Journal of Histochemistry & Cytochemistry

Monaghan, P; Robertson, D; Amos, T A; Dyer, M J; Mason, D Y; Greaves, M F

doi: 10.1177/40.12.1453000pmid: 1453000

Previous cell subfractionation studies have indicated that bcl-2 is an inner mitochondrial membrane protein. We have sought to determine the ultrastructural localization of bcl-2 protein in lymphoma and breast carcinoma cell lines and biopsy material known to overexpress bcl-2 using immunoelectron microscopy. To avoid the possibility of processing artifacts, samples were prepared by three different methods: progressive lowering of temperature, cryosectioning, and freeze-substitution. In all instances the labeling of bcl-2 protein was relatively weak but the distribution the same. In both lymphoma and breast carcinoma tissues, bcl-2 protein was detected on the periphery of mitochondria: little labeling of either the mitochondrial matrix or cristae could be detected. Labeling was also detected on the perinuclear membrane and throughout the cytoplasm, as also indicated by confocal microscopy. These data therefore indicate that bcl-2 protein can be detected at several intracellular sites and that at the likely functional destination, the mitochondria, there appears to be, contrary to expectations, a preferential association with the outer membrane.

Laurie, S M; Mixon, M B; Castle, J D

doi: 10.1177/40.12.1453001pmid: 1453001

Using a monoclonal antibody (SG10A6) raised against secretion granule membranes of the rat parotid gland, we have identified an antigen that is a common component of both exocrine pancreatic and parotid granule membranes. SG10A6 (an IgM) immunoprecipitates antigen that migrates as a single band (M(r) approximately 80 KD unreduced; M(r) approximately 100 KD reduced) and immunoblots at least two polypeptides that are similar to the reduced and nonreduced immunoprecipitated antigen. This granule-associated membrane polypeptide (GRAMP 100; named for the apparent M(r) in reduced form) is also a prominent component of plasma membrane fractions. Immunocytochemical localization at the electron microscopic level demonstrates the presence of GRAMP 100 on granule membranes, especially condensing vacuoles and exocytotic figures, and the apical plasma membrane. Lower levels of antigen are detected on basolateral plasma membrane and on peri-Golgi membranes that may be part of the endosomal system. Both the cell fractionation and immunocytochemical localization indicate that GRAMP 100 differs in distribution from GRAMP 92 and 30K SCAMPs, two other components of exocrine granule membranes identified with monoclonal antibodies. To date, no polypeptides have been identified with this approach that are exclusive components of exocrine granule membranes.

Vandré, D D; Burry, R W

doi: 10.1177/40.12.1453002pmid: 1453002

We examined the immunogold staining of microtubules and microtubule organizing centers using an improved silver-enhancement reagent for small (1-1.4 nm) gold-conjugated secondary antibodies. First, the staining properties of different commercial preparations of gold-labeled antibodies were compared for sample penetration, label uniformity, and labeling density, and Nanogold 1.4-nm gold-conjugated F(ab') was found to be superior to the other probes examined. However, in samples examined for the localization of alpha- and beta-tubulin, gold staining did not extend through the pericentriolar material nor were the centrioles labeled. This apparent lack of centrosomal staining was not due to problems associated with penetration of the antibody probes, since staining adjacent to and within the centriolar cylinder was observed when phosphoprotein antigens recognized by the MPM-2 antibody were localized. The MPM-2 antibodies also localized to mitotic kinetochores, kinetochore fibers, and midbodies, in addition to mitotic centrosomes. The level of MPM-2 staining of the centrosome varied through the cell cycle. At interphase, this staining was restricted within the centriolar cylinder, whereas in mitotic cells extensive staining throughout the pericentriolar material was also observed. These results established the close relationship of MPM-2-reactive phosphoproteins with the centrosome, and suggest that this technique may be useful for ultrastructural localization of other cytoskeletal proteins.

Burry, R W; Vandré, D D; Hayes, D M

doi: 10.1177/40.12.1453003pmid: 1453003

In pre-embedding EM immunocytochemistry with gold probes, the gold must be small enough to penetrate through cell membranes treated with mild detergents. Antibodies labeled with small gold probes (1-1.4 nm) are too small to be resolved in thin sections but can be seen if they are silver-enhanced after the gold has bound to the antigens in the cells. We investigated several aspects of gum arabic-silver lactate-hydroquinone enhancement solution (Danscher solution) by examining gold-conjugated antibodies embedded in agar, sectioned on a vibrotome, and enhanced with different solutions. The rate of silver enhancement was optimized in 50% gum arabic and 200 mM HEPES buffer, pH 5.8. We also examined chemicals used as developers and found that N-propyl gallate (NPG) gave a more uniform development than the routinely used hydroquinone (HQ). The diameter of the silver-enhanced particles after incubation in osmium tetratoxide (OSO4) decreased somewhat with longer incubation time and higher percentages, but the density (number per unit area) of silver-enhanced particles was little changed. The loss of silver-enhanced particle diameter was reduced by lowering the concentration of OSO4 to 0.1%. Comparison of commercial small gold probes showed that NPG enhancement of Nanogold gave more uniform particle size and a better correlation between enhancement time and particle density. When this procedure was applied to cell cultures with monoclonal antibodies, the silver-enhanced particles were similar to those in the agar sections. When free-floating tissue sections were used, longer silver enhancement times were needed to obtain similarly sized particles. This new NPG-silver-enhancement procedure offers a reliable and easy method to localize proteins in cultured cells and tissue sections by pre-embedding electron microscopic immunocytochemistry.

Wirth, H; Wermuth, B

doi: 10.1177/40.12.1453004pmid: 1453004

Carbonyl reductase, an NADPH-dependent oxidoreductase of broad specificity, is present in many human tissues. Its precise localization, however, has remained unclear, as well as its physiological and possible pathophysiological significance. The present study reports the immunohistochemical localization of the enzyme in normal human tissues. Immunostaining was detectable in all organs investigated. The highest concentrations were found in the parenchymal cells of the liver, the epithelial cells of the stomach and small intestine, the epidermis, the proximal tubules of the kidney, neuronal and glial cells of the central nervous system, and certain cells of the anterior lobe of the pituitary gland. Consistently pronounced staining was also observed in smooth muscle fibers and the endothelium of blood vessels. The results are in agreement with a housekeeping function of carbonyl reductase in the elimination of reactive carbonyl compounds.

Iborra, F J; Renau-Piqueras, J; Portoles, M; Boleda, M D; Guerri, C; Pares, X

doi: 10.1177/40.12.1453005pmid: 1453005

Alcohol dehydrogenase (ADH), the major enzyme catalyzing the biological oxidation of ethanol in mammals, includes four classes with very different capacities for ethanol oxidation. Class III ADH is present in all the tissues and is well conserved throughout evolution. This enzyme has a low activity with ethanol, is specific for the glutathione-dependent oxidation of formaldehyde, and is therefore a formaldehyde dehydrogenase (FALDH). Until now there have been few and conflicting studies concerning its intracellular distribution, which is important for the understanding of its role in cell function. In the present work we used biochemical and immunocytochemical methods to assess the distribution of FALDH in rat hepatocytes and astroglial cells. With the glutathione-dependent formaldehyde dehydrogenase assay, we found the highest activity in the cytosol of hepatocytes and brain cells (12 and 2.6 mU/mg protein, respectively), but nuclei also exhibited significant activity (1.16 and 2.1 mU/mg protein, respectively). The immunocytochemical results showed the presence of FALDH binding sites in both the cytoplasm and the nucleus of the different cell types studied. Whereas no specific gold particle labeling was seen associated with any cytoplasmic component, in the nucleus the particles were found mainly over condensed chromatin and interchromatin regions. Finally, the gold particle density over both the nucleus and cytoplasm was greater in differentiated than in proliferating astrocytes in primary culture. In contrast, class I ADH, primarily responsible for ethanol metabolism, was found only in the cytoplasm of hepatocytes. We propose that one of the functions of FALDH is to protect cell structures, including DNA, from the toxic effects of endogenous formaldehyde, which is an intermediate in many metabolic process.

Urieli-Shoval, S; Meek, R L; Hanson, R H; Ferguson, M; Gordon, D; Benditt, E P

doi: 10.1177/40.12.1280665pmid: 1280665

Tissues fixed with organic solvent fixatives such as Carnoy's solution are known to give poor and erratic results with in situ hybridization, whereas those fixed with paraformaldehyde produce more consistent results. To understand this difference and to improve the utility of Carnoy's-fixed tissue for in situ hybridization, we explored several parameters of RNA integrity and preservation. Carnoy's-fixed, paraffin-embedded livers and paraformaldehyde-fixed, paraffin-embedded livers of mice were compared for RNA extractability, degradation, and hybridizability. In addition, retention of RNA in tissue sections after sequential in situ hybridization treatments was compared. RNA was found to be easily extractable from Carnoy's-fixed liver and was well preserved, with only slight degradation of high molecular weight RNA. Conversely, only a small percentage of the RNA was extractable from paraformaldehyde-fixed liver unless the tissue was digested with protease. The extracted RNA was well preserved, without detectable degradation. Sections of tissue fixed in Carnoy's solution subjected to in situ hybridization retained only about 10% of their original RNA content and gave correspondingly weak in situ hybridization signals. Formaldehyde-fixed tissues retained much more of the RNA (about 45%) and produced strong in situ hybridization signals. Treatment of Carnoy's-fixed tissue sections with vaporous formaldehyde increased retention of RNA and provided in situ hybridization signals comparable with those of paraformaldehyde-fixed tissues.

McLaren, J; Brawer, J R; Schipper, H M

doi: 10.1177/40.12.1453006pmid: 1453006

A subpopulation of astrocytes in periventricular brain regions and in cysteamine-treated neuroglial cultures contains cytoplasmic granules that exhibit an affinity for Gomori stains, orange-red autofluorescence, and non-enzymatic peroxidase activity. The autofluorescence and pseudoperoxidase activity are consistent with the presence of porphyrins and heme iron, respectively. In the present study, we employed diaminobenzidine cytochemistry, transmission electron microscopy, and energy-dispersive X-ray microanalysis (electron microprobe) in an attempt to correlate fine structure with the peroxidase activity and elemental composition of the cysteamine-induced inclusions in cultured astrocytes. In osmicated preparations, these membrane-bound inclusions varied greatly in size, were round or ovoid in shape, and exhibited an intensely electron-dense granular matrix. In non-osmicated preparations, many inclusions exhibited internal membranous partitions producing complex subcompartmentalization. Diaminobenzidine reaction product, indicative of endogenous peroxidase activity, was occasionally observed distributed diffusely throughout the granule matrix. More commonly, peroxidase activity was restricted to specific intraorganellar compartments. Elemental iron was detected in the inclusions by electron microprobe analysis. The presence and concentration of iron in these organelles correlated closely with the presence and intensity of diaminobenzidine staining, suggesting that redox-active iron mediates the pseudoperoxidase reactions in these cells. Cysteamine-induced derangements of porphyrin-heme biosynthesis may be responsible for the proliferation of iron-containing gliosomes in these astrocytes.

Iida, H; Hatae, T; Shibata, Y

doi: 10.1177/40.12.1453007pmid: 1453007

By using immunocytochemical techniques, we examined the localization of a 67 kDa Ca2+ binding protein (p67) and calpactin I heavy chain (p36) in ventricular myocytes, skeletal myocytes, and intestinal smooth muscle cells. Immunofluorescence microscopy revealed that the p67 was expressed in all these muscle cells, whereas anti-p36 antibody stained cells in connective tissues but failed to stain these muscle cells. Immunogold electron microscopy was carried out to examine the subcellular localization of the p67 in muscle cells. The results showed that the p67 was exclusively confined to the plasma membrane of muscle cells and the presumptive transverse tubules of the striated myocytes. Immunoblot analysis with anti-p67 antibody showed that the p67 was indeed a constitutive protein of the sarcolemma isolated from rat hearts. These results indicate that the p67 is a sarcolemma-associated Ca2+ binding protein expressed in both striated myocytes and intestinal smooth muscle cells.

Yamamoto, K; Völkl, A; Fahimi, H D

doi: 10.1177/40.12.1360481pmid: 1360481

We investigated the immunoreactivity of the peroxisomal lipid beta-oxidation enzymes acyl-CoA oxidase, trifunctional protein, and thiolase in guinea pig liver and compared it with that of homologous proteins in rat, using immunoblotting of highly purified peroxisomal fractions and monospecific antibodies to rat proteins. In addition, the immunocytochemical localization of beta-oxidation enzymes in guinea pig liver was compared with that of catalase. All antibodies showed crossreactivity between the two species, indicating that these peroxisomal proteins have been well conserved, although all exhibited some differences with respect to molecular size and, in the case of acyl-CoA oxidase, in frequency of the immunoreactive bands. In the latter case, a distinct second band in the 70 KD range was observed in guinea pig, in addition to the regular band due to subunit A present in rat liver. This novel band could be due either to trihydroxycoprostanoyl-CoA oxidase or to the non-inducible branched chain fatty acid oxidase described recently. All three beta-oxidation enzymes were immunolocalized by light and electron microscopy to the matrix of peroxisomes, in contrast to catalase, which is also found in the cytoplasm and the nucleus of hepatocytes in guinea pig liver.