Histochemical studies on the hyaline capsule of Holopedium gibberum Zaddach (Crustacea,Cladocera)

Summary The jelly capsule of the water flea Holopedium gibberum, was subjected to histochemical procedures for the visualization of acid mucopolysaccharides, amino acids, and proteins. The affinity of the capsule for azure A, alcian blue, colloidal iron, aldehyde fuchsin, and iron diamine reagents, at low pH, indicates the presence of a sulfated mucopolysaccharide. The presence of carboxyl groups, in addition, is indicated by alcian blue affinity in the combined aldehyde fuchsin-alcian blue and high-iron diamine-alcian blue procedures, as well as by the restoration of weak, but definite, basophilia after methylation-saponification pretreatment. The capsule remained alcianophilic in solutions of MgCl₂ as high as 0.4 molar. Cetylpyridinium blockade was removed by KCl solutions of 0.5–1.0 molar. The periodic acid-Schiff reaction was nil to very weak, in spite of extended oxidizing periods. None of the methods used for the visualization of amino acids or proteins gave unequivocally positive results. A possible origin of the capsular material is proposed.     

Some histochemical reactions of mast cells of gerbils,hogs, armadillos and cats

Summary Mast cells of the Mongolian gerbil Meriones unguiculatus, the hog Sus scrofa, the cat Felis catus and the armadillo Pasypus novemcinctus were studied histochemically in relation to various fixation procedures, using azure A at pH 1 and 3, alcian blue at pH 1 and 2.5, diazosafranin at pH 3 and 7.8–8, and the PAS reaction. Fixations were performed in buffered 10% formol and 5% glutaraldehyde, in Kose's fluid, buffered sublimate (B4), lead nitrate and lead acetate formol.With azure A and alcian blue many mast cells were found in the gerbil with the aldehyde fixatives, fewer with the heavy metals. The diazosafranin reaction was present only in the aldehyde material, the PAS reaction was negative.In the hog, mast cells were more numerous after heavy metal fixation, fewer with aldehydes. Azure A stained metachromatically at pH 1 and 3, alcian blue reacted only at pH 1, the PAS reaction was negative, the pH 3 and 8 diazosafranin reactions were positive with all 4 fixations.In the cat, mast cells were moderately numerous with lead acetate formol, rare with formol and absent with glutaraldehyde. They stained with azure A at pH 1 and 3, with alcian blue at pH 1 and 2.5, with diazosafranin at pH 3 and 8 and by the PAS reaction.Armadillo mast cells were more numerous after heavy metal fixations, stained with azure A and alcian blue at pH 1 and 2.5 to 3, and with acid and alkaline diazosafranin.The mast cells of the 4 species vary in their requirements for aldehyde and heavy metal fixation, in their PAS reactivity and in their pH 2.5 alcian blue staining. All are sufficiently sulfated to react to cationic dyes at pH 1, but vary in PAS reactivity, indicating partial or complete sulfation. The presence of 5-hydroxytryptamine is indicated in all four species.Assisted by grant from National Cancer Institute C-04816.     

Alcian Blue Pyridine Variant-a Superior Alternative to Alcian Blue 8GX: Staining Performance and Stability

We compared the staining performance, dye content, solubility, and visual absorption maximum of two batches of alcian blue pyridine variant and of five batches of alcian blue 8GX (C.I. 74240). Whenever possible, we also compared results to those obtained with the same dye batches produced at an earlier date to provide information concerning dye stability. Both alcian blue pyridine variant batches were of high dye content, stable, of satisfactory solubility, and performed well in both the routine Mowry mucin stain and in the critical electrolyte concentration (CEC) stain. Of the five alcian blue 8GX samples, some were also of appropriate dye content, were sufficiently stable, and gave good staining in the two procedures. Two batches, however, were unstable, and three batches were unsatisfactory in staining performance and solubility in the CEC stain. Consequently alcian blue pyridine variant is a superior substitute for alcian blue 8GX.     

Alcian Blue Pyridine Variant–a Superior Alternative to Alcian Blue 8GX: Staining Performance and Stability

We compared the staining performance, dye content, solubility, and visual absorption maximum of two batches of alcian blue pyridine variant and of five batches of alcian blue 8GX (C.I. 74240). Whenever possible, we also compared results to those obtained with the same dye batches produced at an earlier date to provide information concerning dye stability. Both alcian blue pyridine variant batches were of high dye content, stable, of satisfactory solubility, and performed well in both the routine Mowry mucin stain and in the critical electrolyte concentration (CEC) stain. Of the five alcian blue 8GX samples, some were also of appropriate dye content, were sufficiently stable, and gave good staining in the two procedures. Two batches, however, were unstable, and three batches were unsatisfactory in staining performance and solubility in the CEC stain. Consequently alcian blue pyridine variant is a superior substitute for alcian blue 8GX.     

An interesting case of colloidal iron positivity

Summary An interesting case of a colloidal iron (CI) positive basophilic substance in the adrenal medullary cells of amphibia and reptilia is reported here. The substance, however, does not stain by alcian blue (AB). It is negative to PAS, Azure A, aldehyde fuchsin, AB at pH 1 and MgCl₂ — AB though orthochromatically stained by toluidine blue at pH 3. More work is needed to establish the exact nature of the CI positive material.     

Novel Fixation of Plant Tissue, Staining through Paraffin with Alcian Blue and Hematoxylin, and Improved Slide Preparation

Onion (Allium cepa) root tips were fixed in a proprietary solution without aldehyde, toxic metals or acetic acid. Fixed specimens were embedded in paraffin, sectioned on a rotary microtome and mounted on detergent-washed slides without adhesive. Slides with ribbon segments affixed were immersed in 0.2% aqueous alcian blue 8GX in screw-capped Coplin jars in a water bath at 50 C for 1 hr. Excess alcian blue was rinsed off under cold running tap water and the slides were immersed in quick-mixed hematoxylin at room temperature for 15 min. Stained slides were deparaffinized, rinsed with isopropanol, air dried, and coverslips were affixed with resin. Thus, the traditional paraffin microtechnique has been modified at all steps from fixation to finishing slides with coverslips.     

Staining Tomato Fruit Cuticle and Exocarp Tissues

Immature fruit of tomato, Lycopersicon esculentum (Celebrity), was examined to observe the cuticle, its interface with the epidermis, and the general histology of the outer exocarp. Paraffin sections were stained first with Bismarck brown Y. Structures already stained in various hues of brown were stained again with either azure B, aluminum hematoxylin and alcian blue 8GX, or the periodic acid-Schiff (PAS) reaction. Bismarck brown-azure B displayed the cuticle in strong contrast with subjacent tissue; however, nuclei were not easily identified at low magnification. Bismarck brown-hematoxylinalcian blue produced a sharply contrasted combination of yellow cuticle, bright blue cell walls and purple nuclei. Nuclei stained purple with hematoxylin were easily identified at × 100. Bismarck brown-PAS stained the cuticle golden brown and subjacent tissues magenta red. Surprisingly, epidermal cells stained specifically and intensely with PAS while pretreatment with an aldehyde blockade and omission of periodic acid prevented staining of all other tissues.     

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.     

Correlation of Size of Dye Particle and Density of Substrate, with Special Reference to Mucin Staining

Phase contrast observations indicate that most mucins, and the perilacunar capsules of cartilage matrix, are of low refractive index and hence probably of low density. Mast cell granules and cell nuclei are somewhat more dense, but are rather variable. Cytoplasmic chromidial substance, nucleoli and the interstitial matrix of cartilage are of high density. The selectivity of alcian blue, dialysed iron, mucicarmine, mucihaematein and aldehyde fuchsin depends partly on these dyes being of large particle size (as shown by dialysis experiments); they are able to penetrate into and stain basophilic structures of low density (high “permeability” or “porosity”) but not into denser structures. Best's carmine also consists of large particles, and probably stains only those mucins which are of low density and which contain some strongly basic (acidophilic) groups.     

Effects of fuchsin variants in aldehyde fuchsin staining

Aldehyde fuchsin stains pancreatic B cell granules, hypophyseal basophils, goblet cell mucins, gastric chief cells, hyaline cartilage, and elastica. Neither the chemical structure of aldehyde fuchsin nor its staining mechanism is known. This study was undertaken to clarify the role of the fuchsin component of aldehyde fuchsin in its staining reaction. The major findings of this investigation include: 1) single N-methylation of the fuchsin molecule abolishes staining of unoxidized pancreatic B cells, although it does not prevent reaction of fuchsin with paraldehyde; 2) aldehyde fuchsin is probably a Schiff base condensation product of pararosaniline and acetaldehyde; 3) a Schiff base structure alone cannot account for aldehyde fuchsin staining of unoxidized pancreatic B cells; 4) a fully potent aldehyde fuchsin is possibly a Tris-Schiff base derivative of pararosaniline.     

Staining properties of aldehyde fuchsin analogs.

This investigation was designed to clarify the role of the aldehyde component of aldehyde fuchsin in its staining reactions. Several aldehyde fuchsin analogs were prepared by using different aldehydes. The staining quality of these analogs and pararosaniline-HCl was compared with that of aldehyde fuchsin prepared with paraldehyde in the usual way. The major findings of this investigation include: 1) Aldehyde fuchsin staining of nonoxidized pancreatic B cells requires a stain prepared with either paraldehyde or acetaldehyde. 2) An aldehyde moiety is required for aldehyde fuchsin staining of strong tissue anions. 3) Staining of elastic tissue with aldehyde fuchsin analogs resembles staining of strong tissue anions more than staining of nonoxidized pancreatic B cells. Possible reaction mechanisms of aldehyde fuchsin with tissue substrates are discussed.     

Tannic acid, Iron hematoxylin, Alcian blue, and Basic fuchsin for staining islets and reticular fibers of the pancreas

In this technique alpha cells are stained by basic fuchsin, beta cells by iron-hematoxylin, reticular fibers by ferric tannate, and much by alcian blue. Among 6 commonly used fixatives tested, Bouin's fluid fixation (8-12 hr) gave the best staining results. Procedure: paraffin sections to water; 0.5% Li₂CO₃ to remove picric acid; 20% tannic acid, 15 min; wash well; 2-4 sec in 0.5% basic fuchsin containing 10% alcohol; rinse, then differentiate in 1% aniline in 90% alcohol until alpha cells are red and beta cells pink; 1% phosphomolybdic acid, 1 min; 5% hematoxylin in 2% iron alum, 0.5 min; wash well; 1% filtered alcian blue SGX, 15 sec; rinse, dehydrate, clear, and mount in synthtic resin. Results: reticular fibers, black; acinar cells, orange to gray; alpha cells, red; collagenous fibers, red; beta cells, gray granules; ducts, bluish-green. The method was tested on rat, rabbit, dog, hamster, cow and man.     

Energy dispersive X-ray microanalysis of sulfated glycosaminoglycans in cartilage matrix stained with alcian blue 8GX

X-ray spectra were recorded from 400-700 nm matrix areas of 0.5 micron sections prepared from the articular cartilages of 15- and 23-year-old human cadavers. The X-ray microanalysis was carried out (i) on untreated material; (ii) after removing sulfate group by a methylation procedure; (iii) after staining with a copper containing cationic phatolcyanin dye, alcian blue 8GX, preceded by carboxymethylation. K alpha peaks of sulphur could be detected in methylated (i.e. desulfated) samples. These peaks probably indicated the presence of sulphur-containing amino acids in different matrix proteins. Consequently, the measurements of sulphur despite its general use cannot be recommended for the X-ray microanalysis of sulfated glycosaminoglycans of cartilage matrix. K alpha peaks of copper could be identified after carboxymethylation and staining with alcian blue. After carboxymethylation, alcian blue can only be bound to the dissociated sulfate groups of glycosaminoglycans in the cartilage matrix. According to our spectrophotometric studies, approximately one molecule of alcian blue combined with one sulfate group. These data suggested that this technique could be used for semiquantitative estimation of sulfated glycosaminoglycans in small areas of the cartilage matrix. Using this method, we found a higher occurrence of sulfated glycosaminoglycans in the territorial matrix than in the interterritorial matrix of the intermediate and deep zones of the human articular cartilage.     

Only aldehyde fuchsin made from pararosanilin stains pancreatic B cell granules and elastic fibers in unoxidized microsections: problems caused by mislabelling of certain basic fuchsins

The most distinctive property of aldehyde fuchsin is its staining of certain nonionic proteins and peptides in unoxidized cells and tissues. These substances include granules of pancreatic islet B cells, elastic fibers and hepatitis B surface antigen. Aldehyde fuchsin made from two different basic fuchsins, each certified by the Biological Stain Commission and labelled C.I. (Colour Index) No. 42500 (pararosanilin), did not stain pancreatic B cells at all. Stain Commission's records and retesting showed that each of the "faulty" basic fuchsins was not pararosanilin, but rosanilin, whose Colour Index number is 42510. These basic fuchsins were labelled with the wrong Colour Index number when packaged. Additional basic fuchsins were coded by V.M.E. and tested by R.W.M. for their capacity to make satisfactory aldehyde fuchsins. Only certain of these aldehyde fuchsins stained unoxidized pancreatic islet B cells. The same aldehyde fuchsins stained elastic fibers strongly. Each basic fuchsin whose aldehyde fuchsin was judged satisfactory proved to be pararosanilin. Aldehyde fuchsin solutions made from other basic fuchsins stained elastic fibers only weakly and did not stain pancreatic B cells at all in unoxidized sections. Each basic fuchsin whose aldehyde fuchsin was unsatisfactory proved to be rosanilin. It appears that only aldehyde fuchsin made from pararosanilin stains unoxidized pancreatic B cell granules dependably. We found that basic fuchsins from additional lots of Commission-certified pararosanilin and rosanilin were also labelled with incorrect Colour Index numbers when packaged. Steps were taken to prevent recurrences of such mislabelling which has made it difficult until now to correlate differences in the properties of pararosanilin and rosanilin. A table is provided of all basic fuchsins that have been certified by the Biological Stain Commission since 1963 when they began the practice of subdesignating basic fuchsins according to whether they are pararosanilins or nonpararosanilins. The consumer can readily determine from the certification number on the label the correct subdesignation of any Commission-certified basic fuchsin listed here. Until now, mislabelling of some lots of pararosanilin as rosanilin and vice-versa has confused and frustrated the users of basic fuchsins in other applications such as the carbol fuchsin staining of tubercle bacilli and certain cytochemical tests, e.g. esterase and acid phosphatase, that utilize hexazotized pararosanilin as a coupling reagent. Consumers experiencing trouble with any Commission-certified dye should look to the Biological Stain Commission for help. This is an important reason for purchasing, whenever possible, only Biological Stain Commission certified dyes.     

On the stainability of plant cell walls with alcian blue

This work is a continuation of a communication on the stainability of broad bean (Vicia faba L.) root tip cells with alcian blue, published some time ago. Following the standard method of staining with alcian blue, the cell walls are very strongly stained, the nuclei (except nucleolus) lightly, the nucleolus and cytoplasm are practically colourless. The weak dyeing of the nucleus is not equal throughout the whole section so that the comparison of stainability of cell walls and nuclei by itself cannot explain the staining with alcian blue. The results of this work on the staining of cell walls (if not including model experiments and experiments in vitro, which are not considered as decisive here) can be summarized as follows: the pH dependence of staining, the loss of stainability as a result of pectinase digestion, blocking of staining by methylation and regeneration of stainability by demethylation and, finally, the impossibility of staining in the presence of NaCl lead to the conclusion that the staining of the material studied in this work is primarily caused by the salt linkage of alcian blue with the free carboxyls of pectic substances. From the comparison of staining with alcian blue and with other basic dyes it follows that in the case of alcian blue some other factors may also take part and are the reason for the selectivity and firmness (fastness) of the staining of cell walls with this dye. Otherwise, the staining of plant cell walls with alcian blue corresponds quite well to the staining of carboxyls containing polysaccharides of animal tissues with this dye. By staining with alcian blue it was found impossible to distinguish between younger and older cell walls within the meristem. However, this staining is suitable for routine use when studying the meristematic tissue. It is often possible to use solutions of a higher pH than generally used.     

LANTHANUM STAINING OF THE SURFACE COAT OF CELLS : Its Enhancement by the Use of Fixatives Containing Alcian Blue or Cetylpyridinium Chloride

Among the techniques which have been reported to stain the surface coat of cells, for electron microscopy, is lanthanum staining en bloc. Similarly, the presence of the cationic dye, Alcian blue 8GX, in a primary glutaraldehyde fixative has been reported to improve the preservation of the surface coat of cells of many types; however, the preserved coat is not very electron opaque unless thin sections are counterstained. The present paper shows that for several rat tissues lanthanum staining en bloc is an effective electron stain for the cell surface, giving excellent contrast, if combined sequentially with prefixation in an aldehyde fixative containing Alcian blue. The cationic substance cetylpyridinium chloride was found to have a similar effect to that of Alcian blue in enhancing the lanthanum staining of the surface coat material of the brush border of intestinal epithelial cells. The patterns of lanthanum staining obtained for the tissues studied strikingly resemble those reported in the literature where tissues are stained by several standard methods for demonstrating mucosubstances at the ultrastructural level. This fact and the reproduction of the effect of Alcian blue by cetylpyridinium chloride constitute a persuasive empirical argument that the material visualized is a mucopolysaccharide or mucopolysaccharide-protein complex.     

Cationic dyes reveal proteoglycans on the surface of epithelial and endothelial kidney cells

The glomerular epithelial cells of the rat kidney fixed by vascular perfusion with an aldehyde solution containing either safranine O or alcian blue (and 0.3 M MgCl2) display filaments which are located close to the outer surface of the plasma membrane. These filaments are similar to those revealed by the same methods in the laminae rarae of the glomerular basement membrane. Alcian blue (and MgCl2) further demonstrates the presence of anionic sites inside the endothelial cell pores of the glomerular and peritubular capillaries, on the luminal surface of endothelial cells of large renal vessels and along the basolateral surface of the epithelial cells of the Bowman capsule and of the proximal convoluted tubule.     

Subependymal glycosaminoglycan networks in adult and developing rat brain

Summary Histochemical studies of normal adult rat brain indicate two types of glycosaminoglycans in the subependymal region of the lateral ventricle. One network is characterized by an affinity for the cationic dyes alcian blue, aldehyde fuchsin and colloidal iron. These reactions occur at pH 1.0 and at 0.5–0.3 M concentration of MgCl₂, which suggests that this material is chondroitin sulfate. The other system is identified by metachromasia with toluidine blue and a loss of PAS staining following sulfation. These findings are consistent with non-sulfated and non-anionic acid mucopolysaccharides. In developing rat brain the differential development of these networks enhances their separate identity. The metachromatic network is present at least by the 10th postnatal day but the polyanionic electrolytes cannot be identified until the 16th to the 22nd days. The possible functional importance of these systems is discussed.     

Subependymal glycosaminoglycan networks in adult and developing rat brain

Histochemical studies of normal adult rat brain indicate two types of glycosaminoglycans in the subependymal region of the lateral ventricle. One network is characterized by an affinity for the cationic dyes alcian blue, aldehyde fuchsin and colloidal iron. These reactions occur at pH 1.0 and at 0.5-0.3 M concentration of MgCl2, which suggests that this material is chondroitin sulfate. The other system is identified by metachromasia with toluidine blue and a loss of PAS staining following sulfation. These findings are consistent with non-sulfated and non-anionic acid mucopolysaccharides. In developing rat brain the differential development of these networks enhances their separate identity. The metachromatic network is present at least by the 10th postnatal day but the polyanionic electrolytes cannot be identified until the 16th to the 22nd days. The possible functional importance of these systems is discussed.