Histological and Histochemical Uses of Periodic Acid

Periodic acid acts upon the 1,2 glycol linkage (-CHOH -CHOH-) of carbohydrates in tissue sections to produce aldehyde (RCHO+RCHO) which can be colored with Schiff s reagent. The method can be used on frozen or paraffin sections and is useful as a reaction for carbohydrates of tissues: glycogen (in paraffin section only), mucin, basement membrane, reticulin, the colloid of the pituitary stalk and thyroid, some of the acidophile cells of the human anterior hypophysis, the granular cells of the renal arteriole, etc.

In abnormal tissues, it colors many of the “hyaline” materials— amyloid infiltrations, arteriolosclerotic hyaline, colloid droplets, mitotic figures, etc.

The histochemical uses of the periodic-acid-Schiff's reagent (PAS) need careful control because of the possibility of attachment of iodate or periodate to tissue constitutents, producing a recoloration of the Schiff's reagent. Whenever possible the positive reacting material should be further identified by other methods since Lison showed other substances besides aldehydes can recolorize SchifFs reagent.     

Studies on the molecular arrangement of RNA in tissues with a selective topo-optical reaction of RNA

Summary Selective, demonstration of RNA in tissues was achieved by treating tissue sections with potassium permanganate followed by bisulfite and toluidine blue at pH. 1.0 (PBT reaction). It is suggested that this reaction is due to aldehyde groups which are formed by the oxidative cleavage of the pyrimidine rings of RNA which can be selectively demonstrated using bisulfite-toluidine blue as the aldehyde reagent.The specificity of the reaction was tested after RNAase treatment, after acid hydrolysis, and on pure RNA droplets. The aldehyde nature of the reacting groups was checked, after permanganate oxidation, by Schiff's leucofuchsin reagent, and by aldehyde blocking reactions.Two types of intracellular molecular arrangement of RNA molecules could be distinguished by polarization optics after application of the PBT reaction: 1) The strong birefringence, dichroism and metachromatic staining of membrane-bound RNA in ergastoplasm of pancreas, liver and plasma cells indicate a linear (planar) molecular order of RNA molecules on the surface of the membranes, and 2) the isotropic, basophilic staining of RNA not organized in membrane structures (Nissl substance, nucleoli) suggest a random distribution of their dye binding sites.     

Studies on the molecular arrangement of RNA in tissues with a selective topo-optical reaction of RNA.

Selective demonstration of RNA in tissues was achieved by treating tissue sections with potassium permanganate followed by bisulfite and toluidine blue at pH 1.0 (PBT reaction). It is suggested that this reaction is due to aldehyde groups which are formed by the oxidative cleavage of the pyrimidine rings of RNA which can be selectively demonstrated using bisulfite-toluidine blue as the aldehyde reagent. The specificity of the reaction was tested after RNAase treatment, after acid hydrolysis, and on pure RNA droplets. The aldehyde nature of the reacting groups was checked, after permanganate oxidation, by Schiff's leucofuchsin reagent, and by aldehyde blocking reactions. Two types of intracellular molecular arrangement of RNA molecules could be distinguished by polarization optics after application of the PBT reaction: 1) The strong birefringence, dichroism and metachromatic staining of membrane-bound RNA in ergastoplasm of pancreas, liver and plasma cells indicate a linear (planar) molecular order of RNA molecules on the surface of the membranes, and 2) the isotropic, basophilic staining of RNA not organized in membrane structures (Nissl substance, nucleoli) suggest a random distribution of their dye binding sites.     

An alternative technique to reveal polysaccharides in Toxoplasma gondii tissue cysts

Ultrathin sections of tissue cysts isolated from the brain of Toxoplasma gondii infected mice were submitted to two different methodologies derived from the periodic acid - Schiff's reagent (PAS) technique. The use of osmium tetroxide vapor as a developing agent of the aldehyde oxidation to reveal polysaccharides with periodic acid resulted in positive reaction in amylopectin granules in bradyzoites, as well as in the wall and matrix of the cysts, with excellent increment of the ultrastructural morphology. This technique can be used for study of T. gondii-host cell intracellular cycle, the differentiation tachyzoite-bradyzoite, and also for the formation of cysts into the host cells.     

The Selective Staining of Curious Bodies in Lymph Nodes of Patients as a Means for Diagnosis of Sarcoid

Paraffin sections of formalin-fixed tissue from some human lymph nodes manifesting the characteristic lesions of sarcoid contain minute bodies 3-15 μ in diameter. These bodies can be stained by direct application -of Schiff's reagent adjusted to pH 3-3.5, without prior hydrolysis or oxidation. They react positively to the naphthoic acid hydrazide procedure for aldehyde, and their reactivity to both these reagents was blocked by aniline and dimedone. These reactions indicate that the peculiar bodies in sarcoid tissues contain reactive aldehydes, present either before or after the processing of the tissue.     

Improvement in the specificity of the silver staining technique for AgNOR-associated acidic proteins in paraffin sections

Some recently developed silver staining methods allow selective staining of acidic nucleolar proteins. Pretreating deparaffinized sections with Schiff's reagent improves the specificity of Goodpasture and Bloom's AgNOR staining (as modified by Kodama et al.) after aldehyde fixation.     

Some comments on the PAS reaction of glycogen

Synopsis The periodic acid-Schiff (PAS) reaction has been studied in sections of mouse liver using a self-assembled microspectrophotometer. Increased colour intensity was obtained up to 4 hr of oxidation with periodic acid and 2 hr treatment with Schiff's reagent. The oxidation curve showed an initial, steep increase in colouration with a levelling off afterwards, that could not be attributed to loss of aldehyde groups. The results obtained from carrying out the PAS reaction on sections pretreated with -amylase suggest that the reaction takes place in two phases in which the outer glucosyl groups of the glycogen molecule are oxidized more rapidly than the inner ones.     

Autoradiographic thymidine-3H activity after successive steps of the Feulgen reaction.

Autoradiographs were prepared of sections of the ovary of Dytiscus marginalis labelled with thymidine-3H after each successive step of the Feulgen reaction and after treatment with each separate component of the Schiff's reagent. Results of grain counts over ovarian nurse cells showed that losses of thymidine-3H activity occur not only during hydrolysis but also during the successive steps of the Feulgen reaction. It is suggested that the latter decrease in radioactivity may depend on the extraction of fragments of apurinic acid from the sections. An emulsion desensitizing effect has also been observed in sections stained with basic fuchsin alone; this effect appears, however, to be strongly counteracted by the metabisulphite present in the Schiff's reagent.     

Studies on the Preparation and Recoloration of Fuchsin Sulfurous Acid

Some of the factors affecting the recoloration of Schiff's Reagent (fuchsin sulfurous acid or FSA) by formaldehyde have been studied spectrophotometrically to determine the optimal conditions for the reaction of this reagent with aldehydes.

Of the various reducing agents utilized in the preparation of the leuco dye from basic fuchsin, sodium sulfite and bisulfite proved to be the most satisfactory for obtaining in the reagent maximal sensitivity to recoloration with minimal quantitative variation of results.

The relative proportions of reducing agent and basic fuchsin present in die leuco dye determine its sensitivity to recoloration. Under the conditions of the present experiments, greatest reagent recoloration was obtained when the leuco dye contained 0.01 mole of sodium bisulfite and 0.001 mole of basic fuchsin per 100 ml., a ratio of 10/1.

The recoloration of a given amount of FSA is related to the amount of aldehyde and the temperature of the reaction.

The present experiments indicate the desirability of standardizing the composition of FSA and the conditions under which it is used, if the results of different investigators are to be readily reproduced or compared.     

Studies on the Quantitative Nature of the Feulgen Stain

Bacterial suspensions were stained with Schiff's reagent according to the procedure suggested in essence by Dondero et al. (1954). Cell suspensions, Schiff's reagent, supernatant fluids and stained cells were analyzed by a micro-Kjeldahl procedure in an effort to quantitate the Feulgen reaction. The concentration of the bacterial suspension, type of fixative, time of hydrolysis and pH of cells and dye were varied and the effects analyzed quantitatively. While the cells were often stained deeply as determined by visual observation, the quantity of dye nitrogen in the cells was not large enough to be measured with the procedure employed. Significant quantitative results were obtained consistently only when the pH of the Schiff's reagent was raised. Feulgen reactions with solutions of formaldehyde and with solutions of DNA were also analyzed quantitatively after removing the colored compounds with charcoal. The analyses indicated that the DNA solution and the formaldehyde solution reacted differently with the dye.     

Sequential staining of DNA-aldehyde with Schiff's reagent and acriflavine-SO2.

Acid hydrolysed DNA of rat liver was stained with Schiff's reagent at pHs 1.7 or 3.0 followed by staining with acriflavine-SO2 at pH 2.0 as well as with acriflavine-SO2 followed by Schiff's reagent at pH 1.7 or 3.0. Nuclei stained with Schiff's reagent at pH 1.7 were brown-yellow and an analysis of their absorption characteristics revealed two peaks--one at 470 nm and the other at 570 nm. Although nuclei stained with Schiff's reagent at pH 3.0 followed by acriflavine-SO2 were deep magenta in colour, they also showed similar peaks of maximum absorption. Identical peaks were also seen when the sequence of staining was reversed. It is suggested that in the conventional Feulgen-type reactions only some of the DNA-aldehyde molecules are stained; the remaining molecules can be stained by sequential application of another Schiff or Schiff-type reagent such as acriflavine-SO2. The possible mechanism of staining in these cases has been discussed.     

Plain Water as a Rinsing Agent Preferable to Sulfurous Acid After the Feulgen Nucleal Reaction

After staining for the Feulgen nucleal reaction with Schiff's reagent, slides were immediately submerged in running distilled or tap water and washed for 30 sec or longer. Rapid and complete removal of residual Schiff's reagent from the stained tissue will give preparations which show all details characterizing the nucleal reaction, and which are more durable in storage than those processed with the customary washing in a solution of SO₂. Care must be taken to insure that all parts of the slides are thoroughly washed and that, on the surface of the sections, no spilled adhesive or other interfering coating retards the washing. Standardization of the procedure for quantitative DNA determination may be facilitated by this modification.     

Studies in lipid histochemistry

Summary The control reaction with Schiff's reagent demonstrates besides free aldehydes also plasmalogens and is not a proper control test in lipid histochemistry in cases when reactions with Schiff's reagent are used in tissues containing plasmalogens. For the elimination of genuine aldehydes neutral blocking tests should be applied whenever plasmalogens are present.     

A new interpretation of the direct Schiff reaction of elastic connective tissue

A direct Schiff reaction of elastic tissues has been known for many years, but the nature of the native aldehyde-rich components has not been clear. In this study, chicken, quail, and rat embryos and adult rat lung, aorta, and kidney were fixed in methacarn or in a formalin solution, embedded in paraffin, and sections of 8-10 micron obtained. Rehydrated sections were incubated for various periods in solutions of the enzymes chondroitinase ABC, clostripain, collagenase, elastase, heparatinase, hyaluronidase, subtilisin Carlsberg ("protease"), or trypsin, and in solutions of phosphomolybdic acid or sodium borohydride. After incubation, sections were placed, without prior oxidation, in Schiff's reagent, and were ultimately observed and photographed in transmitted light or with blue or green epifluorescence. A Schiff-positive substance was found, always and exclusively, in elastic tissues of the vasculature and lungs, which was hydrolyzed by the proteolytic enzymes to an extent that ranged from complete loss of Schiff reaction in minutes (trypsin) to no loss of Schiff reaction in 22 hr (clostripain). The Schiff-reactive protein preceded the time of appearance of elastin in the early embryos. We conclude that the aldehyde-rich protein responsible for this reaction is a harbinger of elastogenesis in vivo and speculate that it may represent the elastic microfibril or a component thereof.     

The Effect of Formaldehyde on Tissue Lipids and on Histochemical Reactions for Carbonyl Groups

Histcchemical and chemical evidence indicates that formaldehyde combines with unsaturated lipids at the double bond. The resulting complex contains a free carbonyl group which probably originates from the formaldehyde. The reaction occurs over a wide pH range, and takes place in the absence of oxygen or moisture. The reaction product is visualized by the Schiff reagent, and by the Ashbel-Seligman procedure. In the plasmal procedure, when performed on formalin-treated material, the reaction has the same significance as the pseudo-plasmal reaction, i.e. it denotes the presence of double bonds. The Ashbel-Seligman technic seems to be more sensitive to this complex than the Schiff reagent and shows it more markedly than it does the true plasmals and the atmospherically oxidized unsaturated compounds.     

The Effect of Formaldehyde on Tissue Lipids and on Histochemical Reactions for Carbonyl Groups

Histcchemical and chemical evidence indicates that formaldehyde combines with unsaturated lipids at the double bond. The resulting complex contains a free carbonyl group which probably originates from the formaldehyde. The reaction occurs over a wide pH range, and takes place in the absence of oxygen or moisture. The reaction product is visualized by the Schiff reagent, and by the Ashbel-Seligman procedure. In the plasmal procedure, when performed on formalin-treated material, the reaction has the same significance as the pseudo-plasmal reaction, i.e. it denotes the presence of double bonds. The Ashbel-Seligman technic seems to be more sensitive to this complex than the Schiff reagent and shows it more markedly than it does the true plasmals and the atmospherically oxidized unsaturated compounds.     

Silver staining of the nucleolar organizer regions (NORs) in semithin Lowicryl sections

The one-step silver technique was applied to semithin Lowicryl sections of root meristem cells of Allium cepa and a human tumor cell line (TG cells). In vegetal cells, after 5 min of staining reaction, the Ag-NOR proteins formed ring-shaped structures peripherally within the nucleolus. In animal cells silver granules were distributed over the entire nucleolus. The specificity of the staining reaction was increased by incubation of the sections in NH4Cl and Schiff's reagent prior to Ag-NOR silver staining.     

Studies in lipid histochemistry

Summary The influence of different terminal rinsing bathes on the results of methods using Schiff's reagent (S.r.) was studied in tissue sections and in chromatograms. The compound resulting in the reaction of aldehydic groups with S.r. is not stable in the acidic pH range. The amount of aldehydic groups which are set free increases with the acidity of the rinsing bath. This results in a substantial weakening of the original coloration. The use of a slightly acid bisulphite-HCl bath followed by thorough washing in tap water proved to be very good in practice. Strongly acidic bathes (2 N-3 N HCl) must be avoided.     

Silver Staining of the Nucleolar Organizer Regions (NORS) in Semithin Lowicryl Sections

The one-step silver technique was applied to semithin Lowicryl sections of root meristem cells of Allium cepa and a human tumor cell line (TG cells). In vegetal cells, after 5 min of staining reaction, the Ag-NOR proteins formed ring-shaped structures peripherally within the nucleolus. In animal cells silver granules were distributed over the entire nucleolus. The specificity of the staining reaction was increased by incubation of the sections in NH₄Cl and Schiff's reagent prior to Ag-NOR silver staining.     

Light microscopic histochemical detection of terminal galactose and N-acetylgalactosamine residues in rodent complex carbohydrates using a galactose oxidase--Schiff sequence and peanut lectin--horseradish peroxidase conjugate

A technique was investigated for the direct visualization on paraffin sections of galactose and N-acetylgalactosamine residues terminating saccharide chains in complex carbohydrates. Sections were incubated with the enzyme galactose oxidase (GO), which oxidizes the C-6 hydroxyl of galactose or N-acetylgalactosamine (GalNAc) residues, and the resulting aldehyde was visualized by its reaction with Schiff's reagent. Submaxillary and sublingual glands, pancreas, stomach, duodenum, and ileum from mice and rats were stained with the GO-Schiff sequence and results were compared with staining by a peanut lectin-horseradish peroxidase (PL-HRP) conjugate that binds selectively to terminal galactose and preferentially to the terminal dimer beta-D-Gal-(1 leads to 3)-D-GalNAc. Three classes of reactive sites were revealed: 1) those reactive with both GO-Schiff and PL-HRP, 2) those stained with the GO-Schiff sequence but unreactive with PL-HRP, and 3) those GO-Schiff unreactive but PL-HRP positive. Based on the carbohydrate binding specificity of GO and PL, it is suggested that tissue complex carbohydrates in group one contain terminal beta-galactose residues with unmodified hydroxyls at C-2, C-4, and C-6, whereas those in group two contain terminal GalNAc residues. The structure of oligosaccharides in group 3 sites remains enigmatic.