Exposure of cells to static magnetic field accelerates loss of integrity of plasma membrane during apoptosis

BACKGROUND: Much attention is being paid to the biologic effects of magnetic fields (MFs). Although MFs enhance tumorigenesis, they are neither mutagenic nor tumorigenic. The mechanism of their tumorigenic effect has not been elucidated. METHODS: To investigate the effect of MFs on apoptosis in HL-60 cells, we exposed the cells to static MFs of 6 mT generated by a magnetic disk of known intensity. Apoptosis was triggered by the DNA topoisomerase I inhibitor, camptothecin (CPT). Activation of caspases in situ using the fluorochrome-labeled inhibitor (FLICA) method and determination of plasma membrane integrity by excluding propidium iodide (PI) were measured by both laser scanning cytometry (LSC) and flow cytometry (FC). LSC and FC identified cells at three sequential stages of their demise: early apoptosis (cells with activated caspases and PI negative); late apoptosis (cells with activated caspases but unable to exclude PI); secondary necrosis (cells with apoptotic morphology no longer stained with FLICA, not excluding PI). RESULTS: MF alone did not induce any apoptogenic or necrogenic effect. CPT exposure led to the sequential appearance of apoptotic cells. In the presence of CPT and MF, the overall proportion of cells undergoing apoptosis was not significantly changed. However, we consistently observed a significant increase in the frequency of late apoptotic/necrotic cells when compared with samples treated with CPT alone (P < 0.001), as well as a decrease in the percentage of early apoptotic cells (P = 0.013). The data obtained by FC and LSC were consistent with each other, showing a similar phenomenon. CONCLUSION: Whereas MF alone or with CPT did not affect overall cell viability, it accelerated the rate of cell transition from apoptosis to secondary necrosis after induction of apoptosis by the DNA-damaging agent, CPT. Modulation of the kinetics of the transition from apoptosis to secondary necrosis by MF in vivo may play a role in inflammation and tumorigenesis.     

Translocation of Bax to mitochondria during apoptosis measured by laser scanning cytometry

BACKGROUND: During induction of apoptosis, the pro-apoptotic member of the Bcl-2 protein family (Bax) undergoes translocation to the mitochondria. The translocation, which leads to accumulation of Bax in the mitochondrial intermembrane space, appears to be the critical event determining release of cytochrome c to cytosol: the latter event triggers the irreversible steps of apoptosis, namely, the activation of caspases and the initiation of the degradation of many proteins. The aim of this study was to utilize the morphometric capabilities of the laser scanning cytometer (LSC) and adapt this instrument to detect and measure in situ the process of translocation of Bax to mitochondria. METHODS: Human breast carcinoma MCF-7 cells growing on microscope slides were treated with the DNA topoisomerase I inhibitor, camptothecin (CPT). CPT is known to induce apoptosis preferentially of S-phase cells. The cells were fixed and permeabilized on the slides, their DNA was stained with propidium iodide (PI), Bax was detected immunocytochemically with the fluoresceinated antibody, and red and green fluorescence emission was measured by the LSC. RESULTS: Prior to induction of apoptosis, Bax was uniformly and diffusely dispersed in the cell nucleus and cytoplasm. Its translocation and accumulation in mitochondria in cells undergoing apoptosis were detected and measured by the LSC as the increase in intensity of maximal pixel of Bax immunofluorescence. Bivariate analysis of DNA content versus maximal pixel of Bax fluorescence revealed that the CPT-induced Bax translocation into mitochondria was preferential to S-phase cells. Total cellular Bax immunofluorescence measured by flow cytometry, however, was increased in all phases of the cycle without a preference to S-phase cells. CONCLUSION: Changes in abundance and localization of particular proteins that undergo translocation within the cell, leading to their altered local density, may be conveniently detected by the LSC by taking advantage of its morphometric capabilities. Measurement of total cellular Bax immunofluorescence by flow cytometry combined with analysis of its translocation by LSC revealed that apoptosis of S-phase cells induced by CPT was unrelated to overall Bax abundance per cell but correlated with its accumulation in mitochondria.     

Antimycin A-induced apoptosis of HL-60 cells

BACKGROUND: Previous experiments in our laboratory investigating apoptosis induced in HL-60 cells by camptothecin (CAM) have revealed that the sequence and rapidity of the apoptotic phenomena in an individual cell depend on the proliferative state of that cell when it encounters CAM. The role of mitochondria in HL-60 apoptosis was explored using an inhibitor of oxidative phosphorylation, antimycin A (AMA). METHODS: Changes in cell light scatter, binding of annexin V-fluorescein isothiocyanate (FITC), uptake of propidium iodide (PI), and DNA content after membrane fixation/permeabilization were monitored by flow cytometry. Z-VAD-FMK was used to inhibit caspases. Fluorescence microscopy was used to examine cell morphology. RESULTS: Cells in the G1 phase of the cell cycle were the first to exhibit signs of apoptosis in response to 100 microM AMA and some of these cells disintegrated without exposing to phosphatidylserine (PS). Caspase inhibition prevented fragmentation of DNA, the nucleus, and the cell, but only delayed PS exposure and loss of plasma membrane integrity. CONCLUSIONS: The highly active mitochondria of G1-phase HL-60 cells make them particularly sensitive to AMA. PS exposure and plasma membrane damage are mediated by noncaspase molecules released from mitochondria. We hypothesize that if mitochondria are subjected to a sufficiently severe insult, whether indirectly as a result of extensive CAM-induced DNA damage or directly by the effect of AMA on electron transport, the nature and quantities of the proapoptotic molecules released are such that apoptosis proceeds to the point of cell disintegration before the PS exposure pathway is complete.     

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.     

Effects of caspase inhibition on camptothecin-induced apoptosis of HL-60 cells

BACKGROUND: During camptothecin (CAM)-induced apoptosis of HL-60 cells, the external exposure of phosphatidylserine (PS) can either precede or follow DNA cleavage. The evidence suggests that cells in S-phase when CAM is added undergo rapid DNA, nuclear, and cellular disintegration before exposing PS on the outside of the plasma membrane, whereas cells moving from G1 into S-phase after CAM is added expose PS before they manifest the other phenomena. This study describes further investigations using the broad spectrum caspase inhibitor Z-VAD-FMK. The cells were cultured for a period long enough to ascertain whether a particular phenomenon was only delayed or was blocked completely. METHODS: Changes in cell light scatter, binding of annexin V-fluorescein isothiocyanate (FITC) to PS, uptake of propidium iodide (PI) as a measure of plasma membrane integrity, and DNA content after membrane fixation/permeabilization were monitored by flow cytometry during 24-h cultures. Fluorescence microscopy was used to examine cell morphology. RESULTS: Caspase inhibition blocked DNA cleavage, breakdown of the nuclear membrane, and formation of apoptotic bodies. It also revealed the existence of a CAM-activated early S-phase checkpoint. Cells arrested in early S-phase preceded the appearance of PS-positive cells. Caspase inhibition delayed both PS exposure and loss of plasma membrane integrity but did not prevent either. CONCLUSIONS: The results support the hypothesis that the sequence of apoptotic phenomena in an individual CAM-treated HL-60 cell depends on the stage of proliferation of that cell when it encounters the CAM. They are also consistent with the hypothesis that caspases are not required for PS exposure or the loss of plasma membrane integrity, but they are involved indirectly in promoting these phenomena.     

Multiparameter analysis of human epithelial tumor cell lines by laser scanning cytometry

Laser scanning cytometry (LSC) is a relatively new slide-based technology developed for commercial use by CompuCyte (Cambridge, MA) for performing multiple fluorescence measurements on individual cells. Because techniques developed for performing four or more measurements on individual lymphoid cells based on light scatter as a triggering parameter for cell identification are not suitable for the identification of fixed epithelial tumor cells, an alternative approach is required for the analysis of such cells by LSC. Methods for sample preparation, event triggering, and the performance of multiple LSC measurements on disaggregated fixed human cells were developed using normal lymphocytes and two human breast cancer cell lines, JC-1939 and MCF-7, as test populations. Optimal conditions for individual cell identification by LSC were found to depend on several factors, including deposited cell density (cells per unit area), the dynamic range of probe fluorescence intensities, and intracellular distribution of the fluorescent probe. Sparsely deposited cells exhibited the least cell overlap and the brightest immunofluorescent staining. Major advantages of using DNA probes over a cytoplasmic immunofluorescent protein marker such as tubulin for event triggering are that the former exhibit greater fluorescence intensity within a relatively sharply demarcated nuclear region. The DNA-binding dye LDS-751 was found to be suboptimal for quantitative DNA measurements but useful as a triggering measurement that permits the performance of simultaneous fluorescein isothiocyanate-, phycoerythrin-, and indodicarbocyanine-based measurements on each cell. A major potential advantage of LSC over flow cytometry is the high yields of analyzable cells by LSC, permitting the performance of multiple panels of multicolor measurements on each tumor. In conclusion, we have developed and optimized a technique for performing multiple fluorescence measurements on fixed epithelial cells by LSC based on event triggering using the DNA-binding dye LDS 751. Although not ideal for quantitative measurements of cell DNA content, the large Stokes shift of this dye permits the performance of three or more additional fluorescence measurements on each cell.     

Detection of localized caspase activity in early apoptotic cells by laser scanning cytometry

BACKGROUND: Caspase activation is a critical early step in the onset of apoptosis. Cell-permeable fluorogenic caspase substrates have proven valuable in detecting caspase activation by flow cytometry. Nevertheless, detection of early low-level caspase activation has been difficult using conventional area or peak fluorescence analysis by flow cytometry, despite the apparent presence of these cells as observed by microscopy. We describe a method utilizing maximum fluorescence pixel analysis by laser scanning cytometry (LSC) to detect early apoptotic cells. METHODS: The PhiPhiLux-G(1)D(2) caspase 3/7 substrate was used in combination with DNA dye exclusion and annexin V binding to identify several stages of apoptosis in EL4 murine thymoma cells by both traditional flow and LSC. LSC analysis of maximum pixel brightness in individual cells demonstrated an intermediate caspase-low subpopulation not detectable by flow or LSC integral analysis. LSC analysis of caspase activity was then carried out using the larger UMR-106 rat osteosarcoma cell line to determine if this apparent early caspase activity could be correlated with localized, punctate caspase activity observed by microscopy. RESULTS: The caspase-low subpopulation found in apoptotic EL4 cells was also observable in UMR-106 cells. Relocation to cells with low fluorescence due to caspase activity and subsequent examination by microscopy demonstrated that these latter cells indeed show punctate, highly localized caspase activation foci that might represent an early stage in caspase activation. CONCLUSIONS: Cells with low-level, localized caspase expression can be detected using maximum pixel analysis by LSC. This methodology allows an early step of apoptotic activation to be resolved for further analysis.     

Nuclear protein following heat shock: protein removal kinetics and cell cycle rearrangements

Nuclear protein and DNA content of HeLa cells was determined as a function of time following hyperthermia by staining isolated nuclei with two fluorescent dyes: fluorescein isothiocyanate (FITC) for protein content and propidium iodide (PI) for DNA content. Bivariate FITC and PI histograms were obtained by flow cytometry. Univariate flow cytometric analysis was shown to be inadequate for this study, because some of the nuclear protein changes were due to cell cycle redistribution. Posthyperthermia cell kinetics could be divided into two distinct phases: an early phase characterized by the removal of heat-induced excess nuclear proteins with little or no cell progression through the cell cycle; and a late phase characterized by a redistribution of cells in the cell cycle resulting in an accumulation of cells in G2. The duration of these phases was dependent upon the hyperthermia dose. In the early phase, the rate of removal of excess nuclear protein was found to vary with heating time and temperature for time-temperature combinations which resulted in the same amount of excess nuclear protein. In the late phase, the cells blocked in G2 did not reduce their nuclear protein levels back to control values.     

Laser scanning cytometry (LCS) allows detailed analysis of the cell cycle in PI stained human fibroblasts (TIG-7)

We have demonstrated a method for the in situ determination of the cell cycle phases of TIG-7 fibroblasts using a laser scanning cytometer (LSC) which has not only a function equivalent to flow cytometry (FCM) but also has a capability unique in itself. LSC allows a more detailed analysis of the cell cycle in cells stained with propidium iodide (PI) than FCM. With LSC it is possible to discriminate between mitotic cells and G₂ cells, between post-mitotic cells and G₁ cells, and between quiescent cells and cycling cells in a PI fluorescence peak (chromatin condensation) vs. fluorescence value (DNA content) cytogram for cells stained with PI. These were amply confirmed by experiments using colcemid and adriamycin. We were able to identify at least six cell subpopulations for PI stained cells using LSC; namely G₁, S, G₂, M, postmitotic and quiescent cell populations. LSC analysis facilitates the monitoring of effects of drugs on the cell cycle.     

Comparison of methods based on annexin-V binding, DNA content or TUNEL for evaluating cell death in HL-60 and adherent MCF-7 cells

HL-60 and MCF-7 cells were treated with 0.15 μ M camptothecin (CPT) or with the solvent dimethylsulfoxide (DMSO) for the controls, for 2, 3 and 4 h or for 24, 48 and 72 h, respectively. The apoptotic index (AI) was then evaluated in parallel by the following flow cytometric methods: (1) double staining of unfixed cells with fluoresceinated annexin V and propidium iodide (PI), this after detachment by trypsinization in the case of MCF-7 cultures; (2) prefixation in 70% ethanol, extraction of degraded, low molecular weight DNA with 0.2 M phosphatecitrate buffer and analysis of the DNA content stained with PI; (3) TUNEL, i.e. labelling of DNA strand breaks with biotin-dUTP, followed by staining with streptavidin-fluorescein and counterstaining with PI. In HL-60 cells, the three methods gave similar results for the AI (3–4% in the controls and at 2 h of CPT treatment, and 35–43% at 3 and 4 h after CPT). This indicates that CPT-induced membrane alteration and DNA fragmentation occurred concomitantly in those cells. For MCF-7 cells, CPT-induced apoptosis developed more slowly, the AI, whether based on annexin V or on DNA content, remained unchanged at 24 h, then was increasing to 8% at 48 h and to 25% at 72 h of treatment. In these cells, the TUNEL index did not increase prior to 72 h, and the increase was minor (up to 9% vs. 2–3% in the controls) at 72 h of the treatment. This indicates that in MCF-7 cells DNA strand breaks cannot be effectively labelled, which may be due to inaccessibility of 3-OH ends in the breaks to exogenous terminal deoxynucleotidyl transferase. The mechanism of endonucleolytic DNA fragmentation thus may be different, depending on the cell type.     

Detection of caspases activation by fluorochrome-labeled inhibitors: Multiparameter analysis by laser scanning cytometry

BACKGROUND: The fluorochrome-labeled inhibitors of caspases (FLICA) were recently used as markers of activation of these enzymes in live cells during apoptosis (Bedner et al.: Exp Cell Res 259:308-313, 2000). The aims of this study were to (a) explore if FLICA can be used to study intracellular localization of caspases; (b) combine the detection of caspase activation with analysis of the changes with cell morphology detected by microscopy and laser scanning cytometry (LSC); and (c) adapt the assay to fixed cells that would enable correlation, by multiparameter analysis, of caspase activation with the cell attributes that require cell permeabilization in order to be measured. METHODS: Apoptosis of human MCF-7, U-937, or HL-60 cells was induced by camptothecin (CPT) or tumor necrosis factor-alpha (TNF-alpha) combined with cycloheximide (CHX). Binding of FLICA to apoptotic versus nonapoptotic cells was studied in live cells as well as following their fixation and counterstaining of DNA. Intensity of cell labeling with FLICA and DNA-specific fluorochromes was measured by LSC. RESULTS: Exposure of live cells to FLICA led to selective labeling of cells that had morphological changes characteristic of apoptosis. The FLICA labeling withstood cell fixation and permeabilization, which made it possible to stain DNA and measure its content for identification of the cell cycle position of labeled cells. When fixed cells were treated with FLICA, both apoptotic and nonapoptotic cells became strongly labeled and the labeling pattern was consistent with the localization of caspases as reported in the literature. A translocation of the FLICA binding targets from mitochondria to cytosol was seen in the MCF-7 cells treated with CPT. FLICA binding was largely (> 90%) prevented by the substrates of the caspases or by the unlabeled caspase inhibitors having the same peptide moiety as the respective FLICA. CONCLUSIONS: The detection of caspase activation combined with cell permeabilization requires exposure of live cells to FLICA followed by their fixation. Cell reactivity with the respective FLICA, under these conditions, identifies the activated caspases and makes it possible to correlate their activation with the cell cycle position and other cell attributes that can be measured only after cell fixation/permeabilization. FLICA can also be used to study intracellular localization of caspases, including their translocation.     

Role of ancillary techniques in diagnosing and subclassifying non-Hodgkin''s lymphomas on fine needle aspiration cytology

Non-Hodgkin's lymphomas (NHL) are tumours of the lymphoid cells. During the process of development of lymphoid cells, neoplasia may evolve at any point. Neoplastic cells usually carry the imprint of cell of origin at the stage of origin. Various types of NHL may have similar morphology with wide variation in origin, immunophenotype and other biological features. Different ancillary laboratory techniques may help to overcome the limitations of morphology in this aspect. The commonly used ancillary techniques in lymphomas are immunocytochemistry (IC), flow cytometry, Southern blot (SB) technique, polymerase chain reaction (PCR) and fluorescent in situ hybridization (FISH). In addition, laser scanning cytometry (LSC) and DNA microarray technologies are in the research phase. Various laboratory techniques are used for immunophenotyping, demonstration of monoclonality, identification of chromosomal translocation, assessment of cell kinetics and expression of mRNA in the tumour cells. Flow cytometry helps in rapid immunophenotying of NHL and it has an added advantage over IC in recognizing the co-expression of CD markers. Fine needle aspiration cytology (FNAC) combined with flow immunophenotyping may help us to diagnose and subclassify certain NHLs, such as follicular lymphoma and mantle cell lymphoma, which were previously recognized as pure morphological entities. Loss of morphology is one of the important limitations of flow cytometry. LSC can overcome this limitation by studying morphology along with the immunophenotyping pattern of individual cells. Chromosomal changes in NHL can be identified by SB, PCR and FISH. Molecular diagnosis of NHL helps in diagnosis, subclassification, prognostic assessment and even in planning of therapy. DNA microarray is a relatively newer and promising technology. It gives information about the expression of several thousands of genes in a tumour in a single experiment. In the near future, FNAC combined with ancillary techniques may play a major role in diagnosis, subclassification and management of lymphomas.     

Laser scanning cytometer (LSC) analysis of fraction of labelled mitoses (FLM)

Abstract. In this report we describe the successful application of a novel microscope-based multiparameter laser scanning cytometer (LSC) to measure duration of different phases of cell cycle in HL-60 human leukaemic cell lines by the fraction of labelled mitoses (FLM) method. Exponentially growing cells were harvested after various time intervals following pulse-labelling with 5'-bromo-2'-deoxyuridine (BrdUrd), cytocentrifuged, fixed in ethanol, and then exposed to UV light to induce DNA strand breaks at the sites of incorporated BrdUrd. The 3'OH termini of the photolytically generated DNA strand breaks were labelled with BrdUTP in the reaction catalysed by exogenous terminal deoxynucleotidyl transferase (TdT), followed by FITC-labelled BrdUrd antibodies. DNA was counterstained with propidium iodide (PI). Due to differences in chromatin structure between the interphase and mitotic cells, the LSC identified the latter by virtue of their higher red (PI) fluorescence intensity values among all pixels over the measured cell. To confirm that the cells selected were indeed cells in mitosis, predominantly in metaphase, the recorded X-Y coordinates of selected cells were used to re-position the cell for their visual examination. From the time lapse analysis of percentage BrdUrd-labelled cells progressing through mitosis it was possible to calculate the duration of individual phases of the cell cycle. The duration of S (T_s) and G₂+ M (T_G2+M) was 8 and 3 h, respectively, and the minimal duration of G₂ (T_G2) was 2 h. The cell cycle time (T_c) estimated for the cohort of the most rapidly progressing cells was 13 h. The ability to automatically and rapidly discriminate mitotic cells combined with the possibility of their subsequent identification by image analysis makes LSC the instrument of choice for the FLM analysis.     

Quantitative histology by multicolor slide-based cytometry.

BACKGROUND: In lymphatic organs, the quantitative analysis of the spatial distribution of leukocytes by tissue cytometry would give relevant information about alterations during diseases (leukemia, HIV, AIDS) and their therapeutic regimen, as well as in experimental settings. METHODS: We have developed a semiautomated analysis method for laser scanning cytometry (LSC) termed "multiple thresholding," which is suitable for archived or fresh biopsy material of human lymph nodes and tonsils. Sections are stained with PI for nuclear DNA and up to four antigens using direct or indirect immunofluorescence staining. Measurement is triggered on DNA-fluorescence (argon laser, Ar) or on specific cell labeling. Due to the heterogeneity of cell density, measurements are performed repeatedly at different threshold levels (low threshold: regions of low cellular density, germinal center; high threshold: dense regions, mantle zone). Data are acquired by single- (Ar) or dual-laser excitation (Ar-HeNe) in order to analyze single- (FITC) up to four-color (FITC/PE/PECy5/APC) stained specimen. RESULTS: Percentage and cellular density of cell-subsets is quantified in different microanatomical regions of the specimen. These data were highly correlated with manual scoring of identical specimens (r(2) = 0.96, P < 0.0001). With LSC, semiautomated operator-independent immunophenotyping in tissue sections of lymphatic organs with up to three antibodies simultaneously is possible. CONCLUSIONS: We expect this tissue cytometric approach to yield new insight into processes during diseases and help to quantify the success of therapeutic interventions.     

Scanning fluorescent microscopy analysis is applicable for absolute and relative cell frequency determinations.

BACKGROUND: Flow cytometry (FCM) and laser scanning cytometry (LSC) are the routine techniques for fluorescent cell analysis. Recently, we developed a scanning fluorescent microscopy (SFM) technique. This study compares SFM to LSC (two slide-based cytometry, SBC, techniques) and FCM, in experimental and clinical settings. METHODS: For the relative cell-frequency determinations, HT29 colorectal cancer cells and Ficoll separated blood mononuclear cells (FSBMCs) were serially diluted (from 1:1 to 1:1,000) and measured by each of the three techniques. For the absolute cell number determinations (only for SBC) FSBMCs were smeared on slides, then HT29 cells were placed on the slide with a micromanipulator (5-50 cells). Tumor cells circulating in the peripheral blood were isolated by magnetic separation from clinical blood samples of colorectal cancer patients. All samples were double-stained by CD45 ECD and CAM5.2 FITC antibodies. For slides, TOTO-3 and Hoechst 33258 DNA dyes were applied as nuclear counter staining. RESULTS: In the relative cell frequency determinations, the correlations between the calculated value and measured values by SFM, LSC, and FCM were r(2) = 0.79, 0.62, and 0.84, respectively (for all P < 0.01). In the absolute cell frequency determinations, SFM and LSC correlated to a high degree (r(2) = 0.97; P < 0.01). CONCLUSIONS: SFM proved to be a reliable alternative method, providing results comparable to LSC and FCM. SBC proved to be more suitable for rare-cell detection than FCM. SFM with digital slides may prove an acceptable adaptation of conventional fluorescent microscopes in order to perform rare-cell detection.     

Verification of flow cytometorically-sorted X- and Y-bearing porcine spermatozoa and reanalysis of spermatozoa for DNA content using the fluorescence in situ hybridization (FISH) technique

Flow cytometric sperm sorting based on X and Y sperm DNA difference has been established as the only effective method for sexing the spermatozoa of mammals. The standard method for verifying the purity of sorted X and Y spermatozoa has been to reanalyze sorted sperm aliquots. We verified the purity of flow-sorted porcine X and Y spermatozoa and accuracy of DNA reanalysis by fluorescence in situ hybridization (FISH) using chromosome Y and 1 DNA probe. Eight ejaculates from 4 boars were sorted according to the Beltsville Sperm Sexing method. Porcine chromosome Y- and chromosome 1-specific DNA probes were used on sorted sperm populations in combination with FISH. Aliquots of the sorted sperm samples were reanalyzed for DNA content by flow cytometry. The purity of the sorted X-bearing spermatozoa was 87.4% for FISH and 87.0% for flow cytometric reanalysis; purity for the sorted Y-bearing spermatozoa was 85.9% for FISH and 84.8% for flow cytometric reanalysis. A total of 4,424 X sperm cells and 4,256 Y sperm cells was examined by FISH across the 8 ejaculates. For flow cytometry, 5,000 sorted X spermatozoa and 5,000 Y spermatozoa were reanalyzed for DNA content for each ejaculate. These results confirm the high purity of flow sorted porcine X and Y sperm cells and the validity of reanalysis of DNA in determining the proportions of X- and Y-sorted spermatozoa from viewing thousands of individual sperm chromosomes directly using FISH.     

Bivariate analysis of cellular DNA versus RNA content by laser scanning cytometry using the product of signal subtraction (differential fluorescence) as a separate parameter

BACKGROUND: The cytometric methods of bivariate analysis of cellular RNA versus DNA content have limitations. The method based on the use of metachromatic fluorochrome acridine orange (AO) requires rigorous conditions of the equilibrium staining whereas pyronin Y and Hoechst 33342 necessitate the use of an instrument that provides two-laser excitation, including the ultraviolet (UV) light wavelength. METHODS: Phytohemagglutinin (PHA)-stimulated human lymphocytes were deposited on microscope slides and fixed. DNA and double-stranded (ds) RNA were stained with propidium iodide (PI) and protein was stained with BODIPY 630/650-X or fluorescein isothiocyanate (FITC). Cellular fluorescence was measured with a laser scanning cytometer (LSC). The cells were treated with RNase A and their fluorescence was measured again. The file-merge feature of the LSC was used to record the cell PI fluorescence measurements prior to and after the RNase treatment in list mode, as a single file. The integrated PI fluorescence intensity of each cell after RNase treatment was subtracted from the fluorescence intensity of the same cell measured prior to RNase treatment. This RNase-specific differential value of fluorescence (differential fluorescence [DF]) was plotted against the cell fluorescence measured after RNase treatment or against the protein-associated BODIPY 630/650-X or FITC fluorescence. RESULTS: The scattergrams were characteristic of the RNA versus DNA bivariate distributions where DF represented cellular ds RNA content and fluorescence intensity of the RNase-treated cells, their DNA content. The distributions were used to correlate cellular ds RNA content with the cell cycle position or with protein content. CONCLUSIONS: One advantage of this novel approach based on the recording and plotting of DF is that only the RNase -specific fraction of cell fluorescence is measured with no contribution of nonspecific components (e.g., due to the emission spectrum overlap or stainability of other than RNA cell constituents). Another advantage is the method's simplicity, which ensues from the use of a single dye, the same illumination, and the same emission wavelength detection sensor for measurement of both DNA and ds RNA. The method can be extended for multiparameter analysis of cell populations stained with other fluorochromes of the same-wavelength emission but targeted (e.g., immunocytochemically) for different cell constituents.     

Analysis of apoptosis by laser scanning cytometry

Flow cytometry techniques that are widely used in studies of cell death, and particularly in the identification of apoptotic cells, generally rely on the measurement of a single characteristic biochemical or molecular attribute. These methods fail to recognize cell death lacking that attribute, as in some examples of atypical apoptosis. Since apoptosis was originally defined by morphologic criteria, we suggest that for any new cell system the cytometry-defined apoptosis be confirmed by morphologic examination. This quality assurance measure is now provided by laser scanning cytometry (LSC). LSC measurements of cell fluorescence are precise and highly sensitive, comparable to flow cytometry (FCM), and can be carried out on cells on slides, permitting cell by cell correlation of fluorescence cytometry with visual microscopic morphology. In this report we describe adaptations of various flow cytometry techniques for detection of apoptosis by laser scanning cytometry. We also describe features unique to LSC that are useful in recognizing apoptosis. Hyperchromicity of DNA, reflecting chromatin condensation, is evidenced by high maximal pixel values for fluorescence of the DNA-bound fluorochrome. Mitochondrial probes that have been adapted to LSC to measure the drop in mitochondrial transmembrane potential that occurs early in apoptosis include rhodamine 123, 3,3'-dihexiloxadicarbocyanine [DiOC6(3)], and the aggregate dye 5,5',6,6'tetrachloro-1,1',3,3'-tetraethylbenzimidazolcarbocyanine iodide (JC-1). The changes in plasma membrane phospholipids and transport function, also early in apoptosis, are probed by a combination of the fluoresceinated annexin V and DNA fluorochromes such as propidium or 7-aminoactinomycin D. We also review methods of detection of apoptosis based on analysis of DNA fragmentation and their application to clinical oncology. Visual examination of the presumed apoptotic cells detected by cytometry makes it possible to discriminate those that are genuine from monocytes/macrophages that have ingested nuclear fragments via apoptotic bodies. Applications of flow cytometry and laser scanning cytometry in analysis of cell death are discussed and their respective advantages and disadvantages compared.     

Alterations of neuronal nuclear matrix and chromatin structure after irradiation under aerobic and anoxic conditions

This study was undertaken to determine if structural alterations of the bulk chromatin and the amount of protein associated with the nuclear matrix in cerebellar neurons depend on radiation dose and a cell's state of oxygenation. After irradiation with 2.5 to 25.0 Gy under both aerobic and anoxic conditions, the sensitivity of the neuronal chromatin to m. nuclease digestion increase linearly with dose up to about 5 Gy, beyond which there was no further increase. The same increase in accessibility of chromatin to micrococcal nuclease digestion was observed when neuronal nuclei were irradiated at 4 degrees C. Neuronal nuclei were stained with propidium iodide (PI) for DNA and with fluorescein isothiocyanate (FITC) for protein, both before and after complete digestion with DNase I, and analyzed by flow cytometry. There was no change in either the PI (P greater than 0.4) or the FITC (P greater than 0.9) fluorescence of undigested nuclei after irradiation. For the DNase I digested nuclei, the PI fluorescence was unchanged after irradiation (P greater than 0.4), but the FITC fluorescence increased significantly (P less than 0.02). This increase in the FITC fluorescence was linear with dose up to about 5 Gy, beyond which there was no further increase. The flow cytometry results from DNase I digested nuclei were identical for neurons irradiated under aerobic or anoxic conditions, indicating that this phenomenon is oxygen independent. This increase in FITC fluorescence after irradiation was inhibited at ice-cold temperatures and probably reflects an increase in protein content at the nuclear matrix that requires metabolism. This may explain our previously observed resistance of nuclear matrix-associated DNA to digestion by DNase I. This protein increase at the nuclear matrix appears to follow "saturation" kinetics identical to that previously reported for repair of DNA strand breaks in cerebellar neurons. However, the exact molecular nature of this process and its role in DNA repair or cell survival remains to be determined.     

Flow cytometric determination of cell cycle parameters of V79 cells by continuous labeling with bromodeoxyuridine

A simple method with which to determine the cell cycle parameters, TG1, TS and TG2M (the durations of the G1, S and G2 + M phases) is described. V79 Chinese hamster lung cells were used to evaluate the method. After continuous labeling with bromodeoxyuridine (BrdU), V79 cells were stained with anti BrdU-monoclonal antibody with FITC (fluorescein isothiocyanate) and with PI (propidium iodide). The individual cells were checked by flow cytometry for green and red fluorescences whose signal intensities corresponded to the BrdU and cellular DNA contents. The durations of G1, S and G2 + M phases of V79 cells were determined by measuring the cell fractions containing the nonlabeled G1, labeled S and nonlabeled G2 + M phases. The reliability of this method is discussed.