Topo-optical reactions on the membrane of the human red cell ghost (author's transl)]

Previous studies have proved that the thiazin dyes toluidine blue, azure A, azure B, 1.9-dimethyl methylene blue and the quinolin dyes N,N'-diethylpseudoisocyanine chloride, N,N'-6,6'-dichlorpseudoisocyanine chloride are suitable for topo-optical reaction on the membrane of the red blood cells. In the present study the applicability of the thiazin and quinolin dyes on the membrane of the human red cell ghost was examined. Optical analysis revealed that the thiazin dyes are bound in radial position to the membrane, while the quinolin dyes are bound parallel to the membrane's plane.     

Mechanisms of chromosome banding

A thorough understanding of the mechanisms of R-, C-and G-banding will come only from studies of the binding of Giemsa dyes to isolated and characterized preparations of heterochromatin and euchromatin. Since such studies require an exact knowledge of the optical characteristics of Giemsa, the spectral adsorption curves and extinction coefficients of Giemsa and its component dyes at various concentrations in the presence and absence of DNA were determined. — Although Giemsa is a complex mixture of thiazin dyes plus eosin; methylene blue, and azure A, B or C alone gave good banding. Thionin, with no methyl groups, gave poor or no banding. Eosin was not a necessary component for banding. — The most striking characteristic of the thiazin dyes is that they are strongly metachromatic, i.e., their adsorption spectra and extinction coefficients change as the concentration of the dye increases or as they bind to positively charged compounds (chromotropes). These changes, especially for methylene blue, are described in detail and allow a distinction between concentration dependent binding to DNA by intercalation and binding by side stacking.     

Methylene blue plus light mediates 8-hydroxyguanine formation in DNA

Exposure to methylene blue (MB) plus light mediates formation of large levels of 8-hydroxyguanine in DNA. The amount of 8-hydroxy-2'-deoxyguanosine (8-OHdG) present in DNA increased as the amount of MB concentration increased throughout the 2 to 200 microM range studied and was dependent on light exposure. As the time of light exposure increased so did the 8-OHdG content to levels of about 750 8-OHdG/10(5) deoxyguanosine after 15 min of light exposure when MB was at 20 microM. Even though previous research has demonstrated that hydroxyl free radicals formed from a variety of sources mediate 8-OHdG formation in DNA, inclusion of mannitol, superoxide dismutase, catalase, and desferal in the MB plus light experiments demonstrated that these scavengers of oxygen free radical intermediates or precursors caused either no change or an increase in the 8-OHdG content of DNA exposed to MB plus light. These results appear to rule out the direct role of oxygen free radical intermediates in the primary events involved in the MB plus light mediated formation of 8-OHdG in DNA. Oxygen was essential to cause MB plus light mediated 8-OHdG formation in DNA. It was noted that when the reaction was carried out where the deuterium oxide content had been increased to 100%, the amount of 8-OHdG formed in DNA increased about threefold over that observed when comparable reactions were carried out in pure H2O. Use of the singlet oxygen scavenger 2,5-dimethylfuran has yielded variable results on the MB plus light mediated formation of 8-OHdG in DNA. The data taken collectively clearly indicate that MB plus light mediates 8-OHdG formation in DNA. The D2O data and the requirement for oxygen suggest that singlet oxygen may be an intermediate.     

Purification of Thionin, Azure A, Azure B and Methylene Blue

Column and paper chromatography of four thiazin dyes revealed both inorganic and organic impurities. In thionin, azure A, azure B and methylene blue, sodium and other metal cations were found as inorganic impurities. The analysis for organic impurities revealed that the dyes were mixtures; specifically each dye contained one or more of the other dyes as impurities. Inorganic impurities were detected by ashing the dyes in the presence of H₂SO₄ and chromatographing the sulfate salts on paper. They were removed by filtration through ion exchange resins. Organic impurities were detected by paper chromatography and removed by column chromatography on Woelm's neutral alumina.     

Methods for the Standardization of Biological Stains Part V

In this paper are given the methods for determining the suitability of certain dyes of the pyronin, thiazin, oxazin, azin and natural dye groups for certification by the Commission on Standardization of Biological Stains. These methods have been developed by the Commission in cooperation with the Color and Farm Waste Division, Bureau of Chemistry and Soils, U. S. Department of Agriculture. The dyes for which the methods are given in the present paper are: Pyronin G, pyronin B, neutral red, safranin, nigrosin water-soluble, brilliant cresyl blue, cresyl violet, Nile blue A, thionin, methylene blue, methylene azure (azure A), azure C, toluidine blue O, indigo carmin (indigotine) and carmin. For each of these dyes methods are discussed under the following headings: (1) identification or qualitative examination; (2) quantitative analysis; and (3) biological tests.     

Methods for the Standardization of Biological Stains Part V

In this paper are given the methods for determining the suitability of certain dyes of the pyronin, thiazin, oxazin, azin and natural dye groups for certification by the Commission on Standardization of Biological Stains. These methods have been developed by the Commission in cooperation with the Color and Farm Waste Division, Bureau of Chemistry and Soils, U. S. Department of Agriculture. The dyes for which the methods are given in the present paper are: Pyronin G, pyronin B, neutral red, safranin, nigrosin water-soluble, brilliant cresyl blue, cresyl violet, Nile blue A, thionin, methylene blue, methylene azure (azure A), azure C, toluidine blue O, indigo carmin (indigotine) and carmin. For each of these dyes methods are discussed under the following headings: (1) identification or qualitative examination; (2) quantitative analysis; and (3) biological tests.     

The suitability of further thiazine and quinoline dyes for topo-optical reactions on the plasmalemma (author's transl)]

The present studies prove that the thiazin dyes, azure B, azure C and thionin, and the quinolin dyes pinacyanol and its hydrochloride, are suitable for topo-optical staining of the plasmalemma. On the membrane surface the orientated bound dye molecules become stabilized, and with subsequent precipitation the anisotropic effect is reinforced. On optical analysis, the thiazin dye molecules (azure B, AZURE C and Thionin) are bound radially on the membrane. The molecules of the previously studied quinolin dye, N,N'-diethylpseudoisocyanide chloride are bound parallel to the membrane, while pinacyanol and its hydrochloride, like the thiazin dyes, are bound in the radial position.     

Lower azure B methylene blue ratios in Giemsa type blood and malaria stains

Starting from ancient reports that rare samples of methylene blue were apparently sufficiently contaminated with azures to give red plasmodial and red purple nuclear chromatin in Chenzinsky type methylene blue eosin stains, it was decided to determine how little azure B would suffice for such staining in methylene blue eosin stains. The traditional 1902 Giemsa had an azure : methylene blue : eosin ratio of about 6 : 3 : 6.3 : 10; Lillie's 1943 formula had a 5 : 7 : 10 ratio. In the current series of tests 5 : 7 : 10 (I), 4 : 8 : 10 (II), 3 : 9 : 10 (III), 2 : 10 : 10 (IV), 1 : 11 : 10 (V), and 0 : 12 : 10 (VI) were used. Malaria and blood stains were better than the standard 5 : 7 : 10 (I) in III, IV and II in that order. Normal and leukemic human blood, mouse blood with Plasmodium berghei, and monkey blood with the CDC strain of Pl. falciparum were used as test materials. The staining mixtures were made from highly purified samples of azure B and methylene blue. Staining mixtures contained 12 ml 0.1% thiazin dye, 10 ml 0.1% eosin, 2 ml each of glycerol, methanol and 0.1 M phosphate buffer pH 6.5, 3 ml acetone as accelerator, and distilled water to make 40 ml; staining times of 10--30 min were used.     

Additional Schiff-Type Reagents for Use in Cytochemistry

Twenty-four new Schiff-type reagents were discovered in a survey of 140 different dyes. These dyes include acid fuchsin, acridine yellow, acriflavine hydrochloride, azure C., Bismarck brown R, Bismarck brown Y, celestine blue B, chrysoidine 3R, chrysoidine Y extra, cresyl violet, crystal violet, gentian violet, methylene blue, neutral violet, phenosafranin, phosphine GN, proflavine, toluidine blue O, and toluylene blue. Positive results obtained with crystal violet and a few samples of methylene blue are considered due to impurities. Various chemical extractions, aldehyde blocking reagents, and enzymatic treatments were used to verify the aldehyde specificity of the above dye-SO₂, reagents as well as azure A, brilliant cresyl blue, neutral red, safranin O, and thionin which have been mentioned by other workers. These reagents were tested in the Feulgen reaction for DNA and the PAS reaction for polysaccharides. Absorption curves were obtained from individual nuclei stained for DNA. The absorption peaks ranged from 450 mμ, to 630 mμ. depending on the dye studied. The Feulgen reaction could be followed by the PAS reaction or vice versa in mouse intestine using reactive dyes of complementary colors. The evidence indicates that a potential Schiff-type reagent must have at least one free NH₂ group on the dye molecule.     

The purification of methylene blue and azure B by solvent extraction and crystallization.

Detailed schemes are described for the preparation of purified methylene blue and azure B from commercial samples of methylene blue. Purified methylene blue is obtained by extracting a solution of the commercial product in an aqueous buffer (pH 9.5) with carbon tetrachloride. Methylene blue remains in the aqueous layer but contaminating dyes pass into the carbon tetrachloride. Metal salt contaminants are removed when the dye is crystallized by the addition of hydrochloric acid at a final concentration of 0.25 N. Purified azure B is obtained by extracting a solution of commercial methylene blue in dilute aqueous sodium hydroxide (pH 11-11.5) with carbon tetrachloride. In this pH range, methylene blue is unstable and yields azure B. The latter passes into the carbon tetrachloride layer as it is formed. Metal salt contaminants remain in the aqueous layer. A concentrated solution oa azure B is obtained by extracting the carbon tetrachloride layer with 4.5 X 10(-4)N hydrobromic acid. The dye is then crystallized by increasing the hydrobromic acid concentration to 0.23 N. Thin-layer chromatography of the purified dyes shows that contamination with related thiazine dyes is absent or negligible. Ash analyses reveal that metal salt contamination is also negligible (sulphated ash less than 0.2%).     

Lower Azure B Methylene Blue Ratios in Giemsa Type Blood and Malaria Stains

Starting from ancient reports that rare samples of methylene blue were apparently sufficiently contaminated with azures to give red plasmodial and red purple nuclear chromatin in Chenzinsky type methylene blue eosin stains, it was decided to determine how little azure B would suffice for such staining in methylene blue eosin stains. The traditional 1902 Giemsa had an azure:methylene blue: eosin ratio of about 6:3:6.3:10; Lillie's 1943 formula had a 5:7:10 ratio. In the current series of tests 5:7:10 (I), 4:8:10 (II), 3:9:10 (III), 2:10:10 (IV), 1:11:10 (V), and 0:12:10 (VI) were used. Malaria and blood stains were better than the standard 5:7:10 (I) in III, IV and II in that order. Normal and leukemic human blood, mouse blood with Plasmodium berghei, and monkey blood with the CDC strain of Pl. falciparum were used as test materials. The staining mixtures were made from highly purified samples of azure B and methylene blue. Staining mixtures contained 12 ml 0.1% thiazin dye, 10 ml 0.1% eosin, 2 ml each of glycerol, methanol and 0.1 M phosphate buffer pH 6.5, 3 ml acetone as accelerator, and distilled water to make 40 ml; staining times of 10-30 min were used.     

STUDIES ON PENETRATION OF DYES WITH GLASS ELECTRODE : V. WHY DOES AZURE B PENETRATE MORE READILY THAN METHYLENE BLUE OR CRYSTAL VIOLET?

Glass electrode measurements of the pH value of the sap of cells of Nitella show that azure B in the form of free base penetrates the vacuoles and raises the pH value of the sap to about the same degree as the free base of the dye added to the sap in vitro, but the dye salt dissolved in the sap does not alter the pH value of the sap. It is concluded that the dye penetrates the vacuoles chiefly in the form of free base and not as salt. The dye from methylene blue solution containing azure B free base as impurity penetrates and accumulates in the vacuole. This dye must be azure B in the form of free base, since it raises the pH value of the sap to about the same extent as the free base of azure B dissolved in the sap in vitro. The dye absorbed by the chloroform from methylene blue solution behaves like the dye penetrating the vacuole. These results confirm those of spectrophotometric analysis previously published. Crystal violet exists only in one form between pH 5 and pH 9.2, and does not alter the pH value of the sap at the concentrations used. It does not penetrate readily unless cells are injured. A theory of "multiple partition coefficients" is described which explains the mechanism of the behavior of living cells to these dyes. When the protoplasm is squeezed into the sap, the pH value of the mixture is higher than that of the pure sap. The behavior of such a mixture to the dye is very much like that of the sap except that with azure B and methylene blue the rise in the pH value of such a mixture is not so pronounced as with sap when the dye penetrates into the vacuoles. Spectrophotometric measurements show that the dye which penetrates from methylene blue solution has a primary absorption maximum at 653 to 655 mµ (i.e., is a mixture of azure B and methylene blue, with preponderance of azure B) whether we take the sap alone or the sap plus protoplasm. These results confirm those previously obtained with spectrophotometric measurements.     

Microspectrophotometric Studies of Romanowsky Stained Blood Cells. III. The Action of Methylene Blue and Azure B

The performances of two standardized Romanowsky stains (azure B/eosin and azure B/methylene blue/eosin) have been compared with each other and with a methylene blue/eosin stain. Visible-light absorbance spectra of various hematological substrates have been measured. These have been analyzed in terms of the quantities of bound azure B, methylene blue and eosin dimers and monomers, and in terms of the CIE color coordinates. It has been found that the addition of methylene blue to azure B/eosin produces little change in performance, at least using these two analytical methods. Methylene blue/eosin does not produce the purplish colorations typical of the Romanowsky effect. This is due not to differences between the spectra of methylene blue and azure B, but to the fact that methylene blue does not facilitate the binding of eosin to cellular substrates to the same extent as azure B.     

Microspectrophotometric studies of Romanowsky stained blood cells. III. The action of methylene blue and azure B

The performances of two standardized Romanowsky stains (azure B/eosin and azure B/methylene blue/eosin) have been compared with each other and with a methylene blue/eosin stain. Visible-light absorbance spectra of various hematological substrates have been measured. These have been analyzed in terms of the quantities of bound azure B, methylene blue and eosin dimers and monomers, and in terms of the CIE color coordinates. It has been found that the addition of methylene blue to azure B/eosin produces little change in performance, at least using these two analytical methods. Methylene blue/eosin does not produce the purplish colorations typical of the Romanowsky effect. This is due not to differences between the spectra of methylene blue and azure B, but to the fact that methylene blue does not facilitate the binding of eosin to cellular substrates to the same extent as azure B.     

Methylene blue plus light mediates 8-hydroxy 2''-deoxyguanosine formation in DNA preferentially over strand breakage.

Methylene blue (MB) plus light, in the presence of oxygen, mediates formation of 8-hydroxyguanine in DNA. The yield of 8-hydroxyguanine may be as much as from 2 to 4% of the guanines present. The results presented here show that treatment of supercoiled plasmid DNA with methylene blue plus light causes single-stranded nicks. However, single-stranded nicking occurs approximately 17-fold less frequently than does formation of 8-hydroxyguanine. The nicking rate is reduced in the presence of Mg ion but is not prevented by inhibitors of the iron-catalyzed Fenton reaction or by scavengers of hydroxyl free radicals. Extensive exposure of DNA to light in the presence of MB produces no detectable thiobarbital reactive material thus implicating that single strand nicking does not occur by hydroxyl free radical attack on deoxyribose. Formation of 8-hydroxyguanine is apparently not dependent upon intercalative binding of MB to DNA, since it is formed in polydeoxyguanylic acid.     

Topo-optische Reaktionen an der Membran von menschlichen Erythrocytenschatten

Zusammenfassung Frühere Untersuchungen erwiesen, daß die Thiazinfarbstoffe Toluidinblau, Azur A, Azur B, 1:9-Dimethyl-Methylenblau, sowie die Chinolinfarbstoffe N,N-Diäthylpseudoisocyaninchlorid und N,N-6,6-Dichlorpseudoisocyaninchlorid für die topo-optische Reaktion an der menschlichen Erythrocytenmembran geeignet sind. In dieser Studie wird die Verwendbarkeit der Thiazin- und Chinolinfarbstoffe an den menschlichen Erythrocytenschatten gezeigt. Auf Grund der optischen Analyse sind die Thiazinfarbstoffmoleküle radiär zur Membran ausgerichtet, während sich die Chinolinfarbstoffmoleküle membranparallel anlagern.

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Topo-optical reactions on the membrane of the human red cell ghost

Summary Previous studies have proved that the thiazin dyes toluidine blue, azure A, azure B, 1.9-dimethyl methylene blue and the quinolin dyes N,N-diethylpseudoisocyanine chloride, N,N-6,6-dichlorpseudoisocyanine chloride are suitable for topo-optical reaction on the membrane of the red blood cells. In the present study the applicability of the thiazin and quinolin dyes on the membrane of the human red cell ghost was examined. Optical analysis revealed that the thiazin dyes are bound in radial position to the membrane, while the quinolin dyes are bound parallel to the membrane's plane.

     

Metal contaminants in commercial thiazine dyes.

The iron, potassium, sodium and zinc content of commercial samples of the thiazine dyes azure A (C.I. 52005), azure B (C.I. 52010), azure C (C.I. 52002), methylene blue (C.I. 52015), new methylene blue (C.I. 52030), polychrome methylene blue, thionine (C.I. 52000) and toluidine blue (C.I. 52040) have been determined by atomic absorption spectrophotometry. The metal concentration varied widely in the 38 samples examined--iron, potassium, sodium and zinc together comprised between 0.02% and 25.35% of individual samples.     

Metal Contaminants in Commercial Thiazine Dyes

The iron, potassium, sodium and zinc contents of commercial samples of the thiazine dyes azure A (C.I. 52005), azure B (C.I. 52010), azure C (C.I. 52002), methylene blue (C.I. 52015), new methylene blue (GI. 52030), polychrome methylene blue, thionine (C.I. 52000) and toluidme blue (C.I. 52040) have been determined by atomic absorption spectrophotometry.

The metal concentrations varied widely in the 38 samples examined—iron, potassium, sodium and zinc together comprised between 0.02% and 25.35% of individual samples.     

SPECTROPHOTOMETRIC STUDIES OF PENETRATION : V. RESEMBLANCES BETWEEN THE LIVING CELL AND AN ARTIFICIAL SYSTEM IN ABSORBING METHYLENE BLUE AND TRIMETHYL THIONINE.

The rate of diffusion through the non-aqueous layer of the protoplasm depends largely on the partition coefficients mentioned above. Since these cannot be determined we have employed an artificial system in which chloroform is used in place of the non-aqueous layer of the protoplasm. The partition coefficients may be roughly determined by shaking up the aqueous solutions with chloroform and analyzing with the spectrophotometer (which is necessary with methylene blue because we are dealing with mixtures). This will show what dyes may be expected to pass through the protoplasm into the vacuole in case it behaves like the artificial system. From these results we may conclude that the artificial system and the living cell act almost alike toward methylene blue and azure B, which supports the notion of non-aqueous layers in the protoplasm. There is a close resemblance between Valonia and the artificial system in their behavior toward these dyes at pH 9.5. In the case of Nitella, on the other hand, with methylene blue solution at pH 9.2 the sap in the artificial system takes up relatively more azure B (absorption maximum at 650 mµ) than the vacuole of the living cell (655 mµ). But both take up azure B much more rapidly than methylene blue. A comparison cannot be made between the behavior of the artificial system and that of the living cell at pH 5.5 since in the latter case there arises a question of injury to cells before enough dye is collected in the sap for analysis.     

Investigation of Thiazin Dyes as Biological Stains I. The Staining Properties of Thionin and its Derivatives as Compared with Their Chemical Formulae

An investigation has been made of the staining properties of eight dyes of the thionin group. The dyes studied are as follows: tetra-ethyl thionin, asymmetrical di-ethyl thionin, tetra-methyl thionin (methylene blue), tri-methyl thionin (azure B), asymmetrical di-methyl thionin (azure A), symmetrical di-methyl thionin, mono-methyl thionin (azure C), and unsubstituted thionin. The staining properties were tested on sections of paraffin embedded material following five different methods of fixation. No counterstain was employed. It was shown that there was a general correlation between the extent of ethylation or methylation of the dyes and their staining properties. As one passes from tetra-ethyl thionin down the series to thionin itself, there is a progressive decrease in the amount of green showing in the preparations, and an increase in the amount of red present, also an increase in the metachromatic effects, and in the intensity of nuclear staining. There seems, also, to be a similar relation between staining qualities on the one hand and the color and solubility of the dye base on the other.