Application of current chemical concepts to metal-hematein and -brazilein stains

Current chemical concepts were applied to Weigert's, M. Heidenhain's and Verhoeff's iron hemateins, Mayer's acid hemalum stain and the corresponding brazilein compounds. Fe bonds tightly to oxygen in preference to nitrogen and is unlikely to react with lysyl and arginyl groups of proteins. Binding of unoxidized hematoxylin by various substrates has long been known to professional dyers and was ascribed to hydrogen bonding. Chemical data on the uptake of phenols support this theory. Molecular models indicate a nonplanar configuration of hematoxylin and brazilin. The traditional quinonoid formula of hematein and brazilein was revised. During chelate formation each of the two oxy- groups of the dye shares an electron pair with the metal and contributes a negative charge to the chelate. Consequently, the blue or black 2:1 (dye:metal) complexes are anionic. Olation of such chelates affects the staining properties of iron hematein solutions. The color changes upon oxidation of hematoxylin, reaction of hematein with metals, and during exposure of chelates to acids can be explained by molecular orbital theory. Without differentiation or acid in dye chelate solutions, staining patterns are a function of the metal. Reactions of acidified solutions are determined by the affinities of the dye ligands. Brazilein is much more acid-sensitive than hematein. This difference can be ascribed to the lack of a second free phenolic -OH group in brazilein, i.e. one hydrogen bond is insufficient to anchor the dye to tissues. Since hematein and brazilein are identical in all other respects, their differences in affinity cannot be explained by van der Waals, electrostatic, hydrophobic or other forces.     

Brazilwood,sappanwood, brazilin and the red dye brazilein: from textile dyeing and folk medicine to biological staining and musical instruments

Abstract

Brazilin is a nearly colorless dye precursor obtained from the heartwood of several species of trees including brazilwood from Brazil, sappanwood from Asia and the Pacific islands, and to a minor extent from two other species in Central America, northern South America and the Caribbean islands. Its use as a dyeing agent and medicinal in Asia was recorded in the 2^nd century BC, but was little known in Europe until the 12^th century AD. Asian supplies were replaced in the 16^th century AD after the Portuguese discovered vast quantities of trees in what is now Brazil. Overexploitation decimated the brazilwood population to the extent that it never fully recovered. Extensive environmental efforts currently are underway to re-create a viable, sustainable population. Brazilin is structurally similar to the better known hematoxylin, thus is readily oxidized to a colored dye, brazilein, which behaves like hematein. Attachment of the dye to fabric is by hydrogen bonding or in conjunction with certain metallic mordants by coordinative bonding. For histology, most staining procedures involve aluminum (brazalum) for staining nuclei. In addition to textile dyeing and histological staining, brazilin and brazilein have been and still are used extensively in Asian folk medicine to treat a wide variety of disorders. Recent pharmacological studies for the most part have established a scientific basis for these uses and in many cases have elucidated the biochemical pathways involved. The principal use of brazilwood today is for the manufacture of bows for violins and other stringed musical instruments. The dye and other physical properties of the wood combine to produce bows of unsurpassed tonal quality.     

Iron Hematoxylin Chelates. I. The Weil Staining Bath

The procedure for the preparation of the staining solution for the Weil myelin sheath stain was systematically varied in respect to pH, concentration, time, temperature and relative proportions of the ingredients. The results were explainable on the basis of the presence of a number of iron hematoxylin chelates in the staining bath. Compounds of the form of [Fe_nHem]^m+ are nuclear stains, those of the form of [FeHem_n]^m± are myelin sheath stains while the precipitate is probably [Fe_nHem_y]_x^m±. The following procedure for the stain is recommended. Mix equal portions of a 0.25% solution of ripened hematoxylin prepared from a 10% alcoholic solution and 1% ferric ammonium sulphate and use immediately. Preferably, the solutions should be at a temperature of about 5 C and the staining done in the refrigerator, but room temperature may be used. Higher temperatures are contraindicated. Hematein should not be substituted for ripened hematoxylin; the resulting stains are too weak to be usable. The absorbance of hematein is no measure of the concentration of the component that stains myelin sheaths. Hematein apparently consists largely of a sparingly soluble highly colored inactive compound.     

Nuclear staining with alum hematoxylin

The hematoxylin and eosin stain is the most common method used in anatomic pathology, yet it is a method about which technologists ask numerous questions. Hematoxylin is a natural dye obtained from a tree originally found in Central America, and is easily converted into the dye hematein. This dye forms coordination compounds with mordant metals, such as aluminum, and the resulting lake attaches to cell nuclei. Regressive formulations contain a higher concentration of dye than progressive formulations and may also contain a lower concentration of mordant. The presence of an acid increases the life of the solution and in progressive solutions may also affect selectivity of staining. An appendix lists more than 60 hemalum formulations and the ratio of dye to mordant for each.     

Nuclear stains with soluble metachrome metal mordant dye lakes. The effect of chemical endgroup blocking reactions and the artificial introduction of acid groups into tissues.

Following our study on the effect of deoxyribonucleic acid (DNA) extraction on nuclear staining with soluble metal mordant dye lakes covering 29 dye lakes we chose a series of lakes representing the three groups: (1) readily prevented by DNA removal, (2) weakened by DNA extraction but not prevented, (3) unaffected by DNA removal, for application of other endgroup blockade reactions. The lakes selected were alum and iron hematoxylins, iron alum and ferrous sulfate galleins, Fe2+ gallo blue E, iron alum celestin blue B, iron alum fluorone black and the phenocyanin TC-FeSO4 sequence. Azure A with and without an eosin B neutral stain, was used as a simple cationic (and anionic) dye control. Methylation was less effective than with simple cationic dyes, but did weaken celestin blue, gallo blue E and phenocyanin Fe2+ nuclear stains. These dyes also demonstrate other acid groups: acid mucins, cartilage matrix, mast cells, central nervous corpora amylacea and artificially introduced carboxyl, sulfuric and sulfonic acid groups. Alum hematoxylin stained cartilage weakly and demonstrated sulfation and sulfonation sites. The iron galleins, iron fluorone black and acid iron hematoxylin do not. A pH 4 iron alum hematoxylin gave no staining of these sites; an alum hematoxylin acidified with 1% 12 N HCl gave weaker results. Deamination prevented eosin and orange G counterstains but did not impair nuclear stains with any of the mordant dye lakes. The simple acetylations likewise did not alter mordant dye nuclear staining, the Skraup reagent gave its usual sulfation effect on other tissue elements, but did not alter nuclear stains by mordant dyes. The mordant dyes do not bind to periodic acid engendered aldehyde sites and p-toluidine/acetic acid and borohydride aldehyde blockades did not alter mordant dye lake nuclear staining. Nitration by tetranitromethane, which blocks azo coupling of tyrosine residues, did not alter nuclear staining by the mordant dye lakes. Benzil at pH 13, which prevents the beta-naphthoquinone-4-Na sulfonate (NQS) arginine reaction and the Fullmer reaction of basic nucleoprotein, did not affect iron gallein, iron or alum hematoxylin stains of nuclei or lingual keratohyalin.     

News from the Biological Stain Commission

Abstract

The origins of repeated hematoxylin shortages are outlined. Lack of integration in the hematoxylin trade exacerbates the problems inherent in using a natural product. Separate corporations are engaged in tree growth and harvesting, dye extraction, processing of extracts to yield hematoxylin, and formulation and sale of hematoxylin staining solutions to the end users in biomedical laboratories. Hematoxylin has many uses in biological staining and no single dye can replace it for all applications. Probably, the most satisfactory substitutes for aluminum-hematoxylin (hemalum) are the ferric complexes of celestine blue (CI 51050; mordant blue 14) and eriochrome cyanine R (CI 43820; mordant blue 3, also known as chromoxane cyanine R and solochrome cyanine R). The iron-celestine blue complex is a cationic dye that binds to nucleic acids and other polyanions, such as those of cartilage matrix and mast cell granules. Complexes of iron with eriochrome cyanine R are anionic and give selective nuclear staining similar to that obtained with acidic hemalum solutions. Iron complexes of gallein (CI 45445; mordant violet 25), a hydroxyxanthene dye, can replace iron-hematoxylin in formulations for staining nuclei, myelin, and protozoa.     

Nuclear stains with soluble metachrome metal mordant dye lakes

Summary Following our study on the effect of deoxyribonucleic acid (DNA) extraction on nuclear staining with soluble metal mordant dye lakes covering 29 dye lakes we chose a series of lakes representing the three groups: (1) readily prevented by DNA removal, (2) weakened by DNA extraction but not prevented, (3) unaffected by DNA removal, for application of other endgroup blockade reactions. The lakes selected were alum and iron hematoxylins, iron alum and ferrous sulfate galleins, Fe²⁺ gallo blue E, iron alum celestin blue B, iron alum fluorone black and the phenocyanin TC-FeSO₄ sequence. Azure A with and without an eosin B neutral stain, was used as a simple cationic (and anionic) dye control.Methylation was less effective than with simple cationic dyes, but did weaken celestin blue, gallo blue E and phenocyanin Fe²⁺ nuclear stains. These dyes also demonstrate other acid groups: acid mucins, cartilage matrix, mast cells, central nervous corpora amylacea and artificially introduced carboxyl, sulfuric and sulfonic acid groups. Alum hematoxylin stained cartilage weakly and demonstrated sulfation and sulfonation sites. The iron galleins, iron fluorone black and acid iron hematoxylin do not. A pH 4 iron alum hematoxylin gave no staining of these sites; an alum hematoxylin acidified with 1% 12 N HCl gave weaker results.Deamination prevented eosin and orange G counterstains but did not impair nuclear stains with any of the mordant dye lakes. The simple acetylations likewise did not alter mordant dye nuclear staining, the Skraup reagent gave its usual sulfation effect on other tissue elements, but did not alter nuclear stains by mordant dyes.The mordant dyes do not bind to periodic acid engendered aldehyde sites and p-toluidine/acetic acid and borohydride aldehyde blockades did not alter mordant dye lake nuclear staining. Nitration by tetranitromethane, which blocks azo coupling of tyrosine residues, did not alter nuclear staining by the mordant dye lakes¹. Benzil at pH 13, which prevents the -naphthoquinone-4-Na sulfonate (NQS) arginine reaction and the Fullmer reaction of basic nucleoprotein, did not affect iron gallein, iron or alum hematoxylin stains of nuclei or lingual keratohyalin.Assisted by Contract Nol-CB-43912 National Cancer Institute     

Does progressive nuclear staining with hemalum (alum hematoxylin) involve DNA,and what is the nature of the dye-chromatin complex?

Previous investigators have disagreed about whether hemalum stains DNA or its associated nucleoproteins. I review here the literature and describe new experiments in an attempt to resolve the controversy. Hemalum solutions, which contain aluminum ions and hematein, are routinely used to stain nuclei. A solution containing 16 Al³⁺ ions for each hematein molecule, at pH 2.0–2.5, provides selective progressive staining of chromatin without cytoplasmic or extracellular “background color.” Such solutions contain a red cationic dye-metal complex and an excess of Al³⁺ ions. The red complex is converted to an insoluble blue compound, assumed to be polymeric, but of undetermined composition, when stained sections are blued in water at pH 5.5–8.5. Staining experiments with DNA, histone and DNA + histone mixtures support the theory that DNA, not histone, is progressively colored by hemalum. Extraction of nucleic acids, by either a strong acid or nucleases at near neutral pH, prevented chromatin staining by a simple cationic dye, thionine, pH 4, and by hemalum, with pH adjustments in the range, 2.0–3.5. Staining by hemalum at pH 2.0–3.5 was not inhibited by methylation, which completely prevented staining by thionine at pH 4. Staining by hemalum and other dye-metal complexes at pH ≤ 2 may be due to the high acidity of DNA-phosphodiester (pK_a ~ 1). This argument does not explain the requirement for a much higher pH to stain DNA with those dyes and fluorochromes not used as dye-metal complexes. Sequential treatment of sections with Al₂(SO₄)₃ followed by hematein provides nuclear staining that is weaker than that attainable with hemalum. Stronger staining is seen if the pH is raised to 3.0–3.5, but there is also coloration of cytoplasm and other materials. These observations do not support the theory that Al³⁺ forms bridges between chromatin and hematein. When staining with hematein is followed by an Al₂(SO₄)₃ solution, there is no significant staining. Taken together, the results of my study indicate that the red hemalum cation is electrostatically attracted to the phosphate anion of DNA. The bulky complex cation is too large to intercalate between base pairs of DNA and is unlikely to fit into the minor groove. The short range van der Waals forces that bind planar dye cations to DNA probably do not contribute to the stability of progressive hemalum staining. The red cation is precipitated in situ as a blue compound, insoluble in water, ethanol and water-ethanol mixtures, when a stained preparation is blued at pH > 5.5.     

The characterisation of structural and antioxidant properties of isoflavone metal chelates

Isoflavone metal chelates are of interest as isoflavones act as oestrogen mimics. Metal interactions may enhance isoflavones biological properties so understanding isoflavone metal chelation is important for the commercial application of isoflavones. This work aimed to determine if isoflavones, daidzein (4',7-dihydroxyisoflavone) and genistein (4',5,7-trihydroxyisoflavone) could chelate with metals as isoflavone chelates. Biochanin A (4'-methoxy-5,7-dihydroxyisoflavone) was also examined for it's ability to chelate with Cu(II) and Fe(III). This study found daidzein does not chelate with Cu(II) and Fe(III) but genistein and biochanin A chelate with a 1:2 M/L stoichiometry. The copper and iron chelates were synthesised and characterised by elemental analysis, FTIR, thermogravimetric analysis (TGA) and electrospray ionisation mass spectrometry (ESI-MS). These studies indicated a 1:2 M/L stoichiometry and suggested the isoflavones bind with the metals at the 4-keto and the 5-OH site. 2,2-diphenyl-1-picrylhydrazyl (DPPH) inhibition assays showed that copper isoflavone chelates have higher antioxidant activity than free isoflavones while the iron isoflavone chelates showed pro-oxidant activity compared to the free isoflavone. Synergistic DPPH studies with 0.02 mM ascorbic acid revealed copper chelates exhibit reduced antioxidant activity versus free isoflavones whereas the iron chelates showed lower pro-oxidant activity except at 1.0 mM.     

Isohematein as a Biological Stain

The possible use of isohematein as a biological stain is considered. Certain characteristics of the dye are discussed in relation to staining technic. A preliminary series of experiments is described. The stomach of the frog, skeletal muscle of the frog, and spinal cord of the cat were used as representative tissues. The dye has greater tinctorial power than hematoxylin (hematein) but it is not so selective for nuclei. The results at hand indicate that the dye may have some value as a differential stain for nerve cell bodies. Fibrillae in smooth muscle cells and cross striatums in skeletal muscle were also brought out.     

Hematoxylin Substitutes: A Survey of Mordant Dyes Tested and Consideration of the Relation of Their Structure to Performance as Nuclear Stains

In the search for hematoxylin substitutes 26 dyes were more or less extensively tested for performance as nuclear stains, usually in combination with aluminum, chromic, ferrous and ferric salts. Reports from the literature on hematoxylin substitutes were also considered, and efforts were made to obtain samples of favorably reported dyes and test them. The reports on anthocyanins include isolated reports on several berry juices and a considerable number of studies on Sambucus niger and Vaccinium mytillus. None of these have so far been tested by us. Otherwise favorable reports have appeared on eleven synthetic dyes and on carmine, brazilin, and hematein. Except for one of the synthetics, naphthazarin, which is no longer manufactured, we had samples of all of these. In addition, more or less unsuccessful trials were made on twelve dyestuffs, some of which were new syntheses designed to combine chelating capacity with nucleophilia. Following Fyg's report of blue nuclear staining with chrome alum carmine, trial was made to change the red nuclear stain of kernechtrot by altering the metal mordant.

The most successful dyes were phenocyanin TC, gallein, fluorone black, alizarin cyanin BB and alizarin blue S. Celestin blue B with an iron mordant is quite successful if properly handled to prevent gelling of solutions.     

Staining Myelin, Elastic Fibers and Nuclei with Iron Hematoxylin

Two iron hematoxylin staining procedures were developed. Both use stable stock solutions and can be prepared volumetrically. The nuclear stain is progressive but differentiation is required for myelin sheath and elastic tissue staining. Histochemical procedures demonstrated that acid, hydroxyl, and aldehyde groups play no role in the staining but amine groups are essential. With both types of stains neither electrostatic bonding nor hydrogen bonding is essential but the nature of the union between tissue and the iron hematoxylin complex was not determined.     

Iron uptake from ferrichrome A and iron citrate in Ustilago sphaerogena.

Double radioactive label transport assays with iron, chromium, and gallium chelates were used to investigate the mechanism of iron uptake by Ustilago sphaerogena. In iron-deficient cells, ferrichrome A iron was taken up without appreciable uptake of the ligand. Iron-sufficient cells partially accumulated the ligand with the metal. The chromium- and gallium-containing analogs of ferrichrome A were transported as intact chelates. Ferrichrome A iron uptake was inhibited by dipyridyl. The data suggest that the intact ferrichrome A chelate binds to a specific receptor, the iron is then separated from the ligand at the membrane by reduction, and the metal is released to the inside of the cell while the ligand is released to the exterior. The reduction step is not transport rate limiting. Iron chelated to citrate was taken up by an energy-dependent process. The citrate ligand was not taken up with the metal. Uptake was sensitive to dipyridyl and ferrozine. Chromic ion chelated to citrate was not transported, suggesting that the iron, rather than the chelate, is recognized by the receptor or that reduction of the metal is required for transport.     

Effects of additives on alum hematoxylin staining solutions.

All additives tested (ethyl alcohol, glycerine, chloral hydrate, ethylene and propylene glycol, and citric, malonic and maleic acids) in varying degrees limited the conversion of hematein to insoluble compounds. Peak absorbances increased slightly in hematoxylin solutions containing citric, malonic and maleic acids, but decreased with other additives, and in controls. After four months storage the absorbance in all solutions increased about 50%, acidity increased and staining effectiveness increased.     

The choice of a masking agent in the histochemical staining of metals

Summary The masking effects of standard masking agents (aminopolycarboxylic acids, carboxylic acids and phosphates) have been investigated in both test-tube experiments and tissue sections in order to ascertain the factors which must be considered when choosing a masking agent for the histochemical staining of a metal. The masking effectsin vitro were determined by spectrophotometry through the complexing of the dye Chrome Azurol S with aluminium, beryllium, and iron at pH 5 and 7. The effects were also examined by staining metal-containing tissue sections in a Chrome Azurol S masking agent system at the same pH values. In many cases, the masking effects observed in sections did not agree with those obtained in the test-tube experiments. This means that the published values of stability constants are not a sufficient guide for choosing a suitable masking agent for the staining of metals. The discrepancy is mainly attributable to the presence of protein in a solid state when metals are stained in sections. Therefore, in the future, consideration should be given to a metal-protein or masking agent-protein interaction using a model compound such as a chelate resin. The polyphosphates are among the most useful masking agents for metal staining in acidic solutions from a practical standpoint.     

Effects of Additives on Alum Hematoxylin Staining Solutions

All additives tested (ethyl alcohol, glycerine, chloral hydrate, ethylene and propylene glycol, and citric, malonic and maleic acids) in varying degrees limited the conversion of hematein to insoluble compounds. Peak absorbance increased slightly in hematoxylin solutions containing citric, malonic and maleic acids, but decreased with other additives, and in controls. After four months storage the absorbance in all solutions increased about 50%, acidity increased and staining effetiveness increased.     

Metal Chelates as Reversible Stains for Detection of Electroblotted Proteins: Application to Protein Microsequencing and Immunoblotting

Coomassie brilliant blue and Ponceau red have traditionally been used to stain electroblotted proteins, since they are compatible with existing N-terminal and internal protein microsequencing as well as with immunoblotting procedures. With recent improvements in sequencing and immunoblotting technology, detection of significantly smaller amounts of protein has become necessary. Metal complexes were evaluated as alternatives to conventional stains. Electroblotted proteins were detected by blocking nonspecific sites with polyvinylpyrrolidone-40 followed by incubation in metal chelate solutions at acidic pH values. Two of the most promising metal chelate stains were the Ferrozine/ferrous complex and the ferrocyanide/ferric complex. Both stained a wide variety of proteins and peptides quantitatively. Dot blots and 1D and 2D electroblots were successfully stained using iron chelates. When these two stains were utilized in combination, they were of equivalent sensitivity to colloidal gold stain. The reversibility of the metal chelate stains was substantiated by incubating stained membranes at neutral to basic pH in the presence of 20 mM ethylenediaminetetraacetic acid to rapidly elute the complexes from the bound proteins. The chelate stains were determined to be fully compatible with immunoblotting, N-terminal, and in situ internal protein microsequencing.     

Negative and positive assays of superoxide dismutase based on hematoxylin autoxidation

Hematoxylin, a natural dye commonly used as a histological stain, generates superoxide upon oxidation to its quinonoid product, hematein. The parameters affecting this reaction were assessed in developing a new and versatile assay for superoxide dismutase. The autoxidation of hematoxylin to hematein was accompanied by an increase in absorbance between 400 and 670 nm. The autoxidation rate was proportional to hematoxylin concentration and increased with pH above 6.55. Trace metals accelerated the autoxidation and this effect was eliminated by EDTA. Superoxide dismutase inhibited the autoxidation 90-95% below pH 7.8, but above pH 8.1 the rate was augmented by superoxide dismutase. The rate inhibition at low pH was proportional to the superoxide dismutase concentration up to 70% inhibition. The rate acceleration at high pH was proportional to superoxide dismutase concentration up to approximately 200% acceleration. The autoxidation rate was not significantly affected by ethanol, cyanide, azide, hydrogen peroxide, or catalase. However, the reaction was inhibited by the reducing agents NADH, reduced glutathione, ascorbate, and dithiothreitol, and by undialyzed extracts of Escherichia coli B. When cell extracts were dialyzed prior to assay, the degree of inhibition observed was proportional to the concentration of superoxide dismutase in the extract. These observations form the basis for negative and positive assays of superoxide dismutase which are inexpensive and simple to perform. The negative assay has the added advantage of being applicable at physiological pH.     

Metal chelates of 2-hydroxy-4-methylthiobutanoic acid in animal feeding. Part 2: Further characterizations, in vitro and in vivo investigations

The alpha-hydroxyacid 2-hydroxy-4-methylthiobutanoic acid (the so-called methionine hydroxy-analogue, MHA), largely used in animal nutrition as a source of methionine, forms stable metal chelates with divalent metals of formula [{CH(3)SCH(2) CH(2)CH(OH)COO}(2)M].nH(2)O. Protonation and iron(III) and copper(II) complex formation constants have been determined by potentiometry at 25 degrees C. Distribution diagrams show that no free Fe(3+) cations are present in solution at pH>2.5. ESI-MS (Electron-Spray Ionization Mass Spectrometry) investigations carried out both on iron and zinc complexes in solution have evidenced various species with different MHA/metal ratios. In vivo trials were carried out with rats. After receiving a zinc-deficient diet for 3 weeks, animals were fed the same diet added with zinc sulfate or zinc/MHA chelate; the zinc content of faeces was higher (+45%; P<0.05) in sulfate fed rats, whereas zinc retention was higher (+61%; P<0.05) in the Zn/MHA diet. Experiments in vitro with human intestinal Caco-2 cells indicated that the MHA/Fe chelate was taken up by the cells without any apparent toxic effect. The iron uptake was higher than that of iron nitrilotriacetate (Fe(3+)NTA), an effective chelate for delivering iron to milk diets. In conclusion, these data indicate that the use of MHA chelates could be a valuable tool to increase bioavailability of trace minerals and reduce the environmental impact of animal manure.     

A Simple Assay Procedure for Mixtures of Hematoxylin and Hematein

A simple and rapid method for the simultaneous quantitative analysis of mixtures of hematoxylin and hematein uses the molar extinction coefficients of the pure substances calculated by Lalor and Martin (1959). Absorbance measurements of the samples dissolved in methanol are made at wavelengths of 292 nm and 445 nm, the wavelengths of maximum absorption of hematoxylin and hematein respectively. The hematoxylin absorbance at 292 nm is corrected for the presence of hematein.

Using this method it was found that of 12 commercial samples labelled “hematoxylin” all contained at least 90% of the compound. Hematein contents of these samples fell in the range 0.1% to 6.8%. In 9 commercial samples labelled “hematein” the hematein contents fell in the range 1.2% to 90.7%. The hematoxylin contents of these samples fell in the range of 1.0% to 82.7%.

This paper describes also a chromatographic method for the identification of hematein and its oxidation products.