Spectrophotometry of Dyes: 1. Methyl Green. 2. Pyronin

Comparisons of absorption peaks of seven samples of methyl green showed that two different types of the dye were represented. One type (2 samples) had the visible peak near 617 mμ; the other (4 samples) near 630 mμ, while one sample was intermediate in spectral characteristics. Using these findings as a means of differentiating between heptamethyl and hexamethylethyl pararosanil-in is suggested. The Y and B forms of pyronin were found to be readily distinguishable by comparing their absorption maxima (Y, 546 mμ, B, 557-8 mμ). A check on the application of Beer's law of dilution showed that it held (1-3 mg./liter) for pyronin and that the relative effect of dilution was a slow increase with pyronin but a rapid decrease with methyl green.     

Spectrophotometry of Dyes: 1. Methyl Green. 2. Pyronin

Comparisons of absorption peaks of seven samples of methyl green showed that two different types of the dye were represented. One type (2 samples) had the visible peak near 617 mμ; the other (4 samples) near 630 mμ, while one sample was intermediate in spectral characteristics. Using these findings as a means of differentiating between heptamethyl and hexamethylethyl pararosanil-in is suggested. The Y and B forms of pyronin were found to be readily distinguishable by comparing their absorption maxima (Y, 546 mμ, B, 557-8 mμ). A check on the application of Beer's law of dilution showed that it held (1-3 mg./liter) for pyronin and that the relative effect of dilution was a slow increase with pyronin but a rapid decrease with methyl green.     

A Mixture of Methyl Green and Pyronin for Cell Fractionation Studies

A staining mixture consisting of 0.57% methyl green and 0.1 1 % pyronin B (calculated from the actual dye content) dis- solved in glycerol, 20 ml.; 2% aqueous phenol, 100 ml.; and 95% ethanol, 25 ml., was found to be optimum for differentiating cell components containing desoxypentose and pentose nucleic acids. The stain can be used for either fresh suspensions or unfixed dried smears of tissue homogenates. Nuclei are stained bright blue, and nucleoli and cytoplasmic particles, bright pink.     

An investigation of new commercial samples of Methyl Green and Pyronin Y

Summary New commercial samples of Methyl Green (Gurr Certistain), Pyronine G (Gurr Certistain) and Pyronin Y (Polysciences) have been investigated using spectrophotometry, thin layer chromatography and nuclear magnetic resonance, in addition to standardized simultaneous and sequential staining methods using purified Ethyl Green and pure Pyronin Y as reference dyes.The Methyl Green was found to be Ethyl Green contaminated with Crystal Violet. It did not have any advantages compared with Ethyl Green supplied by American dye companies. The Pyronine G sample was Pyronin Y with a high dye content that gave good staining results when used with purified Ethyl Green. Pyronin Y from Polysciences was found to be essentially pure Pyronin Y.     

Dye standards, Part II.1: Pyronin Y (CI 45005)

The names and affiliations of the SRMTS members are cited in Part I: terminology and general principles,Histochem. J. (1992)24, 217–19.     

Chloroplast membranes of the green alga Acetabularia mediterranea. I. Isolation of the photosystem II.

1. In the presence of Triton X-100, chloroplast membranes of the green alga Acetabularia mediterranea were disrupted into two subchloroplast fragments which differed in buoyant density. Each of these fractions had distinct and unique complements of polypeptides, indicating an almost complete separation of the two fragments. 2. One of the two subchloroplast fractions was enriched in chlorophyll b. It exhibited Photosystem II activity, was highly fluorescent and was composed of particles of approx. 50 A diameter. 3. The light-harvesting chlorophyll-protein complex of the Photosystem II-active fraction had a molecular weight of 67 000 and contained two different subunits of 23 000 and 21 500. The molecular ratio of these two subunits was 2:1.     

Interactions of voltage-sensing dyes with membranes. I. Steady-state permeability behaviors induced by cyanine dyes.

The effects of a series of thiadicarbocyanine dyes, diSCn(5), in altering the electrical properties of lipid bilayer membranes have been studied as a function of the membrane's intrinsic surface-charge density, the aqueous ionic strength, and the length (n) of the hydrocarbon side chains on the dye. Zero-current conductances, transmembrane potentials, and conductance-voltage relationships induced by these dyes were measured. All dyes studied altered membrane permeability properties; however these alterations were much larger at lower (e.g. 10(-3) M) than at higher (e.g. 10(-1) M) ionic strengths. The data suggest that such perturbations would not be troublesome for most biological preparations in which these dyes have been studied. The mechanisms by which these dyes alter membrane permeabilities vary in going from short-chained to long-chained dyes, the former forming voltage-gated, ion-permeant pores and the latter acting predominantly as anion carriers (forming 2:1 dye-anion complexes). In the case of diSC3(5), the predominant mechanism of altering membrane permeabilities changes in going from neutral to negatively charged membranes and also depends upon aqueous ionic strength and dye concentration.     

Schiff-Type Reagents in Cytochemistry. 2. Detection of Primary Amine Dye Impurities In Pyronin B and Pyronin Y(G)

Many batches of pyronin B (C.I. 45010), pyronin Y or G (C.I. 45005), and acridine red (C.I. 45000) produce positive Feulgen or PAS reactions when their 0.25% solutions are saturated with SO₂ and used on acid-hydrolyzed or periodate-oxidized tissue sections. These dyes behave as Schiff-type reagents and stain aldehyde-containing structures orange, brown, pink, red, or violet, depending on the particular batch used. The most frequent contaminants are violet and are nonfluorescent. Aldehyde groups are stained by these dyeSO₂ solutions as is shown by using unhydrolyzed controls in the Feulgen reaction and unoxidized controls in the PAS reaction, and by dye solutions lacking SO₂. Other procedures included reactions with aldehyde-blocking reagents, treatment with deoxyribonuclease and diastase, and extraction of nudeic acids with trichloroaeetic acid. The standard Schiff reagent was used in the Same procedures as a basis for comparing results. Since the Schiff-aldehyde reaction requires a dye with a primary amine group and since true pronins contain only secondary or tertiary amines, the positive histochemical results are evidently caused by dye contaminants possessing primary amine groups. The PAS reaction is more sensitive than the Feulgen reaction in detecting dye contaminants. Tissues used were chiefly formalin-fixed mouse intestine and ascites cells. Seventy-five commercial pyronins were studied from 21 different firms. Among 19 batches of pyronin B, 14 were found to contain primary amine dye contaminants. Among 39 batches of pyronin Y(G), 19 contained similar primary amine dye contaminants. Of the 8 batches of acridine red tested, 7 were found to contain primary amine dye contaminants. Nine commercial mixtures of methyl green-pyronin were studied and 4 were found to be likewise contaminated, but these reactive dye contaminants in them are apparently not associated with methyl green. A tabulated summary of the pyronin batches containing primary amine contaminants, and a list of sources and distributors of pyronin dyes are included.     

Chloroplast membranes of the green alga Acetabularia mediterranea. I. Isolation of the Photosystem II

1. In the presence of Triton X-100, chloroplast membranes of the green alga Acetabularia mediterranea were disrupted into two subchloroplast fragments which differed in buoyant density. Each of these fractions had distinct and unique complements of polypeptides, indicating an almost complete separation of the two fragments.

2. One of the two subchloroplast fractions was enriched in chlorophyll b. It exhibited Photosystem II activity, was highly fluorescent and was composed of particles of approx. 50 Å diameter.

3. The light-harvesting chlorophyll-protein complex of the Photosystem II-active fraction had a molecular weight of 67 000 and contained two different subunits of 23 000 and 21 500. The molecular ratio of these two subunits was 2:1.     

Detection of Ribonucleic Acid with Pyronin

Pyronin, when used in the methyl green-pyronin stain, is useful in localizing ribonucleic acid (RNA). That it has rarely been used alone is perhaps a result of the observation (Kurnick 1955) that pyronin stains deoxyrobonucleic acid (DNA) of animal tissue when not competitively inhibited by methyl green. The tests described in this note indicate that pyronin alone can be used to demonstrate RNA in fixed plant tissues.     

Interaction of lysozyme with dyes. II. Binding of bromophenol blue

The binding of lysozyme with bromophenol blue (BPB) at various dye concentrations and pH was carried out at 25 degrees C by equilibrium dialysis, ultraviolet (UV) difference and circular dichroism (CD) spectral techniques. Binding isotherms at pH 5.0 show non-cooperative binding at low dye concentrations, which change over to cooperative binding at higher concentrations indicating biphasic nature. However, binding isotherms at pH 7.0 and 9.0 show cooperative binding only, at all concentrations of the dye. The number of available binding sites decreases with the increase of pH. Gibbs free energy change, calculated on the basis of Wyman's binding potential concept, decreases with the increase of pH. Binding isotherms at pH 5.0 obtained at a lower temperature of 8 degrees C, also indicate the biphasic nature similar to those observed at 25 degrees C, but with a slight decreased strength of binding. The UV difference spectra of the complex do not show any distinct peaks in the 285 to 297 nm region eliminating any possible interaction of BPB with tryptophan and tyrosine residues of the lysozyme molecule. The CD spectra of lysozyme-BPB complex show a decrease in ellipticities with reference to native lysozyme in the near UV and far UV regions. This indicates that the lysozyme-BPB complex has a lower helical content probably due to the conformational changes induced into the native enzyme. The appearance of new positive peaks at 315 nm in the near UV region and at 592 nm in the visible region of the CD spectra may be due to the induced asymmetry into the BPB molecule as a result of its binding to a cationic residue (probably a lysine residue) of lysozyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metachromasia of basic dyes induced by mercuric chloride. I

Summary Interactions of the cationic dye methylene blue with mercuric chloride have been studied conductometrically, analytically and spectrophotometrically. Methylene blue produces red colored precipitate with mercuric chloride; in presence of large excess of mercuric chloride a strong metachromasia is induced in the dye. Metachromasia induced by mercuric chloride is more hypsochromic as well as hypochromic than that induced by chromotopes like heparin. The complexes formed between methylene blue and mercuric chloride have variable compositions, the complex responsible for the red metachromatic color of the dye has the composition 2 dye: 1 HgCl₂. A model has been proposed for the metachromatic complex consisting hexa-coordinated mercury, dye is coordinated to the mercury by donating the lone pair electrons of terminal nitrogen. The non-metachromatic dye capri blue also interacts with mercuric chloride but without any change in the visible spectrum. Potassium iodide also gives metachromatic reddish blue colored precipitate with methylene blue.University Research Scholar.     

Biodegradation of dyes by some green algae and cyanobacteria

The ability of Chlorella vulgaris, Lyngbya lagerlerimi, Nostoc lincki, Oscillatoria rubescens, Elkatothrix viridis and Volvox aureus to decolorize and remove methyl red, orange II, G-Red (FN-3G), basic cationic, and basic fuchsin was investigated. These algae showed different efficiency for colour removal; varied from 4 to 95% according to the algal species, its growth state and the dye molecular structure. Basic cationic and basic fuchsin were the most susceptible dyes for decolorisation and removal by all algae being tested, and up to 82% of methyl red was also removed by N. lincki and O. rubescens. However, the algal activity to decolorize orange II and G-Red was markedly fluctuated and lower. C. vulgaris displayed activity to remove 43.7 and 59.12% while as V. aureus removed 5.02 and 3.25% of the added dyes respectively. The results also showed that treatment of either C. vulgaris or N. Linckia with G-Red or methyl red, respectively, induced the algal azo dye reductase enzyme by 72 and 71% at the same order.     

Transformation of aromatic dyes using green synthesized silver nanoparticles

Nowadays, increasing use of nanoproducts in area of human and environmental applications raises concern about safety aspects of nanoparticles synthesized using traditional physicochemical methods. Silver nanoparticles (AgNPs) synthesis at ambient parameters using latex of medicinally important plant Jatropha gossypifolia (J. gossypifolia) is reported in the present study. Potential of AgNPs in degradation of methylene blue and eosin B was also evaluated. Rapid formation of stable AgNPs was analyzed by visual color change from colorless to yellow-red after addition of latex in AgNO₃ solution and by characteristic surface plasmon resonance (SPR) peak at 430 nm in UV–Vis spectroscopy. FT-IR analysis, protein coagulation test showed capping of proteins, flavonoids, terpenoids and polyphenols of latex on surface of AgNPs. FE-SEM, HR-TEM analysis revealed spherical shape of AgNPs. Narrow size range of AgNPs (5–40 nm) observed in HR-TEM analysis. EDS analysis confirms the presence of elemental silver while XRD revealed crystalline nature of AgNPs. Zeta potential of ?21.4 mV indicates high stability of AgNPs. Effects of different parameters (pH, temperature, incubation time) on nanosynthesis were studied in the present study. Dye reduction studies were performed using UV–Vis spectroscopy, TLC, FT-IR and HPLC analysis showing decreased absorbance maxima of both dyes with respect to time, change in R _f values, changes in wave number, transmittance, and retention time of dyes after AgNPs addition. The rate constant for methylene blue and eosin B reduction by AgNPs was found to be 0.062 and 0.022 min^?1.     

Comparisons of Pyronin Dyes Obtained from Various Commercial Sources. 1. History

The history of pyronin dyes is discussed, beginning with the synthesis of pyronin Y(G) in 1889. The chemical structures of the dyes are given in addition to references to literature describing methods of synthesis. The early histological use of pyronins is described as well as the distribution and use of pyronins in the U. S. A. and Europe. Further discussion is devoted to the use of pyronins for histochemical demonstration of ribonucleic acid, especially in relation to sources, dye variability, contamination, and substitution by rhodamines. Additional studies with improved pyronins are advocated to evaluate histochemical staining mechanisms and to investigate possible quantitative uses.