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.     

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.     

Effect of light of various spectral composition on kinetics of changes in a green leaf resistivity]

The kinetics of changes in the resistance of a green leaf by the action of exciting light was studied. It was shown that the illumination-induced changes in leaf conductance are mainly due to an elevation of temperature caused by the absorption of light energy. Based on the experimental results, the fraction of absorbed light energy converted into heat calculated under assumption that heating of the leaf across the thickness is uniform. It was found that the fraction of absorbed energy converted into heat does not depend on the intensity of radiation in the IR range and increases with decreasing intensity of photosynthetically active radiation. An explanation of the phenomenon is proposed, which is based on that in reality the heating of the leaf across the thickness is nonhomogeneous and this inhomogeneity of heating becomes more pronounced upon photoinduced changes in absorption resulting from a decrease in photosynthetically active radiation. It was shown that nonphotochemical fluorescence quenching does not substantially affect the leaf conductance at intensities of photosynthetically active radiation not higher than 200 Wt/m2.     

Automatic cell identification and enrichment in lung cancer. II. Acridine orange for cell sorting of sputum.

Fluorescence spectra were obtained from cells from sputum and pleural effusions stained with different fluorescent dyes and fixed by alternate methods. The spectra were referenced to a standard allowing for fluorescence comparisons of unstained and stained cells under various conditions. The metachromasia of acridine orange-stained cells offers nuclear/cytoplasmic differentiation in a single stain; mithramycin and propidium iodide do not. Unstained cells have an appreciable amount of green (546 nm) fluorescence, as does Carbowax in Saccomanno's preservative. Cytoplasm stained with acidine orange also has appreciable green fluorescence. Consequently, cells with much cytoplasm have high total fluorescence. Cytoplasmic fluorescence is negligible with mithramycin or propidium iodide. The metachromasia of acridine orange-stained cells is altered by alcohol and Carbowax levels in fixatives, keeping other factors constant.     

Automatic cell identification and enrichment in lung cancer. III. Light scatter and two fluorescence parameters.

Two fluorescence parameters and size are used in a flow through system to enrich sputum specimens for cancer cells. Human cells in sputum which are stained with acridine orange show a characteristic distribution of red and green fluorescence from which cancer cells can be localized. The peak enrichment is obtained by selectively sorting cells with the largest values of red and green fluorescence. Cancer cells located in other distribution regions having smaller fluorescence intensities show progressively diminished nuclear and cytoplasmic tinctorial features by Papanicolaou stain, consistent with the decreased intensity of red and green fluorescence.     

Analysis of Plasmodium falciparum growth in culture using acridine orange and flow cytometry

The growth of Plasmodium falciparum in cultures of human red blood cells was studied using acridine orange to stain RNA and DNA, followed by flow cytometric analysis. The cycle of the parasite is characterized by a period of growth, prior to initiation of DNA synthesis, in which a significant increase in red fluorescence is observed, with only a small change in green fluorescence. Following this phase, which is formally similar to the G1 period in mammalian cells, initiation of DNA synthesis is characterized by increases in green fluorescence. Sorting of cells from several regions of the two-dimensional display shows that the distribution of morphological stages correlates with differences in red and green fluorescence. The effect of aphidicolin on the growth cycle of the parasite was also studied.     

Flow cytometric detection of a two-step cell death induced by hyperthermia

A human leukaemic cell line (REH) was subjected to various temperatures approximately greater than 42 degrees C for various time intervals; the cells were stained with a mixture of ethidium bromide and acridine orange, and red and green fluorescence were analysed by flow cytometry. Nontreated cells appeared as one cluster (V) in the biparameter histograms, but with time of heat treatment, two further discrete clusters (D1,D2) of cells appeared successively. They were distinguished by both the degree of red and green fluorescence. The kinetics of transit from one cluster to the other was dependent on temperature, the time lag between both steps becoming shorter with higher temperatures. It was shown previously that the same effect occurred during incubation with various cytostatic agents, and that only the D2 stage correlated with the stage of cell death monitored by the usual trypan blue exclusion test. Therefore the ethidium bromide technique seems to monitor an earlier stage of cell death. The decrease in the number of dye-excluding (V) cells during heat exposure occurred in two phases. After an initial decrease a plateau of number of dye-excluding cells was reached; the duration and level of this plateau depended on the temperature. The plateau was followed by a second phase where the remaining cells ceased to exclude the dye.     

A novel technique for viable cell determinations

We have developed a simple method to determine cell viability using two fluorescent dyes, Hoechst 33258 and acridine orange. When these dyes are used in combination, dead cells fluoresce brilliant blue and live cells fluoresce green. This method works over a range of dye concentrations (Hoechst 33258, 0.25-2 micrograms/ml; acridine orange, 1-5.0 micrograms/ml) and the fluorescence spectra of the two dyes are such that only one set of filters is required to visualize the effects of both dyes simultaneously. It is insensitive to a wide range of exogenous serum concentrations and is read with greater uniformity by different observers.     

Evaluation of lysosomal stability in living cultured macrophages by cytofluorometry. Effect of silver lactate and hypotonic conditions

The ability of living mouse peritoneal macrophages to retain the lysosomotropic photosensitizer acridine orange (AO) within their secondary lysosomes was studied with a novel cytofluorometric method. During exposure to blue light, cellular AO fluorescence turned from a red granular pattern to that of diffuse green. The resulting change in total fluorescence intensity versus time - a primary decline due to red fluorescence bleaching and a secondary recovery due to the spectral shift - was interpreted as the result of leakage of AO from the lysosomal vacuome. The hypothesis that this time course should be affected by changes in lysosomal membrane stability was tested by labilizing the lysosomes by exposure of cultured macrophages to either hypotonic medium or silver lactate. In hypotonic medium, the ability to retain AO decreased continuously. Exposure to low concentrations of silver lactate (10 microM) also decreased AO retention time. We suggest that this method could be used, within appropriate experimental conditions, to evaluate lysosomal membrane stability in living cells.     

Evaluation of lysosomal stability in living cultured macrophages by cytofluorometry

The ability of living mouse peritoneal macrophages to retain the lysosomotropic photosensitizer acridine orange (AO) within their secondary lysosomes was studied with a novel cytofluorometric method. During exposure to blue light, cellular AO fluorescence turned from a red granular pattern to that of diffuse green. The resulting change in total fluorescence intensity versus time -a primary decline due to red fluorescence bleaching and a secondary recovery due to the spectral shift -was interpreted as the result of leakage of AO from the lysosomal vacuome. The hypothesis that this time course should be affected by changes in lysosomal membrane stability was tested by labilizing the lysosomes by exposure of cultured macrophages to either hypotonic medium or silver lactate. In hypotonie medium, the ability to retain AO decreased continuously. Exposure to low concentrations of silver lactate (10 μM) also decreased AO retention time. We suggest that this method could be used, within appropriate experimental conditions, to evaluate lysosomal membrane stability in living cells.     

Discrimination of cycling and non-cycling lymphocytes by BUdR-suppressed acridine orange fluorescence in a flow cytometric system.

Stimulated lymphocytes which pass through the cell cycle may be distinguished from dormant G0 lymphocytes rapidly by flow cytometry. The method is based on cell incubation with 5-bromodeoxyuridine (BUdR) and their subsequent staining with acridine orange under conditions in which cellular DNA and RNA stain differentially. The DNA-specific green fluorescence of stimulated, cycling cells is suppressed while RNA-specific red fluorescence is affected only minimally. It is possible, therefore, to distinguish cycling vs non-cycling cells based on two entirely different parameters, i.e. BUdR incorporation and RNA content.     

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.     

A Novel Technique for Viable Cell Determinations

We have developed a simple method to determine cell viability using two fluorescent dyes, Hoechst 33258 and acridine orange. When these dyes are used in combination, dead cells fluoresce brilliant blue and live cells fluoresce green. This method works over a range of dye concentrations (Hoechst 33258, 0.25-2 μg/ml; acridine orange, 1-5.0 μg/ml) and the fluorescence spectra of the two dyes are such that only one set of filters is required to visualize the effects of both dyes simultaneously. It is insensitive to a wide range of exogenous serum concentrations and is read with greater uniformity by different observers.     

A comparative study of spermatozoal chromatin using acridine orange staining and flow cytometry

Spermatozoa obtained from fish (Clarias gariepinus), human (Homo sapiens), turkeys (Meleagris gallapova), rats (Rattus norvegicus), hamsters (Mesocricetus auratus), and monkeys (Macaca fascicularis) were stained with acridine orange before measuring fluorescence by flow cytometry. These mature sperm from various species produced different intensities of fluorescence while displaying similar ratios of red/green fluorescence. Comparison of the green fluorescence values for the various species showed the sequence (descending order of fluorescence values) human, turkey, monkey, hamster, rat and fish. The DNA complement (as base pairs in the haploid genome) of the various species did not increase in direct proportion to the fluorescence values. This suggests that the DNA was not equally accessible to the dye in the different species tested. The similarity in ratios of red/green fluorescence suggests that the structure of DNA in the chromatin is similar in the different species but abnormal 'satellite' populations of cells that show higher red/green fluorescence ratios than the parent population have been found in sperm samples from monkeys and from some infertile men. Their high red fluorescence intensities were not caused by RNA because treatment with RNAse did not alter the red fluorescence. It is possible that these cells contain larger amounts of denatured (single stranded) DNA.     

Fluorescence microscopy of viable mast cells stained with different concentrations of acridine orange.

Freshly harvested rat peritoneal mast cells were stained with different concentrations of acridine orange, a metachromatic fluorochrome known to form complexes with chromatin and muscopolysaccharides. Fluorescence metachromasia was observed in cytoplasmic granules in cell populations with intracelluar dye contents as low as 5 X 10(-16) mole per cell, one-half decade lower than required to produce metachromatic staining of the nucleus. Cytoplasmic granules did not stain uniformly throughout the cell; some granules exhibited red fluorescence and others green. As the amount of acridine orange uptake per cell was increased, cytoplasmic fluorescence became uniformly red and nuclear fluorescence gradually changed from green to yellow.     

Inhibitory analysis of the functions of the oxidative metabolic systems of tumor cells in tissue culture

As has been previously reported an increased intensity of light-induced green fluorescence is observed for some tumor cells. The present paper deals with the cause of this phenomenon, employing for this hepatoma cells of line HTC acted upon with 2,4-DNP, amytal and malonate. It has been shown that the light-induced increase in green fluorescence in cells is due to the oxidation of NADH-dehydrogenase, a mitochondrial flavine-containing enzyme, occurring at the time of fluorescence induction. The increased intensity of green fluorescence of flavoproteins in tumor cells is associated with an infringement in oxidation of NAD-dependent substrates in these, and with the activation of the reverse electron transport in the oxidative chain. The exciding light activates NADH-dehydrogenase and accelerates the translocation of reduced equivalents from this enzyme, which results in its oxidation, and thus--in the observed effect of increased intensity of green fluorescence.     

Fluorescence microscopy of viable mast cells stained with different concentrations of acridine orange

Summary Freshly harvested rat peritoneal mast cells were stained with different concentrations of acridine orange, a metachromatic fluorochrome known to form complexes with chromatin and mucopolysaccharides. Fluorescence metachromasia was observed in cytoplasmic granules in cell populations with intracellular dye contents as low as 5×10^–16 mole per cell, one-half decade lower than required to produce metachromatic staining of the nucleus. Cytoplasmic granules did not stain uniformly throughout the cell; some granules exhibited red fluorescence and others green. As the amount of acridine orange uptake per cell was increased, cytoplasmic fluorescence became uniformly red and nuclear fluorescence gradually changed from green to yellow.     

The fluorescence of elastic fibres stained with Eosin and excited by visible light

Synopsis Fluorescent light of any wavelength, emitted by a microscopical specimen excited with visible light, can be observed using crossed polarizers and a dark-field condenser. The absorbance of Eosin is high in the green portion of the spectrum, so that visible light from a tungsten lamp is highly effective in exciting the fluorescence of this dye.Elastic fibres in routine sections stained with Haemalum and Eosin have been found to fluoresce rather strongly, while most other Eosin-stained structures fluoresce less or not at all. The reason for this relatively selective fluorescence of Eosin-stained elastic fibres is obscure, although the phenomenon may prove useful in routine histology. It is possible, however, that in most stained substrates the fluorescence of Eosin is largely quenched by aggregation of the dye molecules, but that this is inhibited inside the relatively dense (i.e. impermeable) elastic fibres.     

A Color Image Analysis Method for Assessment of Germination Based on Differential Fluorescence Staining of Bacterial Spores and Vegetative Cells Using Acridine Orange

Color fluorescence image analysis of acridine orange (AO) stained germinating Bacillus subtilis var. niger bacteria revealed a cell population initially dominated by small green spores followed by the emergence of at least three additional discernible subpopulations in response to stimulation with D-glucose. These subpopulations were small, round or oblong red cells; intermediate to large metachromatic cells; and large red rods. Large green rods were rarely observed. An increase in red emissions (i.e., putative RNA synthesis) was sometimes seen as early as 90 min after exposure to D-glucose and uptake of AO at room temperature. This may represent either metabolic recovery from quiescence or RNA synthesis associated with germination. In the absence of D-glucose, or using autoclaved bacteria in the presence of glucose, no relative increase in the red signal was observed despite hours of observation. Digital image analysis was used for relative measurement of red, green and blue signals and to correlate the size of various subpopulations with their fluorescence color emissions over time. Image analysis demonstrated a trend toward increasing size and red emission in the presence of glucose. The average red emission was found to be a good discriminator of the various subpopulations, while the average green emission was approximately equal among the subpopulations making it a poor discriminator. These data suggest that AO staining might be used for rapid computer-assisted discrimination of spores vs. vegetative cells.