Lipid-mediated regulation of pore-forming activity of syringomycin E by thyroid hormones and xanthene dyes

The effects of dipole modifiers, thyroid hormones (thyroxine and triiodothyronine) and xanthene dyes (Rose Bengal, phloxineB, erythrosin, eosinY and fluorescein) on the pore-forming activity of the lipopeptide syringomycin E (SRE) produced by Pseudomonas syringae were studied in a model bilayer. Thyroxine does not noticeably influence the steady-state number of open SRE channels (N_op), whereas triiodothyronine decreases it 10-fold at − 50 mV. Rose Bengal, phloxine B and erythrosin significantly increase N_op by 350, 100 and 70 times, respectively. Eosin Y and fluorescein do not practically affect the pore-forming activity of SRE. Recently, we showed that hormones decrease the dipole potential of lipid bilayers by approximately 60 mV at 50 μM, while Rose Bengal, phloxine B and erythrosin at 2.5 μM reduce the membrane dipole potential by 120, 80 and 50 mV, respectively. In the present study using differential scanning microcalorimetry, confocal fluorescence microscopy, the calcein release technique and measurements of membrane curvature elasticity, we show that triiodothyronine strongly affects the fluidity of model membranes: its addition leads to a significant decrease in the temperature and cooperativity of the main phase transition of DPPC, calcein leakage from DOPC vesicles, fluidization of solid domains in DOPC/DPPC liposomes, and promotion of lipid curvature stress. Thyroxine exerts a weaker effect. Xanthene dyes do not influence the phase transition of DPPC. Despite the decrease in the dipole potential, thyroid hormones modulate SRE channels predominantly via the elastic properties of the membrane, whereas the xanthene dyes Rose Bengal, phloxine B and erythrosine affect SRE channels via bilayer electrostatics.     

Toxicity of Xanthene Dyes to Entomopathogenic Fungi

Effects of xanthene dyes on mycelial growth and conidial germination in three species of entomopathogenic fungi, Beauveria bassiana, Metarhizium anispoliae and Paecilomyces fumosoroseus, were evaluated in a variety of assay systems. In a disk-diffusion assay, erythrosin B and phloxine B (but not eosin B) produced zones of inhibition in colonies of all three species under continuous exposure to light at disk-loadings of 100mug. None of the dyes produced zones of inhibition in the absence of light at disk loadings of 100mug. Both erythrosin B and phloxine B inhibited mycelial growth of all three species in the light in a dose-dependent manner. Weaker dose-responses for inhibition of growth in the dark were observed for some fungus/dye combinations. Erythrosin B, tested singly, completely inhibited conidial germination in the light in all eight fungal strains tested at 100mug ml-1 medium, but failed to inhibit conidial germination in any of these strains in the dark at the same concentration of dye. For single strains of each of the three fungi, erythrosin B and phloxine B inhibited conidial germination in a dose-dependent manner in the light with IC50s < 6.2mug dye ml-1 medium for all fungus/dye combinations. Phloxine B was a more potent inhibitor of germination than erythrosin B for all three fungal species. At fixed dosages of erythrosin B and phloxine B, inhibition of conidial germination in all three species increased with time of exposure to light. These results constitute the first quantitative demonstration of photodynamic inhibition of conidial germination in fungi by xanthene dyes.     

Spectrophotometric Characteristics and Assay of Biological Stains III. The Xanthenes

In this continuation paper of the work on the chemical and spectrophotometic characteristics of commercial stains, data on the xanthene dyes are presented. In the xanthene group of dyes, it has been found possible to assay pyronin B, eosins B and Y and ethyl eosin by spectrophotometric means. Phloxine B, rose Bengal, and erythrosin B are assayed by die color acid precipitation method. Typical absorption curves are given for these dyes as well as representative spectral and assay data.     

Iodine-containing hormones--dipole modifiers of phospholipid membranes

The hormones of thyroid gland thyroxine and triiodothyronine were shown to increase the permeability of bilayer lipid membrane (BLM) and inner mitochondrial membrane for hydrophobic positively charged complex K+-nonactine and to decrease the permeability of these membranes for hydrophobic anion FCCP-. These facts imply that the thyroid hormones affect the phospholipid membranes like the dipole modifyers decreasing the positive potential of hydrophobic region of the membranes in respect to the water phase.     

Compatibility of Photoactive Dyes with Insect Biocontrol Agents

Integrated pest management (IPM) programmes often look for more specific ways to control pests. Biological control agents, such as the bacterium, Bacillus thuringiensis Berliner, and the fungus, Beauveria bassiana (Balsamo) Vuillemin, can control insects with minimal disturbance to the environment because of their host specificity and short half-lives. Often these agents alone cannot prevent yield loss or are too expensive. This study looked at the in vitro combination of these agents and photoactive dyes, especially phloxine B (red dye D&C 28), a Food and Drug Administration approved dye, with the intent to provide better insect control. Photoactive dyes are being tested for the control of many pest insects. Phloxine B and related xanthene dyes, eosin y, fluorescein and rose bengal inhibited the growth of both B. thuringiensis and B. bassiana . Phloxine B was the most inhibitory and fluorescein the least inhibitory dye for both microbes. The magnitude of inhibition increased with increasing concentration of dye and light intensity. Therefore, an adverse effect on the field performance of these biological control agents in combination with xanthene dyes would be expected.     

Insecticidal activity of photoactive dyes to American and migratory grasshoppers (Orthoptera: Acrididae)

Many photoactive dyes are relatively nontoxic to vertebrates despite their insecticidal properties. Several photoactive dyes known to be toxic to some groups of insects were evaluated at various concentrations for toxicity to American and migratory grasshoppers in laboratory and field studies. Rose bengal and phloxine B were effective at inducing mortality of grasshoppers when applied at 2 and 5% to bran bait, though erythrosin B and uranine were ineffective. Partial replacement of phloxine with uranine in dye mixtures resulted in no significant loss of efficacy. Some indication of feeding inhibition was observed at high dye concentrations, so minimum effective dosages, probably 2%, are optimal. Phloxine B and rose bengal appeared to be stable upon exposure to sunlight, and able to withstand at least 24 h of sunlight without significant degradation. Dyes such as phloxine B could be a viable grasshopper control agent for small or medium-sized grasshopper species because mortality can be induced by consumption of a single flake dusted with 5% dye, and yet pose little hazard to vertebrates. Large species such as American grasshopper must consume several flakes before mortality is induced.     

Fertilization in the sea urchin, Strongylocentrotus purpuratus is blocked by fluorescein dyes.

Fertilization in gametes of the sea urchin Strongylocentrotus purpuratus was reversibly inhibited by several analogs of the anionic dye fluorescein. The dyes acted very rapidly and were effective when added before or several seconds after insemination. Eggs and sperm did not appear to be irreversibly modified by incubation in seawater solutions containing tetraiodofluorescein (erythrosin B). Sperm binding to the vitelline layer was also inhibited by erythrosin B, but required concentrations greater than that necessary to block fertilization. The ability of the compounds to block fertilization was a function of the particular fluorescein derivative used and its concentration. The concentration required to inhibit fertilization in 50% of the eggs was related to dye lipid solubility. The dyes may inhibit fertilization by preventing gamete membrane fusion.     

Inhibition of Vesicular Glutamate Uptake by Rose Bengal-Related Compounds: Structure–Activity Relationship

Synaptic vesicular accumulation of glutamate is a vital initial step in glutamate transmission. We have previously shown that Rose Bengal, a polyhalogenated fluorescein analog, is a potent inhibitor of glutamate uptake into synaptic vesicles. Here, we report the structural features of Rose Bengal required for this inhibition. Various Rose Bengal-related compounds, with systematic structural variations, were tested. Results indicate that the four iodo groups and the phenyl group attached to the xanthene moiety are critical for potent inhibitory activity. Replacement of these groups with two iodo groups and an alkyl group, respectively, results in substantial reduction in potency. Of further interest in creating high potency is the critical nature of the oxygen atom which links the two benzene rings of xanthene. Thus, the phenyl group and multiple iodo groups, as well as the bridging oxygen of xanthene, are crucial elements of Rose Bengal required for its potent inhibitory action.     

Eosin interaction of alpha-synuclein leading to protein self-oligomerization

Among various dyes including congo red, thioflavin S, thioflavin T, eosin, rhodamine 6G, and phenol red, the eosin was the only dye that induced self-oligomerization of alpha-synuclein in the presence of a chemical coupling reagent of N-(ethoxycarbonyl)-2-ethoxy-1, 2-dihydroquinoline. To analyze chemical nature of the eosin interaction with alpha-synuclein, the phenomenon of self-oligomerization was further examined with eosin congeners such as ethyl eosin, eosin B, phloxine B, erythrosin B, and rose bengal. The followings are the conclusions we have reached. First of all, intactness of the benzoate moiety of eosin and the negative charge on the carboxylic group of the dye are important factors leading to the specific interaction with alpha-synuclein. Secondly, the localized negative charge on the xanthene moiety of eosin is another critical factor for the interaction. As far as substituting halides are concerned, bromides and iodides on the xanthene moiety of the dyes do not make any difference on the alpha-synuclein interaction because both eosin and erythrosin B have induced the common phenomenon of self-oligomerization. The binding curve between eosin and alpha-synuclein was sigmoidal as the dye concentrations were increased. A double reciprocal plot of the saturation curve showed that the maximum number of eosin binding sites on alpha-synuclein was 1.85 with a dissociation constant of 390 microM. The dye binding to the protein appeared to occur via a positive cooperativity. The eosin binding site(s) was suggested to be located predominantly on the NAC region and partly related to the acidic C-terminus of alpha-synuclein. It has been, therefore, expected that this information might be useful to develop alpha-synuclein interactive molecules, which could provide eventual preventive or possible therapeutic means against various alpha-synuclein related disorders including Parkinson's disease.     

Microspectrophotometric Analysis of Accumulation of the Fluorones K-Fluorescein, Rose Bengal and Phloxine Red in Living Plant Cells

Spectrophotometry investigations of dye solutions in different media and of living stained cells from the upper epidermis of the scaleleaf of Allium cepa were carried out with the dyes K-fluorescein, rose Bengal and phloxine red to elucidate the mechanism of the accumulation of these dyes in the cytoplasm, the nucleus and the cell sap. Thin layer chromatography and paper electrophoresis indicate that the K-fluorescein used here contains no detectable contaminants. Besides the main component, rose Bengal contains two components in small quantities with Rf values of 0.64 and 0.57, plus three more components in traces. Besides the two main components (Rf values of 0.83 and 0.73), phloxine red also contains five more components in traces. Electrophoretic investigations reveal that in aqueous solution the fluorones rose Bengal and phloxine red from pH 2.0-11 show a migration toward the anode. K-fluorescein from pH 2.9-10.4 shows a migration toward the anode, but at pH 1.9 a migration toward the cathode. By shaking aqueous solutions of K-fluorescein, rose Bengal and phloxine red at different pH values with different organic solvents, the above used stainings show different spectral absorption curves according to the polarity of the solvent. The position of the absorption maxima and the shape of the absorption curves of these three anionic dyes lead to the conclusion that the staining of the living cytoplasm and nucleus is due to ion accumulation by means of the “ion trap mechanism” within the aqueous phase of the cytoplasm (cytosol) and the nucleus. Adsorption of dye particles in the protein phase of the cytoplasm cannot be excluded. There seems to be a fundamental difference in the vital staining of the protoplasm by anionic and cationic dyes, the latter apparently accumulating as neutral dye molecules in the lipid phase of the protoplasm. The concentration of the dyes used in the living cytoplasm (cytosol) is approximately 0.2-0.05%. During natural and artificial displacement of K-fluorescein from the cytoplasm to the vacuole, it appears that accumulation of the dye within the vacuole is performed through an ion trap mechanism in the form of bivalent ions. Along with natural displacement, it is possible that ion accumulation also occurs in metabolic products.     

Investigation of staining,polarization and fluorescence microscopic properties of myoepithelial cells

Summary During studies of early arteriosclerotic lesions fibers with the staining properties of myosins were observed in epithelial cells of various organs. To obtain a basis for further studies, staining, oolarization and fluorescence microscopic properties of classical myoepithelial cells and tonofibrils were investigated. The tannic acid-phosphomolybdic acid (TP)-Levanol Fast Cyanine 5RN stain for myosins and related proteins was applied to sections of tongue and skin. In other series various milling dyes, xanthene dyes and Thiazine Red R were substituted for Levanol Fast Cyanine 5RN.Myoepithelial cells of lingual and eccrine sweat glands showed the microscopic properties of smooth muscle cells; tonofibrils had little or no affinity for the dyes tested. The terminal bar-terminal web system of glandular epithelium and the fibrous layer in ducts of eccrine sweat glands resembled myosins and differed significantly from proteins of the epiderminkeratin group, e.g. tonofibrils. In preliminary studies the iodinated xanthene dyes Rose Bengal G, Erythrosin B and Y were found suitable for light, fluorescence and electron microscopic studies.     

Comparison of the photodynamic action of Rose Bengal and tetrachlorosalicylanilide on isolated porcine erythrocyte membranes

The light-mediated effects of Rose Bengal and 3,3',4',5-tetrachlorosalicylanilide (T4CS) on porcine erythrocyte membranes have been investigated. Irradiation in the presence of Rose Bengal and oxygen causes extensive destruction of the unsaturated fatty acids of the erythrocyte membrane. This results in a decrease in the membrane flexibility as measured by a nitroxide spin probe. Irradiation in the presence of T4CS and oxygen had no measurable effect on the unsaturated fatty acids or on the membrane flexibility. Irradiation of erythrocyte membranes both in the presence of Rose Bengal and oxygen and of T4CS gave rise to polymerisation of the membrane proteins. This was evident by polyacrylamide gel electrophoresis and by freeze-fracture electron microscopy. Aggregation of membrane proteins could be observed with low levels of Rose Bengal and short irradiation times at which no loss of unsaturated fatty acids could be detected. Irradiation of the n-butanol-extracted apoprotein of porcine erythrocyte membranes both in the presence of Rose Bengal and of T4CS resulted in polymerisation of the protein as measured by gel electrophoresis and electron microscopy. The results obtained from the two photodynamic compounds are compared in terms of their different mechanisms of action on the membrane. The implications of the results in determining the molecular events leading to photohaemolysis are discussed.     

Study on the inhibition of testicular polyadenylate polymerase stimulated by manganese]

Many different types of naturally occurring substances and of drugs were examined as potential inhibitors of a Mn++-stimulated and poly(A)-primed polyadenylate polymerase that was partially purified from rat testis. By far the most active inhibitors were anionic dyes that were either of the diazo naphthyl sulfonate category, such as Evans Blue, or were halogenated derivatives of fluorescein, like Rose Bengal. The characteristics of these in vitro inhibitions, which did not involve any photo-sensitized reactions, were examined in considerable detail.     

Photodynamic activity and binding of sulfonated metallophthalocyanines to phospholipid membranes: contribution of metal-phosphate coordination

Photosensitized efficacy of tetrasulfonated phthalocyanines of zinc, aluminum and nickel (ZnPcS(4), AlPcS(4) and NiPcS(4), respectively) as studied by gramicidin channel (gA) photoinactivation was compared with adsorption of the dyes on the surface of a bilayer lipid membrane as measured by the inner field compensation method. The adsorption of the negatively charged phthalocyanines on diphytanoylphosphatidylcholine (DPhPC) membranes led to formation of a negative boundary potential difference between the membrane/water interfaces. Good correlation was shown between the photodynamic activity and the membrane binding of the three metallophthalocyanines. ZnPcS(4) appeared to be the most potent of these photosensitizers, while NiPcS(4) was completely ineffective. All of these phthalocyanines displayed no binding and negligible gA photoinactivation with membranes formed of glycerol monooleate (GMO), whereas Rose Bengal exhibited significant binding and photodynamic efficacy with GMO membranes. Gramicidin photoinactivation in the presence of AlPcS(4), being insensitive to the ionic strength of the bathing solution, was inhibited by fluoride and attenuated by phosphate ions. A blue shift of the fluorescence peak position of ZnPcS(4) dissolved in ethanol was elicited by phosphate, similarly to fluoride, which was indicative of the coordination interaction of these ions with the central metal atom of the phthalocyanine macrocycle. This interaction was enhanced in the medium modeling the water-membrane interface. The results obtained imply that binding of tetrasulfonated metallophthalocyanines to phospholipid membranes is determined primarily by metal-phosphate coordination.     

Photodynamic activity and binding of sulfonated metallophthalocyanines to phospholipid membranes: Contribution of metal-phosphate coordination

Photosensitized efficacy of tetrasulfonated phthalocyanines of zinc, aluminum and nickel (ZnPcS₄, AlPcS₄ and NiPcS₄, respectively) as studied by gramicidin channel (gA) photoinactivation was compared with adsorption of the dyes on the surface of a bilayer lipid membrane as measured by the inner field compensation method. The adsorption of the negatively charged phthalocyanines on diphytanoylphosphatidylcholine (DPhPC) membranes led to formation of a negative boundary potential difference between the membrane/water interfaces. Good correlation was shown between the photodynamic activity and the membrane binding of the three metallophthalocyanines. ZnPcS₄ appeared to be the most potent of these photosensitizers, while NiPcS₄ was completely ineffective. All of these phthalocyanines displayed no binding and negligible gA photoinactivation with membranes formed of glycerol monooleate (GMO), whereas Rose Bengal exhibited significant binding and photodynamic efficacy with GMO membranes. Gramicidin photoinactivation in the presence of AlPcS₄, being insensitive to the ionic strength of the bathing solution, was inhibited by fluoride and attenuated by phosphate ions. A blue shift of the fluorescence peak position of ZnPcS₄ dissolved in ethanol was elicited by phosphate, similarly to fluoride, which was indicative of the coordination interaction of these ions with the central metal atom of the phthalocyanine macrocycle. This interaction was enhanced in the medium modeling the water-membrane interface. The results obtained imply that binding of tetrasulfonated metallophthalocyanines to phospholipid membranes is determined primarily by metal-phosphate coordination.     

The Interaction of Dipole Modifiers with Polyene-Sterol Complexes

Recently, we showed that the effect of dipole modifiers (flavonoids and styrylpyridinium dyes) on the conductance of single amphotericin B (AmB) channels in sterol-containing lipid bilayers primarily resulted from changes in the membrane dipole potential. The present study examines the effect of dipole modifiers on the AmB multi-channel activity. The addition of phloretin to cholesterol-containing membranes leads to a significant increase in the steady-state AmB-induced transmembrane current. Quercetin significantly decreases and RH 421 increases the current through ergosterol-containing bilayers. Other tested flavonoids and styrylpyridinium dyes do not affect the channel-forming activity of AmB independently on the sterol composition of the bilayers. The effects obtained in these trials may instead be attributed to the direct interaction of dipole modifiers with AmB/sterol complexes and not to the effect of dipole potential changes. The presence of double bonds in the Δ7 and Δ22 positions of sterol molecules, the number of conjugated double bonds and amino sugar residues in polyene molecules, and the conformation and adsorption plane of dipole modifiers are important factors impacting this interaction.     

Estimation of the membrane permeability of liposomes via use of eosin Y chemiluminescence catalysed by peroxidase encapsulated in liposomes.

The initial rate of horseradish peroxidase (HRP)-catalysed chemiluminescence (CL) reaction in an aqueous compartment of liposomes was applied to the estimation of membrane permeability of liposomes. HRP-encapsulated liposomes were prepared by an extrusion method, and a CL reagent and H(2)O(2) were added into the liposomes suspensions. Fluorescein, eosin Y and phloxin B, which are xanthene dyes with different chemical structures, were used as CL reagents. Xanthene dye and H(2)O(2) permeate into the inner phase of liposomes, resulting in initiation of the HRP-catalysed xanthene dye CL reaction with H(2)O(2). The initial rate of the CL reaction was independent of the xanthene dye used. The reproducibility of the initial rate with eosin Y was better than that with fluorescein and phloxin B. When the membrane permeability of the liposomes was changed by altering the concentration of cholesterol in them, the initial rate of the eosin Y CL reaction was dependent on the membrane permeability of the liposomes.     

An Evaluation of the Metachromasy of Anionic Dyes. I. Visual Observations on Tissue Sections

Thirteen dyes of the azo (benzopurpurin, Congo red, trypan blue, chromotrope 2R, orange G), indigoid (indigocarmine), triphenylmethane (acid fuchsin, aniline blue, light green, methyl blue), and xanthene (eosin B, eosin Y, erythrosin B) groups were applied under standard conditions to a variety of human, rabbit, rat, mouse and frog tissues in paraffin sections. Sections were examined for color changes which might indicate metachromatic reactions analogous to the metachromasy of cationic dyes. Disazo and xanthene dyes showed shifts in hue, with some qualification on the shifts of xanthenes. Metachromatic shifts of anionic dyes were generally of low order compared to those of cationic dyes. Nuclei, erythrocytes, inner elastic laminae of arteries, keratinous structures, and certain areas in the ground substance of connective tissue most often elicited metachromasy. It is suggested that basic proteins are responsible for the metachromatic reactions. Equally interesting areas were those staining poorly (cartilage matrix, most types of mucus), since these are sites of highly acidic substances capable of binding proteins.     

Two phases of gramicidin photoinactivation in bilayer lipid membranes in the presence of a photosensitizer

The kinetics of the light-induced decrease in the gramicidin-mediated current across a bilayer lipid membrane in the presence of a photosensitizer has been shown to include a slow phase with a characteristic time of the order of 1 s and a fast phase. Based on the dependence of the slow phase relative amplitude and characteristic time on the gramicidin-mediated stationary conductance we concluded that the slow phase reflected the establishment of an equilibrium between gramicidin monomers and dimers in the membrane after the distortion of this equilibrium resulting from modification of a portion of gramicidin molecules by reactive oxygen species generated upon excitation of the photosensitizer. The dependence of the fast phase contribution to the overall kinetics on the stationary conductance allowed us to conclude that the fast phase is associated with transition of gramicidin dimers into a nonconducting state. The characteristic time of the fast phase measured with nanosecond laser excited pulses is 1.5 ms. The slow phase of the decrease in the gramicidin-mediated current was considerably decelerated in the presence of Rose Bengal. The results obtained indicate that adsorption of Rose Bengal on the bilayer interface leads to a reduction of the dipole potential drop at the membrane-solution boundary, similarly to the action of phloretin.     

Electrostatic modeling of ion pores. II. Effects attributable to the membrane dipole potential.

This paper presents calculations of the shielded dipole potential in the interior of a pore piercing a lipid membrane that is at a potential V0 with respect to the aqueous solution. Except in the case of long narrow pores, there is substantial shielding of the membrane dipole potential. The associated dipole field never extends a significant distance into the aqueous region. The fact that the single-channel conductance of gramicidin B is only twice as large in glyceryl monooleate membranes as in phosphatidyl choline (PC) membranes, even though PC is approximately 120 mV more positive with respect to water, is interpreted in terms of the potential energy profile calculated for a gramicidin-like channel. It is demonstrated that the membrane dipole potential can significantly affect channel conductance only if the pore is narrow and if the peak in the potential energy profile occurs in the pore interior.