Enumerative Fluorescent Vital Staining of Live and Dead Pathogenic Yeast Cells

A quantitative technique is presented for differentiating live and dead yeast cells grown in culture through the use of the fluorescent dye acridine orange. the method gives results that correlate well with those of other commonly used vital staining techniques and is free of certain interpretative errors inherent in them. Vital staining of yeasts with acridine orange also allows for more precise assessment of the physiological state of individual cells and the culture as a whole. the progressive senescence of yeast cells in culture can be monitored by the changing staining characteristics of several subcellular organelles. the method is simple and reliable.     

Discrimination of respiratory dysfunction in yeast mutants by confocal microscopy, image, and flow cytometry

Living yeast cells can be selectively stained with the lipophilic cationic cyanine dye DiOC6(3) in a mitochondrial membrane potential-dependent manner. Our study extends the use of flow cytometric analysis and sorting to DiOC6(3)-stained yeast cells. Experimental conditions were developed that prevented the toxic side effect of the probe and gave a quantitative correlation between fluorescence and mitochondrial membrane potential, without any staining of other membranes. The localization of the fluorochrome was checked by confocal microscopy and image cytometry. The mitochondrial membrane alterations were also tested through cardiolipin staining with nonyl acridine orange. Differences in light scattering and in fluorescence were detected in mutants (rho-, rho degrees, mit-, or pet-) and wild-type (rho+mit+) populations of yeast. The dye uptake of respiratory-deficient yeast strains was significantly reduced as compared to that of the wild-type. Application of an uncoupler (mCICCP), which collapsed the mitochondrial membrane potential (alphapsi(m)), led to a drastic reduction of the dye uptake. It was observed that a decrease in deltapsi(m), was usually correlated with a decrease in cardiolipin stainability by nonyl acridine orange (NAO). Quantitative flow cytometry is a fast and reproducible technique for rapid screening of yeast strains that might be suspected of respiratory dysfunction and/or mitochondrial structural changes. We give evidence that it is an adequate method to characterize and isolate respiratory mutants through sorting procedure, with selective enrichment of the population studied in respiring or non-respiring yeast cells. Confocal microscopy and image cytometry corroborate the flow cytometry results.     

Comparison of Acridine Orange, Acriflavine, and Bisbenzimide Stains for Enumeration of Bacteria in Clear and Humic Waters

In highly humic water, acridine orange precipitated with dissolved humic matter, resulting in such bright background fluorescence that no bacteria could be seen. With bisbenzimide staining, a similar precipitate was nonfluorescent but obscured many cells. An acriflavine staining method proved useful and reproducible both in clear and in humic waters. Fading of fluorescence was not a problem, and stained samples could be stored after preparation. The fluorescence of cells stained with acriflavine was weaker than that with acridine orange, making counting extremely small cells slightly more difficult with the former stain.     

Competitive interaction of serotonin and the dye acridine orange with DNA

The interaction of serotonin and acridine orange dye with DNA isolated from bacterium Escherichia coli and the yeast Candida utilis has been analysed by spectrofluorimetric method. Using data on competitive binding to DNA of serotonin and acridine orange, known as DNA intercalator, a conclusion concerning the formation of intercalated complex between serotonin and DNA has been made. It is shown that for yeast DNA the constant of intercalated binding of serotonin is 3,5-fold smaller than for the bacterial one.     

A comparison of methods for assessing yeast viability

Summary Eight different methods were used to assess the cell viability of four strains of Saccharomyces. Staining with Mg-ANS, primuline yellow, FITC and methylene blue gave a good index of yeast cell viability. The standard plate count technique and microcolony formation also gave a good measure of cell viability. Fluorescent staining with acridine orange was the least useful of the methods tested. INT dye reduction gave a good index of respiring cells depending upon the yeast strain tested.     

Classification of larval circulating hemocytes of the silkworm,<Emphasis Type="Italic"> Bombyx mori</Emphasis>, by acridine orange and propidium iodide staining

Circulating hemocytes of the silkworm can be classified by fluorescence microscopy following staining with acridine orange and propidium iodide. Based on their fluorescence characteristics, three groups of circulating hemocytes can be distinguished. The first group, granulocytes and spherulocytes, is positive for acridine orange and contain bright green fluorescent granules when observed by fluorescence microscopy. In granulocytes, these green granules are heterogeneous and relatively small. In contrast, in spherulocytes, the green granules appear more homogenous and larger. The second group of hemocytes consists of prohemocytes and plasmatocytes. These cells appear faint green following staining with acridine orange and do not contain any green fluorescent granules in the cytoplasm. Prohemocytes are round, and their nuclei are dark and clear within a background of faint green fluorescence. Inside the nucleus there are one or two small bright green fluorescent bodies. Plasmatocytes are irregularly shaped and their nuclei are invisible. Oenocytoids belong to the third group, and their nuclei are positive for propidium iodide. Therefore, all five types of circulating hemocytes of the silkworm, including many peculiar ones that are difficult to identify by light microscopy, can now be easily classified by fluorescence microscopy following staining with acridine orange and propidium iodide. In addition, we show that hemocytes positive for acridine orange and propidium iodide are in fact living cells based on assays for hemocyte composition, phagocytosis, and mitochondrial enzyme activity.     

Frequencies of micronuclei detected on Mytilus galloprovincialis by different staining techniques after treatment with zinc chloride

The frequencies of micronuclei induced by ZnCl2 and detected on the gill tissue of the marine mussel Mytilus galloprovincialis with different staining techniques (acridine orange, gallocyanin chromallum, Feulgen, Giemsa) were compared. At least in the used system, the Feulgen and gallocyanin chromallum methods gave a frequency of micronuclei significantly lower than that obtained with the acridine orange and Giemsa techniques. No significant difference between the frequencies obtained with acridine orange and Giemsa was shown. So, though the acridine orange is surely the method which provides the more reliable data, in environmental screening works the Giemsa technique may be more suitable for its simplicity.     

Acridine orange binding to chromatin of individual cells and nuclei under different staining conditions. Thermadenaturation of Chromatin.

The thermodenaturation of chromatin in situ was studied by staining heat-treated nuclei with acridine orange. It was found that formaldehyde, which under the present conditions had to be used to prevent extensive renaturation of DNA, seriously affects the results of standard acridine orange staining in an unspecific manner. In particular the acetylation step involved in this staining method is strongly inhibited. Thus the standard method of staining can only give qualitative information about the effects of thermodenaturation. On the other hand, acridine orange staining at defined equilibrium, without prior acetylation is insensitive to formaldehyde and multiphasic thermodenaturation profiles are obtained with this method. At low temperatures these profiles mainly reflect changes in the protein-DNA interaction whereas at higher temperatures DNA denaturation also contributes to the curves. Although these two processes cannot be separately quantitated by simple measurements of dye binding, the thermodenaturation profiles still contain biologically significant information about the properties of chromatin in situ.     

A Bacillus thuringiensis delta-endotoxin induces programmed cell death in mosquito larvae

We present evidence that a delta-endotoxin isolated from Bacillus thuringiensis subsp.israelensis induces programmed cell death in polytene midgut cells of Culex pipiens larvae. After exposure to toxin, polytene nuclei in the anterior region of the larval midgut undergo many of the morphological and physiological changes which are characteristic of apoptosis, including the ability to stain with the vital dye, acridine orange, and fragmentation of nuclear DNA as demonstrated by agarose gel electrophoresis and in situ TUNEL labeling. The temporal sequence of toxin ingestion, acridine orange staining and larval death suggests a cause and effect relationship between programmed cell death and larval death. Amino sugars that interfere with toxicity also interfere with the time course of acridine orange staining of larval polytene nuclei. The toxin first causes programmed cell death of anterior midgut and gastric caeca cells and, subsequently, posterior midgut cells. This pattern is similar to the temporal sequence of larval polytene cell death that occurs during metamorphosis. From the size and distribution of the nuclei that are stained with acridine orange, it appears that only polytene midgut cells are affected by toxin and that the diploid regenerative cell are not affected.     

Different sensitivity of chromatin to acid denaturation in quiescent and cycling cells as revealed by flow cytometry.

The properties of DNA in situ as reflected by its staining with acridine orange are different in quiescent nonstimulated lymphocytes as compared with interphase lymphocytes that have entered the cell cycle after stimulation by mitogens. The difference is seen after cell treatment with buffers at pH 1.5 (1.3-1.9 range) followed by staining with acridine orange at pH 2.6 (2.3-2.9). Under these conditions the red metachromatic fluorescence of the acridine orange-DNA complex is higher in quiescent cells than in the cycling lymphocytes while the orthochromatic green fluorescence is higher in the cycling, interphase cells. The results suggest that DNA in condensed chromatin of quiescent lymphocytes (as in metaphase chromosomes) is more sensitive to acid-denaturation than DNA in dispersed chromatin of the cycling interphase cells. The phenomenon is used for flow cytometric differentiation between G0 and G1 cells and between G2 and M cells. In contrast to normal lymphocytes the method applied to neoplastic cells indicates the presence of cell subpopulations with condensed chromatin but with DNA content characteristic not only of G1 but also of S and G2 cells. The possibility that these cells represent quiescent (resting) subpopulations, arrested in G1, S and/or G2, is discussed.     

Acridine Orange—Methyl Green Fluorescent Staining of Nucleoli

The staining of nucleoli with the fluorescent dye acridine orange followed by counter-staining with methyl green differentially stained nucleoli in both plant and animal cells. The nucleoli fluoresced as bright structures highlighted against the quenched fluorescence of the chromatin. This technique provides a simple and highly reproducible method for differential staining of nucleoli.     

The Changes of the Vitality of Armillaria mellea and the Histochemicam Localization of Some Enzymes in the Hyphae Digested Period of Gastrodia elara

The changes of the vitality of Armillaria mellea of infecting corm of Gastrodia elata were observed by appling the live body staining method of acridine orange and by means of fluorescence microscopy. The green fluorescence of vitality was emitted by the first infected hyphae, the yellow one by the decrepit hyphae; but the orange to red fluorescence with the lost vitality were emitted by the fragmentary hyphae and clump form bodies. The large cells containing rich, RNA and protein had been confirmed by the method of the induced fluorescence which the acridine orange and by the method at pH 2.2 which the fast-green staining. The acid-phosphatase was mainly distributed within the cortical cells filled with the infected hyphae. There were few such deposits in the socalled large cells except their walls. The activity of the esterase was shown in the cortical cells filled with the infected hyphae. It were also shown in the clump form bodies and the collapsed nuclei of the large cells. The activities of adenosine triphosphatase (ATPase), peroxidase and polyphenol oxidase was notably shown in the cortical cells filled with the infected hyphae and the large cells.     

3-Amino-6-methoxy-9-(2-hydroxyethylamino) acridine: A new fluorescent dye to detect mycoplasma contamination in cell cultures

A new fluorescent acridine orange derivative, 3-amino-6-methoxy-9-(2-hydroxyethylamino) acridine (AMHA), has been applied to Hela cells in order to set up appropriate conditions for the detection of mycoplasma contaminations. Since AMHA staining reveals intensely fluorescent nuclei and slight fluorescent cytoplasm, we can visualize and localize mycoplasma contamination on each cell. In combination with a shortened Chen's staining method (1977), AMHA should allow a better detection of mycoplasma in animal cell cultures than the well established Hoechst dye.     

Single-cell analysis demonstrates how nutrient deprivation creates apoptotic and quiescent cell populations in tumor cylindroids

Understanding how quiescent and apoptotic populations form in tumors is necessary because these cell types can considerably diminish therapeutic efficacy. Most cancer therapeutics are ineffective against quiescent cells because they target rapidly proliferating cells. Distinguishing apoptosis is important because apoptotic cells are committed to death and do not require treatment. Regrowth of quiescent cell can lead to tumor re-occurrence and metastasis, which are the leading causes of cancer mortality. We hypothesized that cylindroid cultures and acridine orange staining could be used to determine how nutrient diffusion creates apoptotic and quiescent regions in tumors. To test this hypothesis we developed a microscopy technique to measure cellular DNA and RNA content in single cells using thin cylindroids and acridine orange staining. Cell classification was compared to flow cytometry of cells grown in defined monolayer cultures. The presence of apoptosis was confirmed by morphological nuclear analysis. The effect of diffusion was determined by varying incubation time, cylindroid size, and exposing cylindroids to nutrient-deficient media. Four overlapping regions were identified as a function of cylindroid radius: an outer viable/quiescent region; a second quiescent/apoptotic region; a third late-stage apoptotic region; and an inner dead region. In monolayer cultures the absence of glutamine and growth factors induced apoptosis and hypoxia induced quiescence. Treating with nutrient-deficient media suggested that cells became quiescent near the periphery because of glucose and oxygen limitations, and became apoptotic and died further from the edge because of glutamine and growth factor limitations. These results show that cellular microenvironments can be identified in cylindroids using simple acridine orange staining and that single cell fluorescence can be measured in three-dimensional culture. The developed techniques will be useful for developing cancer therapies and determining how cell death and apoptosis are induced in three-dimensional tumor tissue.     

Nuclear RNA quantification in protoplast cell-cycle phases

Using acridine orange staining and flow cytometry the DNA and RNA levels (arbitrary units) of individual cells may be established. Here, this method has been applied to nuclei isolated from plant protoplasts during culture. The specificity of the technique has been validated for such plant material; ribonuclease markedly reduced nuclear staining without modifying the DNA histogram; ribonuclease inhibitor prevented the action of released cell nucleases; and protoplasts cultivated with actinomycin D did not synthesize RNA. First RNA synthesis was evident 18 h after Petunia hybrida protoplasts had been put into culture. An increase of RNA above a critical level was required for cells to be able to initiate DNA replication from G1, termed G1B. G2 nuclei had an RNA:DNA ratio similar to that of G1 nuclei.     

Mass action and acridine orange staining: static and flow cytofluorometry.

We present results involving an approach to acridine orange staining of intact cells based on basic physicochemical considerations. We show by static microfluorometry of several in vitro and in vivo cell lines that the important parameters for such staining are the molar ratio (Formula: see text), and molar concentration of acridine orange. Differential nuclear DNA and cytoplasmic RNA staining are totally controlled by these two parameters. We show this by a physicochemical model of cell-dye interaction. Finally, we use the method to study the growth parameters of complex in vivo cell populations by automated multiparameter flow microfluorometry. We have explored also, both by static and flow systems, the effect on AO-cell staining of various cell pretreatments such as Triton X-100 and chelating agents.     

Acridine orange stabilization of glycosaminoglycans in beginning endochondral ossification

Summary This study indicated that acridine orange, when combined with the initial fixative stabilized soluble matrix glycosaminoglycan in situ in areas where considerable glycosaminoglycan extraction is known to occur. Acridine orange was able to diffuse through bone into areas of undecalcified mineralizing cartilage and to bind with the glycosaminoglycans in these areas equally well as in growth plate cartilage matrix. Matrix staining was visible by light microscopy without further staining and was seen to vary territorially in intensity; although cellular definition was poor. This deficiency was overcome by the additional application of p phenylenediamine, which stained the cells intensely. At the ultrastructure level, glycosaminoglycan was present as electron dense structures in the cartilage matrix. Preliminary X-ray microanalysis studies confirmed that the acridine orange stained structures contain sulphur; this finding extends the use of acridine orange further to quantitative analysis of glycosaminoglycan.     

Cell size and RNA content correlate with cell differentiation and proliferative capacity of rat keratinocytes.

Keratinocytes from rat skin were separated according to their size in a specially designed unit-gravity sedimentation chamber. The fractions obtained with this technique showed clear morphological differences, and analysis of size distribution confirmed that size was the criterion for separation. Simultaneous DNA and RNA staining of the fractions with acridine orange and subsequent flow cytometric analysis enabled one to classify cells into resting, proliferating, and differentiating stages. Cell size was not directly correlated with proliferation in situ as determined with acridine orange flow cytometry, nor with proliferative capacity in culture as assayed by BrdU/Hoechst flow cytometry. The smallest cells, exhibiting low DNA and RNA content, which do not proliferate in vivo, required a prolonged period of serum stimulation in vitro to initiate RNA and DNA synthesis. Cells of intermediate size exhibited early RNA synthesis and maximal proliferative capacity, whereas the largest cell population displayed no RNA synthesis in culture and the least proliferative capacity. In conclusion, these results suggest that RNA synthesis early after serum stimulation, in addition to a specific, optimal cell size, correlates with the proliferative capacity of keratinocytes in cell culture.     

Control of cellular proliferation in HeLa-S3 suspension cultures. Characterization of cultures utilizing acridine orange staining procedures

Growth control is investigated in detail in fed and unfed HeLa-S3 suspension cultures. Two-step acridine orange staining and flow cytometric analysis indicated declines in cellular red fluorescence (proportional to RNA content) of 40-50% between exponential and plateau phase in both culture types. Cellular green fluorescence (DNA content) assessed simultaneously indicates an increment of cells with Gi-DNA content in plateau phase in the unfed cultures, while fed cultures show a brief increment in G1-phase cells in the transition phase followed by a recovery in plateau phase to a value similar to that of exponential cultures. Temporal declines in the 3H-thymidine pulse-labeling index are observed in both culture systems. These data along with the flow cytometry data indicate a distinct G1-arrest in the unfed plateau cultures and suggest a random arrest of cells about the cell cycle in fed plateau cultures. Acidic acridine orange staining and flow cytometric analysis furthermore indicate the occurrence of a quiescent population comprising approximately 345 of the total cells and consisting of both dead and viable cells in plateau phase unfed cultures. In contrast, fed plateau cultures show approximately 14% quiescent, mostly dead cells. Also, both culture systems show temporal declines in the clonogenic index and a longer cell-cycle transit time in plateau phase relative to exponential phase. These findings confirm earlier work which indicates that the environment has a profound influence on the mode of growth control for mammalian cells in vitro.