The histochemistry of Alcian blue

Summary Boric acid has been identified as a major component of Alcian blue 8GX, comprising 40–50% by weight of commercial samples. Several methods are outlined whereby Alcian blue 8GX may be freed of boric acid. The simplest involves differential precipitation of Alcian blue 8GX from aqueous solution with acetone.     

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.     

Histochemistry of Alcian blue

Summary Two new cationic copper phthalocyanins, isomers of each other, have been synthesised, and compared with Alcian blue 8GX as stains for a variety of polyanions. Analysis of dye-substrate affinities has been carried out using the critical electrolyte concentration (CEC) approach. Recently acquired data on the complete structure of Alcian blue permit interpretations of the affinities in terms of clearly defined interactions with known features of the secondary structures of natural and synthetic nucleic acids. Molecular models and the CEC analysis complement each other in providing an integrated picture of the staining mechanism. A size criterion for the intra-helical binding of phthalocyanins has been established, which explains the histochemical staining behaviour of Alcian blue and its analogues. Evidence is produced to show that appropriate dyes may act as templates on which very flexible polyanions containing aromatic rings may take up conformations, in complexes which are very stable.One of the new phthalocyanins based on quinolinic acid, has been shown to have a very specific affinity for RNA in vitro and in tissues, in concentrated salt solutions.The general problem of the analysis of histochemical staining by dyes is discussed. The CEC analysis is obtained in a form which is immediately applicable to the investigation of tissue polyanions.Future developments of cationic phthalocyanin dyes, to perform specific histochemical tasks, are indicated.     

An alternative Alcian Blue dye variant for the evaluation of fetal cartilage

BACKGROUND: The most comprehensive evaluation of vertebrate skeletal development involves the use of Alizarin Red S dye to stain ossified bone and various other dyes to stain cartilage. The dye used most widely to stain fetal cartilage in rodents and rabbits is Alcian Blue 8GX. However, the global supply of this specific dye has been exhausted. Several forms of the dye marketed as Alcian Blue 8GX are now available, although they are not synthesized via the original 8GX manufacturing process. METHODS: One new Alcian Blue 8GX form and two Alcian Blue dye variants were evaluated in rats and rabbits using standard staining procedures. The staining quality of these dyes were evaluated relative to the original form of Alcian Blue 8GX based on cartilage uptake of the dye, clarity of the cartilaginous components, staining intensity of the dye, and overall readability of the specimens under stereomicroscopic evaluation. RESULTS: Staining with the newer form of Alcian Blue 8GX resulted in poor staining quality. The Alcian Blue-Pyridine variant performed well, although staining intensity was less than optimal. The Alcian Blue-Tetrakis variant provided staining characteristics that were most similar to the original form of Alcian Blue 8GX. CONCLUSIONS: Alcian Blue-Tetrakis was markedly better in its ability to stain fetal cartilage than the newer form of Alcian Blue 8GX.     

Histochemistry of Alcian blue

Summary Alcian blue and related copper phthalocyanin dyes carrying cationic charges on substituent aliphatic groups are metachromatic. The unperturbed orthochromatic molecules are easily observed in non-protic solvents of moderately high dielectric constant e. g. dimethyl sulphoxide. Metachromasia is the result of mutual interactions between chromophores. The Alcian blues are aggregated and metachromatic in water at molar concentrations one hundredth those at which toluidine blue is mainly orthochromatic. The relevance of Alcian blue aggregation to the speed of staining, its use in critical electrolyte concentration techniques, and in microspectrophotometry, is considered.     

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.     

Histochemical analysis of extracellular matrix material during embryonic mouse lens morphogenesis in an aphakic strain of mice

Extracellular matrix material (ECM) present during early lens morphogenesis was analyzed histochemically in normal CFW mice and mutant strain aphakia by the Alcian blue 8GX, pH 2.5, Alcian blue 8GX, pH 2.5/periodic acid-Schiff combined, high-iron diamine, and van Gieson methods. At lens placode formation, the optic vesicle basal lamina in both strains was higher in sulfated glycosaminoglycan content than was the ectodermal basal lamina. In the aphakia strain, ECM components were observed intercellularly in the presumptive neural retina and lens rudiment of some specimens. This observation was peculiar to the aphakia strain. At the lens cup stage (10.5 days), the interface ECM became less uniformly dense in the CFW strain, resulting in the formation of a fibrillar structure in the widening interspace area. In contrast, the interface ECM in the mutant strain stained solidly and continuously for acidic materials, particularly sulfated glycosaminoglycans, for a full 2 days longer than in the normal strain. The optic cup and lens rudiment remained closely apposed and intercellular ECM components were observed in these tissues in most mutant specimens throughout these stages. The exact mechanism resulting in these intercellular deposits is unknown, although it is possible that they are either pulled along on the cell surface away from the interface ECM during cell shape changes related to the cell cycle or that they are secreted abnormally due to some disturbed cellular polarity. It is unclear at this time if these abnormalities of the ECM in the aphakia strain play a role in the pathogenesis of the multiple eye anomalies, or if they are a secondary effect of the gene mutation.     

The PARVUS gene is expressed in cells undergoing secondary wall thickening and is essential for glucuronoxylan biosynthesis

Xylan, cellulose and lignin are the three major components of secondary walls in wood, and elucidation of the biosynthetic pathway of xylan is of importance for potential modification of secondary wall composition to produce wood with improved properties. So far, three Arabidopsis glycosyltransferases, FRAGILE FIBER8, IRREGULAR XYLEM8 and IRREGULAR XYLEM9, have been implicated in glucuronoxylan (GX) biosynthesis. In this study, we demonstrate that PARVUS, which is a member of family GT8, is required for the biosynthesis of the tetrasaccharide primer sequence, beta-D-Xyl-(1 --> 3)-alpha-l-Rha-(1 --> 2)-alpha-D-GalA-(1 --> 4)-D-Xyl, located at the reducing end of GX. The PARVUS gene is expressed during secondary wall biosynthesis in fibers and vessels, and its encoded protein is predominantly localized in the endoplasmic reticulum. Mutation of the PARVUS gene leads to a drastic reduction in secondary wall thickening and GX content. Structural analysis of GX using (1)H-nuclear magnetic resonance (NMR) spectroscopy revealed that the parvus mutation causes a loss of the tetrasaccharide primer sequence at the reducing end of GX and an absence of glucuronic acid side chains in GX. Activity assay showed that the xylan xylosyltransferase and glucuronyltransferase activities were not affected in the parvus mutant. Together, these findings implicate a possible role for PARVUS in the initiation of biosynthesis of the GX tetrasaccharide primer sequence and provide novel insights into the mechanisms of GX biosynthesis.     

Dicarboxylic acids with limited numbers of hydrocarbons stabilize cell membrane and increase osmotic resistance in rat erythrocytes

We examined the effect of dicarboxylic acids having 0 to 6 hydrocarbons and their corresponding monocarboxylic or tricarboxylic acids in changing the osmotic fragility (OF) in rat red blood cells (RBCs). Malonic, succinic, glutaric and adipic acids, which are dicarboxylic acids with 1, 2, 3 and 4 straight hydrocarbons located between two carboxylic groups, decreased the OF in a concentration-dependent manner. Other long-chain dicarboxylic acids did not change the OF in rat RBCs. The benzoic acid derivatives, isophthalic and terephthalic acids, but not phthalic acid, decreased the OF in a concentration-dependent manner. Benzene-1,2,3-tricarboxylic acid, but not benzene-1,3,5-tricarboxylic acid, also decreased the OF in rat RBCs. On the other hand, monocarboxylic acids possessing 2 to 7 straight hydrocarbons and benzoic acid increased the OF in rat RBCs. In short-chain dicarboxylic acids, a limited number of hydrocarbons between the two carboxylic groups are thought to form a V- or U-shaped structure and interact with phospholipids in the RBC membrane. In benzene dicarboxylic and tricarboxylic acids, a part of benzene nucleus between the two carboxylic groups is thought to enter the plasma membrane and act on acyl-chain in phospholipids in the RBC membrane. For dicarboxylic and tricarboxylic acids, limited numbers of hydrocarbons in molecules are speculated to enter the RBC membrane with the hydrophilic carboxylic groups remaining outside, stabilizing the structure of the cell membrane and resulting in an increase in osmotic resistance in rat RBCs.     

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.     

Microbial degradation of 19-hydroxy-sterol side chains

Experimental evidence is herein presented to show that C₂₂ acids are key intermediates in the microbial degradation of cholesterol and campesterol (β-sitosterol) side chains. Exposure of 19-hydroxy-sterols to Rhodococcus mutant K-3 gave four new steroid carboxylic acids in addition to that known as estrone (P1); the chemical structures of these metabolites were characterized as 2(3-hydroxy-1,3,5(10)-estratrien-17-yl)-propionic acid (P2), 2-methyl-6(3-hydroxy-1,3,5(10)-estratrien-17-yl)-heptanoic acid (P3), 2,3-dimethyl-6(3-hydroxy-1,3,5(10)-estratrien-17-yl)-heptanoic acid (P4), and 2(3-hydroxy-1,3,5(10), 17-estratetraen-17-yl)-propionic acid (P5). We propose a degradation pathway of 19-hydroxy-cholesterol and campesterol (β-sitosterol) side chains.     

Arabidopsis irregular xylem8 and irregular xylem9: implications for the complexity of glucuronoxylan biosynthesis

Mutations of Arabidopsis thaliana IRREGULAR XYLEM8 (IRX8) and IRX9 were previously shown to cause a collapsed xylem phenotype and decreases in xylose and cellulose in cell walls. In this study, we characterized IRX8 and IRX9 and performed chemical and structural analyses of glucuronoxylan (GX) from irx8 and irx9 plants. IRX8 and IRX9 are expressed specifically in cells undergoing secondary wall thickening, and their encoded proteins are targeted to the Golgi, where GX is synthesized. 1H-NMR spectroscopy showed that the reducing end of Arabidopsis GX contains the glycosyl sequence 4-beta-D-Xylp-(1-->4)-beta-D-Xylp-(1-->3)-alpha-L-Rhap-(1-->2)-alpha-D-GalpA-(1-->4)-D-Xylp, which was previously identified in birch (Betula verrucosa) and spruce (Picea abies) GX. This indicates that the reducing end structure of GXs is evolutionarily conserved in woody and herbaceous plants. This sequence is more abundant in irx9 GX than in the wild type, whereas irx8 and fragile fiber8 (fra8) plants are nearly devoid of it. The number of GX chains increased and the GX chain length decreased in irx9 plants. Conversely, the number of GX chains decreased and the chain length heterodispersity increased in irx8 and fra8 plants. Our results suggest that IRX9 is required for normal GX elongation and indicate roles for IRX8 and FRA8 in the synthesis of the glycosyl sequence at the GX reducing end.     

Staining of interphase nuclei and mitotic figures in cultured cells with alcian blue 8GX

Cultured endothelial cells derived from bovine calf pulmonary artery were subjected to a variety of fixatives and stained with 1% Alcian blue 8GX at pH 2.59 to 3.26. Within this range of pH, interphase nuclei and especially mitotic figures were (a) strongly stained in cells fixed with 10% formalin (phosphate buffered or unbuffered) or 2.5% buffered glutaraldehyde, (b) weakly stained or unstained in cells fixed in formaldehyde containing divalent cations, and (c) unstained in cells fixed in acetic acid-containing fluids. However, optimal nuclear staining with Alcian blue under the conditions of this study was judged to be achieved after fixation with neutral phosphate buffered 10% formalin. Endothelial cell cytoplasm exhibited a similar fixative-dependent staining. At pH 2.59 the cytoplasm of interphase cells fixed in formaldehyde (containing no divalent cations) or glutaraldehyde remained unstained; however, at higher pH cytoplasmic staining did occur and it increased as pH increased. In contrast, when these latter fixatives were employed the cytoplasm of mitotic cells stained at all pH levels tested. In cultured endothelial cells after appropriate fixation, 1% Alcian blue 8GX (pH 2.59) was found to possess the ability to stain nuclei with a selectivity and intensity that compared favorably to those of the Feulgen reaction of Heidenhain iron hematoxylin but without the latters' length and complexity. Therefore, this procedure may provide a rapid, simple, and selective method for visualizing interphase nuclei or mitotic figures, or both in the majority of cultured cells.     

Effects of strong electrolytes on the iron alum-Alcian Blue-Safranin staining of mast cell granules of the rat

Summary Rat mast cells fixed in Carnoy's fluid were stained with iron alum-Alcian Blue-Safranin solution after pre-treatment with strong electrolyte solutions including acids, neutral salts and alkalis. Although both red and blue mast cells were observed without pre-treatment, most mast cells were stained blue and a few red when they were stained after the pre-treatment. Mast cell granules contain salt complexes formed between basic proteins and acidic polysaccharides through ionic linkages between protein basic groups and polysaccharide sulphate and carboxylic acid groups. It is suggested that when sections are treated with strong electrolyte solutions, complexes are broken by disruption of ionic linkages and sulphate and carboxylic acid groups of polysaccharides masked by basic proteins become available for binding Alcian Blue. This was confirmed by model experiments performed with smears of a heparin-lysozyme complex.When mast cells were fixed in aldehyde-containing fixatives, no effects of strong electrolyte solutions on the staining properties of mast cell granules were revealed.     

Staining of interphase nuclei and mitotic figures in cultured cells with Alcian blue 8GX

Summary Cultured endothelial cells derived from bovine calf pulmonary artery were subjected to a variety of fixatives and stained with 1% Alcian blue 8GX at pH 2.59 to 3.26. Within this range of pH, interphase nuclei and especially mitotic figures were (a) strongly stained in cells fixed with 10% formalin (phosphate buffered or unbuffered) or 2.5% buffered glutaraldehyde, (b) weakly stained or unstained in cells fixed in formaldehyde containing divalent cations, and (c) unstained in cells fixed in acetic acid-containing fluids. However, optimal nuclear staining with Alcian blue under the conditions of this study was judged to be achieved after fixation with neutral phosphate buffered 10% formalin. Endothelial cell cytoplasm exhibited a similar fixative-dependent staining. At pH 2.59 the cytoplasm of interphase cells fixed in formaldehyde (containing no divalent cations) or glutaraldehyde remained unstained; however, at higher pH cytoplasmic staining did occur and it increased as pH increased. In contrast, when these latter fixatives were employed the cytoplasm of mitotic cells stained at all pH levels tested. In cultured endothelial cells after appropriate fixation, 1% Alcian blue 8GX (pH 2.59) was found to possess the ability to stain nuclei with a selectivity and intensity that compared favorably to those of the Feulgen reaction or Heidenhain iron hematoxylin but without the latters’ length and complexity. Therefore, this procedure may provide a rapid, simple, and selective method for visualizing interphase nuclei or mitotic figures, or both in the majority of cultured cells.     

Ultrastructural architecture of proteoglycans in the glomerular basement membrane. A cytochemical approach

Rat kidneys were perfused with fixative solutions containing either a) a polycationic dye (Alcian blue 8 GX, Astra blue 6 GLL, cuprolinic blue, ruthenium red), b) a monocationic dye (safranine 0), or c) Alcian blue in the presence of a 0.3 M MgCl2 concentration. Whereas solutions of a revealed the glomerular basement membrane proteoglycans as particles or threads 60 nm apart and arranged in a reticular pattern, solutions of b and c demonstrated new morphological aspects of these molecules. They appeared as tiny filamentous structures, about 100 to 160 nm long, ordered in a network-like pattern with a mesh of about 60-nm width. The filaments displayed lateral branches about 20 nm apart and about 25 nm long, projecting within the meshes. We suggest that the filamentous structures are the protein core, and the branches are the glycosaminoglycans of proteoglycan molecules. Because of this arrangement the negatively charged sites of the glomerular basement membrane would lie closer to each other than previously assumed.     

The structure of mycobactin P, a growth for mycobacterium johnei, and the significance of its iron complex

1. A growth factor for Mycobacterium johnei has been isolated from Mycobacterium tuberculosis as an iron complex; it has been named ferric mycobactin T. 2. Ferric mycobactin T as isolated is a mixture of at least four closely related components differing only in their fatty acid side chains. 3. Mycobactin T resembles mycobactin P in structure but differs in the following respects: (a) the aromatic acid residue is salicylic acid in place of 2-hydroxy-6-methylbenzoic acid; (b) the hydroxy acid residue is (+)-beta-hydroxybutyric acid in place of (-)-3-hydroxy-2-methylpentanoic acid; (c) its components have fatty acid side chains that are mostly different from the side chains of the components in mycobactin P preparations. One minor component in mycobactin T has probably a cis-octadec-2-enoyl side chain. The major side-chain components correspond to acids of chain length C(18)-C(21) that are not n-saturated or n-Delta(2)-unsaturated acids. 4. The differences in biosynthesis between mycobactins T and P are discussed.     

Histochemical analysis of extracellular matrix material in embryonic trisomy 1 mouse eye

Trisomic animals produced from mice doubly heterozygous for Robertsonian translocation chromosomes [Rb(1.3)/Rb(1.10)]consistently show eye defects (e.g., aphakia, microphakia, and retention of lens stalk). To determine if changes in distribution or composition of extracellular matrix material may be a factor in development of these defects, eye structures of trisomy (ts) 1 embryos and normal littermates were studied histochemically using the following methods: Alcian blue 8GX, pH 2.5; periodic acid-Schiff (PAS), Alcian blue/PAS combined; high-iron diamine (HID), and HID/Alcian blue combined. Eye development was divided into stages to account for the known delay in ts 1 mouse development. Differences were found in staining patterns as early as stage 1. In later stages, the most consistent difference was an increased period of contact between lens and optic cup due to retardation of interface matrix dissolution between these rudiments in ts 1 embryos. Eyes in which this occurred had abnormally shaped lenses. Overall, the ts 1 optic cup appeared to have fewer staining abnormalities and dysmorphology than did the lens or interface matrix. Triplication of a chromosome may indirectly alter temporal and spatial organization of extracellular matrix through action on cells responsible for the production of this material. Possible mechanisms of action are discussed.