid - LR London Resin     

Pre-embedding immunohistochemistry as an approach to high resolution antigen localization at the light microscopic level

Summary Pre-embedding immunohistochemistry with subsequent embedding in hydroxypropyl methacrylate enables one to obtain high resolution staining of antigens in 1 tissue sections. A routine method using formaldehyde fixation, methanol permeation, and an indirect method with fluoresceinlabeled second antibody is described. This method is compared with other pre-embedding staining procedures. To illustrate the method the mouse small intestine was chosen as a model and stained with antibodies to tubulin, actin, and fibronectin. Some anticipated and some unusual staining patterns were found.     

Science and Art in Preparing Tissues Embedded in Plastic for Light Microscopy, with Special Reference to Glycol Methacrylate, Glass Knives and Simple Stains

Plastic embedding preserves tissue structure much more faithfully than does paraffin. Acrylic polymerization is innocuous to dye-binding groups in sections. The water solubility of glycol methacrylate monomer and the hydrophilic properties of the polymer allow for convenience in dehydration and for versatility in staining sections. Five years of experience with glycol methacrylate (GMA) embedding for light microscopy is summarized. Methods for purifying GMA monomer are cited. Procedures for fixing, dehydrating, embedding, polymerizing, sectioning and staining, using GMA, are explained. A method is provided for making glass knives long enough to cut large blocks. Simple, reliable, quick staining methods are outlined. When compared with paraffin, GMA offers opportunities for simpler, quicker procedures and yields sections of superior quality, greater information content, and less distortion.     

Science and art in preparing tissues embedded in plastic for light microscopy, with special reference to glycol methacrylate, glass knives and simple stains.

Plastic embedding preserves tissue structure much more faithfully than does paraffin. Acrylic polymerization is innocuous to dye-binding groups in sections. The water solubility of glycol methacrylate monomer and the hydrophilic properties of the polymer allow for convenience in dehydration and for versatility in staining sections. Five years of experience with glycol methacrylate (GMA) embedding for light microscopy is summarized. Methods for purifying GMA monomer are cited. Procedures for fixing, dehydrating, embedding, polymerizing, sectioning and staining, using GMA, are explained. A method is provided for making glass knives long enough to cut large blocks. Simple, reliable, quick staining methods are outlined. When compared with paraffin, GMA offers opportunities for simpler, quicker procedures and yields sections of superior quality, greater information content, and less distortion.     

An easy method for cutting and fluorescent staining of thin roots

Background and Aims

Cutting plant material is essential for observing internal structures and may be difficult for various reasons. Most fixation agents such as aldehydes, as well as embedding resins, do not allow subsequent use of fluorescent staining and make material too soft to make good-quality hand-sections. Moreover, cutting thin roots can be very difficult and time consuming. A new, fast and effective method to provide good-quality sections and fluorescent staining of fresh or fixed root samples, including those of very thin roots (such as Arabidopsis or Noccaea), is described here.

Methods

To overcome the above-mentioned difficulties the following procedure is proposed: fixation in methanol (when fresh material cannot be used) followed by en bloc staining with toluidine blue, embedding in 6 % agarose, preparation of free-hand sections of embedded material, staining with fluorescent dye, and observation in a microscope under UV light.

Key Results

Despite eventual slight deformation of primary cell walls (depending on the species and root developmental stage), this method allows effective observation of different structures such as ontogenetic changes of cells along the root axis, e.g. development of xylem elements, deposition of Casparian bands and suberin lamellae in endodermis or exodermis or peri-endodermal thickenings in Noccaea roots.

Conclusions

This method provides good-quality sections and allows relatively rapid detection of cell-wall modifications. Also important is the possibility of using this method for free-hand cutting of extremely thin roots such as those of Arabidopsis.     

Light and electron microscopical combined staining by immunohistochemical and enzyme histochemical methods using rat prolactin-secreting pituitary tumours

Summary Combined immunohistochemical staining (IHCS) and enzyme histochemical staining (EHCS) methods for light microscopy (LM) and electron microscopy (EM) are reported, using oestrogeninduced rat pituitary tumours. For LM, combined staining for alkaline phosphatase and acid phosphatase by EHCS, using the azo dye method, and for prolactin and ACTH by IHCS, using the enzyme-labelled antibody method, gave the best results on 1 m glycol methacrylate sections. For EM, combined staining by EHCS on 30 m tissue sections followed by IHCS for prolactin on ultrathin Epon sections (enzyme-labelled antibody method) provided acceptable results. By these combined staining methods, the neoplastic prolactin cells were shown to have close affinity to rich alkaline phosphatase-positive capillaries and to possess an alkaline phosphatase-positive cell membrane. Furthermore, they revealed acid phosphatase-positive lysosomal and secretory granules. These combined staining methods may be valuable in studies on the actual functional status of cells.     

Light and electron microscopical demonstration of concanavalin A and wheat-germ agglutinin binding sites by use of antibodies against the lectin or its label (peroxidase)

Summary Three straining protocols for the ultrastructural visualization of concanavalin A (ConA) and wheat germ agglutinin (WGA) binding sites were applied to samples of nervous tissue embedded in Lowicryl K4M. The hypothalamo-neurohypophysial neurosecretory system was chosen for this investigation because it has two major neuronal populations, one secreting vasopressin, whose precursor is glycosylated, and the other secreting oxytocin whose precursor form is not glycosylated.The series of incubations of the tissue sections for the three protocols were: Protocol 1: i) non labeled ConA or WGA; ii) ConA or WGA antibody; iii) protein A-gold; Protocol 2: i) pre-prepared WGA-anti-WGA complex; ii) protein A-gold; Protocol 3: i) peroxidase-labeled ConA or WGA; ii) anti-peroxidase; iii) protein A-gold.The three methods allowed to detect fine differences in the distribution of sugar residues. This, in turn, made it possible to distinguish vasopressin granules containing precursor forms from those containing processed precursor.At the light microscopic level the three methods were successfully applied to paraffin and 1-m methacrylate sections by using a second antibody, PAP complex and the diaminobenzidine reaction.Supported by Grant I/63 476 from Stiftung Volkswagenwerk, Federal Republic of Germany and Grant S-85-39 from Dirección de Investigaciones, Universidad Austral de Chile. The authors wish to acknowledge the technical help of Genaro Alvial and Elizabeth     

A methacrylate embedding technique for combined autoradiography and acid phosphatase histochemistry

Summary A method is described that enables the simultaneous application of autoradiography and histochemistry in tissue sections prepared using a hydroxyethyl methacrylate (HEMA) embedding medium. A novel fixation regime, using a 19 v/v mixture of acetone and 10% neutral buffered formalin, improves section quality, histological staining and reduces tissue and cell shrinkage. The combined localization of [6-³H] thymidine incorporation and acid phosphatase in mouse thymus, duodenum, human stomach biopsy, earthworm and Walker tumour is described and counts of macrophages, phagocytosed cells, pyknotic cells, mitotic figures and thymidine-incorporating cells from young and old mouse thymus are presented.     

THE LOCALIZATION OF ACID PHOSPHATASE IN RAT LIVER CELLS AS REVEALED BY COMBINED CYTOCHEMICAL STAINING AND ELECTRON MICROSCOPY

Discrete localization of stain in pericanalicular granules was found in 10 µ frozen sections of formol-phosphate-sucrose-fixed liver stained by the Gomori acid phosphatase technique and examined in the light microscope. The staining patterns, before and after treatment with Triton X-100 and lecithinase, were identical with those previously reported for formol-calcium-fixed material treated in the same way, and it can be assumed that the stained granules are identical with "lysosomes." Examination in the light microscope of the staining patterns and lead penetration in fixed blocks and slices of various dimensions showed nuclear staining and other artefacts to be present, produced by the different rates of penetration of the various components of the staining medium into the tissue. A uniform pericanalicular staining pattern could be obtained, however, with slices not more than 50 µ thick, into which the staining medium could penetrate rapidly from both faces. The staining pattern produced in 50 µ slices was the same both at pH 5.0 and pH 6.2, and was not altered by subsequent embedding of the stained material in butyl methacrylate. Electron microscopy showed the fine structure of fixed 50 µ frozen slices to be well preserved, but it deteriorated badly when they were incubated in the normal Gomori medium at pH 5.0 before postfixing in osmium tetroxide. After incubation in the Gomori medium at pH 6.2, the detailed morphology was substantially maintained. In both cases lead phosphate, the reaction product, was found in the pericanalicular regions of the cell, but only in the vacuolated dense bodies and never in the microbodies. Not every vacuolated dense body contained lead, and stained and unstained bodies were sometimes seen adjacent to each other. This heterogeneous distribution of stain within a morphologically homogeneous group of particles is consistent with de Duve's suggestion (9) that there is a heterogeneous distribution of enzymes within the lysosome population. It is concluded from these investigations that the vacuolated dense bodies seen in the electron microscope are the morphological counterparts of the "lysosomes" defined biochemically by de Duve.     

Cerium as amplifying agent--an improved cerium-perhydroxide-DAB-nickel (Ce/Ce-H2O2-DAB-Ni) method for the visualization of cerium phosphate in resin sections

A new visualization (Ce/Ce-H2O2-DAB-Ni) procedure for cerium (Ce III) phosphate in semithin and ultrathin plastic sections (Epon 812, Lowicryl K4M, glycol methacrylate) of rat kidney tissues that had been incubated before embedding for the demonstration of phosphatases (alkaline and acid phosphatase, 5(1)-nucleotidase, Mg-dependent ATPase) is described. For this purpose the hydrophobic Epon resin was removed in NaOH-ethanol solution, whereas the hydrophilic Lowicryl and methacrylate sections did not required any etching. The primary reaction product Ce III-phosphate was amplified in a Ce III-citrate solution, subsequently oxidized with H2O2 and then visualized in a H2O2 containing DAB-nickel medium (Ce IV-perhydroxy induced DAB polymerization principle). The method yielded a very clear localization of enzyme activity. The final reaction product (DAB-nickel polymers) in 0.5 - 2.0 microns semithin sections is blue-black; the background staining is completely prevented. An increase of the staining contrast was obtained by posttreatment with OsO4 (osmium black formation). Furthermore, the enzyme reaction product could be demonstrated in 40 nm thick ultrathin sections by silver intensification, which utilized the high argyrophilia of the polymerized DAB-nickel complexes. This procedure replaces the earlier published technique.     

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.     

植入了骨修复材料的小型猪腰椎椎体不脱钙病理组织切片制备方法

摘要 目的：建立植入了骨修复材料小型猪腰椎椎体骨组织标本的不脱钙病理组织切片制备方法。方法：将含骨修复材料的腰椎椎体骨组织标本进行分割暴露组织切面,梯度浓度乙醇脱水后经Technovit 7200 VLC光聚树脂浸润,经黄蓝光共同辐照进行光聚合包埋,借助硬组织病理切磨系统制备含骨修复材料不脱钙病理组织切片。结果：结果显示通过上述方法制备的病理组织切片,经苏木精-伊红（HE）染色及甲苯胺蓝染色后光学显微镜下观察能较好地显示骨的各种组织细胞结构,可清晰的观察到骨小梁的走向及连接情况。结论：研究建立了含骨修复材料骨组织标本病理组织切片制备方法,实现了含骨修复材料不脱钙骨组织病理切片的制备,经病理染色后实现了带植入物的组织学观察,为生物材料及医疗器械动物试验研究提供了新的病理检测手段及组织学评价途径。     

gamma-Glutamyl transpeptidase demonstrated in tissue sections embedded in glycol methacrylate resin

Summary A method is described for the histochemical demonstration of -glutamyl transpeptidase in tissue sections embedded in glycol methacrylate at low temperature. Enzyme activity was preserved by a short (3 h) fixation of tissue in 4% paraformaldehyde at 4° C prior to embedding at 4° C. Tissue embedded in glycol methacrylate combined good morphology with accurate enzyme localization. Blocks of the embedded tissue could be stored at room temperature for at least 3 months without loss of enzyme activity. The resin is non-fluorescent, allowing the use of the fluorescent coupling agent 5-nitrosalicylaldehyde to visualize the reaction product.     

Specific demonstration of ribonucleic acid by chemical bromination and immunohistochemistry

In this report we describe a specific staining procedure for detection of ribonucleic acid (RNA), based on bromination of uracil and subsequent immunohistochemical visualization of 5-bromouracil in RNA. This method is applicable for both cryostat and glycol methacrylate (GMA)-embedded sections. Cryostat sections must be fixed in formaldehyde, whereas tissue pieces to be embedded in GMA are fixed in cold acetone. Before bromination, sections must be treated with trypsin. Bromination was performed in a solution of bromine in potassium bromide. After bromination, excess bromine was removed with sodium bisulfite. The monoclonal antibody MoBu-1 specifically bound to brominated RNA. Ribonuclease digestion, in contrast to deoxyribonuclease digestion, abolished staining. This method makes possible precise localization of RNA, especially well demonstrated in plastic-embedded sections.     

Ultrastructural demonstration of cartilage acid glycosaminoglycans

Synopsis A method for the demonstration of cartilage acid glycosaminoglycans by light and electron microscopy is described. Rabbit ear cartilage was fixed in cacodylate buffered 2.5% methanol-free formaldehyde with 0.001 M Ruthenium Red andp-chloromercuribenzoate (PCMB). Dehydration was carried out in ethylene glycol followed by embedding in the water-soluble glycol methacrylate (GMA). In some experiments unfixed cartilage was rapidly dehydrated. Sections, 1 thick, and ultrathin sections from the same blocks were stained with 0.001 M Ruthenium Red. Semi-thin sections from cartilage fixed without heavy metal additives were, in addition, stained with the acidophilic fluorochrome Berberine sulphate. It was found that Ruthenium Red intensely stained the same pericellular zone that stained metachromatically with Toluidine Blue or fluoresced after staining with Berberine sulphate. Prior treatment with 0.05% cetylpyridinium chloride entirely blocked the three reactions. Previous digestion with 0.2 mg hyaluronidase/ml for 30 min at 37°C led to the abolition of the fluorescence reaction with Berberine sulphate. It is concluded that Ruthenium Red selectively stains cartilage acid glycosaminoglycans. With the electron microscope the pericellular zones were found to be built up of a three-dimensional branched meshwork of fibrils covered with a mantle of electron-dense material, presumably acid glycosaminoglycans bound to Ruthenium Red.     

Embedding Plant Tissue with Plastic Using High Pressure: A New Method for Light and Electron Microscopy

An embedding technique has been developed to overcome difficulties that confront light and electron microscopists working with so-called “hard-to-embed” plant tissue. The method was originally described for freeze-dried material. It uses a modified Quickfit Rotaflo Valve and low heat to generate high pressure to aid in the infiltration and embedding of tissue with propylene oxide and plastic. The technique is not too cumbersome and requires 6 days from the dehydration step to the end of the polymerization process. Thick sections (1-2 μm) obtained from material prepared by this method stain readily with toluidine blue, and thin sections for the electron microscope stain satisfactorily following standard treatment with uranyl acetate and lead citrate. The thin sections are stable under the beam of the electron microscope. Results indicate that the quality of tissue preservation with this high pressure embedding technique is as good as that observed using standard embedding methods for electron microscopy.     

Postembedding immunohistochemical demonstration of antigen in experimental polyarthritis using plastic embedded whole joints

Summary A method is presented for the immunohistochemical demonstration of antigens in whole undecalcified joints of small laboratory animals. With this method of tissue preparation, involving embedding in a medium mainly based on 2-hydroxyethyl methacrylate, preservation of antigenicity is satisfactory. Antigens can be demonstrated in 2 m sections by either immunofluorescence or immunoperoxidase and an indirect technique. Therefore in addition to the morphological analysis of joint alterations in experimental polyarthritis, there is now an opportunity to trace the inciting antigen and to study in parallel the enzymatic equipment of the cells involved, using consecutive sections from a single block of tissue.Supported by Deutsche Forschungsgemeinschaft, Sonderforschungsbereich 54, C2     

N-butyl Methacrylate and Paraffin as an Embedding Medium for Light Microscopy

A method of tissue embedding using n-butyl methacrylate and paraffin is described. Following alcohol dehydration and infiltration with the methacrylate monomer, tissues are embedded in gelatin capsules in a mixture consisting of 3.5 g of paraffin for each 10 ml of methacrylate. Benzoyl peroxide (0.2 g for each 10 ml of monomer) is added as the catalyst and the methacrylate polymerized in a 50 C oven for 18-24 h. Following polymerization the block is trimmed and embedded in paraffin to provide a firm support during sectioning. A water trough attached to the microtome knife is essential to facilitate the handling of sections and ribbons. For serial sections a mixture of equal weights of beeswax and paraffin is used to make the sections adhere to each other. Usual staining procedures can be used since the embedding medium is readily soluble in xylene.     

A simplified technique for low temperature methyl methacrylate embedding

A simplified method for low temperature methyl methacrylate embedding with inhibited methyl methacrylate monomer is demonstrated using proper concentrations of benzoyl peroxide and N,N-dimethylaniline. The polymerized tissue blocks cut well and the tissue sections obtained show excellent acid phosphatase activity when demonstrated with the newly improved technique and Goldner's staining. Likewise, double tetracycline labels are well revealed by fluorescence microscopy.