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.     

Polyacrylamide films as a tool for investigating qualitative and quantitative aspects of the staining of glycosaminoglycans with basic dyes

Synopsis With the introduction of model films of polyacrylamide gel into which purified glycosaminoglycans (GAGs) have been incorporated, the direct recording of metachromatic spectra with virtually no interference of the corresponding orthochromatic peaks has become possible. Because this model system yields situations comparable to those of stained sections under the microscope, it is well suited for investigating qualitative and quantitative aspects of histochemical staining procedures. Previous model experiments have shown that under aqueous conditions only minor differences can be observed between the metachromatic peaks of different GAGs complexed with a suitable dye (e.g. Toluidine Blue O, Thionin, Safranin O, Cresyl Violet, Crystal Violet). In non-aqueous media, such as glycerol and ethylene glycol, the complexes with Toluidine Blue O revealed a special pattern for heparin, having a metachromatic peak (517 nm) about 30 nm lower than that of all other GAGs. This observation has formed the basis of a method for the qualitative microspectro-photometric detection of heparinin situ which was worked out by combining model film experiments with microspectrophotometric data obtained from rat mast cells. Since only a limited number of cells is necessary for obtaining reliable data with this method, the presence of heparin in the cytoplasmic granules of normal human mast cells and basophilic granulocytes could thus be proved directly.Alcian Blue 8GX, another basic dye frequently used in GAG histochemistry, has also been investigated with polyacrylamide films. In contrast to the metachromatic dyes, the rate of staining with Alcian Blue depends to a large extent on the rate of penetration of the dye into the model films. The rate of penetration is also a phenomenon of great importance for dye bindingin situ, where complex basic protein molecules may form a barrier for the Alcian Blue molecules. The model film studies performed so far have yielded conditions that provide maximal staining (up to an optimal level) and a linear relationship between the concentration of GAG and the AB binding. The presence of basic protein, electrostatically bound to the GAG, was not found to influence either the rate of staining or the maximal amount of dye binding.Paper presented at a symposium The Changing directions of carbohydrate histochemistry, at the fifth International Congress of Cytochemistry and Histochemistry in Bucharest, Romania on 1 September 1976.     

Histological, Chromatographic and Spectrophotometric Studies of Toluidine Blue

Chromatographic analysis of commercial batches of toluidine blue shows these to be dye mixtures. Histologically, some samples were found to be poor metachromatic dyes. These unsatisfactory stains contained blue dyes with little or no metachromatic properties as well as a metachromatic fraction. On the other hand, contaminating dyes in histologically satisfactory samples had poor staining qualities and hence did not interfere with the color produced by the metachromatic fraction.

Chromatographic fractionation of different commercial batches of toluidine blue yielded identical, homogeneous metachromatic dyes. These purified dyes had a peak absorption at 615 mμ in contrast to that of purified azure A whose peak absorption was at 622.5 mμ.     

A Microspectrophotometric Analysis of Staining with Carmine, Orcein and Carmine-Orcein

Microspectrophotometric measurements of carmine, orcein and carmine-orcein were made in solutions, in air-dried films and in stained adult and embryonic tissues of the domestic chicken. For individual stains only minor differences were found between dried dye and stained tissue. The absorption curve for carmine in solution showed a single peak at 490 mμ but was bimodal at about 530 and 570 mμ in dry films and stained tissue. Orcein showed a single broad peak at 510 mμ in solution; in dry films and stained tissue a broadening of the absorption curve in the red wavelengths was observed. The dye mixture carmine-orcein in solution showed a single peak at 500 mμ, but in tissue the spectral absorptions closely resembled carmine. With alum-like carmine, spectral changes due to the addition of iron were not detected. The results indicate that nuclear staining with carmine-orcein is due mainly to the carmine component of the mixture. Interpretation of spectral shifts indicates that acew-carmine is a metachromatic stain while aceto-orcein is mainly an ortho-chromatic stain, although some metachromasy is evident.     

Acid polysaccharide content of frog rod outer segments determined by metachromatic toluidine blue staining

Summary Sulfonation of periodate-oxidized vicinal hydroxyl groups on a polysaccharide backbone allows binding of toluidine blue (aldehyde bisulfite-toluidine blue or ABT staining) with a concurrent metachromatic shift of the dye's absorption peak from 630 nm (monomer) to 580 nm (isolated dimer interaction at vicinal sulfonate groups) or 540 nm (dye polymer interaction). A molar absorptivity of 2.358±0.134×10⁴ at 540 nm for polymeric toluidine blue O chloride (TB) aggregates was determined by spectrophotometry of TB bound to hyaluronic acid (HA) and sulfonated glycogen (SG) in water. Microspectrophotometry of ABT stained frog rod outer segments (FROS) showed spectra similar to TB in aqueous HA and SG solutions with absorbances corresponding to 0.063 M dye bound to sugar. Given two dye molecules bound per sugar residue and a rhodopsin concentration of 3.25 mM in FROS, the above indicates 10 stainable sugars per rhodopsin are contained in these cells. Half of these sugars are sensitive to hyaluronidase digestion implying 5 glycosaminoglycan (GAG) repeating units and 5 stainable oligosaccharide sugar residues per rhodopsin in FROS. The GAGs in FROS appear to be primarily HA. Birefringence measurements at 475 nm indicate that this HA and the oligosaccharide of rhodopsin are anisotropically oriented in these cells.Supported by NIH grants EY00012, EY07035 and EY01583     

Direct recording of metachromatic spectra in a model system of polyacrylamide films

Synopsis The metachromatic staining of polyacrylamide films containing different glycosaminoglycans is described. This model system made direct recording of metachromatic curves possible, under circumstances comparable to those of stained sections under the microscope, with virtually no interference of the corresponding orthochromatic peaks.The staining was carried out under standardized conditions (of buffer concentration, pH and temperature) and was shown to follow the Lambert-Beer law. The metachromatic peaks obtained with this system are listed for seven basic dyes, each complexed with seven different glycosaminoglycans.     

Acid polysaccharide content of frog rod outer segments determined by metachromatic toluidine blue staining

Sulfonation of periodate-oxidized vicinal hydroxyl groups on a polysaccharide backbone allows binding of toluidine blue (aldehyde bisulfite-toluidine blue or ABT staining) with a concurrent metachromatic shift of the dye's absorption peak from 630 nm (monomer) to 580 nm (isolated dimer interaction at vicinal sulfonate groups) or 540 nm (dye polymer interaction). A molar absorptivity of 2.358 +/- 0.134 X 10(4) at 540 nm for polymeric toluidine blue O chloride (TB) aggregates was determined by spectrophotometry of TB bound to hyaluronic acid (HA) and sulfonated glycogen (SG) in water. Microspectrophotometry of ABT stained frog rod outer segments (FROS) showed spectra similar to TB in aqueous HA and SG solutions with absorbances corresponding to 0.063 M dye bound to sugar. Given two dye molecules bound per sugar residue and a rhodopsin concentration of 3.25 mM in FROS, the above indicates 10 stainable sugars per rhodopsin are contained in these cells. Half of these sugars are sensitive to hyaluronidase digestion implying 5 glycosaminoglycan (GAG) repeating units and 5 stainable oligosaccharide sugar residues per rhodopsin in FROS. The GAGs in FROS appear to be primarily HA. Birefringence measurements at 475 nm indicate that this HA and the oligosaccharide of rhodopsin are anisotropically oriented in these cells.     

Metachromatic staining and electron dense reaction of glycosaminoglycans by means of Cuprolinic Blue

Summary The cationic phthalocyanin-like dye Cuprolinic Blue, unlike phthalocyanin dyes such as Alcian Blue or Astra Blue, can definitely exhibit a clear metachromatic reaction with appropriate substrates, The application of Cuprolinic Blue to epoxy-embedded semithin sections revealed that mast cell cytoplasmic granules, goblet cell mucin and cartilage matrix stained in violet shades (metachromatic), whereas nuclear chromatin presented a bright blue coloration (orthochromatic). The metachromatic structures showed a high degree of contrast when ultrathin sections treated with Cuprolinic Blue were examined by electron microscopy.Cytophotometric measurements of stained components from the large intestine showed different absorption maxima: at 580 nm for mucin and at 640 nm for nuclei. The spectroscopical analysis revealed a clear-cut metachromatic shift when the dye was in the presence of chondroitin—4-sulphate. The addition of aluminium metal to Cuprolinic Blue solutions resulted in a striking spectral change; under such conditions the dye showed absorption maximum at 530 nm.     

Romanowsky dyes and Romanowsky-Giemsa effect. 5. Structural investigations of the purple DNA-AB-EY dye complexes of Romanowsky-Giemsa staining.

A reproducible Romanowsky-Giemsa staining (RGS) can be carried out with standardized staining solutions containing the two dyes azure B (AB) and eosin Y (EY). After staining, cell nuclei have a purple coloration generated by DNA-AB-EY complexes. The microspectra of cell nuclei have a sharp and intense absorption band at 18,100 cm-1 (552 nm), the so called Romanowsky band (RB), which is due to the EY chromophore of the dye complexes. Other absorption bands can be assigned to the DNA-bound AB cations. Artificial DNA-AB-EY complexes can be prepared outside the cell by subsequent staining of DNA with AB and EY. In the first step of our staining experiments we prepared thin films of blue DNA-AB complexes on microslides with 1:1 composition: each anionic phosphodiester residue of the nucleic acid was occupied by one AB cation. Microspectrophotometric investigations of the dye preparations demonstrated that, besides monomers and dimers, mainly higher AB aggregates are bound to DNA by electrostatic and hydrophobic interactions. These DNA-AB complexes are insoluble in water. Therefore it was possible to stain the DNA-AB films with aqueous EY solutions and also to prepare insoluble DNA-AB-EY films in the second step of the staining experiments. After the reaction with EY, thin sites within the dye preparations were purple. The microspectra of the purple spots show a strong Romanowsky band at 18,100 cm-1. Using a special technique it was possible to estimate the composition of the purple dye complexes. The ratio of the two dyes was approximately EY:AB approximately 1:3. The EY anions are mainly bound by hydrophobic interaction to the AB framework of the electrical neutral DNA-AB complexes. The EY absorption is red shifted by the interaction of EY with the AB framework of DNA-AB-EY. We suppose that this red shift is caused by a dielectric polarization of the bound EY dianions. The DNA chains in the DNA-AB complexes can mechanically be aligned in a preferred direction k. Highly oriented dye complexes prepared on microslides were birefringent and dichroic. The orientation is maintained during subsequent staining with aqueous EY solutions. In this way we also prepared highly orientated purple DNA-AB-EY complexes on microslides. The light absorption of both types of dye complexes was studied by means of a microspectrophotometer equipped with a polarizer and an analyser. The sites of best orientation within the dye preparations were selected under crossed nicols according to the quality of birefringence.(ABSTRACT TRUNCATED AT 400 WORDS)     

Spectroscopic and thermodynamic investigations on the binding of azure B to chondroitin sulfate and the structure of the metachromatic dye complex

The binding of azur B to chondroitin sulfate (CHS) was investigated using absorption spectroscopy. In aqueous solutions it is possible to distinguish three different dye species with absorption bands at 646, 597, and 555 nm. They are assigned to monomers, dimers, and higher aggregates of azure B, which become bound to CHS as the dye concentration (CD) increases. The short-wavelength band (555 nm) causes metachromasia in stained histological materials. When saturation occurs, the metachromatic azure B-CHS complex has a 1:1 composition, i.e., each anionic SO-4 and COO(-)-binding site of CHS binds one dye cation. The composition of the saturated metachromatic complex was determined by spectrophotometric and conductometric titration of CHS with azure B, while the SO-4 and COO- content of CHS was determined by conductometric titration of CHS-acid with NaOH. The binding isotherm of azure B to CHS was determined using gelpermeation chromatography. The isotherm can be described by the model of cooperative binding of ligands to linear biopolymers. We found good agreement between theoretical predictions and experimental findings in the range of 0 less than r less than 0.8 (r = the fraction of occupied binding sites). Using a Schwarz plot, we determined the binding constants of nucleation (Kn = 2.5 X 10(3) M-1) and aggregation (Kq = 1.2 X 10(5) M-1), as well as the cooperativity parameter (q = 50), T = 295 K. With increasing CD, the strong cooperativity of the dye binding favors the formation of metachromatic aggregates rather than monomers and dimers. From the temperature dependence of Kq we evaluated the standard binding enthalpy (delta Hoq = -20.0 kJ mol-1) and entropy (delta Soq = 29.7 JK-1 mol-1) of the cooperative dye binding. The binding was found to be strongly exothermic and accompanied by a thermodynamically favorable entropy increase, this being typical of hydrophobic interactions. Solid azure B-CHS complexes were prepared according to a special dialytic technique and were studied using a microspectrophotometer equipped with a polarizer and an analyzer. The metachromatic 1:1 complex has a broad, intense absorption band whose main peak occurs at 560 nm. This corresponds with the maximum of the metachromatic dye complex in aqueous solution, i.e. 555 nm. The CHS chains of the azure B-CHS complex can be mechanically aligned in a preferred direction (k). We were able to prepare excellently orientated and very fine dye-CHS films which were birefringent and dichroic - the more birefringent, the better the mechanical orientation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mucosal mast cells of the rat intestine: a re-evaluation of fixation and staining properties, with special reference to protein blocking and solubility of the granular glycosaminoglycan

Mucosal mast cells of the gastrointestinal tract constitute a separate cell line within the mast cell system of the rat, differing in several respects from the classical connective tissue mast cells and, unlike the latter, requiring special fixation techniques for their demonstration. We have examined some histochemical properties of mucosal mast cells of the duodenum and compared them with connective tissue mast cells of the tongue or skin. The results indicate that the structural integrity of the granules of both types of mast cell is partly dependent on ionic linkages between glycosaminoglycan and protein. The so far unidentified glycosaminoglycan of mucosal mast cells appears to be more soluble than the heparin of connective tissue mast cells. The strongly fluorescent binding of Berberine to the granules of connective tissue mast cells and, depending on their content, of heparin is absent from mucosal mast cells, confirming previous findings which suggested that they contain a glycosaminoglycan with a lower degree of sulphation. Aldehyde fixation by routine procedures reversibly blocks the cationic dye binding of mucosal mast cell granules. The dye binding groups may be unmasked by trypsination or by long staining times of the order of several days. The results suggest that the blocking of staining by aldehydes is caused by a diffusion barrier of a protein nature. Mucosal and connective tissue mast cells thus differ with respect to the spatial arrangement of glycosaminoglycan and protein in their granules. As a result of the study a modified method for the demonstration of mucosal mast cells in tissue sections is described, based on normal formaldehyde fixation and staining in Toluidine Blue for a long time. It has some advantages over previous methods and preserves the structure of mucosal and connective tissue mast cells equally well.     

DNA-protein binding in interphase chromosomes

The metachromatic dye, azure B, was analyzed by microspectrophotometry when bound to DNA fibers and DNA in nuclei with condensed and dispersed chromatin. The interaction of DNA and protein was inferred from the amount of metachromasy (increased β/α-peak) of azure B that resulted after specific removal of various protein fractions. Dye bound to DNA-histone fibers and frog liver nuclei fixed by freeze-methanol substitution shows orthochromatic, blue-green staining under specific staining conditions, while metachromasy (blue or purple color) results from staining DNA fibers without histone or tissue nuclei after protein removal. The dispersed chromatin of hepatocytes was compared to the condensed chromatin of erythrocytes to see whether there were differences in DNA-protein binding in "active" and "inactive" nuclei. Extraction of histones with 0.02 N HCl, acidified alcohol, perchloric acid, and trypsin digestion all resulted in increased dye binding. The amount of metachromasy varied, however; removal of "lysine-rich" histone (extractable with 0.02 N HCl) caused a blue color, and a purplish-red color (µ-peak absorption) resulted from prolonged trypsin digestion. In all cases, the condensed and the dispersed chromatin behaved in the same way, indicating the similarity of protein bound to DNA in condensed and dispersed chromatin. The results appear to indicate that "lysine-rich" histone is bound to adjacent anionic sites of a DNA molecule and that nonhistone protein is located between adjacent DNA molecules in both condensed and dispersed chromatin.     

Detection and quantitation of proteoglycans extracted from cell culture medium and cultured cartilage slices

Detection and quantitation of extracted proteoglycans, by staining with the dye Alcian blue on cellulose acetate followed by dissolution of the stained cellulose acetate strips in dimethyl sulfoxide containing 0.5% (v/v) sulfuric acid for absorbance measurement, is described. It is shown that, in the present system, the dye uptake by the proteoglycan is dependent only on the glycosaminoglycan content of the proteoglycan. The method is applied to the quantitation and characterization of proteoglycans and glycosaminoglycans, which have been extracted from radiolabeled bovine ankle cartilage and from mononuclear cell supernatant and which have been separated by DEAE-Sephacel column chromatography. The high sensitivity of the method allows detection of proteoglycans in 25-microliters samples of solutions containing as little as 1 microgram of glycosaminoglycan per milliliter of solution.     

Fluorescence microscopy of viable mast cells stained with different concentrations of acridine orange.

Freshly harvested rat peritoneal mast cells were stained with different concentrations of acridine orange, a metachromatic fluorochrome known to form complexes with chromatin and muscopolysaccharides. Fluorescence metachromasia was observed in cytoplasmic granules in cell populations with intracelluar dye contents as low as 5 X 10(-16) mole per cell, one-half decade lower than required to produce metachromatic staining of the nucleus. Cytoplasmic granules did not stain uniformly throughout the cell; some granules exhibited red fluorescence and others green. As the amount of acridine orange uptake per cell was increased, cytoplasmic fluorescence became uniformly red and nuclear fluorescence gradually changed from green to yellow.     

Thin layer chrornatography and histochemistry of Sudan Black B

Summary Thin layer chromatography of commercial Sudan Black B on silica gel with chloroform-benzene (11) as the developing solvent reveals two blue main fractions with R_f values of 0.49 and 0.19, SBB-I and SBB-II respectively. Furthermore at least eighteen secondary fractions or impurities have been found. SBB-I and SBB-II were isolated and purified by preparative thin layer chromatography. Commercial Sudan Black B consists of about 20 p.c. SBB-I, 60 p.c. SBB-II and 20 p.c. secondary fractions.From spectrophotometrical and histochemical investigations it appeared that SBB-I stains lipids more pronounced than SBB-II; moreover SBB-I is more specific for neutral lipids than SBB-II, which fraction may also stain some proteins and acid mucopolysaccharides. Contrary to SBB-II the staining with SBB-I is fairly independent of pH. Finally, the colour of SBB-II changes under the influence of light and air, while SBB-I is much more stable.A physico-chemical study of the nature of SBB-I and SBB-II, including spectrophotometry, chromatography, infrared spectroscopy and chemical analysis revealed, that SBB-II is a basic dye, while SBB-I in spite of the structural resemblance behaves as a neutral one, dissolving therefore better in neutral lipids.As yet the chemical composition of SBB-I and SBB-II, and the relation to the scheme of synthesis of Sudan Black B has not been solved. The unspecificity of lipid staining by Sudan Black B is due to the basicity of SBB-II, and to the instability of this dye toward light and air. Moreover the some eighteen impurities may have some influence on the staining properties. The question of solubility or adsorption processes in the case of lipid staining by Sudan dyes is at least partially answered by the proposition of a dissolving fraction SBB-I and an adsorbed fraction SBB-II. The changing absorption spectra by the corresponding solvatochromic and metachromatic effects may give information about the nature of the lipids stained.     

X-ray microanalysis of toluidine blue stained chromosomes: a quantitative study of the metachromatic reaction of chromatin

Summary The stoichiometry of metachromatic staining of chromatin by toluidine blue was investigated in isolated metaphase chromosomes from L929 cells using X-ray microanalysis. Microspectrophotometric measurements revealed that a hypsochromic shift (from 595 to 570 nm) occurs in toluidine blue stained chromosomes in relation to the staining solution. Under the electron microscope, stained chromosomes showed higher electron density than control chromosomes. After toluidine blue staining, X-ray microanalysis of chromosomes revealed a large increase for sulphur counts and a considerable increase for Fe and Cu counts, while the signal of Mg, Ca, Cl, K and Zn was reduced. After subtraction of the intrinsic sulphur signal, S/P ratios of 0.82 — for euchromatic arms — and 0.85 — for centromeric heterochromatin — were obtained. They are considered representative of dye/DNA phosphate ratios. These results indicate the occurrence of a nearly stoichiometric binding of toluidine blue to chromatin DNA and suggest that an external dye stacking is responsible for the metachromatic staining of metaphase chromosomes.     

Spectroscopic properties of complexes of acridine orange with glycosaminoglycans II. Aggregated complexes-evidence for long-range order.

Aggregated complexes of acridine orange with dermatan and chondroitin sulfates have been studied in aqueous solution by absorption and circular dichroism spectroscopy. Aggregation was found to be favored at high-dye and glycosaminoglycan concentrations, and in solutions where anionic sites of the glycosaminoglycan are effectively complexed with dye. The aggregates can be removed from solution by centrifugation at 27,000 × g for 1 hr or by filtration through a membrane containing pores of 0.1 μm diameter. The aggregated complexes exhibit large-magnitude-ellipticity circular dichroism bands. In addition, the circular dichroism spectrum observed for a solution containing aggregated acridine orange/chondroitin 4-sulfate complexes is nearly a mirror image of that obtained for aggregated acridine orange/dermatan sulfate complexes. Cooperative alterations (sharp transitions) in the circular dichroism ellipticities of the aggregates occur at elevated temperatures, and result in spectroscopically distinct aggregates upon cooling. The circular dichroism properties and temperature effects are attributed to a supramolecular ordering of acridine orange/glycosaminoglycan complexes within the aggregates, which can be reorganized to a more stable form at high temperatures. Mixed aggregates, containing two different glycosaminoglycans, can be formed. The circular dichroism properties of the mixed aggregates also indicate the existence of long-range order in the arrangement of the complexes. Mixed aggregates containing dermatan sulfate and either chondroitin 4-sulfate or chondroitin 6-sulfate resemble pure dermatan sulfate aggregates in circular dichroism characteristics.     

A microfluorometric study of masked metachromasia in cells of the endocrine polypeptide (APUD) series

Synopsis Masked metachromasia can be demonstrated by staining with a metachromatic basis dye after a Feulgen-type hydrolysis of suitably fixed tissue, and is believed to be indicative of polypeptides with a high concentration of side-chain acidic groups and a random-coil conformation. In this investigation, the metachromatic fluorochrome Coriphosphine O was used. After staining, the degree of metachromasia under various conditions and in several tissues was assessed by microspectrofluorometric measurements of the ratio of metachromatic fluorescence (red) to orthochromatic fluorescence (green). This technique was employed, in the first instance, to determine the optimum staining conditions; details of the final staining method are presented. Measurements of metachromasia in different tissues under standardized conditions showed that the degree of metachromasia varied between different cell types in the APUD series.     

Investigations of dye binding in the sequential staining of mucosaccharides by Alcian Yellow-Alcian Blue. II. Spot tests and experiments on dye-mucopolysaccharide (glycosaminoglycan) precipitates

Synopsis The amounts of dye bound to mucopolysaccharide in the histochemical sequential staining Alcian Yellow-Alcian Blue method were determined by studying dye-mucopolysaccharide (glycosaminoglycan) precipitates in test-tube and spot test experiments. In the second step (Alcian Blue) of the method, previously bound Alcian Yellow was released into the staining solution and simultaneously the precipitate took up Alcian Blue. The amounts of Alcian Yellow released and Alcian Blue taken up varied for different mucosaccharides, and depended on the staining time of the second step (Alcian Blue) of the sequence, as well as on the concentration of dye and salt in the Alcian Blue solution. It is thought that, among other things, the Alcian Blue in solution displaces some of the bound Alcian Yellow. Some observations could be explained by the aggregation of dye molecules. The results were in agreement with previous histochemical observations.     

Acharan sulfate, the new glycosaminoglycan from Achatina fulica Bowdich 1822. Structural heterogeneity, metabolic labeling and localization in the body, mucus and the organic shell matrix.

Acharan sulfate, a recently discovered glycosaminoglycan isolated from Achatina fulica, has a major disaccharide repeating unit of -->4)-2-acetyl,2-deoxy-alpha-d-glucopyranose(1-->4)-2-sulfo-alpha-l-idopyranosyluronic acid (1-->, making it structurally related to both heparin and heparan sulfate. It has been suggested that this glycosaminoglycan is polydisperse, with an average molecular mass of 29 kDa and known minor disaccharide sequence variants containing unsulfated iduronic acid. Acharan sulfate was found to be located in the body of this species using alcian blue staining and it was suggested to be the main constituent of the mucus. In the present work, we provide further information on the structure and compartmental distribution of acharan sulfate in the snail body. Different populations of acharan sulfate presenting charge and/or molecular mass heterogeneities were isolated from the whole body, as well as from mucus and from the organic shell matrix. A minor glycosaminoglycan fraction susceptible to degradation by nitrous acid was also purified from the snail body, suggesting the presence of N-sulfated glycosaminoglycan molecules. In addition, we demonstrate the in vivo metabolic labeling of acharan sulfate in the snail body after a meal supplemented with [35S]free sulfate. This simple approach might be applied to the study of acharan sulfate biosynthesis. Finally, we developed histochemical assays to localize acharan sulfate in the snail body by metachromatic staining and by histoautoradiography following metabolic radiolabeling with [35S]sulfate. Our results show that acharan sulfate is widely distributed among several organs.