A new fluorescent test for cell vitality using calcofluor white M2R

The fluorescent fabric-brightener dye, Calcofluor white M2R (CFW), can be used to distinguish between living and dead cells from a variety of animal and plant sources. CFW does not stain living mouse fibroblasts or trout red blood cells and stains only the cell walls in living cells from the epidermis of onion bulb scale, staminal hairs of Tradescantia, and longitudinal sections of broad bean stems and roots. Heat-killed plant or animal cells are recognized by their lightly stained cytoplasm and brightly stained nuclei. The optimum staining concentrations were very low (0.01% to 0.03%) and nontoxic. Using onion scale epidermis in which some cells had been killed by heating as a test system, and the plasmolysis-deplasmolysis rection as the ultimate test for cell vitality, results from CFW staining correctly predicted cell vitality for about 98% of the cells tested. This success rate was comparable to those for Evans blue, uranin or neutral red in this test system.     

A New Fluorescent Test for Cell Vitality Using Calcofluor White M2R

The fluorescent fabric-brightener dye, Calcofluor white M2R (CFW), can be used to distinguish between living and dead cells from a variety of animal and plant sources. CFW does not stain living mouse fibroblasts or trout red blood cells and stains only the cell walls in living cells from the epidermis of onion bulb scale, staminal hairs of Tradescantia, and longitudinal sections of broad bean stems and roots. Heat-killed plant or animal cells are recognized by their lightly stained cytoplasm and brightly stained nuclei. The optimum staining concentrations were very low (0.01% to 0.03%) and nontoxic. Using onion scale epidermis in which some cells had been killed by heating as a test system, and the plasmolysisdeplasmolysis rection as the ultimate test for cell vitality, results from CFW staining correctly predicted cell vitality for about 98% of the cells tested. This success rate was comparable to those for Evans blue, uranin or neutral red in this test system.     

An Evaluation of the Metachromasia of Bromophenol Blue

The heterogeneity of bromophenol blue from different commercial sources was revealed by paper chromatography. Isopropanol:ammonia:water (20:1:2) as the solvent system gave the best separation. A variety of impurities: violet, pink, light blue and yellow coloured ones were observed. Two of the yellow fractions showed a spectral shift to red in the presence of ammonia vapour. The respone of the main dye component with the anionic chromotropes such as heparin and hyaluronate was found to be metachromatic similar to that exhibited by the dye solution and not due to a polychromatic effect. The metachromatic effect was blocked by FeCl₃ as in the case of cationic dye metachromasy. The observed metachromatic colour is not one of the colours which characterize those resulting from changes caused by pH.     

Extracellular pH modulates Helicobacter pylori-induced vacuolation and VacA toxin internalization in human gastric epithelial cells

In this study we investigated whether an acidic extracellular pH may inhibit H. pylori-induced internalization of bacterial virulence factors by gastric epithelium, thus preventing ingestion of potentially dangerous luminal contents and resulting cellular damage. The interaction of H. pylori VacA toxin and ammonia (produced by H. pylori urease) with partly polarized gastric MKN 28 cells in culture was investigated at neutral and moderately acidic pH (6.2, compatible with cell viability) by means of neutral red dye uptake and ultrastructural immunocytochemistry. We found that acidic extracellular pH virtually abolished both VacA-dependent and ammonia-dependent cell vacuolation, as shown by the neutral red test, and caused a 50% decrease in VacA internalization into endosomal vesicles and vacuoles, as assessed by quantitation of immunogold particles. In addition, acidic pH blocked endosomal internalization of H. pylori outer membrane vesicles, a convenient indicator of endocytosis. Our data raise the possibility that suppression of gastric acid may increase H. pylori-induced gastric damage by enhancing epithelial internalization of H. pylori virulence factors through activation of endocytosis. Increased transmembrane diffusion of ammonia could also contribute to this process.     

A plate method for screening of bacteria capable of degrading aliphatic nitriles

A novel indicator plate method was developed for screening of aliphatic-nitrile-degrading bacteria. Isolated bacteria were tested for utilization of acetonitrile as sole source of carbon and nitrogen with the release of ammonia. The released ammonia causes increase of the pH of the medium. Phenol red indicator is used for detection of ammonia based on colour change of the indicator dye from red to pink. The liberation of ammonia from aliphatic-nitrile-utilizing bacteria is also studied in plates containing other indicators such as bromothymol blue and phenolphthalein. The usefulness of the indicator plate is demonstrated for bacteria that degrade certain aliphatic nitriles. Bacteria degrading nitriles as a nitrogen source can also be isolated with a medium containing additional carbon source. This plate method would be useful in isolation and screening of bacteria for degradation of aliphatic nitriles and also for production of nitrile-hydrolyzing enzymes.     

Neutral red uptake assay for the estimation of cell viability/cytotoxicity

The neutral red uptake assay provides a quantitative estimation of the number of viable cells in a culture. It is one of the most used cytotoxicity tests with many biomedical and environmental applications. It is based on the ability of viable cells to incorporate and bind the supravital dye neutral red in the lysosomes. Most primary cells and cell lines from diverse origin may be successfully used. Cells are seeded in 96-well tissue culture plates and are treated for the appropriate period. The plates are then incubated for 2 h with a medium containing neutral red. The cells are subsequently washed, the dye is extracted in each well and the absorbance is read using a spectrophotometer. The procedure is cheaper and more sensitive than other cytotoxicity tests (tetrazolium salts, enzyme leakage or protein content). Once the cells have been treated, the assay can be completed in <3 h.     

Stomatal responses towards neutral red uptake and particulate movement in some arid zone plants

The stomata and their behaviour towards neutral red uptake in a few arid zone plant species under stress conditions have been inve stigated. Variable patterns of accumulation or non-accumulation and retention of this vital dye, by various cells of leaf epidermis have been observed. The neutral red uptake by the cells of the epidermal strip, coalescence of particles and their movement appear to be connected with the open/closed condition of the stomata.     

Uptake and intracellular distribution of neutral red in cultured fibroblasts

Neutral red (2-methyl-3-amino-7-dimethylamino-phenazine) is taken up by cultured fibroblasts through a non-saturable process and its concentration in the cells reaches several hundred times that in the medium. The dye stains consistently discrete cytoplasmic granules; their size appears related to the level of cellular accumulation of neutral red. By isopycnic centrifugation of cytoplasmic extracts in sucrose gradients, we could clearly evidence an association of neutral red with (1) the lysosomal enzymes cathepsin D and N-acetyl-β-glucosaminidase; it is thought that neutral red accumulates in lysosomes by proton trapping; (2) cell constituents equilibrating at a median density of 1.15 g/cm³; this second compartment, with a concentration power as large as lysosomes, becomes apparent only when neutral red is more than 25 μM in the culture fluid; it serves as a temporary storage site, and the dye is thereafter transferred to lysosomes. We suggest this second compartment to be the Krinom vesicles, i.e. large autophagic vacuoles induced by and containing neutral red. Finally, a small amount of intracellular neutral red could be associated with either secretory or endocytic vesicles.     

Monodansylpentane as a blue-fluorescent lipid-droplet marker for multi-color live-cell imaging

Lipid droplets (LDs) are dynamic cellular organelles responsible for the storage of neutral lipids, and are associated with a multitude of metabolic syndromes. Here we report monodansylpentane (MDH) as a high contrast blue-fluorescent marker for LDs. The unique spectral properties make MDH easily combinable with other green and red fluorescent reporters for multicolor fluorescence imaging. MDH staining does not apparently affect LD trafficking, and the dye is extraordinarily photo-stable. Taken together MDH represents a reliable tool to use for the investigation of dynamic LD regulation within living cells using fluorescence microscopy.     

Fluorescent cytochemistry of acid phosphatase and demonstration of fluid-phase endocytosis using an azo dye method

 The aim of this work was the development of a fluorescent microscopy technique to visualize acid phosphatase activity in living and pre-fixed cells. We have shown that a coupling azo dye method, using naphthol AS-MX phosphate (NP) as substrate and fast red TR (FR) as a diazonium salt coupling agent, gives rise to a fluorescent azo dye reaction product which permits a highly sensitive demonstration of lysosomal acid phosphatase in both living and pre-fixed monolayer cell cultures. The granular staining is prevented by inhibition of acid phosphatase activity using fluoride and/or orthovanadate in both living and pre-fixed preparations. Lysosomal staining in living cells is also abolished by inhibition of fluid-phase endocytosis using low temperatures or inhibition of oxidative phosphorylation. It was shown that whilst NP entered living cells by passive diffusion, occurrence of FR in lysosomes resulted from fluid-phase endocytosis. Spectroscopic analysis of the emission and absorption features of FR, NP, naphthol AS-MX (N), and the N–FR azo dye reaction product in solution corroborated our microscopic results. The differing uptake mechanisms, and the occurrence of lysosomally localized azo dye, were also in keeping with the predictions of quantitative structure–activity relationship models of this system. Accepted: 24 April 1997     

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.     

Hydrophobic acridine dyes for fluorescence staining of mitochondria in living cells. 2. Comparison of staining of living and fixed Hela-cells with NAO and DPPAO

The hydrophobic fluorescence dyes NAO and DPPAO (see scheme of structural formulae) stain the mitochondria of living HeLa-cells. The trans-membrane potential favours the dye accumulation of the cation NAO and supports the hydrophobic interaction of the dye with the mitochondrial membrane lipids and proteins. The lecithin-like dye DPPAO is electrical neutral. Its binding to mitochondria of living cells is only caused by hydrophobic interaction. NAO and DPPAO stain also the mitochondria of glutaraldehyde fixed HeLa-cells in aqueous medium. Fluorescence staining occurs even after extraction of the lipids of the cell with acetone. We suppose that the dye accumulation in the mitochondria of the fixed cells is caused by the hydrophobic interaction between the dyes and the very hydrophobic mitochondrial lipids and proteins.     

Application of Nile red, a fluorescent hydrophobic probe, for the detection of neutral lipid deposits in tissue sections: comparison with oil red O

Nile red is a phenoxazone dye that fluoresces intensely, and in varying color, in organic solvents and hydrophobic lipids. However, the fluorescence is fully quenched in water. The dye acts, therefore, as a fluorescent hydrophobic probe. We utilized this novel property of nile red to develop a sensitive fluorescent histochemical stain for tissue lipids. Nile red was prepared by boiling Nile blue A under reflux for 2 hr in 0.5% H2SO4, and extracting the product into xylene. For staining, the purified dye is dissolved in 75% glycerol (1-5 micrograms/ml) and applied to frozen tissue sections. Tissue lipids then fluoresce yellow-gold to red, depending on their relative hydrophobicity. Using sections of liver and aorta from a cholesterol-fed rabbit, we assessed the value of Nile red as a stain for neutral lipids by comparing the staining pattern obtained with that produced by oil red O, a commonly used dye for tissue cholesteryl esters and triacylglycerols. In the cholesterol fatty liver, Nile red staining was comparable to that of oil red O. In contrast, Nile red staining of rabbit aortic atheroma revealed ubiquitous lipid deposits not observed with oil red O staining. These latter results suggest that Nile red can detect neutral lipid deposits, presumably unesterified cholesterol, not usually seen with oil red O or other traditional fat stains.     

A Comparative Study of Several Samples of Neutral Rep and Their Effects on Paramoecium Caudatum

Several samples of neutral red have been studied; first, for the determination of their relative color intensities, and second, to determine their toxic effects on Paramoecium caudatum.

It was found that each of these dyes varied in physical characters both in dry form and in solution. The duration of life of groups of Paramoecia varied in each dye solution. These differences are probably due, at least in part, to differences in the chemical composition of each dye. This suggests that the varying results obtained by experimenters, in staining living material when using the same kind of dye under uniform conditions, may probably be attributed to these differences of chemical constitution of the dyes.

In the comparison of the toxic effects of the several samples most uniform results were obtained at concentrations of 1:5,000 and 1:10-000. At a concentration of 1:100,000 neutral red was found toxic but the results obtained were not in agreement with those obtained at lower concentrations.     

A Comparative Study of Several Samples of Neutral Rep and Their Effects on Paramoecium Caudatum

Several samples of neutral red have been studied; first, for the determination of their relative color intensities, and second, to determine their toxic effects on Paramoecium caudatum.

It was found that each of these dyes varied in physical characters both in dry form and in solution. The duration of life of groups of Paramoecia varied in each dye solution. These differences are probably due, at least in part, to differences in the chemical composition of each dye. This suggests that the varying results obtained by experimenters, in staining living material when using the same kind of dye under uniform conditions, may probably be attributed to these differences of chemical constitution of the dyes.

In the comparison of the toxic effects of the several samples most uniform results were obtained at concentrations of 1:5,000 and 1:10-000. At a concentration of 1:100,000 neutral red was found toxic but the results obtained were not in agreement with those obtained at lower concentrations.     

Differential Congo Red staining: The effects of pH, non-aqueous solvents and the substrate

Summary Congo Red is an acid-base indicator dye. In free solution the colour and absorption characteristics of Congo Red depend not only on the pH but are also governed by the nature of the solvent environment. In tissue sections stained by Congo Red, alteration of the pH and the use of non-aqueous solvents can effect differential colouring of the tissue components. Stained sections of unmodified and chemically substituted celluloses show that differential red or blue coloration reflects the acidic or basic character of the substrate. In stained tissue sections, secondary protein structure and porosity of the substrate may also influence their colour. The effect of non-aqueous solvents is probably to modify the ionization state of the dye- substrate complex, thus altering the colour of the Congo Red. Such solvents may also change the aggregation or solvation states of the dye, with consequent modification in the colour of tissue components.     

Über hydrophobe Acridinfarbstoffe zur Fluorochromierung von Mitochondrien in lebenden Zellen

Summary The hydrophobic fluorescence dyes NAO and DPPAO (see scheme of structural formulae) stain the mitochondria of living HeLa-cells. The trans-membrane potential favours the dye accumulation of the cation NAO and supports the hydrophobic interaction of the dye with the mitochondrial membrane lipids and proteins. The lecithinlike dye DPPAO is electrical neutral. Its binding to mitochondria of living cells is only caused by hydrophobic interaction. NAO and DPPAO stain also the mitochondria of glutaraldehyde fixed HeLa-cells in aqueous medium. Fluorescence staining occures even after extraction of the lipids of the cell with acetone. We suppose that the dye accumulation in the mitochondria of the fixed cells is caused by the hydrophobic interaction between the dyes and the very hydrophobic mitochondrial lipids and proteins.     

Neutral Red as a Lipid Fluorochrome

Aqueous 0.1% neutral red adjusted to pH 6.5, or mixed 1:1 with seawater, produced conspicuous fluorescence in plant and animal fats while acting as a conventional stain for acidic groups including volutin. The water-soluble, nonfluorescent dye predominating in acid solutions became deprotonized, lipophilic and fluorescent under neutral and alkaline conditions. Neutral dye crystals fluoresced dull red, whereas the fluorescence was either bright lemon yellow or blue-green in lipids, apparently dependent upon their composition.     

Characterization of the isolated calcium-binding vesicles from the green alga Mougeotia scalaris,and their relevance to chloroplast movement

The calcium-binding vesicles from the green alga Mougeotia scalaris were isolated and characterized after staining in vivo by neutral red or rhodamine B. They were found to possess, a protonated group with a pK_a-9.9, typifying phenolic hydroxyl groups; upon titration, both, phenolic compound(s) and vital dye were concomitantly released from the vesicular matrix. A shift in peak absorbance from 450 nm to 540 nm of the vitally stained vesicles indicated that the neutral form of neutral red was bound to the vesicular, matrix as an intermediate form, stabilized via intermolecular hydrogen bonds to the phenolic compound(s). Up to 8.5.10⁹ dye molecules were calculated to be adsorbed to a mean-size vesicle. Analysis of Langmuir adsorption isotherms, indicated that there were two binding sites each for both neutral red and rhodamine B. The isolated vesicles were devoid of calcium, probably because vesicular calcium, bound to the vesicle matrix, was displaced upon dye binding. Dye adsorption to the vesicles in vivo results in substantial inhibition of the reorientational movement of the Mougeotia chloroplast and is explained by dye-mediated disorder of the cellular calcium homoeostasis.Abbreviations NR neutral red - RB rhodamine B - SDS sodium dodecyl sulfate This paper is part of the Ph.D. thesis of F. Grolig at Justus-Liebig-Universität Giessen, FRG     

Permeability of the Plasmalemma as Compared with that of the Tonoplast

In recent years there has been an increasing tendency to regard the tonoplast as the decisive diffusion barrier of the protoplast. The plasmalemma has been assumed to be more or less freely permeable, especially to ions (Brooks 4, Arisz 1, Epstein 8, Briggs and Robertson 3, Sutcliffe 12). This view is, however, based on observations which are far from unequivocal.
In the following we shall try to elucidate the question of the relative permeability and susceptibility of the two plasma membranes towards sodium hydroxide and sodium carbonate. The tests were made on internodal cells of Nitellopsis obtusa , staminal hairs of Tradescantia virginiana and T. zcbrina and epidermal cells of Allium cepa var. sanguinetim. These cells show protoplasmic streaming and either contain anthocyanins or were stained with neutral red.
In these experiments the plasmalemma, or some other layer outside the streaming part of the protoplasm, is assumed to be more or less impermeable towards sodium hydroxide as long as protoplasmic streaming is going on in the cells lying in the strongly alkaline solution. On the other hand, by the time the colour of the cell sap changes a considerable amount of NaOH must have passed through the whole protoplast, including both plasmalemma and tonoplast. The principal object of the experiments was, therefore, to compare (a) the time necessary to stop the protoplasmic streaming, irreversibly, with (b) the time required for the colour of the vacuole to change either to yellow (neutral red) or to blue (anthocyanin).