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.     

Thermoluminescence properties of the isolated photosystem two reaction centre

Formation of thermoluminescence signals is characteristics of energy- and charge storage in Photosystem II. In isolated D1/D2/cytochrome b-559 Photosystem II reaction centre preparation four thermoluminescence components were found. These appear at -180 (Z band), between -80 and -50 (Z_v band), at -30 and at +35°C. The Z band arises from pigment molecules but not correlated with photosynthetic activity. The Z_v and -30°C bands arise from the recombination of charge pairs stabilized in the Photosystem II reaction centre complex. The +35°C band probably corresponds to the artefact glow peak resulting from a pigment-protein-detergent interaction in subchloroplast preparations (Rózsa Zs, Droppa M and Horváth G (1989) Biochim Biophys Acta 973, 350–353).Abbreviations Chl chlorophyll - Cyt cytochrome - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - D1 psbA gene product - D2 psbD gene product - P680 primary electron donor of PS II - Pheo pheophytin - PS II Photosystem II - Q_A primary quinone acceptor of PS II - Q_B secondary quinone acceptor of PS II - RC reaction centre of PS II - TL thermoluminescence     

Heterogeneity of catalase staining in human hepatocellular peroxisomes

Hepatocellular peroxisomes stained for catalase activity have different electron densities. When measured by scanning transmission electron microscopy, density is inversely linear to diameter. We investigated whether this phenomenon is the result of a staining artifact that reflects more efficient diffusion of substrate into smaller peroxisomes (higher surface-to-volume ratio), or of differences in endogenous enzymatic activity. Measurements of optical density show that the amount of reaction product is proportional to the diaminobenzidine concentration in the medium; this is not the case for H2O2. Modifying the concentration of both substrates does not alter the heterogeneous staining pattern. Heterogeneity persists when the reaction is slowed by inhibitors or when diffusion takes place before the reaction, and in preparations that have not been subjected to cytochemical staining. These data show that catalase activity is different in individual peroxisomes and that the staining differences are not a consequence of variations in substrate diffusion. Some implications of this conclusion are discussed.     

Identification of Spermatozoa in Criminological Investigations

Materials used for study were viral smears or ultra-thin sections containing viral cell inclusions. They were stained with the Feulgen reaction and other cytochemical procedures. Stained preparations were dried and then shadow-cast with metallic chromium for 30 seconds in a bell jar with a vacuum of at least 0.1 µ (10^?4mm.) of mercury, and placed at a shadowing angle of 10–12°. Shadow-cast preparations were cleared with xylene and mounted in Canada balsam. Dried smears or deparaffinized sections without staining were suited to this method also. A virus which stained indistinctly with cytochemical procedures alone could be adapted to visible light microscopy by shadowing, and in addition, used for observations on its chemical composition.     

Enhancement of the Affinity of Nucleoli and Chromosomes for Zinc by Treatment with Chromic Acid

Cultured mammalian cells and wet touch preparations from human organs were fixed for 10 min in 5:85:10 acetic-alcohol-formalin; placed in 5% aqueous CrO₃ for 30 min at 22-25 C; washed in running water 1 min; placed in 2 mM zinc acetate in 0.14 M veronal-acetate buffer, pH 6.5, at 37 C, 30 mm; rinsed 5 sec in 50% acetone; and stained 10 min in a solution dithizone. This results in selective staining of the nucleoli of interphase cells, and of the chromosomes of mitotic cells.     

In situ electron microscopic observation of negatively stained tissue culture cells contaminated with mycoplasmas

A simple, fast, and in situ method of detecting the inapparent infection of cultured cells with mycoplasmas is reported. Animal cells grown on Formvar-coated electron microscopic grids were directly fixed with glutaraldehyde, negatively stained with phosphotungstic acid and examined by transmission electron microscopy. Cells contaminated with mycoplasmas could be discriminated from uncontaminated cells. The micro-organisms in the negatively stained preparations corresponded with those revealed by thin sectioning, and the distribution of mycoplasmas in cultured cells coincided with those revealed by the Hoechst staining method. Most of the highly resolved mycoplasmas were polymorphic, and closely associated with host cells; often more than 500 organisms per host cell were seen.     

Long-term storage and regular repeated use of diluted antisera in glass staining jars for increased sensitivity, reproducibility, and convenience of single- and two-color light microscopic immunocytochemistry

A procedure is described for the dilution and storage of antisera in glass staining jars into which whole slides are immersed for incubation during light microscopic neuropeptide immunocytochemistry. Diluted antisera, stored at 4 degrees C and continuously reused, were found to be stable for long periods of time (to date over 3 years), and consistently yielded high quality staining in both single- and two-color immunoperoxidase staining. We found this procedure to be more convenient than conventional incubation procedures, allowing the more rapid processing of large numbers of slides and reducing the loss of slides due to technical errors. The consistency and reproducibility of day to day staining were also improved. The immersion of whole slides into the antisera permitted the use of long incubation times (up to 7 days) without the sections drying out, which in many cases substantially enhanced the sensitivity of the staining obtained. A procedure for two-color immunoperoxidase staining is described using diaminobenzidine for a brown color and alpha-naphthol/pyronin for a red/purple color. We found the alpha-naphthol/pyronin reaction superior to the more commonly used 4-chlornaphthol reaction as a second color. The two-color staining was found useful not only for demonstrating nerve cell bodies stained different colors, but also for staining nerve terminals one color that are around and contacting nerve cell bodies stained another color.     

Ethidium bromide- and propidium iodide-PTA staining of nucleic acids at the electron microscopic level

Ultra-thin sections of various tissues were stained with ethidium bromide or propidium iodide, two fluorescent markers widely used for quantitation of nucleic acids. The fluorochromes, tested at different concentrations, were then revealed by incubation of the sections with neutralized phosphotungstic acid. We showed that at the electron microscopic level only nucleic acid-containing structures are revealed. Chromatin, nucleolus, and ribosomes appear to be stained by the end-product of the reaction. Furthermore, controls with proteases and nucleases showed that the staining is related to the binding of the fluorochromes to DNA and RNA and to the subsequent detection of the dyes by neutralized PTA.     

A comparison of neuropeptide immunocytochemistry in fluid-fixed and freeze-dried brains

Summary Immunocytochemical staining of luteinizing hormone-releasing hormone (LHRH), somatostatin, and neurophysin was compared in rat brains fixed with 1) formalin, 2) Bouin's solution, 3) freeze-dried (FD), or 4) freeze-dried + paraformaldehyde vapor perfused (FDV). The distribution of LHRH fibers was similar in all preparations; however, beads of granular reaction product often appeared finer and more numerous in the median eminence of FD- and FDV brains. Positively stained LHRH perikarya were not observed in any of the preparations. In contrast, somatostatin-immunoreactive perikarya were present in the fluid-fixed and FD brains, although few were observed in FDV brains. Somatostatin-immunoreactive fibers were present in all preparations, but appeared most numerous in the median eminence of FD brains. Staining of neurophysin-containing perikarya and fibers was similar in all preparations. These observations suggest that the FD brain can provide a suitable tissue substrate for immunocytochemistry, demonstrating staining comparable to or surpassing that of more conventional preparations. However, staining of antigens in FD brain was not uniformly successful and may depend on stereochemical characteristics of each antigen as well as properties of the primary antisera used in the staining procedure.     

COMBINED CYTOCHEMICAL AND ELECTRON MICROSCOPIC DEMONSTRATION OF β-GLUCURONIDASE ACTIVITY IN RAT LIVER WITH THE USE OF A SIMULTANEOUS COUPLING AZO DYE TECHNIQUE

Rat liver was fixed in formal-cacodylate-sucrose and frozen sections were incubated in a simultaneous-coupling medium containing naphthol AS-BI glucuronide as substrate and hexazonium pararosanilin as the diazo reagent. By light microscopy, the sections demonstrated β-glucuronidase activity as red discrete granules in the pericanalicular cytoplasm and as a generalized cytoplasmic stain in the parenchymal cells. Brief treatment of sections in cold ethanol prior to incubation markedly enhanced the staining for the enzyme and made it possible to demonstrate sufficient amounts of the reaction product in sections embedded in epoxy resin following dehydration and propylene oxide treatment. Electron microscopy revealed that the reaction product was moderately electron opaque and deposited in greater amounts in the vacuolated dense bodies and occasionally in the dense bodies which did not show obvious vacuoles. In each dense body, the deposits occurred preferentially at the edge as well as in the area surrounding the vacuoles in the matrix. Control sections incubated in the presence of glucosaccharo-1:4-lactone were devoid of the reaction product. No deposits of the reaction product were found in the nucleus, mitochondria, or microbodies. The limitations of the present cytochemical technique for use in electron microscopy are briefly discussed.     

Evaluation of histochemical methods for the detection of intracytoplasmic mucin in serous effusions

We have studied 25 serous effusions containing definitive morphologic evidence of adenocarcinoma to evaluate the ability of two mucin stains (Mayer's mucicarmine, D-PAS) to detect intracytoplasmic mucin in both cytologic (cytospin) and corresponding histological (cell block) preparations. Mucicarmine stain was positive in six of 25 (24%) cytospins and 13 of 25 (52%) cell blocks. D-PAS was positive in 19 of 25 (76%) cytospins and 20 of 25 (80%) cell blocks. Eight cases were identified which showed mucicarmine positivity in the cell block but not the corresponding cytospin; prolonging incubation time resulted in a positive mucicarmine in cytospin preparations for seven of these cases. We conclude that: (i) D-PAS is a more sensitive stain for the detection of intracytoplasmic mucin in all preparations; (ii) mucicarmine shows preferential staining for cell blocks; (iii) alterations in the staining protocol may permit mucin detection by mucicarmine staining in cytologic preparations in a significant number of cases.     

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.     

ENZYME-LABELED ANTIBODIES FOR THE LIGHT AND ELECTRON MICROSCOPIC LOCALIZATION OF TISSUE ANTIGENS

Enzymes, either acid phosphatase or horseradish peroxidase, were conjugated to antibodies with bifunctional reagents. The conjugates, enzymatically and immunologically active, were employed in the immunohistochemical localization of tissue antigens utilizing the reaction product of the enzymatic reaction as the marker. Tissues reacted with acid phosphatase-labeled antibodies directed against basement membrane were stained for the enzyme with Gomori's method, and those reacted with peroxidase-labeled antibody were stained with Karnovsky's method. The reaction products of the enzymes localized in the basement membrane. Unlike the preparations of the fluorescent antibody technique, enzyme-labeled antibody preparations were permanent, could be observed with an ordinary microscope, and could be examined with the electron microscope. In the latter, specific localization of antibody occurred in the basement membrane and in the endoplasmic reticulum of cells known to synthesize basement membrane antigens. The method is sensitive because of the amplifying effect of the enzymatic activity. The ultrastructural preservation and localization were better with acid phosphatase-labeled antibody than with peroxidase-labeled antibody, but acid phosphatase conjugated antibody was unstable and difficult to prepare. Peroxidase-antibody conjugates were stable and could be stored for several months at 4°C, or indefiniely in a frozen state.     

Protein transport to the epididymal lumen

Summary Experiments were performed to clarify the debate over the entry of circulating proteins into the epididymal lumen by use of the marker horseradish peroxidase (HRP). Epididymal tubules from the caput epididymidis of the rat were immersed in medium TC 199 containing HRP (3.5 mg/ ml) for 5 min to 3 h at 33° C. Sections were examined for the presence of tracer within the epithelial cells by electron microscopy. From 5 min to 3 h, vesicles containing peroxidase reaction products were found throughout the cytoplasm of the principal cells. Vesicles occurred close to both the basal and apical membranes, and many were found opening into the interstitial space and lumen, depending on the length of incubation. By 5 min labelled vesicles were infrequently found in the apical part of the cells. Reaction product was observed in the epididymal lumen adhering to the microvilli from 30 min of incubation onwards. At all periods of incubation peroxidase was present at the base of the epithelium and between the cells, but it was never found within the tight junctional complexes, and no reaction deposits were found within epithelial cells of tubules incubated in the absence of peroxidase. It is concluded that large molecules leaving the capillaries may enter the epididymal lumen in the caput by means of fluid-phase endocytosis.     

THE LOCALIZATION BY ELECTRON MICROSCOPY OF HELA CELL SURFACE ENZYMES SPLITTING ADENOSINE TRIPHOSPHATE

Cultures of normally proliferating Hela cells have been examined in thin sections by electron microscopy following glutaraldehyde fixation, staining in Wachstein and Meisel's adenosine triphosphate containing medium, postosmication, and embedding in an epoxy resin. The cells were stained in suspension in order to ensure uniform accessibility to reagents. Discrete localization of the enzyme reaction product (lead phosphate) was found at the plasma membranes of about half the cells, but nowhere else. It appeared in the form of an intensely electron-opaque deposit lying close against the outer surface of the cells and varying in amount from a chain of small particles to a dense band about 30 mµ in width. This opaque reaction product was present over microvilli when absent elsewhere on a cell, was heaviest where microvilli and processes were profuse, and was minimal or lacking where cell surfaces were smooth. These observations are discussed in relation to both the idea that surface enzyme activity varies with the physiological phase of individual cells in a population, and the problem of how such enzyme activity becomes manifest at a given site on a morphologically changing membrane system.     

Diffuse cytoplasmic staining of retinal capillary endothelium

The distribution of several hemeprotein tracers in retinal capillaries of Wistar-Furth rats was studied by electron microscopic cytochemistry after incubation in 3,3'-diaminobenzidine. Diffuse cytoplasmic reaction product was frequently observed in the endothelial cells after intravenous injection of horseradish peroxidase (HRP) or lactoperoxidase (LP), or after perfusion of HRP. Occasionally, pericytes were also diffusely stained. In contrast, injection of microperoxidase, catalase, or hemoglobin did not cause diffuse staining. The diffuse staining was similar with HRP types II, VI, and VIII, and at concentrations of 2.5, 5, and 10 mg/100 g body weight. Despite the staining, the blood-retinal barrier remained intact. The findings indicate that HRP and LP are capable of causing diffuse nonspecific staining of retinal capillary endothelial cells, even at relatively low concentrations. Since these tracers are frequently used in studies of the blood-retinal barrier, the results of such studies should be interpreted with caution.     

Immune complex receptors on cell surface. I. Ultrastructural demonstration of macrophages.

A method is described for ultrastructural localization of immune complex receptors on the surface of viable peritoneal exudate cells. The technique entails incubation with a soluble complex of horseradish peroxidase (HRP) and specific antibody to HRP at 4 degrees C followed by exposure to diaminobenzidine and processing for electron microscopy. The bound immune complexes were evident as focal deposits of HRP reaction product, adhering closely to the external surface of macrophages with an uninterrupted periodicity varying between 30 and 120 nm. Following incubation with an insoluble immune complex containing a higher proportion of antibody, receptor sites stained frequently, but large aggregates adhered to the cells. Rinsing cells after staining with soluble complexes partially displaced the bound immune complexes. Fixation prior to exposure to immune complexes largely eliminated the binding capacity of the immune complex receptors.     

Effects of Incubation Time and Temperature on In Vitro Selective Delignification of Silver Leaf Oak by Ganoderma colossum

The effects of incubation time and temperature on the ability of isolates of the chlamydosporic and thermophilic fungus Ganoderma colossum (Fr.) C. F. Baker to cause selective delignification of Quercus hypoleucoides A. Camus were evaluated by standard in vitro agar block tests. Chemical and scanning electron microscopy studies of decayed wood were used to determine the extent of selective delignification or simultaneous decay caused by each fungal isolate. At 35 deg C, the percent weight loss increased from 6.1% after 4 weeks to a maximum of 32.5 to 33.0% after 16 and 20 weeks of incubation. The average percent Klason lignin-chlorite holocellulose ratios (PKL/CHC) decreased from 0.35 in the control wood block to 0.22 in wood blocks incubated for 12 weeks; this indicated selective delignification. The average PKL/CHC increased for the 16- and 20-week incubation periods, indicating greater removal of polysaccharides during longer incubation periods. In temperature studies, the percent weight loss after 12 weeks was 26 to 27% between 30 and 40 deg C and less than 16% for the 25 and 45 deg C treatments. The average PKL/CHC ranged from 0.18 to 0.16 between 35 and 40 deg C, whereas they were 0.23 and 0.31 for the 25 and 45 deg C treatments, respectively. Scanning electron microscopy confirmed an optimum temperature range near 35 to 40 deg C and incubation times of 8 to 12 weeks for selective delignification. Under these conditions, ray parenchyma, fiber tracheids, and vessels were devoid of middle lamella; pit regions of cells were visible with significantly enlarged apertures; and individual cells were separated and clearly delimited. Extensive delignification of wood occurred throughout the wood blocks evaluated. Incubation times longer than 12 weeks resulted in greater degradation of wood cell walls and thus in greater removal of the polysaccharide component of the wood. For incubation times of 4 weeks or a temperature of 25 deg C, limited to no degradation of cells was observed. At 45 deg C, walls of fiber tracheids were eroded and ray parenchymal cells were extensively degraded, indicating that simultaneous degradation of cell walls occurred. Thus, the incubation temperature influenced the type of decay by G. colossum observed on oak wood blocks: extensive selective delignification at 35 to 40 deg C after more than 8 weeks of incubation or simultaneous decay at 45 deg C with 14% weight loss after 12 weeks of incubation. Isolates of G. colossum may prove useful in studies on mechanisms of delignification and biotechnological applications (e.g., biopulping) of lignin-degrading fungi.     

The Membrane Method of Electron Microscope Autoradiography

Thin sections of methacrylate and Araldite embedded tissues labelled with radioactive isotopes were transferred with a wire loop or brush from the knife edge onto thin formvar membranes which covered 7 mm holes in 76 × 25 × 1.5 mm or 76 × 38 × 1.5 mm plastic slides. To facilitate the mounting of sections, a platform supported the plastic slides close to the ultramicrotome knife. Photographic emulsion diluted 1:5 or 1:10 with water was applied with a pipette to the upper surface of each formvar membrane to cover the mounted sections. Excess emulsion was drained off and the remaining thin film was dried on a warm plate at 45 C to produce a uniform layer over the sections. After storing in the dark for several weeks, preparations were processed in photographic solutions and washed, and sometimes stained, before applying electron microscope grids to the underside of each formvar membrane. To detach each grid with its adherent formvar, section and emulsion, the membrane was pierced around the perimeter of the grid. Grain counts made over nuclei of cells labelled with tritiated thymidine indicate that emulsion is uniformly distributed over each section and that quantitative comparison is possible between labelled areas.     

Delineation of human chromosome contour by heat treatment and hematoxylin staining

An unusual form of staining was observed as a result of heat treatment: chromosome contour became easily recognizable. Chromosome contour is optimally delineated by heat treatment of metaphase preparations in 0.06 M phosphate buffer, pH 6.8–7.0 at 95° C for 10 min, and subsequent staining with Heidenhain's hematoxylin. This result is obtained by a process similar to that in which Giemsa has been reported to stain particular foci considered to represent selective staining of constitutive heterochromatin. Mordanting with 3% ferrous ammonium sulfate produced maximum staining. However, hematoxylin (Harris) also stained the periphery of chromosomes. A transitional temperature existed between 70° C and 80° C in which contour became evident. When metaphase preparations were heated at 90–95° C, contour occurred on some chromosomes within 3 min and was demonstrated in 100% of the chromosomes analysed after 10 min of heat treatment.Supported in part by a grant to C. Romero-Sierra from the Defence Research Board of Canada (DRB 9350-24) and to E. A. MacKinnon from the Medical Research Council of Canada (MA-4135).