Light microscopic, non-immunologic demonstration of iron-binding proteins in hematopoietic cells

Iron-binding proteins were localized by their saturation with iron using iron nitrilotriacetate (FeNTA), maintenance of protein-iron-binding at specific values of pH, and visualization of the iron with acid ferrocyanide (AF). Human neutrophilic cells showed strong blue granular and diffuse cytoplasmic staining. Human mid- and late-stage erythroblasts showed moderate diffuse cytoplasmic staining. Monocytes and macrophages showed reactions similar to those seen with AF technique alone. Other hematopoietic cells showed minimal or no stain positivity. Nuclear positivity was not observed in any cells. Concanavalin A (ConA) treatment of purified neutrophils reduced their FeNTA-AF positivity; supernatants from these cells showed precipitin lines of identity with anti-lactoferrin (Lf) stainable with FeNTA and AF. Cellulose acetate electrophoresis of crude neutrophil extracts treated with [59Fe]NTA showed multiple protein bands; one band co-migrated with purified Lf and showed autoradiographic positivity. Rabbit heterophils and rat neutrophils showed less FeNTA-AF positivity, consistent with less Lf in these cells than in human neutrophils. Washing smears with 0.1 M citrate, pH 6.0, between FeNTA and AF treatments eliminated only erythroblast positivity; 0.1 M citrate, pH 4.0, ablated neutrophil staining as well. Ferritin-hemosiderin staining was preserved at both values of pH. These results indicate that FeNTA-AF technique specifically visualizes neutrophil Lf, and suggest that the observed erythroblast positivity is due to transferrin (Tf).     

GLUT2 immunoreactivity in Gomori-positive astrocytes of the hypothalamus.

A specialized subtype of astrocyte, the Gomori-positive (GP) astrocyte, is unusually abundant and prominent in the arcuate nucleus of the hypothalamus. GP astrocytes possess cytoplasmic granules derived from degenerating mitochondria. GP granules are highly stained by Gomori's chrome alum hematoxylin stain, by the Perl's reaction for iron, or by toluidine blue. The source of the oxidative stress causing mitochondrial damage in GP astrocytes is uncertain, but such damage could arise from the oxidative metabolism of glucose transported into astrocytes by high-capacity GLUT2 glucose transporters. In accord with this hypothesis, the reported anatomical distribution of astrocytes staining positively for GLUT2 glucose transporters closely matches that of GP astrocytes. To examine whether or not these two staining procedures detect the same population of astrocytes, immunocytochemistry was performed on semithin sections to detect GLUT2 protein and sections were then stained with toluidine blue to detect GP granules. It was determined that GP astrocytes are frequently immunoreactive for the GLUT2 transporter protein. These data support the possibility that GP astrocytes may have an important influence upon the reactivity of the hypothalamus to glucose and that a specialized glucose metabolism may in part underlie the development of mitochondrial abnormalities in hypothalamic GP astrocytes.     

A Simple Polychrome Stain for Conventionally Fixed Epon-Embedded Tissues

The described technique, based upon a one-step Mallory-Heidenhain stain, can be applied as a routine stain for glutaraldehyde or OsO₄ fixed, Epon embedded tissues of various organs. The technique consists of a short treatment of the sections with H₂O₂, a nuclear staining with celestine blue B and a final staining in a modified Cason's solution. The different tissue and cell components are displayed as follows: dark brown nuclei, yellow cytoplasm, red collagen fibers and blue elastic' fibers. Intra cytoplasmic components as glycogen and mucus are stained respectively blue and violet, whereas other inclusions such as leucocyte granules are colored orange to red.     

Buffered Romanowsky-Giemsa method for formalin fixed,paraffin embedded sections: taming a traditional stain

Romanowsky-Giemsa (RG) stains were devised during the 19th century for identifying plasmodia parasites in blood smears. Later, RG stains became standard procedures for hematology and cytology. Numerous attempts have been made to apply RG staining to formalin-fixed paraffin-embedded tissue sections, with varied success. Most published work on this topic described RG staining methods in which sections were overstained, then subjected to acid differentiation; unfortunately, the differentiation step often caused inconsistent staining outcomes. If staining is performed under optimal conditions with control of dye concentration, pH, solution temperature and staining time, no differentiation is required. We used RG and 0.002 M buffer, pH 42, for staining and washing sections. All steps were performed at room temperature. After staining and air drying, sections were washed in 96?100% ethanol to remove extraneous stain. Finally, sections were washed in xylene and mounted using DPX. Staining results were similar to routine hemalum and eosin (H &; E) staining. Nuclei were blue; intensity depended largely on chromatin density. RNA-rich sites were purple. Collagen fibers, keratin, muscle cells, erythrocytes and white matter of the central nervous system were stained pinkish and reddish hues. Cartilage matrix, mast cell granules and areas of myxomatous degeneration were purple. Sulfate-rich mucins were stained pale blue, while those lacking sulfate groups were unstained. Deposits of hemosiderin, lipofuscin and melanin were greenish, and calcium deposits were blue. Helicobacter pylori bacteria were violet to purple. The advantages of the method are its close similarity to H &; E staining and technical simplicity. Hemosiderin, H. pylori, mast cell granules, melanin and specific granules of different hematopoietic cells, which are invisible or barely distinguishable by H &; E staining, are visualized. Other advantages over previous RG stains include shorter staining time and avoidance of acetone.     

Hepatic and Hippocampus Iron Status is not Altered in Response to Increased Serum Ceruloplasmin and Serum “Free” Copper in Wistar Rat Model for Non-Wilsonian Brain Copper Toxicosis

Copper and iron dyshomeostasis has been implicated directly or indirectly in the pathogenesis of neurodegenerative diseases. Previously, we have shown the first in vivo evidence of significant increase in the hippocampus copper and zinc content with spatial memory impairments, astrocytes swelling (Alzheimer type-II cells) coupled with increase in the number of astrocytes, copper deposition in the choroid plexus, and degenerated neurons in copper-intoxicated Wistar rats. In continuation with our previous study, the aim of this study was to further investigate the effects of intraperitoneally injected copper lactate (0.15 mg Cu/100 g body weight) daily for 90 days on serum “free” copper levels, iron levels in the liver, and hippocampus by atomic absorption spectrophotometry and histopathological study of the liver and brain tissues of Wistar rats using Perls' Prussian blue (PPB) stain. A massive significant increase in serum “free” copper (79.48 % increase) along with strong correlation (r?=?0.978) was found between serum copper and serum “free” copper in copper-intoxicated rats. No significant difference was detected in hepatic and hippocampus iron levels between control and copper-intoxicated rats. PPB stain demonstrated very few scattered grade 1 haemosiderin deposits within sinusoidal cells predominantly Kupffer cells; however, brain sections were negatively stained with PPB stain. In conclusion, the current study demonstrates that chronic copper toxicity causes increase in serum “free” copper, which may serve as predisposing factor for the development of neurodegeneration and memory deficits, and grade 1 haemosiderin deposition in Kupffer cells without altering hepatic and hippocampus iron levels in male Wistar rats.     

The usefulness of alkaline solutions for clearing the uterus and staining implantation sites in rats

The alkaline solution method for detecting uterine implantation sites (metrial glands or spots after delivery), which indicate the position of the embryo, was compared with conventional methods using Turnbull blue (Salewski's technique) and benzyl benzoate (Orsini's technique) in rats. When rat uteri were immersed directly in 2% sodium hydroxide [NaOH], potassium hydroxide [KOH] solution or one of several other alkaline solutions for one hour, the uteri were cleared. Then the metrial glands could be observed without further staining, and the spots after delivery with further staining. After alkaline treatment, unstained metrial glands appeared as yellowish-white degenerated masses and stained spots after delivery appeared as yellowish-brown patches covered with yellowish-white lumps. These yellowish-brown or yellowish-white sites were probably stained by the iron in hemosiderin deposits in the placental scar or in a vestige of the metrial glands left over from pregnancy. Formalin-fixed uteri were not cleared by immersion in a high concentration of NaOH, KOH or other alkaline solutions, but the spots after delivery were stained by this treatment. Turnbull blue did not stain the metrial glands, which contain no iron. Benzyl benzoate cleared fixed or unfixed uteri and allowed observation of the metrial glands and spots after delivery although the entire process required a few days and the specimens became hard and shriveled. The best and most convenient solution for clearing the rat uterus and for staining implantation sites was 2% NaOH or KOH.     

Ferrocyanide staining of transferrin and ferritin-conjugated antibody to transferrin.

To evaluate the ultrastructural distribution of transferrin on the surface of L1210 ascites tumor cells, we used ferrocyanide to stain ferric iron (Prussian blue reaction) in transferrin, as well as in ferritin conjugated to antibody that was immunologically attached to the transferrin. Small deposits averaging 5 nm in diameter identified transferrin iron, whereas large cuboidal deposits averaging 50 nm in diameter stained ferritin conjugated-antibody that was bound to both transferrin and apotransferrin on the cell surface. The ability of transferrin to deliver iron to ascites tumor cells was confirmed by kinetic studies of transferrin labeled with 59Fe and 125I. These preliminary results are consistent with release of transferrin iron at the cell surface and demonstrate additional uses for ferrocyanide in ultrastructural cytochemical techniques.     

Immunocytochemical localization of 2,4-dienoyl-CoA reductase in the liver of normal and di-(2-ethylhexyl)phthalate-fed rats

Summary Localization of 2,4-dienoyl-CoA reductase (DCR) in rat liver was studied using immunoenzyme and immunogold techniques. The animals were fed on a laboratory diet with or without 2% di-(2-ethylhexyl)phthalate (DEHP), a peroxisome proliferator, for two weeks. For light microscopy (LM), semithin Epon sections were stained by immunoenzyme technique after removal of the epoxy resin. For electron microscopy (EM), ultrathin Lowicryl K4M sections were stained by the protein A-gold technique. By LM, in untreated rats reaction deposits showing the antigenic sites for DCR were present in the cytoplasmic granules. Hepatocytes, epithelial cells of interlobular bile duct, and sinus-lining cells contained these granules. After administration of DEHP, the cytoplasmic granules stained similarly. The staining intensity of the heaptocytes increased markedly, but that of the other cells decreased. The sinus-lining cells became mostly negative. By EM, gold particles indicating the antigenic sites for DCR were present in both the mitochondria and peroxisomes of hepatocytes of untreated rats. In the other cells, the gold label was confined to the mitochondria. After administration of DEHP, labelling intensity of the hepatocyte mitochondria increased markedly, but that of the peroxisomes conversely decreased. Quantitative analysis of labelling density showed that the mitochondrial DCR increased to about three times that in the untreated rat, but the peroxisomal DCR decreased to 1/6. The results show that in the rat liver, DCR exists in both, mitochondria and peroxisomes. DEHP can induce mitochondrial DCR, but not peroxisomal DCR.     

Ultrastructural localization of acidic glycoconjugates with the low iron diamine method

The present study has applied the low iron diamine (LID) method at the ultrastructural level to demonstrate acid glycoconjugates. We have examined rat epiphyseal cartilage, human bone marrow, rat tracheal glands, and mouse sublingual glands stained with LID prior to embedment. The LID staining appeared to require postosmication for adequate visualization at the electron microscope level. Thiocarbohydrazide-silver proteinate (TCH-SP) staining of thin sections variably enhanced LID reactive sites. LID-TCH-SP stained carboxyl and sulfate groups of glycosaminoglycans in the extracellular cartilage matrix, secretory granules, and expanded Golgi saccules of chondrocytes. In human bone marrow, LID-TCH-SP variably stained the cytoplasmic granules, known to contain sulfated glycosaminoglycans, and the external surface of the plasma membrane of leukocytes. Moderately strong LID staining was observed in secretory granules in mucous tubules of rat tracheal glands, known to contain sulfated glycoproteins, and in acinar cells of mouse sublingual glands, known to contain a sialoglycoprotein. The lack of sulfated glycoconjugates in acinar cells of the mouse sublingual gland was confirmed by their failure to stain with the high iron diamine method. Thus these studies indicate that the LID and LID-TCH-SP methods are useful for the ultrastructural localization of carboxylated and sulfated glycoconjugates in extracellular and intracellular sites.     

A combined stain for identifying epithelial cells of the gastric mucosa

New techniques are proposed for differentiating each type of gastric epithelial cell in the same tissue section. The techniques combine the following stains: paradoxical concanavalin A staining (PCS) to identify mucous neck cells, periodic acid Schiff-concanavalin A staining to distinguish mucous neck cells from surface mucous cells, and a modified Bowie's stain to demonstrate zymogen granules of chief cells. Feulgen hydrolysis preceding the Bowie stain was found to remove most of the nonspecific coloration encountered with the original Bowie method. The results obtained by the new sequences were as follows: Feulgen hydrolysis-PCS-Bowie staining: mucous neck cells stained brown and chief cell zymogen granules deep blue. The other mucin-secreting cells remained unstained; Feulgen hydrolysis-PAS-concanavalin A-Bowie staining: mucous neck cells stained brown, zymogen granules stained deep blue to purplish blue and surface mucous cells stained purplish red.     

A study on the cytoplasmic granules of the pericardial gland cells of some bivalve molluscs

The pericardial glands of three bivalve molluscs are composed of convoluted epithelium that appears as pouches on the auricles of Mytilus and as tubules in the connective tissue at the anterior-lateral sides of the pericardial cavity of Mercenaria and Anodonta. The pericardial gland cells are attached to each other by many randomly placed desmosome-like cell junctions and gap junctions. Belt-desmosomes that are characteristic of epithelial cells were not observed. The basal membrane of these cells is invaginated producing complex interdigitating cytoplasmic processes and filtration slits. The pericardial gland cells stain for the presence of iron with Prussian blue stain. Electron-dense and electron-lucent granules of various diameters are present in the cytoplasm. Many electron-dense granules contain ferritin-like particles in which the presence of iron has been demonstrated by microanalysis. It is suggested that these particles are the iron storage protein ferritin since they contain iron, and are water soluble, heat stable, and morphologically similar to mammalian ferritin. Ferritin particles are probably both synthesized and broken down by the pericardial gland cells; thus the pericardial gland cells may be involved in iron homeostasis in these molluscs.     

A Combined Stain for Identifying Epithelial Cells of the Gastric Mucosa

New techniques are proposed for differentiating each type of gastric epithelial cell in the same tissue section. The techniques combine the following stains: A) paradoxical concanavalin A staining (PCS) to identify mucous neck cells, B) periodic acid Schiff-concana-valin A staining to distinguish mucous neck cells from surface mucous cells, and C) a modified Bowie's stain to demonstrate zymogen granules of chief cells. Feulgen hydrolysis preceding the Bowie stain was found to remove most of the nonspecific coloration encountered with the original Bowie method. The results obtained by the new sequences were as follows: 1) Feulgen hydroIysis-PCS-Bowie staining: mucous neck cells stained brown and chief cell zymogen granules deep blue. The other mucin-secreting cells remained unstained; 2) Feulgen hydrolysis-PAS-concanavalin A-Bowic staining: mucous neck cells stained brown, zymogen granules stained deep blue to purplish blue and surface mucous cells stained purplish red.     

Staining Streptomyces Scabies in Lesions of Common Scab of Potato

Toluidine blue can be used to stain Streptotnyces scabies distinctively in slide cultures or in the lesions of common potato scab. This staining method is based on the metachromaticism of volutin, a constant constituent of the spores and mycelium of S. scabies. Either sections or smears are fixed in FPA (formalin, 5 parts; propionic acid, 7.5; 50% alcohol, 87.5), stained in a 1:100 dilution of saturated aqueous toluidine blue from 20 minutes to 24 hours, dehydrated in an acetone-xylene series and mounted. Cellular constituents of the potato tuber stain blue or are colorless whereas the mycelium of Streptomyces appears as a series of red volutin spheres in the blue stained cytoplasm. The criteria of volutin and cytoplasmic staining along with the 1 µ diameter of the mycelium make it possible to distinguish Streptomyces from the other microorganisms and cells in the lesion region.     

Morphology and histochemistry of the adrenal medulla. I. Various types of primary catecholamine-storing cells in the mouse adrenal medulla.

Semithin sections (Araldite) of mouse adreno-medullary tissue were examined in the light microscope after perfusion fixation with glutaraldehyde, glutaraldehyde/formaldehyde or after freeze-drying followed by a treatment with hot formaldehyde gas. The following methods were employed: (i) aldehyde-induced fluorescence of catecholamines, (ii) Schmorl's ferric ferricyanide reaction, (iii) argentaffin reaction, and (iiii) staining with alkaline lead citrate followed by Timm's silver sulphide reaction. The correspondence of results obtained by the various methods was proven in consecutive sections or by successively applying different methods to identical sections. Four types of primary catecholamine-storing cells were identified. NA1 cells contain cytoplasmic granules up to 0.3 mum in diameter which stain black with ammoniacal silver and display a bright white to yellow fluorescence. NA2 cells show smaller cytoplasmic granules which stain brown with the argentaffin method and give white catecholamine fluorescence. NA3 cells appear yellow-earth after applying the argentaffin reaction and show greenish fluorescence. NA4 cells are hardly identified in the light microscope. These cells are significantly smaller than the above mentioned cells and characterized by a high nucleo-cytoplasmic ratio. They become straw coloured with ammoniacal silver and show greenish fluorescence. The argentaffin reaction was also used to identify these cells in semithin sections of glutaraldehyde/osmium tetroxide fixed material. The fine structure of the various noradrenalin-storing cells was studied in consecutive thin sections. NA1 cells were found to contain two populations of granules, the larger ones measuring between 300 and 350 nm, the smaller ones about 175 nm. The granules in NA2 cells correspond to this latter population (175 nm). NA3 cells contain an uniform granule population with a main diameter of 120 nm. The smallest granules are seen in NA4 cells being in the dimension of 80 nm. Granules in NA1 and NA2 cells show uniformly high density, whereas those in NA3 and NA4 cells display cores of varying density. Granules with moderately dense cores in NA3 and NA4 cells may represent partially emptied sites of noradrenalin storage or dopamin containing particles.     

A combination Verhoeff's elastic and Masson's trichrome stain for routine histology

A method for the combined staining of elastic, muscle and connective tissue for routine use in histopathology is described. The elastica, stained black by Verhoeff's technique, is contrasted with the muscle and connective tissue stained red and green or blue respectively by a modification of Masson's trichrome. Cell nuclei stain blue-black with Weigert's iron hematoxylin. The procedure takes approximately two hours and is most suitable for the study of vascular pathology in surgical and autopsy sections.     

A Combination Verhoeffs Elastic and Masson's Trichrome Stain for Routine Histology

A method for the combined staining of elastic, muscle and connective tissue for routine use in histopathology is described. The elastica, stained black by Verhoeffs technique, is contrasted with the muscle and connective tissue stained red and green or blue respectively by a modification of Masson's trichrome. Cell nuclei stain blue-black with Weigert's iron hematoxylin. The procedure takes approximately two hours and is most suitable for the study of vascular pathology in surgical and autopsy sections.     

Unmasking and redistribution of lysosomal sulfated glycoconjugates in phagocytic polymorphonuclear leukocytes

Rabbit heterophil and human neutrophil primary granules contain sulfated glycosaminoglycans (GAGs) and acid phosphatase, which can be readily stained in immature but not mature lysosomes. To determine whether this loss of staining represents masking of reactive components or removal of these components, we examined rabbit heterophils to see if high-iron diamine (HID)-reactive sulfate and acid phosphatase staining reappears in phagocytic vacuoles. Rabbit heterophils, obtained by peritoneal lavage, were incubated in vitro with latex beads or Pseudomonas aeruginosa for 15-60 min. Pre-embedment HID staining was enhanced in thin sections of unosmicated specimens with thiocarbohydrazide and silver proteinate (TCH-SP). Phagocytosis of latex beads or bacteria was progressively more prominent with time. Primary granules that were degranulated or in the process of degranulating into phagocytic vacuoles demonstrated intense sulfate staining with large (13 +/- 7 nm) HID-TCH-SP stain deposits. Smaller (6 +/- 1 nm) HID-TCH-SP stain deposits were present in tertiary granules, which were less frequently observed degranulating into phagosomes. Acid phosphatase staining was most intense during early phagolysosome formation. HID-TCH-SP staining was also observed in extracellular degranulated lysosomal matrices and on the surface of many peritoneal heterophils. These results indicate that loss of sulfate staining in mature heterophil granules is the result of masking by intragranular substances rather than of removal, and that these components may be unmasked during phagocytosis and/or redistributed to the cell surface after exocytosis.     

Alcian Blue Staining of Nuclear Chromatin in Insect Gut After Beta-Glucuronidase Treatment

Sections of the gut (ventriculus and proventriculus) of the cockroaches, Blattus germanicus and Blaberus giganticus, were prepared after fixation in Carnoy's solution. In sections treated with beta-glucuronidase and hyaluronidase (1 nig per 1 ml at pH 7.0), the nuclear chromatin of the epithelium stained deeply with alcian blue (0.1% in 2% acetic acid). The sites of this staining coincided with the green-staining components seen in untreated control sections stained by methyl green-pyronin. Moreover, the alcian blue staining after this treatment agreed closely with the sites of positive Feulgen reaction in control sections. Prior treatment in deoxyribonuclease (1 mg per 10 ml of glass-distilled water) before digestion in beta-glucuronidase nullified the alcian blue staining of the chromatin. Ribonuclease had a similar effect except that after its action the chromatin would still stain with nuclear fast red.     

Mutant vasopressin precursor in the endoplasmic reticulum of the Brattleboro rat. Ultrastructural evidence from individual “vasopressin” cells localized with the light microscope by use of a new gold/silver method for immunostain enhancement

Summary This ultrastructural study demonstrates that the vasopressin immunoreactivity found in the occasional, densely stained cells in the hypothalamus of the homozygous Brattleboro rat is localized in the rough endoplasmic reticulum. 50-m Vibratome sections were stained with anti-vasopressin serum by use of a peroxidase method with 3,3-diaminobenzidine as chromogen. The diaminobenzidine end-product has a specific capability to bind gold particles from a chloroauric acid solution and the bound gold was used to precipitate silver grains from a silver developer. The stained sections were flat embedded in resin and ultrathin sections were cut of areas containing the immuno-identified occasional cells. In these densely stained, vasopressin-immunoreactive cells of homozygous Brattleboro rats the rough endoplasmic reticulum was dilated. The lumen of the reticulum contained both end-products of diaminobenzidine and gold/silver grains, but some parts of the reticulum appeared unstained. No other cell organelles were immunostained and no secretory granules were found. In control rats, gold/silver deposits were found throughout the cytoplasm of vasopressin-immunoreactive cells. In these immunostained cells secretory granules were seen.     

Identification of normal and leukemic granulocytic cells with merocyanine 540

After fixation in a modified Bouin's solution, the acid dye merocyanine 540 stained granules in granulocytic cells intensely. In immature granulocytes, such as promyelocytes and myelocytes, granules stained pink to violet. In some leukemic myeloblasts, promyelocytes and monocytes, granules also stained deep pink to violet. In more mature granulocytes, such as metamyelocytes, bands, and neutrophils, granules stained bright red to orange. In eosinophils and basophils, granules stained deep red. Granules of the type described were not visualized in normal plasma cells, lymphocytes, monocytes, or megakaryocytes. In normoblasts, cytoplasm stained diffusely red. Cytoplasmic staining in erythroblasts became darker as the cell matured, probably reflecting hemoglobin content. Used as a single agent stain, merocyanine 540 may be useful in distinguishing normal and leukemic granulocytic cells from other types of blood cells.