Absence of Free Aldehydes in Fresh Tissues, as Shown with a Neutralized Schiff Reagent

A neutralized Schiff's reagent (pH 6.7) was prepared and used to investigate the role of the acidic nature of the routine Schiff's reagent (pH 2.6) in the plasmal reaction. The neutralized reagent was satisfactory as an aldehyde reagent in the nucleal reaction on gut and, although giving a less intense reaction than the routine reagent in the PAS reaction on the gut and plasmal reaction on the aorta, was satisfactory here in respect to localization and thus to aldehyde specificity. Control sections for the plasmal reaction of unfixed nerve and aorta gave positive results when placed in the routine Schiff's, this increasing with time left in the reagent. Similar control sections in the neutralized Schiff's reagent remained consistently negative even though left in this reagent for 0.5 hr. The positive reaction of such control sections is apparently due to acid hydrolysis of labile plasmalogens by the routine Schiff's reagent in myelin and elastin and not to the presence of “free” aldehydes in these tissue elements     

Studies of the mechanism of the periodic acid-Schiff histochemical reaction for glycogen using infrared spectroscopy and model chemical compounds.

It has been proposed in the literature that Schiffs reagent reacts with aldehydes to form one of the following types of compounds: alkylsulfonic acids, N-sulfinic acid derivatives, or Schiff bases. Model compounds whose structures are consistent with those proposed in the literature have been synthesized and subjected to infrared analysis. Also, actual products of Schiff reagent reactions with various aldehydes have been isolated and examined using infrared spectroscopy. Comparison of the spectra of the model compounds with those of Schiff-aldehyde reaction products yielded the following conclusions: 1. The reaction of simple organic aldehydes with Schiff's reagent produces an alkylsulfonate-type reaction product. 2. The reaction of periodate-oxidized glycogen with Schiff's reagent probably involves the formation of an alklsulfonate-type compound. 3. The product of the Schiff-aldehyde reaction exists as neither an N-sulfinic acid nor a Schiff base derivative of the fuchsin molecule.     

On the history of basic fuchsin and aldehyde-schiff reactions from 1862 to 1935

Summary The nature of products formed by aldehydes and Schiff's reagent, whether they are sulfonic or sulfinic acid compounds, has been the subject of much discussion. It seems therefore timely to review early studies of aldehyde-Schiff reactions, including the history of pararosanilin and related dyes. Dyes of the basic fuchsin group have been studied extensively since 1862, and their triphenylmethane structure was established in 1878. The currently used structural formulas were introduced around the turn of the century. Reactions of basic fuchsin with aldehydes, with and without addition of SO₂, were investigated by Schiff in the 1860's i.e. before the structure of these dyes was known. In 1900 Prud'homme showed that the reaction products of basic fuchsin, sodium bisulfite and formaldehyde are alkylated and sulfonated derivatives of the parent compound; further chemical studies indicated attachment of the sulfonic acid group to the carbon atom of the aldehyde. Prud'homme's findings were repeatedly confirmed during the following decades. Wieland and Scheuing were apparently unaware of these studies and introduced the sulfinic acid theory in 1921; furthermore, they considered substitution at two amino group of Schiff's reagent essential for formation of the colored compound. However, later chemical and spectroscopic studies showed no evidence of-N-sulfinic acids but supported the sulfonic acid theory of Prud'homme.     

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.     

Plasmalogen degradation by oxidative stress: production and disappearance of specific fatty aldehydes and fatty alpha-hydroxyaldehydes.

Plasmalogens are often considered as antioxidant molecules that protect cells from oxidative stress. Their vinyl ether bond could indeed be among the first targets for newly formed radicals. However, the long chain aldehydes released from plasmalogens were seldom studied and possible injurious or harmless effects were poorly examined. Thus, the sensitivity of the vinyl ether bond of plasmalogens was investigated in a cerebral cortex homogenate under UV irradiation- or Fe2+/ascorbate-induced peroxidation. Kinetics of aldehyde production was followed by gas chromatography/mass spectrometry. This confirmed that plasmalogens were highly sensitive to oxidative stress (70% cleavage after 90 min UV irradiation and 30% after 30 min of Fe2+/ascorbate). The aldehydes corresponding to sn-1 position 16:0, 18:0, or 18:1 were poorly detected. Conversely, oxidation of plasmalogens yielded preferentially 15:0, 17:0, and 17:1 aldehydes under UV and the alpha-hydroxyaldehydes 16:0-OH and 18:0-OH following a Fe2+/ascorbate oxidation. Kinetics showed that free aldehydes and above all free alpha-hydroxyaldehydes disappeared from the medium as soon as produced. Consequently, the behavior of these released aldehydes in the tissues has to be investigated in order to ascertain the protective effect of plasmalogens against oxidation.     

A method for the quantitative determination of glycerolipids containing O-alkyl and O-alk-1-enyl moieties.

We have developed a spectrophotometric procedure, based on a combination of established methods, for the quantitative determination of aklyl and alk-1-enyl (plasmalogens) ether-linked glycerolipids. It depends upon the release of alkylglycerols and alk-1-enylglycerols from phospholipids by phosphlipase C (Bacillus cereus) followed by saponification or by Vitride reduction the phospholipids; aldehydes are subsequently formed and measured colorimetrically after reacting them with a fuchsin reagent. The total alkyl and alk-1-enyl content of glycerolipids is determined oxidation of the sample withperiodate to form aldehydes and alkylglycolic aldehydes. The O-alk-1-enyl lipid content is determined on a separate sample by measuring the aldehydes produced after acid hydrolysis. The quantity of O-alkyl lipids is calculated from the difference between the values obtained for the total ether-lipid content and that of the O-alk-1enyl lipid content. Alternately, direct determination of alk-1-enylglycerols and alkylglycerols can be made if these hydrolytic products are first separated by thin-layer chromatography.     

Quantification of long-chain aldehydes by gas chromatography coupled to mass spectrometry as a tool for simultaneous measurement of plasmalogens and their aldehydic breakdown products

The cleavage of the specific vinyl ether linkage at the sn-1 position of plasmalogens leads to the formation of two products: the 1-lyso-2-acyl glycerophospholipid and a long-chain fatty aldehyde. Plasmalogens are measured by quantifying one of these two products. In this paper, we describe a rapid and sensitive procedure for measuring plasmalogens via quantification of long-chain fatty aldehydes. After lipid extraction, the sn-1 vinyl ether bond of plasmalogens is cleaved by acidic hydrolysis. The produced aldehydes are then derivatized with (pentafluorobenzyl)hydroxylamine hydrochloride and analyzed by gas chromatography/mass spectrometry in selected-ion mode. Plasmalogens are then indirectly quantified by subtracting the free aldehydes obtained without prior HCl treatment from the total aldehydes obtained after acidic hydrolysis. This method is applied to three rat brain areas selected for this study. Two of these are affected in neurodegenerative diseases (cerebral cortex and hippocampus) and one is rich in white matter (cerebellum). In comparison to other procedures, the advantages of this method are not only its usefulness in plasmalogen quantification but also the identification of aldehydic breakdown products.     

Reactive chlorinating species produced during neutrophil activation target tissue plasmalogens: production of the chemoattractant, 2-chlorohexadecanal.

Recently alpha-chloro fatty aldehydes have been shown to be products of reactive chlorinating species targeting the vinyl ether bond of plasmalogens utilizing a cell-free system. Accordingly, the present experiments were designed to show that alpha-chloro fatty aldehydes are produced by activated neutrophils and to determine their physiologic effects. A sensitive gas chromatography-mass spectrometry technique was developed to detect pentafluorobenzyl oximes of alpha-chloro fatty aldehydes utilizing negative ion chemical ionization. Phorbol 12-myristate 13-acetate activation of neutrophils resulted in the production of both 2-chlorohexadecanal and 2- chlorooctadecanal through a myeloperoxidase-dependent mechanism that likely involved the targeting of both 16 and 18 carbon vinyl ether-linked aliphatic groups present in the sn-1 position of neutrophil plasmalogens. 2-Chlorohexadecanal was also produced by fMLP-treated neutrophils. Additionally, reactive chlorinating species released from activated neutrophils targeted endothelial cell plasmalogens resulting in 2-chlorohexadecanal production. Physiologically relevant concentrations of 2-chlorohexadecanal induced neutrophil chemotaxis in vitro suggesting that alpha-chloro fatty aldehydes may have a role in neutrophil recruitment. Taken together, these studies demonstrate for the first time a novel biochemical mechanism that targets the vinyl ether bond of plasmalogens during neutrophil activation resulting in the production of alpha-chloro fatty aldehydes that may enhance the recruitment of neutrophils to areas of active inflammation.     

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.     

The Feulgen reaction after glutaraldehyde fixation.

A technique is described for performing the Feulgen reaction for DNA on cells and tissues fixed in glutaraldehyde. Blockade free aldehydes by reducing them with fresh 0.5% NaBH4 in 1% NaH2PO4 for 1 hr at room temperature, then rinse in water. Follow by a Feulgen reaction (hydrolysis at room temperature in 6 N HCl for 20 min, Schiff's reagent for 60 min.). Controls assure the completeness and irreversibility of the borohydride blockade. Cytophotometry shows that the DNA content per nucleus is unaffected by the blockade procedure.     

Evidence for the reactivity of fatty aldehydes released from oxidized plasmalogens with phosphatidylethanolamine to form Schiff base adducts in rat brain homogenates

The vinyl ether bond of plasmalogens could be among the first target of free radicals attack. Consequently, because of their location in the membranes of cells, plasmalogens represent a first shield against oxidative damages by protecting other macromolecules and are often considered as antioxidant molecules. However, under oxidative conditions their disruption leads to the release of fatty aldehydes. In this paper, we showed using gas chromatography-mass spectrometry (GC-MS) analyses that fatty aldehydes released from plasmalogens after oxidation (UV irradiation and Fe2+/ascorbate) of cerebral cortex homogenates can generate covalent modifications of endogenous macromolecules such as phosphatidylethanolamine (PE), like the very reactive and toxic malondialdehyde (MDA) and 4-hydroxynonenal (4-HNE). These newly formed Schiff base adducts could be responsible for deleterious effects on cells thus making the protective role of plasmalogens potentially questionable.     

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.     

The Feulgen Reaction after Glutaraldehyde Fixation

A technique is described for performing the Feulgen reaction for DNA on cells and tissues fixed in glutaraldehyde. Blockade free aldehydes by reducing them with fresh 0.5% NaBH₄ in 1% NaH₂PO₄ for 1 hr at room temperature, then rinse in water. Follow by a Feulgen reaction (hydrolysis at room temperature in 6 N HCI for 20 min, Schiff's reagent for 60 min.). Controls assure the completeness and irreversibility of the borohydride blockade. Cytophotometry shows that the DNA content per nucleus is unaffected by the blockade procedure.     

Histochemical Localization of Citral Accumulation in Lemongrass Leaves (Cymbopogon citratus(DC.) Stapf., Poaceae)

Lemongrasses (Cymbopogonspp., Poaceae) are a group of commerciallyimportant C₄tropical grasses. Their leaves contain up to 1.5%(d.wt) essential oils with a typical lemon-like aroma, consistingmainly of citral (a mixture of the isomeric acyclic monoterpenealdehydes geranial and neral). To specifically locate the sitesof citral accumulation in lemongrass we employed Schiff's reagent,which reacts with aldehydes and gives a purple-red colorationwith citral. Using this technique, single oil-accumulating cellswere detected in the adaxial side of leaf mesophyll, commonlyadjacent to non-photosynthetic tissue, and between vascularbundles. Cell walls of these oil cells are lignified. Our resultssuggest that citral accumulation takes place in individual oilcells within the leaf tissues.Copyright 1998 Annals of BotanyCompany Lemongrass;Cymbopogon citratus; Poaceae; oil cells; histochemistry; citral; aldehydes; Schiff's-reagent.     

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.     

The protective role of plasmalogens in iron-induced lipid peroxidation

The role of plasmalogens in iron-induced lipid peroxidation was investigated in two liposomal systems. The first consisted of total brain phospholipids with and without plasmalogens, and the second of phosphatidylethanolamine/phosphatidylcholine liposomes with either diacyl- or alkenylacyl-phosphatidylethanolamine. By measuring thiobarbituric acid reactive substances, oxygen consumption, fatty acids and aldehydes, we show that plasmalogens effectively protect polyunsaturated fatty acids from oxidative damage, and that the vinyl ether function of plasmalogens is consumed simultaneously. Furthermore, the lack of lag phase, the increased antioxidant efficiency with time, and the experiments with lipid- and water-soluble azo compounds, indicate that plasmalogens probably interfere with the propagation rather than the initiation of lipid peroxidation, and that the antioxidative effect cannot be related to iron chelation.     

The chemical nature of de Tomasi Schiff reagent

Summary Samples of de Tomasi's Schiff reagent were allowed to age. During this process physical, chemical and staining properties of the reagent were monitored. Certain physical and chemical properties of Schiff's reagent correlated with staining intensities. Thus a fall in the iodine titre and a rise in the pH (indicating loss of sulphur dioxide) accompanied falls of intensity of Feulgen-stained frog red-cell nuclei and of P.A.S.-stained cellulose sheet. Ageing sulphite solutions exibited analogous physical and chemical changes. Thin layer and ion-exchange chromatography of Schiff's reagent demonstrated at least four colourless (but colour generating) derivatives, all of which were cationic. NMR spectroscopy showed that the carbon skeletons of these compounds were simple and symmetrical. The ageing of Schiff's reagent appears to be primarily due to changes in its inorganic components. The aldehyde-reactive compounds probably differ only in the nature of the oxysulphur substituent on their central carbon atom.     

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.     

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.