Aldehyde-fuchsin staining of antral endocrine cells.

Correlative studies have been made to identify the endocrine cells stained by Aldehyde-Fuchsin (AF) in the cat and human antral mucosa. D-cells weakly stained by AF after oxidation: this staining might be related to the disulphide group present in the molecule of Somatostatin (the hypothalamic hormone recently localized in D-cells). The gastrin-producing G-cells were on the contrary strongly stained (without oxidation) in tissues fixed in Helly-fluid. Histochemical investigations on the mechanism of such staining lead to the conclusion that it might be related to affinity of the stain for hidden acidic groups.     

Aldehyde fuchsin staining, direct or after oxidation: problems and remedies, with special reference to human pancreatic B cells, pituitaries, and elastic fibers.

Successful production of aldehyde fuchsin (AF) having the unique properties described by Gomori depends on each of many critical variables. AF made from basic fuchsins which contain mainly rosanilin (C.I. 42510) do not stain properly-fixed pancreatic B cells, pituitary basophils, or elastic fibers in unoxidized sections. AF made from basic fuchsins containing mainly pararosanilin (C.I. 42500) stains these entities strongly. Substances stained by AF without oxidation fall into two classes: 1) nonacidic peptides and proteins, most of which contain half-cystines, and 2) polyanions, particularly when sulfated. Group 2 substances stain rapidly, Group 1 substances stain slowly. Many modifications of aldehyde fuchsin have been described. Modified aldehyde fuchsins (MAFs) differ in the kind of aldehyde and in the amount of aldehyde and hydrochloric acid used in their formulation; they differ also in the temperature and duration of the ripening necessary before they can be used. If microsections are first oxidized by acid permanganate or other oxidant, MAF staining of pancreatic B cells, pituitary basophils and other substances containing cystines is speeded and intensified. Most modified methods prescribe oxidation, but the author's does not. The chemical basis, final result and potential side-reactions of oxidation methods (OXMAF) differ from those of direct methods (DIMAF) such as the author's. DIMAF staining is slower but inherently simpler and less destructive. The time required for optimal staining with DIMAF depends on the potency of the stain, which in turn depends on how the stain was made and its age. Detection of DIMAF--reactive peptides and proteins may be hampered by the strong staining of polyanions. This can be remedied if the polyanions are first stained with Alcian blue (AB) or other durable basic dye of contrasting color resistant to acid ethanol. Experiences with the AB-DIMAF staining of pancreatic B cells, pituitaries and elastic fibers in formalin-fixed human tissues are detailed. Proper control of the variables which affect MAF will insure useful and reliable results either directly or after oxidation. Authors and editors are urged to be more careful hereafter to distinguish the results of DIMAF from those of OXMAF methods. Published reports should always specify the parameters that affect the properties of MAF. In OXMAF methods the steps intervening between oxidation and staining should be spelled out. Such care should help dispel the confusion and uncertainty which cloud the use and reputation of aldehyde fuchsin at present. This unique dye deserves wider and wiser use.     

Ultrastructural silver enhancement of Prussian blue-reactive iron in hematopoietic and intestinal cells

Prussian blue has been widely used to localize iron in a variety of tissues at the light and electron microscopic level. In the present study, thin sections of human marrow and blood cells and rat duodenal cells were exposed to silver proteinate (SP) after staining en bloc with acid ferrocyanide (AF), with and without prior iron saturation using iron nitrilotriacetate (FeNTA). Silver deposition was observed over Prussian blue-reactive sites and significantly enhanced sites of minimal AF and FeNTA-AF staining. AF-SP stain deposits were present in the cytoplasmic matrix, granules, and occasionally on the surfaces of macrophages, monocytes, and erythroblasts. FeNTA-AF-SP stained additional cytoplasmic and surface sites in erythroblasts and stained neutrophil granules intensely. Duodenal epithelium from iron-loaded rats demonstrated strong AF-SP staining of ferric iron in microvilli, apical cytoplasmic matrix, and lateral membranes. Similar preparations from iron-replete rats stained sparsely; however, intense AF-SP staining was observed after iron saturation with FeNTA. SP similarly enhanced luminal ferrous iron deposits stained with acid ferricyanide in rats given intraluminal ferrous iron. AF-SP stain deposits were removed by exposure of thin sections to NH4OH, KCN, or HNO3 but were not affected by prior exposure to HIO4 or NaBH4, consistent with a silver cyanide or complex stain precipitate rather than reduced silver or silver ferriferrocyanide. SP enhancement of Prussian blue allows identification of reactive sites not readily visualized with AF or FeNTA-AF alone, and offers the potential for differentiating AF staining from other deposits or organelles of comparable density.     

Use of type-specific antimyosins to demonstrate the transformation of individual fibers in chronically stimulated rabbit fast muscles

Continuous stimulation of a rabbit fast muscle at 10 Hz changes its physiological and biochemical parameters to those of a slow muscle. These transformations include the replacement of myosin of one type by myosin of another type. Two hypotheses could explain the cellular basis of these changes. First, if fibers were permanently programmed to be fast or slow, but not both, a change from one muscle type to another would involve atrophy of one fiber type accompanied by de novo appearance of the other type. Alternatively, preexisting muscle fibers could be changing from the expression of one set of genes to the expression of another. Fluorescein-labeled antibodies against fast (AF) and slow (AS) muscle myosins of rabbits have been prepared by procedures originally applied to chicken muscle. In the unstimulated fast peroneus longus muscle, most fibers stained only with AF; a small percentage stained only with AS; and no fibers stained with both antibodies. In stimulated muscles, most fibers stained with both AF and AS; with increasing time of stimulation, there was a progressive decrease in staining intensity with AF and a progressive increase in staining intensity with AS within the same fibers. These results are consistent with a theory that individual preexisting muscle fibers can actually switch from the synthesis of fast myosin to the synthesis of slow myosin.     

Post-embedding staining of rat gastric mucous cells with lectins

Summary The mucous cells of the rat stomach were stained with lectins by two post-embedding staining methods for electron microscopy. The mucous granules of surface mucous cells and foveolar mucous cells were stained weakly by Ricinus communis agglutinin-ferritin and wheat germ agglutinin-ferritin. The mucous granules of mucous neck cells were stained by concanavalin A-ferritin, Ricinus communis agglutinin-ferritin and wheat germ agglutinin-ferritin. The mucous granules of pyloric gland cells showed an affinity for wheat germ agglutinin-ferritin and concanavalin A-ferritin, while Ricinuscommunis agglutinin-ferritin only slightly stained the granules. The granules of mucous neck cells and pyloric gland cells were also stained by the concanavalin A-horseradish peroxidase-colloidal gold method, but the granules of surface and foveolar mucous cells were not stained by this method. Periodic acid oxidation of the sections before the standard concanavalin A-ferritin procedure enhanced the staining of the granules of mucous neck cells and pyloric gland cells slightly. Reduction of the sections after the periodic acid oxidation weakened the staining. Similar results were obtained using the concanavalin A-horseradish peroxidase-colloidal gold method. Though the staining with Ricinus communis agglutinin-ferritin was inhibited by periodic acid oxidation of the sections before staining, the staining with wheat germ agglutinin-ferritin was not inhibited by the oxidation. It is suggested that the paradoxical staining is closely related to the position of the concanavalin A-binding sugar residues in the carbohydrate chains.This work was supported in part by a grant-in-aid (No. 457008) from the Ministry of Education, Science and Culture, Japan and a grant-in-aid for cancer research (55-21) from the Ministry of Health and Welfare, Japan     

Insulin, glucagon and somatostatin in fetal rat islets maintained free-floating in culture: immunocytochemistry and radioimmunoassay.

Fetal rat islets maintained free-floating in tissue culture represent a source of B-cells. Because we recently noted the occurrence of other cell types during long-term tissue culture, this in vitro model was used to examine the possible development of non B-cells. The changes in the numbers and percentages of B, A and D-cells in vitro were estimated by counting the hormone-positive cells after immunocytochemical staining. Insulin, glucagon, and somatostatin contents were determined in extracts of the cultured tissue. The experiments described here showed that the cultured islets maintained their viability over a two-week culture period, as evidenced by the increase of both the number of B-cells per islet and the DNA content per islet. During the first few days of culture, immunocytochemically stained free-floating islets indicated the presence of rare A- and D-cells at the periphery of B-cells; thereafter, numerous A- and D-cells were seen interdigitating with B-cells. Expressed per islet, the number of A- and D-cells increased during the culture; within the endocrine cell population, the percentage of these cells increased with time, at the expense of the percentage of B-cells. The glucagon and somatostatin contents of the free-floating islets were also increased. These converging observations suggest that additional non B-cells may have been produced by free-floating islets during long-term tissue culture.     

On the nature of the metachromatic cells of pancreatic islets

Summary Islet cells with cytoplasmic granules metachromatically stained by toluidine blue are found in the pancreas of dog, cat, pig, rabbit, teleostian fish, monkey and man, but not in the rat, mouse and guinea pig; dubious results are obtained on duck and ox islets. These cells do not react with the staining methods for the demonstration of A- and B-cells; conversely, they are silver-impregnated by a modification of Davenport's method, and, at least in dog islets, can be readily identified with dark-field microscopy and stained blue with the Mallory-Heidenhain trichrome stain. No obvious changes of this cell type are found either in synthalintreated dogs or in diabetic men.The Authors suggest that the islet argyrophil-metachromatic cells (A₁-cells of Swedish Authors) are identical with D-cells and very likely represent a morphologically and functionally indipendent cell type.     

Histochemical method for demonstrating quail mast cell types simultaneously

Abstract

The development and application of selective staining methods for routine detection of mast cells are of considerable interest, because these cells play an important role in health and disease. The composition of cytoplasmic mast cell granules depends on the species and type of mast cell. The study reported here was conducted to investigate the combined use of aldehyde fuchsin (AF) and the Alcian blue-critical electrolyte concentration (AB-CEC) (pH 5.8, 0.3 M MgCl₂) techniques for differentiating avian mast cell subtypes. Tissue samples from skin, intestines, and lungs of six healthy adult quail and two control rats were fixed in Carnoy's solution and 10% formolin for routine histological processing. To determine the staining properties of sulfated glycosaminoglycans (GAGs), a three-step staining technique was applied using berberine sulfate, AF, and AB-CEC. In quail, AF positivity following application of the AB-CEC technique was found only in the lungs, mostly in cells that gave a berberine sulfate-positive reaction, and this positivity was determined to be localized particularly in the nucleus and perinuclear cytoplasm. In other regions, the pale AF staining of cells that did not emit fluorescence when stained with berberine sulfate was determined to be replaced by a blue color after application of AB-CEC. The AF/AB-CEC (pH 5.8, 0.3 M MgCl₂) technique demonstrated that rat and quail mast cells varied in both GAG types and their distribution within the cell. Especially in avian species, this technique can be applied to distinguish mast cells according to their GAG content. It can be used as an alternative to the AB/safranin O staining procedure for differentiating mast cells that contain and lack heparin.     

Perlecan, the multidomain heparan sulfate proteoglycan of basement membranes, is also a prominent component of the cartilaginous primordia in the developing human fetal spine.

The aim of this study was to localize perlecan in human fetal spine tissues. Human fetal spines (12-20 weeks; n=6) were fixed in either Histochoice or 10% neutral buffered formalin, routinely processed, paraffin-embedded, and 4-microm sagittal sections were cut and stained with toluidine blue, H&E, and von Kossa. Perlecan, types I, II, IV, and X collagen, CD-31, aggrecan core protein, and native and delta-HS 4, 5 hexuronate stub epitopes were immunolocalized. Toluidine blue staining visualized the cartilaginous vertebral body (VB) rudiments and annular lamellae encompassing the nucleus pulposus (NP). Von Kossa staining identified the VB primary center of ossification. Immunolocalization of type IV collagen, CD-31, and perlecan delineated small blood vessels in the outer annulus fibrosus (AF) and large canals deep within the VBs. Perlecan and type X collagen were also prominently expressed by the hypertrophic vertebral growth plate chondrocytes. Aggrecan was extracellularly distributed in the intervertebral disk (IVD) with intense staining in the posterior AF. Notochordal tissue stained strongly for aggrecan but negatively for perlecan and types I and II collagen. Type I collagen was prominent in the outer AF and less abundant in the NP, while type II collagen was localized throughout the IVD and VB. The immunolocalization patterns observed indicated key roles for perlecan in vasculogenic, chondrogenic, and endochondral ossification processes associated with spinal development.     

Hydrazinoacridine staining of proteins and glycoproteins in polyacrylamide gels

The histochemical method for staining polyaldehydes in tissue sections with p-hydrazinoacridine has been adapted for use in polyacrylamide gels. While staining of histological preparations was reported to be specific for polyaldehydes and independent of bisulfite, both glycoproteins (β chain of haptoglobin) and nonglycoproteins (lysozyme and α chain of haptoglobin) were stained following periodate oxidation, and satisfactory results were highly dependent on the presence of bisulfite. Hydrazinoacridine staining of periodate-treated gels produced an extremely sensitive fluorescent labeling of the haptoglobin β chain and also stained haptoglobin α chain and lysozyme. The proteins could be visualized under visible light as yellow bands which were scanned spectrophotometrically at 440 nm. The β chain of haptoglobin could be subjectively distinguished from the nonglycoproteins both by differential intensity of staining with hydrazinoacridine and Coomassie brilliant blue and by the yellow nature of the fluorescence. The sensitivity of hydrazinoacridine staining of the β chain of haptoglobin compared favorably to that of the commonly used periodic acid-Schiff staining procedures and provided the advantage that nonglycoproteins in complex mixtures could be localized in the gels.     

The antisecretory factor: synthesis and intracellular localisation in porcine tissues

The antisecretory factor, AF, is a 41-kDa protein, cloned and sequenced from a human pituitary library. AF is a potent inhibitor of experimental intestinal hypersecretion in rats and pigs. An antiserum against the C-terminal of the truncated, recombinantly produced AF protein was raised in rabbits. The affinity-purified antiserum was used to study the expression of AF in mucosal membranes and in the pituitary gland of the pig; distinctly stained cells were found in lymphoid cells in the connective tissue of all parts of the gastrointestinal, respiratory and urinary tracts. Cytoplasmic AF was demonstrated in endocrine and epithelial cells in the pituitary gland. In situ hybridisation with a digoxigenin-labelled mRNA probe also demonstrated specific cytoplasmic staining in epithelial and lymphoid cells in all of these tissues. The cells stained by either method were similarly distributed topographically within the tissues. The results suggest that a specific defined cell population in these various tissues possesses the capability of both synthesising and storing the AF protein within the cellular cytoplasmic compartment.     

Evaluation of the glyoxal-bis-(2-hydroxyanil)-method for staining of calcium in model gelatin films and pancreatic islets.

The nature of tissue calcium, detectable with glyoxal-bis-(2-hydroxyanil), (GBHA), was investigated using gelatin films as model. The results indicate that in the films the procedure detects only the calcium fraction which was ionized in the original gelatin solution. The GBHA staining intensity (absorbance) appeared to be linear with the amount of ionized calcium in the range from 0 to 2 micrograms/cm2. The method allows detection of amounts of ionized calcium as low as 0.15 micrograms/cm2 or 0.0015 pg/mu2. For the measurement of calcium in pancreatic tissue of fed rats, the tissue was subjected to freeze-substitution at -80 degree C in acetone containing 1% oxalic acid. Adjacent sections were stained with either GBHA or aldehyde-fuchsin (AF). Exocrine tissue hardly stained with GBHA whereas islet tissue stained intensely. For GBHA as well as for AF a variation in staining intensity (visual evaluation) between islets was observed. Islet GBHA- and AF-staining intensities did not correlate. The AF-staining intensity but not the GBHA-staining intensity decreased with increasing islet diameter. Also in pancreatic islet tissue the GBHA method appears to be very sensitive and reproducible and small differences in islet GBHA-staining intensity can be detected. The results indicate that between islets differences in ionized calcium content exist. These differences do not correlate with the degree of B-cell granulation.     

Cysteamine exerts multiple effects on the endocrine cells of the rat pancreas

We have studied the effects by cysteamine in vitro and in vivo on hormone production and islet cell metabolism in isolated pancreatic islets and perfused pancreas of the rat. In isolated islets, cysteamine dose-dependently depleted somatostatin immunoreactivity by 50% after 60 min exposure to 1 mmol/l of the compound. This effect appeared to be independent of interaction of the drug with secretion of somatostatin from the pancreatic D-cells. Cysteamine, however, interacted acutely not only with the D-cells, but also markedly suppressed glucose-induced insulin release. Moreover, cysteamine inhibited islet glucose oxidation, an effect which reflects interference with the metabolism mainly of the B-cells. The effect of cysteamine on glucose-induced insulin release was prolonged, since it was still observed in the isolated rat pancreas perfused 24 h after in vivo treatment with cysteamine. In contrast to the effects on glucose-induced insulin release, the response to glibenclamide remained unaffected by a previous exposure to cysteamine in vivo. However, both glucose- and glibenclamide-induced somatostatin secretion was reduced by 50%, whereas basal glucagon secretion was significantly enhanced in pancreata from cysteamine-treated rats vs. control rats. We conclude that (1) cysteamine does not specifically affect the D-cells of the islets, and (2) the multiple effects by cysteamine on islet cell function, particularly on B-cell metabolism and secretion, renders the compound unsuitable for the study of paracrine interactions in the islets.     

On argyrophil reactions of endocrine cells in the human fetal pancreas

Summary The endocrine cells in the pancreas of five human fetuses with gestational ages of 18–20 weeks were examined by light and electron microscopy with special regard to argyrophil reactions. B-cells and typical A and D-cells were easily identified electron microscopically on the basis of their typical secretory granules. In the Grimelius argyrophil silver stain, a concentration of silver grains over the less electron dense peripheral mantle of the A-cell secretory granules was observed by electron microscopy. In the Hellerström and Hellman modification of the argyrophil Davenport alcoholic silver stain, silver grains were concentrated over the internal structures of the D-cell secretory granules. With this stain an accumulation of silver grains was also seen at the surface of the A-cell secretory granules. The argyrophil reaction of the A-granules was less pronounced than in the D-cells. In addition to B-cells and A- and D-cells, two other types of endocrine cell were observed by electron microscopy. These cells were argyrophil with the silver impregnation method of Grimelius. The electron microscopic findings at least partly explain the frequent overlapping between the two staining methods observed at the light microscope level.This study was supported by the Swedish Medical Research Council (Project No. 102)     

The Aldehyde Fuchsin and colloidal iron staining reactions in the canine thyroid C cell

Synopsis The cytochemically reactive groups which are responsible for Aldehyde Fuchsin (AF) and colloidal iron (CI) staining of C cells were investigated in the canine thyroid gland. To this end, stains for proteoglycans and peptide groups were utilized in conjuction with hydrolysis of glycosidic and amide bonds. In addition, the following procedures were used: acetylation, benzoylation, nitrozation, aldehyde blockade, sulphydryl blockade, methylation and mild acid hydrolysis.No acidic proteoglycan, sialic acid, polyphosphate or polysaccharide ester sulphate were detected in C cells; the results suggest that AF staining, after an oxidation step, and CI staining are due to polypeptides. Sulphydryl and carboxyl groups together are necessary for mediating the attachment of AF in C cells and it is adduced that this attachment is due to the combined charges of sulphonic and carboxylic acids. Methylation and acetylation inhibit CI staining and those staining reactions that depend upon carboxylic acid (TB) and hydroxyl groups (PAS) for their dye attachment in C cells. acid hydrolysis, which increases the demonstration of carboxylic acid in C cells, decreases the attachment of hydroxyferric ions. I speculate that this inhibition is due to extraction of iron binding sites in the C cell and conclude that it is not solely carboxylic acids in C cells that are responsible for CI staining.     

Aldehyde Pararosanilin (True Aldehyde Fuchsin) Stains Purified Insulin, Oxidized or Not, Following Adequate Fixation with Either Formalin or Bouin'S Fluid

Gomori reported that aldehyde fuchsin stained the granules of pancreatic islet beta cells selectively and without need of permanganate pretreatment. Others adopted permanganate oxidation because it makes staining faster though much less selective. All aldehyde fuchsins are not equivalent, being made from “basic fuchsin” whose composition may vary from pure pararosanilin to one of its methylated homologs, rosanilin or a mixture. Mowry et al. have shown that only aldehyde fuchsin made from pararosanilin stained unoxidized pancreatic beta cells (PBC). Aldehyde fuchsins made from methylated homologs of pararosanilin stain PBC cells only after oxidation, which induces basophilia of other cells as well; these are less selective for PBC.

Is the staining of PBC by aldehyde fuchsins due to insulin? Others have been unable to stain pure insulin with aldehyde fuchsins except in polyacrylamide gels and only after oxidation with permanganate. They have concluded that insulin contributed to the staining of oxidized but not of unoxidized PBC. This view denies any inherent validity of the more selective staining of unoxidized PBC cells as an indication of their insulin content.

We describe here indisputable staining of unoxidized pure insulins by aldehyde fuchsin made with pararosanilin. Dried spots of insulin dissolved in the stain unless fixed beforehand. Spots of dried insulin solution made on various support media and fixed in warm formalin vapor were colored strongly by the stain. Insulin soaked Gelfoam® sponges were dried, fixed in formalin vapor and processed into paraffin. In unoxidized paraffin sections, presumed insulin inside gel spaces was stained strongly by aldehyde pararosanilin. Finally, the renal tubules of unoxidized paraffin sections of kidneys from insulin-injected mice fixed in either Bouin's fluid or formalin were loaded with material stained deeply by aldehyde pararosanilin. This material was absent in renal tubules of mice receiving no insulin. The material in the spaces of insulin-soaked gels and in the renal tubules of insulin-injected mice was proven to be insulin by specific immunostaining of duplicate sections. The same material was also stained by aldehyde pararosanilin used after permanganate. So, this dye stains oxidized or unoxidized insulin if fixed adequately.     

Nerve fibers in culture and their interactions with non-neural cells visualized by immunofluorescence

Cultures of embryonic mouse spinal cord explants, alone or in combination with rat myotubes, were stained by indirect immunofluorescence using antibodies against three structural proteins to: (a) reveal the distribution of these proteins among different cell types, and (b) test the usefulness of antibody staining to reveal the gross morphology of the neurite network in complex cultures. Affinity column purified antibodies were used against chicken gizzard actin, porcine brain tubulin, and skeletal muscle alpha-actinin. Neurites were stained intensely by anti-actin as was the stress fiber pattern of underlying fibroblasts. With anti-tubulin, the staining of neurites was an order of magnitude more intense than the staining of the microtubule pattern of background fibroblasts. Neurite cell bodies and astrocyte-like glia cells were stained with anti-tubulin and their nuclei remained unstained. Anti-tubulin could thus be used to trace even the finest extensions of nerve processes in spinal cord and spinal cord-muscle cultures. Furthermore, it could be combined with the histochemical reaction for acetylcholinesterase (AChE, EC 3.1.1.7) to demonstrate AChE-positive neurons and specialized nerve-muscle contact sites. The staining of neural elements with anti-alpha-actinin was generally much weaker than with anti-actin and anti-tubulin. Neurites were stained only moderately in comparison to myotube Z lines in the same culture. However, a distinct staining of the periphery of dorsal root ganglion cells was observed. Thus, a protein immunologically related to muscle alpha-actinin is present in the nervous system. In myotubes, Z lines were stained intensely with anti-alpha-actinin while I bands were only faintly stained with anti-actin. In isolated myofibrils, both structures were stained intensely with the same antibody preparations.     

Genome-wide screening of functional long noncoding RNAs in the epicardial adipose tissues of atrial fibrillation

Atrial fibrillation (AF) is the most common arrhythmias, and patients with AF are facing increased risk of heart failure and ischemic stroke. However, the AF pathogenesis, especially the long noncoding RNAs (lncRNA)-related mechanism, has not been fully understood. In this study, we collected RNA sequencing data of the epicardial adipose tissues (EAT) from 6 AF and 6 sinus rhythm (SR) to identify the differentially expressed protein-coding genes (PCGs) and lncRNAs. Functionally, the differentially expressed PCGs were significantly enriched in bone development disease, chronic kidney failure, and kidney disease. Particularly, we found that homeobox (HOX) genes, especially the antisense RNAs, HOTAIRM1, HOXA-AS2 and HOXB-AS2, were significantly downregulated in EAT of AF. The biological function predictions for the dysregulated lncRNAs revealed that TNF signaling pathway was the most frequent pathway that the lncRNAs might participate in. In addition, SNHG16 and RP11-471B22.2 might participate in TGF-beta signaling and ECM-receptor interaction by interacting with the proteins involved in the pathways, respectively. Collectively, we provided some potentially pathogenic lncRNAs in AF, which might be useful for the related researchers to study their functionality and develop new therapeutics.     

An investigation of aldehyde fuchsin staining of unoxidized insulin

Aldehyde fuchsin is a standard stain for the secretion granules of pancreatic B cells. The participation of either insulin or proinsulin in aldehyde fuchsin staining is in dispute. There is some evidence that permanganate oxidized insulin is stained by aldehyde fuchsin. Aldehyde fuchsin staining of unoxidized insulin has not been investigated adequately despite excellent staining results with tissue sections. Unoxidized insulin and proinsulin suspended by electrophoresis in polyacrylamide gels were fixed with Bouin's fluid and placed in aldehyde fuchsin for one hour. Because the unoxidized proteins were not stained by aldehyde fuchsin, it was concluded that neither insulin or proinsulin are responsible for the intense aldehyde fuchsin staining of unoxidized pancreatic B cell granules in tissue sections. A series of controlled experiments was undertaken to test the effects of fixatives, oxidation and destaining procedures on aldehyde fuchsin staining of insulin, proinsulin and other proteins immobilized in polyacrylamide gels. It was demonstrated that only oxidized proteins were stained by aldehyde fuchsin and that cystine content of the proteins had no apparent relation to aldehyde fuchsin staining. It was concluded that neither insulin nor proinsulin is likely to be responsible for the intense aldehyde fuchsin staining of unoxidized pancreatic B cell granules in tissue sections.     

Selective staining of hepatitis B surface antigen in thick epoxy sections of liver.

Hepatitis B surface antigen (HBsAg) in epoxy-embedded liver tissues can be stained by aldehyde-fuchsin stain. Sections are oxidized in KMnO4 acidified with H2SO4, then bleached in NaHSO3, both at 70 C. Heating for oxidation and bleaching are absolutely necessary. Diluted aldehyde-fuchsin stain adjusted to pH 1.5 to 1.8 with NaOH is used for staining. HBsAg is specifically stained purple. Other components such as mitochondria and bile pigments are also strained, but are easily distinguished from HBsAg. This staining method is advantageous for the identification of HBsAg-positive cells for electron microscopic observation.