Detection of cell cycle subcompartments by flow cytometric estimation of DNA-RNA content in combination with dual-color immunofluorescence

BACKGROUND: Correlated flow cytometric measurements of phenotype and DNA-RNA content offer detailed information on cell cycle status of subpopulations in heterogeneous cell preparations in response to stimulation. We have developed a method for flow cytometric analysis of DNA-RNA content that has been optimized for simultaneous measurement of dual-color immunofluorescence. METHODS: Nucleic acid staining was performed at low pH in the presence of saponin. DNA was stained with 7-aminoactinomycin D (7-AAD) and RNA with pyronin Y(G) (PY); both dyes were used at low concentrations, and 7-AAD was exchanged with nonfluorescent actinomycin D after DNA staining to minimize fluorochrome-fluorochrome interactions. For cell surface antigen staining, allophycocyanin was combined with pH-independent Alexa488 instead of fluorescein-isothiocyanate (FITC) because FITC is pH sensitive. RESULTS: This method identified cell cycle subcompartments in CEM cells comparable to published results on cell lines using other dyes and staining methods. Measurement of DNA-RNA content in CD8 lymphocyte subsets of human peripheral blood mononuclear cells costimulated with CD3/CD28.2 showed that, after 48 h of stimulation, 80% of CD8(+) T cells were in the proliferative state, whereas 86% of CD8(+) non-T cells remained in G(0). CONCLUSIONS: This technique permits the clear identification of cellular subpopulations by phenotype and assessment of their cell cycle status.     

Dead cell discrimination with 7-amino-actinomycin D in combination with dual color immunofluorescence in single laser flow cytometry.

Identification of nonviable cells in immunofluorescently stained cell populations is essential for obtaining accurate data. Fluorescent non-vital DNA dyes, particularly propidium iodide (PI), have been used routinely in flow cytometry for discrimination of dead cells from viable cells on the basis of fluorescence. We describe here the use of an alternative DNA dye, 7-amino-actinomycin D (7-AAD), which can replace PI for the exclusion of nonviable cells. As an example, we present in this paper the utilization of 7-AAD on various leukemic cell lines for dead cell exclusion whenever the viable cell population could not be discriminated reliably from nonviable cells on the light scatter histogram; 7-AAD is suitable for dead cell discrimination in lengthy experiments because it is efficiently excluded by intact cells and has a high DNA binding constant. In addition, the dye is valuable in combination with phycoerythrin (PE)-fluorescence dual-color flow cytometry on a single argon laser instrument, since its emission in the far red can easily be separated from the emission of PE; 7-AAD was used on fluoresceinisothiocyanate (FITC) and PE surface-labeled human thymocytes for characterization of the dying subpopulation of cells which is undergoing programmed cell death. In this heterogeneous cell preparation, the spectral properties of the dye permitted the classification of viable and nonviable cell subpopulations by multiparameter analysis.     

Fluoro-Gold: An alternative viability stain for multicolor flow cytometric analysis.

BACKGROUND: The viability stains propidium iodide (PI) and 7-amino-actinomycin D (7-AAD) are excited at 488 nm, as are the commonly used antibody conjugates fluorescein isothiocyanate (FITC), phycoerythrin (PE), and cyanine 5 dye covalently coupled to R-phycoerythrin (RPE-Cy5). When excited by a single laser, spectral overlap in the emission of PI and 7-AAD with RPE-Cy5 precludes the use of these viability stains for three-color immunophenotyping, particularly when evaluating low levels of marker expression in viable target cells. The ultraviolet excitable dye hydroxystilbamidine methanesulfonate (Fluoro-Gold, or FG) binds to DNA at the A-T-rich regions of the minor groove in permeabilized or dead cells. We assessed the suitability of this dye as a viability stain. METHODS: The ability of FG to detect nonviable cells in fresh and cryopreserved human apheresed peripheral blood cells was compared with that of PI and 7-AAD. The stability of FG staining and the effects of dye and cell concentration on the discrimination of nonviable cells was determined by measuring changes in the median fluorescence of viable and nonviable cells. RESULTS: FG labeling at dye concentrations of 2-8 microM is stable for at least 3 h over a wide range of cell concentrations (4 x 10(5) to 4 x 10(7) cells/ml). Costaining studies and linear regression analysis show that cell viability as determined by FG is strongly correlated with estimates using PI (r = 0.9636) and 7-AAD (r = 0.9879). CONCLUSIONS: FG is a reliable, alternative viability stain that can be used in conjunction with fluorochromes including FITC, PE, and RPE-Cy5 for multicolor analysis using dual-laser instruments.     

A gentle fixation and permeabilization method for combined cell surface and intracellular staining with improved precision in DNA quantification.

A method was developed for gentle fixation of mammalian cells and permeabilization of their membranes. The method is useful for staining of intracellular antigens or quantification of DNA content simultaneously with cell surface staining. Cells are treated for 1 h at 4 degrees C with 0.25% buffered paraformaldehyde then for 15 min at 37 degrees C with 0.2% Tween 20 detergent in PBS. The procedure permits excellent staining of intracellular proteins, very low coefficients of variation (CV) on the G0G1-peak of DNA distributions, and preservation of the integrity of cell surface antigens. The low vs. 90 degrees angle light scatter profile of cell clusters is maintained thereby allowing discrimination of different cell populations including human peripheral blood lymphocytes and monocytes for gating and analytic purposes. The method was successfully used on a variety of other cell types, including human thymocytes, murine thymocytes and spleen cells, and several leukemic cell lines. Dual-color surface antigen staining combined with DNA staining with 7-amino-actinomycin D (7-AAD) on peripheral blood mononuclear cells (PBMC) cultured with tetanus toxoid allowed the determination of the cell subset that was preferentially stimulated. Staining for internal antigens was done on CCRF-CEM for expression of CD3 epsilon and on NALM-6 for expression of mu. The technique we developed gave bright and specific staining of internal antigens in the examples presented here. It is particularly suited for correlations of internal antigen staining with DNA staining and/or surface immunofluorescence.     

Caffeine dissociates complexes between DNA and intercalating dyes: application for bleaching fluorochrome-stained cells for their subsequent restaining and analysis by laser scanning cytometry

BACKGROUND: Removal of the nucleic acid-bound fluorochrome is desirable when stained cells have to be reanalyzed using other fluorochromes. It is also often desirable to remove DNA-bound antitumor drugs from drug-treated cells, to improve cell staining. We have previously observed that in aqueous solutions, the methylxanthine caffeine (CFN) decreases interactions between planar aromatic molecules such as intercalating dyes or antitumor drugs and nucleic acids. The aim of this study was to explore whether this property of CFN can be utilized to remove the DNA-bound intercalating dyes propidium iodide (PI) or 7-aminoactinomycin D (7-AAD) from the cells and whether the bleached cells can be restained and reanalyzed. METHODS: HL-60 cells were fixed in 70% ethanol and their DNA was stained with PI or 7-AAD. The cells were then rinsed with a 0.05 M solution of CFN in phosphate-buffered saline (PBS) or with PBS alone. The decrease in intensity of cell fluorescence during rinsing was measured by laser scanning cytometry (LSC) to obtain the bleaching kinetics of individual cells. The bleached cells were then restained with PI, 7-AAD, or the protein-specific fluorochrome sulforhodamine 101(S101). Their fluorescence was measured again by LSC. In addition, free DNA was subjected to gel electrophoresis, DNA bands in the gels were stained with ethidium bromide (EB), and the gels were rinsed with a solution of CFN or PBS to bleach the DNA band's fluorescence. RESULTS: Rinsing the PI or 7-AAD-stained cells with solutions of CFN led to nearly complete removal of PI and a more than 75% decrease in 7-AAD fluorescence after 10 min. The rinse with PBS decreased the PI cell fluorescence intensity by less than 30% and the 7-AAD fluorescence by about 50%. The differences in kinetics of PI or 7-AAD removal by CFN from G2/M versus G1 cells suggest that these intercalators bind more strongly to DNA in chromatin of G2/M than G1 cells. The CFN-bleached cells were then successfully stained with S101 and again with PI or 7-AAD. The bivariate analysis of the LSC merged files of the cells sequentially stained with PI and S101 revealed typical DNA/protein distributions. The fluorescence of EB-stained DNA bands in gels was also nearly completely removed by rinsing gels in 0.05 M CFN; PBS alone had a distinctly lesser effect. CONCLUSION: Solutions of CFN can dissociate the DNA-bound PI, 7-AAD, EB, and possibly other intercalating fluorochromes. The bleached cells can be restained and reanalyzed by LSC. This approach can also be used to remove such fluorochromes from nucleic acids immobilized in gels and perhaps in other solid matrices. Analysis of the kinetics of fluorochrome removal from cells can possibly be used to study their binding affinities to nucleic acids in situ.     

Flow cytometric estimation of DNA and RNA content in intact cells stained with Hoechst 33342 and pyronin Y

The addition of RNA content estimation to flow cytometric measurement of DNA content provides valuable information concerning cells' transitions between quiescent and proliferative states. Equilibrium staining methods employing acridine orange have been used for DNA/RNA content measurement but are difficult to apply to intact cells and impractical for use in conjunction with fluorescent antibodies or ligands for demonstration of cell surface structures. I have used a combination of Hoechst 33342 (HO342) and pyronin Y (PY) to stain intact cells for DNA/RNA content estimation with a dual source flow cytometer using UV and blue-green or green excitation, measuring HO342 fluorescence at 430--470 nm and PY fluorescence at 590--650 nm. Results obtained with cultured cells and stimulated lymphocytes are in good agreement with those obtained using acridine orange for DNA/RNA staining; about half of the PY fluorescence can be removed from ethanol-fixed cells stained with HO342 and PY by RNAse digestion. The HO342/PY method can be combined with fluorescein immunofluorescence for detection of cell surface markers. HO342 can be combined with other tricyclic heteroaromatic dyes for DNA/RNA estimation; the combination of HO342 and oxazine 1 can be excited in a dual source instrument using a mercury arc lamp and a helium-neon laser. The staining procedure is simple; cells in medium are incubated with 5 microM HO342 at 37 degrees C for 45 min, 5 microM PY (or oxazine 1) is then added and cells are analyzed without washing after an additional 45 min incubation. Suitability of these dye combinations for vital cell staining and sorting remains to be determined.     

A unified procedure for conservative (morphology) and integral (DNA and immunophenotype) cell staining for flow cytometry

BACKGROUND: Current methods for multiparameter DNA flow cytometry suffer from several limitations. These include significant modifications of cell morphological parameters, the impossibility to counterstain cells with certain fluorochromes, and laborious tuning of the instrument that, for some procedures, must be equipped with an ultraviolet (UV) laser. To overcome these problems, we developed a novel method for the simultaneous analysis of morphological parameters, four-color immunophenotyping, and stoichiometric DNA labeling using a bench-top flow cytometer. METHODS: The method consists of a mild permeabilization/fixation treatment at room temperature, followed by labeling with fluorochrome-conjugated monoclonal antibodies (mAbs) and with the DNA dye 7-aminoactinomycin D (7-AAD) at 56 degrees C. RESULTS: Using this method, we analyzed resting peripheral blood mononucleated cells (PBMC), proliferating T cells cultured in the presence of interleukin-2 (IL-2), and lymphoblastoid B cells. Lymphocytes, monocytes, and lymphoblasts treated by this procedure retained differential light scattering (DLS) characteristics virtually identical to those of untreated cells. This allowed regions to be drawn on forward scatter (FSC) and side scatter (SSC) cytograms resolving different cell populations. DLS were preserved well enough to distinguish large lymphoblasts in the S or G2/M phases from small G0/G1 cells. Also, stainability with fluorescein-isothiocyanate (FITC), R-phycoerythrin (PE), allophycocyanin (APC)-conjugated mAbs was generally preserved. DNA labeling with 7-AAD was of quality good enough to permit accurate cell cycle analysis. CONCLUSIONS: The method described here, which we called integral hot staining (IHS), represents a very simple, reproducible, and conservative assay for multiparameter DNA analysis using a bench-top flow cytometer. Last but not least, the cytometer tuning for multiparameter acquisition is straightforward.     

Automated image analysis of live/dead staining of the fungus Aureobasidium pullulans on microscope slides and leaf surfaces

An image analysis program and protocol for the identification and enumeration of live versus dead cells of the yeast-like fungus Aureobasidium pullulans was developed for both populations on microscope slides and leaf surfaces. Live cells took up CellTracker Blue, while nonviable cells stained with DEAD Red. Image analysis macro programs running under Optimas software were used to acquire images and to differentiate and enumerate viable from nonviable cells. The software was capable of discriminating green as a third parameter for identification and quantification of green fluorescent protein-expressing cells in a wild-type population.     

Simultaneous cytofluorometric analysis for the expression of cytoplasmic antigens and DNA content in CD3- human thymocytes

We describe a method of two-color immunofluorescence staining which allows the simultaneous analysis of both cytoplasmic antigens and cell entry into the S/G2/M cell cycle phases. This analysis was performed on CD3(-)-activated thymocytes obtained from either highly purified CD1-CD3-CD4-CD8- cells or fresh thymus cell suspensions, stimulated with low doses of phorbol-12 myristate-13 acetate (0.5 ng/ml) and interleukin-2. On the 14th day under these culture conditions about 90% of thymocytes did not express CD3 antigen on the cell surface. CD3- cells were further purified by cell sorting, fixed in paraformaldehyde, and permeabilized with Nonidet-P40. Then these thymocytes were stained by indirect immunofluorescence with monoclonal antibodies identifying T cell-specific molecules (CD3, CD2, CD28, TCR alpha/beta, and TCR gamma/delta) and analyzed for DNA content. Interestingly, both CD3 and CD28 antigens were detectable in the cytoplasm of most cells (greater than 80%). Further, the majority of the thymocytes which had entered the S/G2/M phases of the cell cycle (20%) expressed intracellular CD3 and CD28 molecules and reacted with the anti-beta framework beta F1 monoclonal antibody. The relationship between the appearance of CD3 and other T cell markers in the cytoplasm, the cell cycle entry, and the thymocyte development is discussed.     

Analysis with flow cytometry of green fluorescent protein expression in leukemic cells.

BACKGROUND: The measurement of DNA content with propidium iodide (PI) in cells transfected with expression vectors encoding the green fluorescent protein (GFP) is a useful tool in studying a variety of biological functions of proteins within cells. The purpose of this study was to determine conditions of formaldehyde fixation that permit intracellular GFP fluorescence and adequate DNA histograms to be generated following transient transfection of cells with a GFP-encoding plasmid. Cell cycle analysis was also performed in GFP-positive cells. METHODS: The murine myeloid leukemic cell line, 32Dcl3, was used as the model system. Cells were transfected with a GFP-encoding plasmid (pEGFPC1). Following fixation in different formaldehyde concentrations and permeabilization with 70% ethanol, cells were stained with PI and analyzed by flow cytometry for GFP fluorescence and DNA content. Transfected cells were also analyzed for GFP fluorescence and DNA content following release from nocodazole block. RESULTS: Fixing cells in 0.51-1.75% formaldehyde concentrations prior to ethanol permeabilization resulted in 14-19% of transfected cells being GFP-positive, with acceptable coefficients of variation on the G(1) peak of DNA histograms. Analysis of cells synchronized to and released from the G(2)-M phase by nocodazole suggested that GFP-positive cells, when compared to GFP-negative cells, did not appear to progress out of G(2)-M following release from nocodazole block. Simultaneous detection of GFP fluorescence and DNA content by PI staining is possible following transient transfection of cells with a single expression vector encoding GFP. Our results demonstrate that GFP expression can be detected, using flow cytometry to perform cell cycle analysis in murine leukemic cells.     

Texture analysis of fluorescence lifetime images of AT- and GC-rich regions in nuclei.

We used intensity and fluorescence lifetime microscopy (FLIM) of 3T3 nuclei to investigate the existence of AT-rich and GC-rich regions of the nuclear DNA. Hoechst 33258 (Ho) and 7-aminoactinomycin D (7-AAD) were used as fluorescence probes specific for AT and GC base pairs, respectively. YOYO-1 (Yo) was used as a dye that displays distinct fluorescence lifetimes when bound to AT or GC base pairs. We combined fluorescence imaging of Ho and 7-AAD with time-resolved measurements of Yo and took advantage of an additional information content of the time-resolved fluorescence. Because a single nucleus could not be stained and measured with all three dyes, we used texture analysis to compare the spatial distribution of AT-rich and GC-rich DNA in 100 nuclei in different phases of the cell cycle. The fluorescence intensity-based analysis of Ho- or 7-AAD-stained images indicates increased number and larger size of the DNA condensation centers in the G2/M-phases compared to G0/1-phases. The lifetime-based study of Yo-stained images suggests spatial separation of the AT- or GC-rich DNA regions in the G2/M-phase. Texture analysis of fluorescence intensity and lifetime images was used to quantitatively study the spatial change of condensation and separation of AT- and GC-rich DNA during the cell cycle.     

Application of pyronin Y(G) in cytochemistry of nucleic acids

Chinese hamster ovary (CHO) cells or isolated nuclei were stained with pyronin Y(PY) and analyzed by absorption or fluorescence microscopy, as well as by flow cytometry. Specificity of the staining reaction was assayed by testing sensitivity of the stainable material to RNase or DNase. The colored complexes detected by light absorption in fixed cells stained with PY are nonfluorescent and are most likely the products of condensation of single-stranded (ss) RNA by PY; the poly(rA) and poly(rA,rG) are the most sensitive to condensation. The products of PY interaction with double-stranded (ds) nucleic acids are fluorescent and can be detected in cells by cytofluorometry. PY used alone stains both DNA and RNA, and the staining capabilities of these nucleic acids vary depending upon the PY concentration at equilibrium; at a concentration above 330 microM, the RNA stainability decreases, perhaps due to its denaturation and condensation caused by the dye. In the presence of Hoechst 33342, PY can specifically stain RNA in fixed cells or isolated cell nuclei. Because only complexes of PY with ds RNA are fluorescent, this dye can be used as a probe of RNA conformation, e.g., to monitor denaturation of RNA in situ. The RNA stainability of mitotic cells is about 25% lower than that of cells in G2 phase, which indicates that during mitosis proportionately less cellular RNA is in the ds conformation. The advantages and limitations of the two cytochemical methods for DNA/RNA detection, one based on the use of Hoechst 33342 and PY, and another employing the metachromatic properties of acridine orange, are compared.     

Ethanol induced apoptosis in human HL-60 cells

In this study flow cytometric and morphologic methods of apoptosis detection in human promyelocytic leukemia cell line HL-60 were compared. HL-60 cells were harvested at 4, 7, 16, 24 a 48 hours after induction of apoptosis by 3 % ethanol. Little changes were observed both by flow cytometry (decrease of forward scatter, increase of unprocessed cells staining with APO2.7 antibody) and viability determination by Trypan-blue staining until after 7 hours. However, after 4 hours morphologic changes were observed in the nuclear and cytoplasmic structures using Diff-Quik stained cytospin preparations and standard light microscopic techniques (50% apoptotic cells). The same results were obtained by flow cytometric measurement of sub-diploid DNA content (sub-G1 cells), and an increase of staining with APO2.7 antibody in cells permeabilised by digitonin prior to staining. After 7 hours almost all cells exhibited apoptotic morphology. After 16 hours the cell size (forward scatter) decreased significantly, and 54% of unprocessed cells were APO2.7 positive. After 24 hours only 6% of cells were alive (high forward scatter) and these cells were APO2.7 negative. The HL-60 cells did not proliferate during the cultivation in 3% ethanol, and after 48 hours all stained by Trypan blue. HL-60 leukemic cells were CD34-/AC133-, CD33+/CD15+, and only 2% of the cells were CD95+. Induction of apoptosis by ethanol did not enhance CD95 antigen expression.     

Fluorescence lifetime imaging of nuclear DNA: effect of fluorescence resonance energy transfer

BACKGROUND: DNA fluorescence dyes have been used to study DNA dynamics, chromatin structure, and cell cycle analysis. However, most microscopic fluorescence studies of DNA use only steady-state measurements and do not take advantage of the additional information content of the time-resolved fluorescence. In this paper, we combine fluorescence imaging of DNA with time-resolved measurements to examine the proximity of donors and acceptors bound to chromatin. METHODS: We used frequency-domain fluorescence lifetime imaging microscopy to study the spatial distribution of DNA-bound donors and acceptors in fixed 3T3 nuclei. Over 50 cell nuclei were imaged in the presence of an AT-specific donor, Hoechst 33258 (Ho), and a GC-specific acceptor, 7-aminoactinomycin D (7-AAD). RESULTS: The intensity images of Ho alone showed a spatially irregular distribution due to the various concentrations of DNA or AT-rich DNA throughout the nuclei. The lifetime imaging of the Ho-stained nuclei was typically flat. Addition of 7-AAD decreased the fluorescence intensity and lifetime of the Ho-stained DNA. The spatially dependent phase and modulation values of Ho in the presence of 7-AAD showed that the Ho decay becomes nonexponential, as is expected for a resonance energy transfer (RET) with multiple acceptors located over a range of distances. In approximately 40 nuclei, the intensity and lifetime decrease was spatially homogeneous. In approximately 10 nuclei, addition of 7-AAD resulted in a spatially nonhomogeneous decrease in intensity and lifetime. The RET efficiency was higher in G(2)/M than in G(0/1) phase cells. CONCLUSIONS: Because RET efficiency depends on the average distance between Ho and 7-AAD, data suggest that the heterogeneity of lifetimes and spatial variation of the RET efficiency are caused by the presence of highly condensed regions of DNA in nuclei.     

Simultaneous detection of cyclin B1, p105, and DNA content provides complete cell cycle phase fraction analysis of cells that endoreduplicate

BACKGROUND: DNA analysis of endoreduplicating cells is difficult because of the overlap between stem-line G2 + M cells and 4C G1 cells. Simultaneous flow cytometry of DNA and cyclin B1 analytically separates these populations. The objective here was to develop simultaneous flow cytometry of DNA, cyclin B1, and p105 (highly expressed in mitosis) for improved, complete cell cycle phase fraction analysis of endoreduplicating cell populations. METHODS: Monoclonal antibody, GNS-1, reactive with human cyclin B1, was conjugated with fluorescein at three different fluorochrome-to-protein (F/P) ratios and tested for optimal sensitivity in a flow cytometric assay. A formaldehyde-methanol fixation procedure was optimized for retention of p105 within mitotic cells by analytic titration of formaldehyde. p105 was stained indirectly with Cy5-conjugated secondary antibody, followed by GNS-1, and DNA was stained with Hoechst 33342. The specificity of p105 in this assay was tested by comparison of manual and flow cytometric mitotic indices and by sorting and microscopic inspection. RESULTS: F/P 4.1 provided optimal fluorescein labeling of GNS-1. Formaldehyde (0.5%), followed by methanol permeabilization, fixed cells sufficiently to quantify stem-line and endoreduplicated G1, S, G2, and M phase fractions. Kinetic measurements of these fractions for both populations were demonstrated. CONCLUSIONS: The fluorochrome-to-protein ratio is important and can be optimized objectively for these assays. A permeabilization-sensitive antigen (p105), previously requiring formaldehyde/detergent-fixed cell preparations, was shown to work equally well with formaldehyde/ methanol fixation. Three-laser, two-parameter intracellular antigen analysis can be successfully coupled with DNA content analysis. Cell cycle kinetic analysis of endoreduplicating populations should be improved.     

Live-cell assay for detection of apoptosis by dual-laser flow cytometry using Hoechst 33342 and 7-amino-actinomycin D

This protocol describes a rapid and simple method for the identification of apoptotic cells. Owing to changes in membrane permeability, early apoptotic cells show an increased uptake of the vital DNA dye Hoechst 33342 (HO342) compared with live cells. The nonvital DNA dye 7-amino-actinomycin D (7-AAD) is added to distinguish late apoptotic or necrotic cells that have lost membrane integrity from early apoptotic cells that still have intact membranes as assayed by dye exclusion. The method is suitable to be combined with cell surface staining using Abs of interest labeled with fluorochromes that are compatible with HO342 and 7-AAD emissions. Surface antigen staining is carried out according to standard methods before staining for apoptosis. The basic assay can be completed in 30 min, and extra time is needed for cell surface antigen staining.     

Staining with pyronin Y detects changes in conformation of RNA during mitosis and hyperthermia of CHO cells

Cellular RNA in Chinese hamster ovary (CHO) cells synchronized in mitosis (M) or G2 phase, as well as in interphase cells subjected to hyperthermia (42 degrees C, 10 min), was stained with acridine orange (AO), ethidium bromide (EB), or pyronin Y (PY) and the resultant fluorescence was measured by flow cytometry. Total RNA content detected after staining with AO increased in M as compared to G2-phase cells, consistent with continued RNA synthesis during G2 phase. The content of double-stranded RNA, stained with EB (after DNase treatment), was also somewhat higher in M cells. In contrast, the stainability of RNA with PY decreased by 27% in M- compared to G2-phase cells. Furthermore, a decrease in stainability of RNA with PY was observed in G2 cells compared to cells in G1 phase. In separate experiments, RNA stainability with AO or EB was generally unaffected when interphase CHO cells were exposed to 42 degrees C for 10 min, though this same treatment resulted in a 26% decrease in RNA stainability with PY. The decreased PY stainability of cellular RNA in M or heat-treated cells was observed at a relatively narrow range of dye concentration (1.0-2.0 micrograms/ml). The observed hypochromicity of RNA coincides with dissociation of polyribosomes into single ribosomes known to occur during mitosis and following exposure to hyperthermia. It is presumed that the phenomenon involves selective denaturation and condensation of ribosomal (r) RNA by PY in single ribosomes which does not occur in polyribosomes. While the molecular mechanisms responsible for stabilization of rRNA in polyribosomes preventing its denaturation and condensation by PY are unknown, PY appears to be a sensitive probe that can be used to detect and study these changes in rRNA confirmation in situ.     

Flow cytometric two-color staining technique for simultaneous determination of human erythrocyte membrane antigen and intracellular malarial DNA.

A novel fixative and permeabilization method is described which allows simultaneous flow cytometric detection of red blood cell membrane antigen and intracellular malaria parasites. To illustrate the method, red blood cells from patients with paroxysmal nocturnal hemoglobinuria were infected with Plasmodium falciparum and maintained in synchronous red blood cell culture. The infected red blood cells were immunolabeled with antibodies directed to the complement regulatory protein decay-accelerating factor (DAF) followed by subsequent fixations in paraformaldehyde and then glutaraldehyde in phosphate-buffered saline. Finally, DNA of the intraerythrocytic parasites was stained with propidium iodide. Using this technique, cellular morphology was well preserved, no cell aggregation was observed, and high-quality indirect immunofluorescence and parasite DNA staining were obtained with negligible nonspecific labelling. Simultaneous measurement of parasite DNA and red blood cell membrane determinants makes possible the investigation of alterations of red cell membrane proteins in association with development of intracellular malaria parasites.     

CUBIC: a three-dimensional colored projection of Consort 30 generated trivariate flow cytometric data.

The CUBIC program displays three-dimensional colored dot plots of flow cytometric trivariate data collected by unmodified commercial instruments (FACScan flow cytometer, FACS 440 cell sorter). Assuming a bimodal distribution of the fluorescence intensity of the cells, the eight theoretical subpopulations involved in a three-color fluorescence histogram are clearly localized in the 3-D space by colored dots that are clustered near each corner of a cubic frame. Rotation, tilting, and zoom functions are available. Table look-up is not needed. CUBIC was illustrated by two experiments: 1) three-color immunofluorescence of antigens on human lymphocytes using monoclonal antibodies conjugated either to fluorescein (FITC), to R-phycoerythrin (PE), or to biotin revealed by a streptavidin coupled to a PE-Texas red tandem conjugate (TC); 2) two-color immunofluorescence of CD4 and CD8 antigens on thymocytes of healthy or preleukemic mice correlated to the DNA content quantified by 7-amino-actinomycin D (7-AAD). The three fluorescences were excited by a single argon-ion laser emitting at 488 nm.     

Radiation-induced apoptosis of stem/progenitor cells in human umbilical cord blood is associated with alterations in reactive oxygen and intracellular pH

To investigate the sensitivity of human hematopoietic stem cell populations to radiation and its relevance to intracellular events, specifically alteration in cellular energy production systems, we examined the frequency of apoptotic cells, generation of superoxide anions (O*2-), and changes in cytosol pH in umbilical cord blood (UCB) CD34+/CD38-, CD34+/CD38+ and CD34-/CD38+ cells before and after 5Gy of X-irradiation. Human UCB mononucleated cells were used in this study. After X-irradiation and staining subgroups of the cells with fluorescence (FITC, PE, or CY)-labeled anti-CD34 and anti-CD38 antibodies, analyses were performed by FACScan using as stains 7-amino-actinomycin D (7-AAD) for the detection of apoptosis, and hydroethidine (HE) for the measurement of O*2- generation in the cells. For intracellular pH, image analysis was conducted using confocal laser microscopy after irradiation and staining with carboxy-SNAFR-1. The frequency of apoptotic cells, as determined by cell staining with 7-AAD, was highest in the irradiated CD34+/CD38- cell population, where the level of O*2- detected by the oxidation of HE was also most highly elevated. Intracellular pH measured with carboxy-SNARF-1-AM by image cytometer appeared to be lowest in the same irradiated CD34+/CD38- cell population, and this intracellular pH decreased as early as 4 h post-irradiation, virtually simultaneous with the significant elevation of O*2- generation. These results suggest that the CD34+/CD38- stem cell population is sensitive to radiation-induced apoptosis as well as production of intracellular O*2-, compare to more differentiated CD34+/CD38+ and CD34-/CD38+ cells and that its intracellular pH declines at an early phase in the apoptosis process.