Positive periodic acid-Schiff staining of acid mucopolysaccharides

Synopsis Evidence is presented to demonstrate that acid mucopolysaccharides will stain with the periodic acid-Schiff technique following prolonged oxidation with periodic acid. Smears of purified acid mucopolysaccharides begin to stain slightly with the Schiff reagent after 4 hr of periodate oxidation and reach an optimal staining intensity some time between 7 and 16 hr. The acid mucopolysaccharides in umbilical cord and cock's comb sections begin to stain at about 7 hr, reaching an optimum between 16 and 24 hr. It is suggested that the mechanism of staining of acid mucopolysaccharides in the PAS technique appears to derive from cleavage oftrans groups of the hexuronic acid fraction which require prolonged oxidation since the theoretical more yield is reached with difficulty. Moreover, it would appear that the mechanism of staining with glycogen under the usual conditions of PAS staining perhaps derives from end-group oxidation and subsequent Schiff staining of the engendered aldehydes since glycogen is almost entirely in thetrans configuration. Acid mucopolysaccharides, on the other hand, will not stain uncer the usual conditions as they appear to have a negligible proportion of end groups.     

Basic Fuchsin in Acid Alcohol: A Simplified Alternative to Schiff Reagent

The use of Schiff reagent to demonstrate polysaccharides (after prior periodic oxidation) and nucleic acids (after prior acid hydrolysis) is unnecessary since the same results are obtained by substituting a 20 min staining in a 0.5% w/v solution of basic fuchsin in acid alcohol (ethanol-water-concentrated HC1, 80:20:1) followed by a rinse in alcohol. The shade of the basic fuchsin staining is a little yellower than that achieved with Schiff reagent but the selectivity, light fastness, response to different fixatives, and to prior histo-chemical blocking of the tissue section were much the same for the two methods. The need for prior oxidation or hydrolysis and the inhibitory effect of aldehyde blocking techniques indicate that basic fuchsin, like Schiff reagent, reacts with aldehyde groups. Infrared studies indicate that for cellulose the reaction product is an azomethine.     

Histochemical identification of side chain substituted O-acylated sialic acids: the PAT-KOH-Bh-PAS and the PAPT-KOH-Bh-PAS procedures

Summary Two new methods, based on the original periodic acid-Thionin Schiff-saponification-periodic acid-Basic Fuchsin Schiff (PAT-KOH-PAS) technique of Cullinget al. (1976), have been devised for the histochemical identificantion of side-chainO-acylated sialic acids. In the first of these, the periodic acid-Thionin Schiff-saponification-borohydride reduction-periodic acid-Basic Fuchsin Schiff (PAT-KOH-Bh-PAS) procedure, the specificity of the original PAT-KOH-PAS technique was improved by: (a) extending, when necessary, the initial period of periodate oxidation, (b) increasing the period of exposure to Thionin Schiff reagent from 30 min to 4 h, (c) using a Thionin Schiff reagent prepared by a different method, (d) interposing a borohydride reduction step between the saponification and PAS steps and, (e) extending the period of oxidation in the final PAS step from 10 to 30 min. In the second procedure, the periodic acid-phenylhydrazine-Thionin Schiffborohydride reduction-periodic acid-Basic Fuchsin Schiff (PAPT-KOH-Bh-PAS), based on the periodic acid-phenylhydrazine-Schiff (PAPS) technique of Spicer (1961), blue Thionin Schiff staining was confined to sialic acid residues with oxidizable side chainvicinal diols by interposing a treatment with 0.5% (w/v) aqueous phenylhydrazine hydrochloride for 2 h at room temperature between the initial periodic acid oxidation and the Thionin Schiff steps of the PAT-KOH-Bh-PAS procedure. These procedures are discussed within the general framework of the methods available for the histochemical identification of side-chainO-acylated sialic acids.     

A Simple Procedure for Crystallization of the Schiff Reagent

Formation of crystals in Schiff reagents prepared from SO₂ gas previously has been reported either soon after preparation, using high dye concentrations and heating, or after long periods of storage at room temperature. With the first type of procedure only a low yield of crystals accompanied by dye precipitation was obtained. Crystallization without dye precipitation took place if the reagent, prepared with pararosaniline base or chloride in a saturated SO₂ solution, was stored for a sufficient time at room temperature in partly filled flasks. These crystals remained colorless if washed with acid alcohol after being separated by filtration. Schiff reagents layered with paraffin oil or supplemented with 0.1 M hydroquinone took much longer to crystallize, suggesting that crystallizaticn is promoted by the partial oxidation of sulfurous acid to sulfuric acid. A high yield of crystals can be obtained at room temperature after as little as 24 hr by adding 0.04 M of H₂SO₄ to a Schiff reagent prepared with 2% pararosaniline chloride in a saturated SO₂ solution. A Schiff reagent prepared with only 0.2% of these crystals gives an intense staining in the Feulgen and in the Periodic acid-Schiff reactions.     

The apparent failure of sodium borohydride reduction to block further PAS reactivity in rat epithelial mucins

Synopsis Sections of rat small intestine were oxidized with 1% periodic acid for periods of 1, 2, 5, 10 and 30 min and were subsequently either (a) stained with Schiff reagent, or (b) reduced with sodium borohydride and then treated with either Schiff reagent alone or or by the standard PAS procedure. It was found that whereas sodium borohydride reduction abolished all Schiff staining, initial periods of oxidation in excess of 10 min were necessary to abolish any subsequent PAS reactivity. The theoretical and practical significance of these data is discussed in relation to the recent publication of Bayliss & Adams (1976).     

Pararosaniline or acriflavine-Schiff staining of epoxy embedded tissue after periodic acid oxidation in ethanol: a method suitable for morphometric and fluorometric analysis of glycogen

A method for preparing tissue sections for automatic image analysis of glycogen is described. Large semithin sections of epoxy embedded tissue fixed in glutaraldehyde-osmium were stained with Schiff reagent and acriflavine (fluorescent staining) after resin removal and periodic acid oxidation in ethanol. We found it essential to avoid tissue rehydration before final staining. The Schiff stain permits an assessment of the cellular volume of glycogen, and the acriflavine allows a fluorometric evaluation of glycogen density.     

Pararosaniline Or Acriflavine-Schiff Staining of Epoxy Embedded Tissue After Periodic Acid Oxidation in Ethanol: A Method Suitable for Morphometric and Fluorometric Analysis of Glycogen

A method for preparing tissue sections for automatic image analysis of glyco-gen is described. Large semithin seaions of epoxy embedded tissue fixed in glutaraldehyde osmium were stained with Schiff reagent and acriflavine (fluorescent staining) after resin removal and periodic acid oxidation in ethanol. We found it essential to avoid tissue rehydra-tion before final staining. The Schiff stain permits an assessment of the cellular volume of glycogen, and the acriflavine allows a fluorometric evaluation of glycogen density.     

Periodic acid-Schiff reaction combined with quantitative autoradiography of 3H-thymidine- or 85S-sulfate-Labeled epithelial cells of colon

Summary The influence of periodic acid-Schiff staining on grain counts was examined using autoradiography of guinea pig colon labeled with either ³H-thymidine or ³⁵S-sulfate. Prestaining decreased the grain count, an effect due to the Schiff reagent but not to periodic acid. Poststaining altered the grains which were partly or completely lost, an effect due to periodic acid but not to the Schiff reagent. The suggested procedure is to pretreat the sections with periodic acid, process for autoradiography, and poststain with the Schiff reagent. No silver grain is then lost.     

Histochemical studies of the mechanism of the periodic acid-phenylhydrazine-Schiff (PAPS) procedure

Summary Histochemical investigations of the periodic acid-phenylhydrazine-Schiff (PAPS) procedure were carried out on tissues containing carbohydrate macromolecules known to produce on periodate oxidation, only sialic acid monoaldehydes or hexosedialdehydes or mixtures of the two. The results indicated that the PAPS reaction is a generalized phenomenon independent of the hydrazine or hydrazide used, the nature of the Schiff reagent or the presence of anionic groups. It is proposed that phenylhydrazine condenses with periodate-engendered sialic acid monoaldehydes to yield the corresponding phenylhydrazone and with periodate-engendered dialdehydes to yield the corresponding morpholine or azido derivatives. Subsequent Schiff treatment results in the reversal of the blockade of sialic acid monoaldehydes but not of the dialdehydes, thus leading to selective Schiff staining of sialic acid residues.     

Fixation,decalcification, and tissue processing effects on articular cartilage proteoglycans

Summary Neutral buffered 4% formaldehyde fixation for 48h preserved well the proteoglycan content of bovine articular cartilage. Neither subsequent demineralization in 10% EDTA, nor light microscopic tissue processing, reduced the hexosamine or uronic acid content of the tissue. Fixation in alcoholic solutions increased Safranin O binding as well as periodic acid Schiff reaction of the cartilage matrix as measured by microspectrophotometry. It is suggested that the enhanced staining of cartilage was due to better preservation of the glycoprotein oligosaccharides. Quaternary ammonium salts in the fixative suppressed the staining of cartilage matrix with Safranin O.     

A new histochemical method for the selective periodate oxidation of total tissue sialic acids

Summary Evaluation of the intensity of the periodic acid—Schiff (PAS) staining produced following oxidation for 1 h at 4°C with 0.4mm periodic acid in approximately 1m hydrochloric acid indicated that this reagent completely oxidized all available sialic acid residues of either the sialo- or sialosulphoglycoproteins of human and rat colon or the sialoglycoproteins of rat sublingual gland. These conditions produced no visible Schiff staining of either neutral macromolecules orvicinal diols located on hexose, 6-deoxyhexose orN-acetylhexosamine residues (neutral sugars) of sialo- and sialosulphoglycoproteins. Furthermore, there was no extraction of epithelial glycoproteins or de-O-acylation of side chain substituted sialic acid residues. These data demonstrate that 0.4mm periodic acid in approximately 1m hydrochloric acid can be used as a specific reagent for the selective visualization of sialic acids in the PAS procedure.Studies of the mechanism of the oxidation of neutral sugars with 0.4mm periodic acid in approximately 1m hydrochloric acid indicated that their lack of PAS reactivity was not due to the production of Schiff unreactive hemiacetals or hemialdals. It is suggested that the selectivity of 0.4mm periodic acid in approximately 1m hydrochloric acid is a result of an increase in the rate of the oxidation of the sialic acid residues together with a decrease in the rate of oxidation of neutral sugars.     

An alcohol-soluble Schiff's reagent: a histochemical application of the complex between Schiff's reagent and phosphotungstic acid.

A schedule for staining partially hydrated PAS-positive structures using non-aqueous solutions has been devised. Tissues are dewaxed, taken down to 70% alcohol, oxidised for 10 min in a 1% w/v alcoholic solution of periodic acid, treated with an alcoholic solution of phosphotungstic acid-Schiff reagent complex (PTA-Schiff reagent) for 25 min, washed in alcohol, cleared in xylene and mounted in a synthetic medium. The PTA-Schiff reagent complex prepared from de Tomasi Schiff reagent by precipitation with PTA may be stored in the deep freeze for many months and dissolved freshly in alcohol for use. The PTA-Schiff reagent used as above allows staining of highly water soluble materials such as dextran. From blocking and digestion studies the mode of action seems similar to de Tomasi Schiff reagent. The partial hydration of the tissues prior to reaction was found to be essential for effective staining.     

An alcohol-soluble Schiff's reagent: A histochemical application of the complex between Schiff's reagent and phosphotungstic acid

Summary A schedule for staining partially hydrated PAS-positive structures using non-aqueous solutions has been devised. Tissues are dewaxed, taken down to 70% alcohol, oxidised for 10 min in a 1% w/v alcoholic solution of periodic acid, treated with an alcoholic solution of phosphotungstic acid-Schiff reagent complex (PTA-Schiff reagent) for 25 min, washed in alcohol, cleared in xylene and mounted in a synthetic medium. The PTA-Schiff reagent complex prepared from de Tomasi Schiff reagent by precipitation with PTA may be stored in the deep freeze for many months and dissolved freshly in alcohol for use. The PTA-Schiff reagent sued as above allows staining of highly water soluble materials such as dextran. From blocking and digestion studies the mode of action seems similar to de Tomasi Schiff reagent. The partial hydration of the tissues prior to reaction was found to be essential for effective staining.     

The Use Of Lead Tetraacetate,Benzidine, O-Dianisidine and A “Film Test” In Investigating The Periodic-Acid-Schiff Technic

In order to obtain a better understanding of the “periodic-acid-Schiff” reaction, also known as the “periodic-acid fuchsin-sulfurous-acid” reaction, three types of investigations were carried out

1) The Schiff reagent was replaced by other aldehyde reagents: benzidine or o-dianisidine. There was no significant change in the histological distribution and intensity of the reactions occurring after periodic acid oxidation.

2) Periodic acid was replaced by another oxidizing agent: lead tetraacetate (dissolved in acetic acid). There was no significant change in the histological distribution of the reactions with the Schiff reagent, but some change in their intensity. It was concluded that 1,2-glycols and a-amino alcohols play the main role in the reactions with both oxidants. The presence of α-hydroxy acids in some types of mucous cells is suggested by the results with lead tetraacetate.

Incidently, glycogen and starch are not sufficiently oxidized by lead tetraacetate (in acetic acid) at room temperature to give positive reactions with the Schiff reagent, while cellulose and other periodic-acid-Schiff reactive substances are.

3) The staining of films of presumed reactive substances with the periodic-acid-Schiff technic C O the intense reactivity of many polysaccharides, mucopolysaccharides and mucoproteins, but not of ordinary proteins. (Hyaluronic and chondroitin sulfuric acid are, however, not reactive in vitro).

In conclusion, the periodic-acid-Schiff technic consists of an oxidation of 1,2-glycols and a-amino alcohols to produce aldehyde groups, which are then stained by the Schiff reagent. The “film test” reveals that these radicals are present in certain polysaccharides, mucopolysaccharides and mucoproteins.     

Flow cytometric determination of carbohydrates in human erythrocytes

Carbohydrate components known from biochemical analysis to be present in peripheral normal human erythrocytes so far could not be detected cytochemically. By periodic acid oxidation followed by Schiff pararosaniline (SO2) staining, however, a specific fluorescent signal can be obtained, strong enough to allow measurement by flow cytometry. Dimethylsuberimidate fixation results in low autofluorescence and low staining of unoxidized cells. By treating erythrocyte ghosts similarly, it is found that about 20% of the signal is present in the membrane, most probably due to glycophorins. The main signal resides in the matrix of the fixed erythrocyte and may be due to traces of glycogen and to the glycosylation of proteins, especially hemoglobin.     

A mechanistic study of the histochemical reactions between aldehydes and Basic Fuchsin in acid alcohol used as a simplified substitute for Schiff's reagent

Synopsis For the identification of polysaccharides after periodic acid oxidation or of DNA after acid hydrolysis, a solution of 0.5% w/v Basic Fuchsin in acid alcohol (water-ethanol-concentrated hydrochloric acid 80:20:1 by volume) may be used instead of Schiff's reagent. Sections are stained in the Fuchsin solution for 20 min, after which the unreacted dye is washed off with ethanol. Except for its yellower colour the Fuchsin staining is almost indistinguishable from Schiff's reagent staining.Histochemical blocking studies indicated that the Fuchsin stain, like Schiff's reagent, reacts with aldehyde groups or subsequent oxidation products. The results of studies of model systems (cellulose film oxidized by periodic acid and also of aqueous formaldehyde solution) in which infra-red spectroscopy and, where appropriate, chromatography were used are consistent with the initial coloured products being azomethines which may react further to produce coloured secondary amine derivatives.     

Acceleration of Mallory's Phosphotungstic Acid-Hematoxylin Staining for Skeletal Muscle Fixed in Formalin

The staining time for mammalian skeletal muscle fixed in neutral phosphate-buffered formalin was shortened from 12-24 hr to 10-30 min. The permanganate-oxalate sequence was omitted although oxidation by periodic acid or with iodine was found to be necessary. The material was embedded in paraffin and cut 6 μ or less. Deparaffinized sections were treated with 1% alcoholic iodine for 10 rain followed by 5% Na₂S₂O₃ for 2 min and placed in an oven at 60 C for 10-30 min to stain in a preheated mixture of 50 ml of ripened Mallory's phosphotungstic acid-hematoxylin and 1 ml of 2% phosphomolybdic acid. Experiments with fixation showed that the staining procedure followed Zenker's fluid successfully but not Bouin's fluid. Oxidation by KMnO₄ was effective only after Zenker fixation; oxidation by CrO₃ was unsuccessful.     

Rapid Staining of Nuclei and Chromosomes in Root Tips

Feulgen reagent quickly heated to and maintained at 60 C just before immersion of plant material, basic fuchsin in acid alcohol at room temperature, and pinacyanol at room temperature will stain hydrolyzed root tip nuclei and chromosomes in one minute or less. This technic, coupled with fast fixation, can be utilized when uncertainties exist as to when to begin sampling plant meristem cells for mitoses or when time does not allow for standard fixation and Schiff staining.     

Dimedone as an Aldehyde Blocking Reagent to Facilitate the Histochemical Demonstration of Glycogen

The demonstration of glycogen by the periodic acid-Schiff technique can be clarified by the interposition of a short dimedone blockade after the periodic acid oxidation. This blocks the PAS reaction of the vast majority of materials, but a very much longer blockade is required to abolish the reaction of glycogen. The dimedone-PAS method is valuable in situations where the demonstration of glycogen is otherwise difficult because of the proximity of diastase-fast PAS positive materials. For this purpose dimedone is best used in alcoholic solution (5% in absolute alcohol for about 3 hr at 60°C), since an aqueous solution permits diffusion of the aldehydes produced from the oxidation of glycogen. A saturated aqueous solution, or a 5% solution in 80% alcohol, is much more rapid in its blocking action, however, and may be more satisfactory when dimedone is used simply as an aldehyde blocking reagent.     

Effects of Hydrogen Ion Dissociation and Concentration on The Reactivity of Dichromate-Fixed Tissue Components to the Pas Procedure: Recommendations for Reducing Undesirable Background Staining

The undesirable PAS reactivity of cytoplasmic aldehydes after dichromate fixation can be suppressed without affecting selective staining by lowering the pH of Lillie's Cold Schiff reagent to 1.5. Alternatively, dilution of pH 2.2 Cold Schiff reagent with distilled water (1:2) is recommended. Hydrogen ion concentration and dissociation affect the rate of color formation in various PAS positive sites differentially with respect to the time of incubation in Schiff reagent. Based on these experiments, aldehydes exposed in different tissue components appear to be chemically distinct and separable depending on the rate of color formation and duration of incubation in Schiff reagent.