Freeze-drying of bone tissue: immunocytochemistry and enzyme histochemistry on paraffin embedded and low-temperature resin embedded specimens

A simple protocol of tissue preparation was sought, which would enable marker enzymes of bone cells and extracellular matrix antigens to be localized in the same tissue section with high optical resolution. For this purpose, snap-frozen samples of rat fetal skeletal tissues were dried in a FDU 010 freeze-drying unit (Balzers) for 8–12 h at –50 to –40°C and 0.02 bar. Freeze-dried tissues were either vacuum-infiltrated at 45°C and embedded undemineralized in Paraplast, or vacuum-infiltrated overnight at 4°C and embedded undemineralized in glycol methacrylate. These procedures enabled enzyme cytochemistry for alkaline phosphatase and tartrate-resistant acid phosphatase, and immunocytochemical staining for collagen types I, III, and laminin to be performed on the same sections. No pretreatment of the sections was necessary to reveal collagen antigenicity. This study reveals the possibility of complementing immunocytochemical studies of extracellular matrix with enzyme cytochemistry and, above all, with the excellent tissue preservation and high resolution afforded by plastic embedding.     

Immunoelectron microscopy of tissues processed by rapid freezing and freeze-substitution fixation without chemical fixatives: application to catalase in rat liver hepatocytes

We report on the immunohistochemical demonstration of an enzyme at the electron microscopic level using specimens processed by rapid freezing and the freeze-substitution technique without the use of any chemical fixatives. Fresh rat liver tissue blocks were rapidly frozen by the metal contact method using liquid nitrogen, and were freeze-substituted with acetone without any chemical fixatives at -80 degrees C. Some of the freeze-substituted tissues were embedded in Lowicryl K4M at -20 degrees C; the others were returned to room temperature and embedded in Epok 812 at 60 degrees C. Ultra-thin sections were stained using anti-peroxisomal catalase antibody by the protein A-gold technique. The ultrastructure of the hepatocytes was very well preserved compared with that of conventionally processed tissues. The labeling for catalase was confined to peroxisomes. When the labeling density was compared among freeze-substituted tissues and conventionally processed tissues, that of freeze-substituted and Lowicryl K4M-embedded tissues was the most intense. These results show the usefulness of freeze-substituted tissues for immunohistochemical analysis of cell organelles.     

Enzyme histochemical demonstration of alkaline phosphatase activity in plastic-embedded tissues using a Gomori-based cerium-DAB technique

We describe a new method for light microscopic demonstration of alkaline phosphatase (ALP) activity in plastic-embedded sections. Rat tissues were fixed in acetone (-20 degrees C), infiltrated in glycol methacrylate (GMA), and embedded at 0 degrees C. Sections were cut at 1 and 2 microns, dried at room temperature, and incubated in the conventional Gomori medium. Cerium chloride was used to convert calcium phosphate into cerium phosphate, which was subsequently converted into cerium perhydroxide. The slight yellow precipitate of cerium perhydroxide was amplified using 3,3'-diaminobenzidine tetrahydrochloride (DAB). For comparison, tissue sections were processed according to the calcium-cobalt method. The method described combines exact localization of ALP activity with optimal preservation of tissue morphology.     

ULTRATHIN FROZEN SECTIONS : II. Demonstration of Enzymic Activity

Endogenous enzyme activity can be readily and routinely demonstrated in ultrathin, frozen sections for electron microscopy. The procedure employed to obtain the best structural preservation as well as enzyme activity in thin sections involved fixation in glutaraldehyde, embedding in thiolated gelatin or pure gelatin, partial dehydration in glycerol, and sectioning in a cryostat at -35°C with a slightly modified Porter-Blum microtome on which the tissue is maintained at -70°C and the knife at -23°C. Kidney cortex was used as test tissue, but a few other organs were occasionally used. Thin sections were floated on the surface of several incubation media routinely employed for enzyme cytochemistry. Positive, specific reactions were obtained for alkaline phosphatase in kidney brush border, for adenosine triphosphatase in brush border and in basal membranes of distal tubules, for acid phosphatase and esterase in lysosomes, and for NADH diaphorase in mitochondria. Mitochondrial ATPase was sporadically evident only in the distal tubule of the kidney. Localizations of enzyme activity reported by other technical approaches were confirmed and in some cases somewhat improved.     

Immunocytochemical localization of protein antigens in large sections of tissues embedded in water-soluble embedding media

JB4 and Immunobed are water-soluble embedding media used for embedding large blocks of tissue. Immunobed was specifically designed for immunocytochemistry because ethanol extraction of an additive in the monomer of the resin is reported to render tissue sections permeable to immunoglobulins. We have modified the manufacturer's protocol to accomplish localization of two protein antigens in tissues embedded in either JB4 or Immunobed. Luteinizing hormone-beta (LH beta) was localized in sections of rat and bovine pituitary tissues and bovine placental lactogen (bPL) was localized in sections of placentomes from bovine placentas. Sections received one of the following pre-treatments: absolute EtOH; NaHCO3 buffer, pH 6-10; EtOH followed by NaHCO3 buffer; one of several enzymes; EtOH followed by enzyme; NaHCO3 buffer followed by enzyme. Anti-LH beta stained only pituitary gonadotrophs and anti-bPL stained only placental binucleate cells, as assessed by absorption controls. Pre-treatment with enzyme was required for staining of sections, but an alkaline pH change (NaHCO3) had little or no effect. Ethanol pretreatment had little or no effect alone or in conjunction with NaHCO3 or enzyme. Sections were sufficiently thin (1.5 micron) to afford resolution of structure, but suitably large (approximately 2 cm2) to minimize problems of sampling.     

Immunocytochemical localization of amylase in gerbil salivary gland acinar cells processed by rapid freezing and freeze-substitution fixation

We examined the immunocytochemical localization of amylase in cryofixed serous acinar cells of gerbil major salivary glands by indirect immunostaining, using anti-gerbil parotid amylase antibody and protein A-gold complex. Fresh tissue blocks were quickly frozen by the metal-contact method, using liquid helium, and were freeze-substituted with either osmium-acetone solution or glutaraldehyde-containing acetone. They were then embedded in an epoxy resin mixture which was polymerized at 60 degrees C. Some tissue blocks substituted with aldehyde-acetone solution were embedded in Lowicryl K4M, polymerized at -30 degrees C. Thin sections of epoxy resin-embedded materials were treated with an oxidizing agent before immunostaining. The labeling density on the materials processed by various protocols for preparatory procedures was quantitatively compared to examine the usefulness of application of cryofixation to immunocytochemistry. The central dense core of heterogeneous secretory granules in the serous acinar cells of the parotid and sublingual glands was heavily labeled with immunogold, regardless of substitution media and embedding resins employed. The immunolabeling pattern clearly distinguished between the dense core and the surrounding matrix. Labeling density in the cryofixed materials was about 1.5 times greater than in those processed by conventional chemical fixation. Seromucous secretory granules in the submandibular gland acinar cells were only faintly labeled. The results obtained indicate that application of immunostaining to quick-frozen, substitution-fixed tissues is useful for high-resolution immunocytochemistry.     

Light and electron microscopical postembedding lectin histochemistry for WGA-binding sites in the renal cortex of the mouse embedded in polyhydroxy aromatic resins LR-White and LR-Gold

This work describes a technique which permits study of the postembedding lectin histochemistry for WGA-binding sites at the light and electron microscopical level on the same resin embedded tissue without removing or etching of the resin. Unfixed kidney pieces or kidney pieces fixed in 4% formaldehyde were embedded in the hydrophilic polyhydroxy aromatic resins LR-Gold and LR-White, following dehydration in up to 70% ethanol, 90% ethanol or 100% ethanol. LR-Gold was cryopolymerised at -25 degrees C using the light sensitive initiator benzil, whereas LR-White was heat-cured at +50 degrees C. The localisation of WGA-binding sites at the light microscopical level was investigated using FITC-labelled WGA. The ultrastructural localisation of WGA-binding sites was performed using 15 nm gold-labelled WGA. The best fluorescence staining results were obtained on fixed or unfixed tissue dehydrated in up to 70% ethanol and embedded in LR-Gold. At the ultrastructural level, the best staining results for WGA-binding sites were seen on tissue sections, dehydrated in up to 90% ethanol prior to embedding in LR-Gold.     

Improved Microradiographic Contrast for Bone Stain-Historadiography

Microradiographs of 5-micron sections of methyl methacrylate embedded undemineralized bone show poor resolution, but prestaining with silver nitrate increases the radioopacity of the calcified tissues to soft x-rays without masking regional differences in microscopic mineralization. Identical results are achieved using aqueous (pH 5.8 and 7.5) or ammoniacal solutions (pH 7.9). Atomic absorption spectrometry detected no loss of calcium from the sections during staining. Osteoid in plastic-embedded bone is not rendered radiopaque by this technique even after prolonged staining times (5 min-2 hr).     

Histochemical studies of acid and alkaline phosphatases in rat tooth germs with undecalcified resin-embedded specimens.

A novel technique for the histochemical demonstration of acid phosphatase (AcPase) and alkaline phosphatase (AkPase) in hard tissues has been proposed. Fresh, unfixed, undecalcified samples of rat tooth germs and surrounding structures were embedded in LR Gold resin at -20 degrees C. Sections of 2 microns were taken and subsequently processed for enzyme histochemistry. AkPase reaction product appeared as strong linear staining outlining cell boundaries and was present in the enamel organ, dental pulp, and osteoblast cells. Tartrate-resistant AcPase staining was seen exclusively in the osteoclasts of developing alveolar bone. Our results demonstrated that the use of unfixed, undecalcified LR Gold resin-embedded specimens for histochemistry is a novel technique which may be of value for certain studies when decalcification of specimens is undesirable. The technique appears to give good preservation of enzyme activity combined with the ability to prepare sections with excellent morphological detail.     

Improved microradiographic contrast for bone stain-historadiography.

Microradiographs of 5-micron sections of methyl methacrylate embedded undemineralized bone show poor resolution, but prestaining with silver nitrate increases the radioopacity of the calcified tissues to soft x-rays without masking regional differences in microscopic mineralization. Identical results are achieved using aqueous (pH 5.8 and 7.5) or ammoniacal solutions (pH 7.9). Atomic absorption spectrometry detected no loss of calcium from the sections during staining. Osteoid in plastic-embedded bone is not rendered radiopaque by this technique even after prolonged staining times (5 min-2 hr).     

Solochrome Cyanine R As An Indicator Dye of Bone Morphology

Sections of undemineralized bone embedded in a polyester resin and cut at 6 μ are stained for 10 min, without removal of the embedding matrix, in an aqueous solution composed of Solochrome cyanine R, 1 gin; glacial acetic acid, 2 ml; and distilled water, 98 ml. A pH about 2 is obtained by the acetic acid. The sections are washed and differentiated in tap water at 30 C, dehydrated in ascending alcohols, cleared and mounted in synthetic resin. “Young osteoid” stains light orange and, in the rest of an osteoid seam, two types of lamellae can be distinguished: one blue layer of ground substance or collagen and one orange layer of fibrillar collagen. The “calcification front” is sharply demarcated by its dark blue color.     

Ca-ATPase and ALPase activities at the initial calcification sites of dentin and enamel in the rat incisor

Summary Enzymatic activities of calcium-magnesium dependent adenosine triphosphatase (Ca-ATPase) and nonspecific alkaline phosphatase (ALPase) were localized at the initial calcification sites of dentin and enamel of rat incisor teeth using electron-microscopic cytochemistry.Ca-ATPase was localized in the Golgi cisternae, cytoplasmic vesicles and along the outer surface of the presecretory and secretory ameloblasts, whereas it was totally absent from the odontoblasts in the pulp. Inversely, ALPase reaction was localized along the outer surface of the odontoblasts, but almost completely absent from the ameloblasts.Diffuse extracellular reactions of both enzymes were distributed throughout the unmineralized fibrous matrix of mantle dentin in which a large number of matrix vesicles were scattered. Both Ca-ATPase and ALPase reactions, which appeared in the matrix vesicles in the process of formation of mantle dentin, became most conspicuous at the site of initial dentin calcification. At this stage, an intense Ca-ATPase reaction also appeared along some of the collagen fibrils adjacent to the reactive matrix vesicles. No ALPase reaction was localized along these Ca-ATPase reactive collagen fibrils.Our observations suggest strongly that Ca-ATPase in the matrix vesicles originates from the inner enamel epithelium and/or preameloblasts whereas ALPase originates from the odontoblasts in the pulp. The importance of the coexistence of both enzymes for the control of initial calcification of dental hard tissues is suggested.     

Decreased collagen stability as a response to the loss of structural integrity of thyroid cartilage

The thermal behavior, birefringence properties, and the biochemical composition of thyroid cartilage tissues have been studied. The hyaline cartilage, which was visualized as a quasi-isotropic medium, was composed of type II collagen, which did not denature at temperatures up to 100 degrees C. However, in hyaline cartilage digested by trypsin, the denaturation of collagen occured at 60 degrees C. Collagen fibers in the perichondrium were composed of type I and II collagen and formed a highly organized anisotropic structure (birefringence about 4.75 x 10(-3)) with a melting temperature of about 65 degrees C. The temperature of collagen denaturation in perichondrium in the whole system perichondrium-hyaline cartilage increased up to 75 degrees C, indicating the immobilization of perichondrium collagen by the extracellular matrix of the hyaline constituent.     

Human specific anti-type IV collagen monoclonal antibodies, characterization and immunohistochemical application

This paper describes two new monoclonal antibodies reactive with human specific type IV collagen epitopes in frozen as well as routinely fixed and processed tissue sections. The antibodies (1042 and 1043) were raised against human placental type IV collagen and were shown by immunoblotting and ELISA tests to react exclusively with type IV collagen determinants. Extensive immunohistochemical survey studies on panels of tissues from various species, using unfixed cryostat sections, demonstrated that antibody 1042 reacted only with human type IV collagen whereas antibody 1043 in addition reacted with rabbit type IV collagen. All tissues showed homogeneous staining of the basement membrane, indicating that the detected epitopes did not show organ-specific distribution. Tissue processing protocols for using these monoclonal antibodies on routinely processed paraffin embedded tissues were developed. It was found that whereas polyclonal anti-type IV collage antisera required pepsin digestion, our monoclonal antibodies required pronase or papain digestion to restore type IV collagen immunoreactivity in paraffin sections. It is concluded that these monoclonal anti-type IV collagen antibodies detect species specific epitopes which can be detected in routinely processed paraffin embedded tissues after appropriate enzyme pretreatment.     

Comparison of extracellular matrix-degrading activities between 64-kDa and 90-kDa gelatinases purified in inhibitor-free forms from human schwannoma cells.

Two kinds of gelatinases (or type IV collagenases), 90-kDa and 64-kDa gelatinases, were purified in a tissue inhibitor of metalloproteinases (TIMP)- or TIMP-2-free form from the serum-free conditioned medium of human schwannoma YST-3 cells, and their activities on extracellular matrix proteins were compared. Sequential chromatographies on a gelatin-Sepharose column, an LCA-agarose column, and a gel filtration column in the presence of 5 M urea yielded 600 micrograms of the 64-kDa enzyme and 45 micrograms of the 90-kDa enzyme from 2.8 liters of the conditioned medium. The purified enzymes showed high gelatinolytic activities without activation by p-aminophenyl mercuric acetate (APMA), indicating that 5 M urea used in the final chromatography not only dissociated the inhibitors from the progelatinases but also activated the proenzymes. The inhibitor-free gelatinases showed a much higher activity than the APMA-activated inhibitor-bound enzymes. The specific activity of the 90-kDa enzyme was nearly 25 times higher than that of the 64-kDa enzyme. The 90-kDa gelatinase hydrolyzed type I collagen as well as native and pepsin-treated type IV collagens at 30 degrees C, while at 37 degrees C it potently hydrolyzed types I, III, and IV collagens but not fibronectin or laminin. The 64-kDa gelatinase showed a similar substrate specificity to that of the 90-kDa enzyme, except that it did not hydrolyze type I collagen and native type IV collagen at 30 degrees C.     

Staining of different endocrine cells with hydrochloric acid-toluidine blue in Epon embedded rat tissue

The usual HCl-toluidine blue staining of different endocrine cells is applicable to paraffin embedded material. A modification for Epon embedded tissue suitable for consecutive light and electron microscopic studies is described which makes it possible to find the same stained cell, both in a semithin section and in subsequent ultrathin sections. This method facilitates the search for scattered specific endocrine cells. Without removing the resin, sections of Epon embedded tissues were hydrolyzed for 17 hr in 1% HCl at 65 C and stained for 2 hr in 0.1% toluidine blue in McIlvaine buffer, pH 5.8. The following cells were stained: C cells in thyroid glands; A and D cells in pancreatic islets; B cells in anterior pituitary; G, D and Ec cells in the gastrointestinal tract; Ad cells of the adrenal medulla.     

The application of lipid-soluble stains in plastic-embedded sections

The present study was designed to develop a routine method for direct demonstration and precise localization of lipid substances in tissue sections. A panel of lipid-rich tissues was fixed in 4% buffered formaldehyde, infiltrated, and embedded in the water-soluble plastics Technovit 7100, EFL-67, and JB-4. The use of alcohol containing fluids was avoided. Staining with the lipid-soluble dyes Sudan Black B and Oil Red O revealed excellent preservation of tissue lipids in Technovit 7100 embedded sections when compared with cryostat sections of the same tissue specimens. Lipid preservation in EFL-67 and JB-4 embedded sections was inconsistent, even when infiltration and polymerization procedures were performed at 4 degrees C. Combination of lipid-soluble dyes with the periodic acid Schiff, Jones' methenamine silver, or Gomori' reticulin method allowed for an exact localization of lipids in high-quality Technovit 7100 embedded sections. The procedure herein is easily applicable in routine histopathology practice.     

Lectin--digoxigenin conjugates: a new hapten system for glycoconjugate cytochemistry.

We report the use of a novel hapten system for lectin cytochemistry. Various lectins conjugated to the steroid hapten digoxigenin (DIG) and monospecific anti-digoxigenin antibodies were applied for the light and electron microscopic detection of glycoconjugates in tissue sections. Both IgG and Fab' anti-DIG antibodies were complexed to particles of colloidal gold and compared to commercially available alkaline phosphatase and horseradish peroxidase conjugated Fab' as general second step reagents. The three different markers performed equally well on paraffin sections whereas the gold-labeled antibodies were superior reagents for semithin and ultrathin sections of Lowicryl K4M embedded tissues. In conjunction with the latter marker, no pretreatment to abolish endogenous enzyme activity was necessary. At the light microscope level, gold signal amplification by the photochemical silver reaction was required. DIG, in contrast to biotin, does not occur in animal tissues thus eliminating the need for blocking reactions prior to lectin incubation. Compared to affinity techniques using glycoprotein-gold complexes as second step reagent the DIG hapten system required smaller amounts of lectins. The staining patterns were indistinguishable from those obtained in other lectin-gold techniques and the specificity of the labeling could be demonstrated in sugar inhibition tests.     

Lectin — digoxigenin conjugates: a new hapten system for glycoconjugate cytochemistry

Summary We report the use of a novel hapten system for lectin cytochemistry. Various lectins conjugated to the steroid hapten digoxigenin (DIG) and monospecific anti-digoxigenin antibodies were applied for the light and electron microscopic detection of glycoconjugates in tissue sections. Both IgG and Fab' anti-DIG antibodies were complexed to particles of colloidal gold and compared to commercially available alkaline phosphatase and horseradish peroxidase conjugated Fab' as general second step reagents. The three different markers performed equally well on paraffin sections whereas the gold-labeled antibodies were superior reagents for semithin and ultrathin sections of Lowicryl K4M embedded tissues. In conjunction with the latter marker, no pretreatment to abolish endogenous enzyme activity was necessary. At the light microscope level, gold signal amplification by the photochemical silver reaction was required. DIG, in contrast to biotin, does not occur in animal tissues thus eliminating the need for blocking reactions prior to lectin incubation. Compared to affinity techniques using glycoprotein-gold complexes as second step reagent the DIG hapten system required smaller amounts of lectins. The staining patterns were indistinguishable from those obtained in other lectin-gold techniques and the specificity of the labeling could be demonstrated in sugar inhibition tests.     

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.