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.     

Selection for and Enrichment of Non-Discharge Mucocyst Variants of Tetrahymena thermophila 1,2

The present protocol for selection for and enrichment of potential non-discharge mucocyst variants of Tetrahymena thermophila is based on the ability of wild-type cells to discharge their mucocyst contents simultaneously when stimulated with alcian blue 8 GS. Under appropriate ionic conditions, the discharged mucocyst contents form a capsule around each cell and prevent its locomotion. Non-discharge variants unable to shed a capsule are assumed to retain their ability to swim and are simulated in this study by cells not induced to shed their capsule. For mass phenotype screening, the conditions for maximum capsule shedding were established for wild-type cells. One hour starvation in Wagner's solution rendered 100% of the cells competent to shed a capsule when triggered with a 0.4% solution of alcian blue 8 GS. Decontamination of the shedding mixture by addition of egg albumin in a final concentration of 0.1% guaranteed survival of >95% of these cells that were now encapsulated, but allowed up to 5% of the cells to escape their capsule and swim freely. Cells with intact mucocysts and cells with emptied mucocysts were separated in reconstruction experiments by density-gradient centrifugation in which 95% of the cells with intact mucocysts appeared in a discrete band. Using the same protocol, the efficiency of separation was tested with mixtures of morphologically marked (food vacuoles stained with India ink) and genetically marked (resistance to cycloheximide) cells. Using 1:1 mixtures of marked cells with intact mucocysts and cells with emptied mucocysts (or vice versa), the cells with intact mucocysts were efficiently separated from other cells; one cell with emptied mucocysts per 100 cells with intact mucocysts was found in the upper discrete gradient band.     

Electron microscopic visualization of proteoglycans with Alcian Blue.

The intercellular matrices of bovine nasal cartilage, chick embryo perichordal cartilage, and chick embryo mesenchymal cells cultured in vitro have been examined by electron microscopy after staining them with Alcian Blue in salt solutions according to Scott & Dorling (1965). Matrix granules, which are typical components of cartilage at the ultrastructural level, are not visible after Alcian Blue staining and are replaced by alcianophilic rod-like particles, varying in length and width. With tissue cultures, Alcian Blue stains 40-120 A thick filaments which display an orthogonal and longitudinal relationship to collagen fibrils. We assume that cartilage matrix granules represent linear proteoglycans that are coiled as a consequence of the usual glutaraldehyde-osmium fixation. It is thought that Alcian Blue, on the other hand, contributes to the stabilization of the proteoglycans in their original structural arrangement. This stabilizing property presumably also results in the sharp visualization of fine filaments in the tissue culture matrix.     

The chemical and histochemical properties of Alcian Blue

Summary It has been shown that AB combines electrostatically, in the main, with tissue polyanions. Uptake of AB into epithelial mucins is suppressed by lowering the pH of the dye solution. Introduction of sulphate ester groups almost always results in strong AB staining, even in those sections in which staining had been previously suppressed by treatment with sialidase. Differences between species have been noted, and considered in the discussion. It has been shown that the added electrolyte (NaCl, KCl, LiBr etc.) markedly enhances AB staining. An explanation of this, based on the polyvalent character of AB, is offered, in conformity with studies presented in Pt. I on polyanions in solution.Supported by Research Grants D-1325, D-1326 and D-01952 of the National Institutes of Health, Bethesda, Md.     

Simultaneous Preparation and Quantitation of Proteoglycans by Precipitation with Alcian Blue

Conditions for specific interaction between Alcian blue and proteoglycans were optimized by comparing the differential spectra of Alcian blue obtained with purified chondroitin sulfate dissolved in water with the spectra obtained with nasal cartilage proteoglycans dissolved in synovial fluid. A method was then designed that provides specific precipitation of proteoglycans or glycosaminoglycans in 4 M guanidine-HCl in the presence of protein, hyaluronic acid, or nucleic acids. The specificity is achieved by using a low pH in combination with detergent and high salt concentration. Stepwise addition of reagents is necessary to avoid binding of Alcian blue to proteins and nucleic acids. All polyanions, except polysulfates, are first neutralized by lowering the pH to 1.5. By including detergent in this step, the hydrophobic protein regions are blocked and not accessible for binding with the dye. These regions could otherwise bind Alcian blue by hydrophobic interaction. When the Alcian blue reagent is added after, only the polysulfated molecules will remain charged and free to interact with Alcian blue. At least 0.4 M guanidine-HCl is required to abolish the negative interference by proteins. All sulfated glycosaminoglycans are precipitated at 0.4 M guanidine-HCl. With increasing guanidine-HCl concentrations, the different glycosaminoglycans are precipitated in accordance with the critical electrolyte concentration of the respective glycosaminoglycan. The Alcian blue precipitation can be performed at different concentrations of guanidine-HCl in order to separate different classes of proteoglycans. Excess dye and contaminating proteins are removed by a wash in a DMSO-MgCl₂ solution and the precipitate is dissolved in a mixture of guanidine-HCl and propanol. For quantitation, the absorbance is recorded in a microplate reader with the 600-nm filter, the assay being linear between 0.5 and 20 μg proteoglycan. Since no digestion of samples with protease is needed, the proteoglycans are recovered in native form. The proteoglycan-Alcian blue complexes dissociate in the guanidine-HCl/propanol mixture and the proteoglycans can be selectivelyprecipitated with propanol. The dye is used for quantitation and the proteoglycans can be utilized for further analysis.     

Impurities and staining characteristics of Alcian Blue samples

Synopsis The composition of various samples of Alcian Blue^* and related dyes was studied, using t.l.c. (with cellulose as adsorbent andn-butanol: acetic acid: water as developing solvent), solvent extraction and precipitation, i.r. spectroscopy and classical semimicro analysis. All the Alcian Blue samples appeared to contain the same coloured components. The Alcian Green samples were mixtures of these blue components and Alcian Yellow. All the Astra Blue samples examined were composed of the same blue constituents. Colourless components identified were boricacid, dextrin and sulphate and sometimes amounted to nearly three-quarters by weight of the crude dyes. Impurities had only a slight effect on staining with Alcian Blue in aqueous acetic acid but appreciably affected staining by the critical electrolyte concentration (C.E.C.) procedure. Dextrin as impurity raised C.E.C. limits while the inorganic salt impurities raised the C.E.C. values of some substrates and lowered those of others.     

A Note on the Purification of Alcian Blue

Alcian blue 8GX is a copper phthalocyanin dye that shows a high degree of specificity for polyanionic substances such as hyaluronic acid, sialic acid and the chondroitin sulfates. This dye has proved useful for both histochemical and electrophoretic staining of these substances. The Biological Stain Commission has recently begun to certify Alcian blue (Schenk 1981). Commercially available lots contain approximately 50% dye. The remaining constituents have been identified as primarily boric acid, as well as sulfates and dextrins (Scott 1972, Horobin and Goldstein 1972). Horobin and Goldstein (1972) have pointed out that these contaminants may adversely affect staining in the critical electrolyte concentration procedure. Scott (1972), while not ascribing any adverse effects to the presence of boric acid, recommends its removal by differential precipitation with acetone. In this procedure one part of a 2-5% aqueous solution of the dye is added to 5-10 parts of acetone. The precipitated dye is approximately 80% pure. While this method is relatively simple, it does have several drawbacks. Low concentrations of Alcian blue (i.e., 2%) must be used to obtain purities near 80%. Thus a minimum of 250 ml of acetone is needed to purify 1 gram of dye. Furthermore, Horobin and Goldstein (1972) have reported that contamination by dextrin or unknown organic substances (detergent?) interferes with precipitation of the dye enough to make purification by Scott's method impossible. When difficulty in the precipitation of Alcian blue by Scott's method was encountered, the following simple method for the purification of the dye was developed.     

A Note on the Purification of Alcian Blue

Alcian blue 8GX is a copper phthalocyanin dye that shows a high degree of specificity for polyanionic substances such as hyaluronic acid, sialic acid and the chondroitin sulfates. This dye has proved useful for both histochemical and electrophoretic staining of these substances. The Biological Stain Commission has recently begun to certify Alcian blue (Schenk 1981). Commercially available lots contain approximately 50% dye. The remaining constituents have been identified as primarily boric acid, as well as sulfates and dextrins (Scott 1972, Horobin and Goldstein 1972). Horobin and Goldstein (1972) have pointed out that these contaminants may adversely affect staining in the critical electrolyte concentration procedure. Scott (1972), while not ascribing any adverse effects to the presence of boric acid, recommends its removal by differential precipitation with acetone. In this procedure one part of a 2-5% aqueous solution of the dye is added to 5-10 parts of acetone. The precipitated dye is approximately 80% pure. While this method is relatively simple, it does have several drawbacks. Low concentrations of Alcian blue (i.e., 2%) must be used to obtain purities near 80%. Thus a minimum of 250 ml of acetone is needed to purify 1 gram of dye. Furthermore, Horobin and Goldstein (1972) have reported that contamination by dextrin or unknown organic substances (detergent?) interferes with precipitation of the dye enough to make purification by Scott's method impossible. When difficulty in the precipitation of Alcian blue by Scott's method was encountered, the following simple method for the purification of the dye was developed.     

Observations on the glycosaminoglycans of aging bronchial cartilage studied with Alcian Blue

Synopsis The changes in the distribution of acidic glycosaminoglycans in the extracellular matrix of aging human bronchial cartilage have been studied with Alcian Blue using the critical electrolyte technique described by Scott & Dorling (1965). Keratan sulphate was detected in the interterritorial matrix early in the first decade. The factors initiating the synthesis of keratan sulphate by chondrocytes are discussed and a hypothesis is proposed to explain the subsequent localization of this glycosaminoglycan in the extracellular matrix.     

The quantitative determination of glycosaminoglycans in urine with Alcian Blue 8GX

1. The effect of MgCl(2) concentration on the interaction of Alcian Blue 8GX and glycosaminoglycans in the urine of patients with mucopolysaccharidosis was studied by using a new quantitative micro method for the measurement of Alcian Blue-glycosaminoglycan complexes. This provided a means of measuring the critical electrolyte concentrations of urinary glycosaminoglycans. 2. Theoretical considerations based on the preceding paper (Whiteman, 1973) and experimental evidence provided here show that Alcian Blue 8GX may be used for the direct quantitative determination of total urinary glycosaminoglycans. The method is simple, requires sample volumes of 50mul or less, and gives results comparable with those obtained by other more complicated methods.     

Histochemical demonstration of hyaluronic acid molecules by Alcian Blue

Summary Specimens of vitreous humour (monkey eye), Wharton jelly (human umbilical cord) and commercial hyaluronates were immersed in buffered fixative solutions containing either aldehydes and Alcian Blue, or aldehydes and Alcian Blue with MgCl₂ as electrolyte. Two MgCl₂ concentrations were used, 0.025m and 0.3m. Immersion in both solutions induced formation of precipitates which were postfixed in OsO₄, dehydrated and embedded for thin section electron microscopy. The use of the same fixative solution produced morphologically comparable precipitates from all three materials. The precipitates, especially after fixation in the presence of electrolyte, were composed of linear, unbranched filaments, frequently aggregated into bundles. The filaments were considered to be molecules of hyaluronic acid.Part of this work was presented at the 10th Meeting of the European Club for Ophthalmic Fine Structure, Copenhagen, September 3–4, 1982.     

Polyacrylamide-gel electrophoresis and Alcian Blue staining of sulphated glycosaminoglycan oligosaccharides.

Oligosaccharide fragments of glycosaminoglycans may be separated for rapid analysis by electrophoresis through a 10% polyacrylamide matrix. An extensive ladder-like set of bands is observed for partial testicular hyaluronidase digests of chondroitin 4- or 6-sulphate, and for dermatan sulphate. Co-electrophoresis of purified oligosaccharides has established that the major bands of these patterns represent fragments differing in chain length by one disaccharide unit, with the smallest fragments having the greatest mobility. Additional minor bands, representing heterogeneity in the repeating unit structure, are also observed. There are slight differences in the mobilities of oligosaccharides derived from the three major types of sulphated glycosaminoglycans. Alcian Blue is employed for visualization of the digest fragments. Sample loads of 5-10 micrograms per band appear optimum. The smallest oligosaccharide which may be stained by this method is the hexasaccharide. After consideration of this effect, a good correlation is found to exist between densitometric scans of the gel-electrophoretic patterns and gel-filtration chromatographic profiles based on uronic acid concentration.     

The Alcian Blue and combined Alcian Blue-Safranin O staining of glycosaminoglycans studied in a model system and in mast cells

Synopsis Polyacrylamide films containing different glycosaminoglycans have been applied to the study of the Alcian Blue and combined Alcian Blue-Safranin O staining procedures. It was found that the polyacrylamide matrix can be interpreted as some kind of barrier around the substrate molecules, a situation which can be compared to a certain extent with what occursin situ, where complex protein molecules can likewise form a barrier.The Alcian Blue staining of the model films was found to follow the Lambert-Beer law. The time to reach optimal dye binding depended on the concentration of the glycosaminoglycan enclosed in the model films and on the concentration of Alcian Blue in the dye solution. Lowering the pH of the dye solution appeared to increase the rate of staining. Optimal staining of model films in the presence of salt or urea was not possible, because under these conditions the pores of the polyacrylamide matrix became blocked. Alcian Blue was found to bind irreversibly to the glycosaminoglycan molecules enclosed in the polyacrylamide films.The results of the combined Alcian Blue-Safranin O staining applied to model films appeared to be highly dependent on the amount of Alcian Blue bound to the glycosaminoglycan in the first step of the double staining procedure. No specific differences were noticed between the behaviour of the different glycosaminoglycan-Alcian Blue complexes towards the Safranin O binding in the mext step. As the theoretical basis for the application of the combined Alcian Blue-Safranin O staining was also found not to be completely valid, the conclusion was reached that this double staining cannot be used for the histochemical identification of glycosaminoglycans. The colour retained by a certain glycosaminoglycan-containing part of the specimen only delivers information about the accesibility of that part for Alcian Blue.     

The Demonstration of Bone and Cartilage Remodelling Using Alcian Blue and Hematoxylin

A new staining technique based on alcian blue and hematoxylin was used during the study of experimentally produced fractures in long bone. The distinction between cartilage, woven bone, mature bone and necrotic bone during successive stages of the fracture healing process was particularly remarkable. This method was found also to be very useful in the study of general tissue morphology. It is suggested that this postdecalcification light microscopy staining method is suitable for studies of cartilage and bone development with particular reference to ossification, remodelling and bone pathology.     

A puzzling feature of Colloidal Iron positive and Alcian Blue negative material

Summary A puzzling feature of Colloidal Iron positive and Alcian Blue negative substance is encountered in yolk sac of young larvae of a fish —Tilapia mossambica. This yolk material is PAS positive (proved to be due to neutral mucopolysaccharide) and negative to Toluidine Blue, Azure A (pH 2 to 4.5), Aldehyde Fuchsin and AB pH 1. More work is necessary to establish the exact chemical nature of the CI positive material.     

Alcian Blue and Colloidal Iron Staining Methods Adapted to Filter Paper Electrophoresis

Filter paper moistened with solutions used in electro-chromatography was spotted with 0.5-1.0μl of solutions of mucopolysaccharides and allowed to air dry. Substances tested with respect to their staining reaction were as follows: (a) From commercial sources: hyaluronic acid, heparin, chondroitin sulfate, ovomucoid and gastric mucin, (b) From natural sources: blood serum, saliva, tears, vitreous filtrate and aqueous humor. Alcian blue was found to be a good general stain for mucopolysaccharides and for locating such material on filter paper, especially when more specific means were used subsequently for identifying the kind of mucopolysaccharide present. Staining by colloidal iron of materials on filter paper was similar to that by the periodic acid-Schiff reaction. However, heparin and chondroitin sulfate were not stained by iron when on filter paper but were stained when placed on glass slides.     

Increase of Growth Rate and Phagocytic Activity of Tetrahymena Induced By Pseudomonas Lectins

Galactosephilic and mannosephilic lectins from Pseudomonas aeruginosa interact with Tetrahymena pyriformis GL. Specific adsorption of these lectins onto the Tetrahymena can be shown by inhibition of hemagglutination and by peroxidase binding to the cells mediated by the mannosephilic lectins. Interaction with the lectins does not agglutinate the protozoa even after immobilization by Na fluoride, formaldehyde, and glutaraldehyde or after papain treatment. However, inclusion of the lectins in the growth medium increases the growth rate of Tetrahymena and their presence in the medium supplied to starved ciliates increases phagocytosis of Chinese ink and vacuolization.