Filipin as a flow microfluorometry probe for cellular cholesterol

The polyene antibiotic filipin, which forms specific complexes with 3 beta-hydroxysterols, displays spectral properties compatible with its use in flow microfluorometry (FMF). The purpose of this study was to test the suitability of filipin as an FMF probe for unesterified cellular cholesterol. The following experimental conditions appeared optimal for cells with an average unesterified cholesterol content of less than 3 nmol per 10(6) cells: 2 X 10(6) fixed cells (1-4% p-formaldehyde, 30 min, 21 degrees C) stained for 2-4 h with 100 micrograms/ml filipin and excited at 350.7/356.7 nm. Fluorescence emission (Em) was measured above 510 nm. Less suitable conditions involved excitation at 488 nm or using cells which had not been fixed. Fixation preserved the live-dead cell discrimination provided by forward light scatter measurements, so that dead cells could be excluded from the FMF analysis of cellular cholesterol. Under the above conditions FMF analysis of a variety of murine cell types showed that in all cases the fluorescence intensity of filipin-stained cells was clearly increased above autofluorescence levels of the unstained control cells. The increase in fluorescence signal in different filipin stained cell types correlated (P less than or equal to .001) with the cellular content of unesterified cholesterol determined by an independent enzymatic assay. The sensitivity of the FMF assay was in the femtomole (10(-15) ) range. Mixing experiments with cells of different cholesterol levels showed that the technique distinguishes cell populations with distinctive levels of unesterified cholesterol. We therefore concluded that filipin is a useful FMF probe for determining relative levels of unesterified cholesterol in cells.     

FLOW CYTOMETRIC ANALYSES OF VIRAL INFECTION IN TWO MARINE PHYTOPLANKTON SPECIES, MICROMONAS PUSILLA (PRASINOPHYCEAE) AND PHAEOCYSTIS POUCHETII (PRYMNESIOPHYCEAE)

Cell characteristics of two axenic marine phytoplankton species, Micromonas pusilla (Butscher) Manton et Parke and Phaeocystis pouchetii (Hariot) Lagerheim, were followed during viral infection using flow cytometry. Distinct differences between noninfected and infected cultures were detected in the forward scatter intensities for both algal species. Changes in side scatter signals on viral infection were found only for P. pouchetii. Chlorophyll red fluorescence intensity per cell decreased gradually over time in the infected cultures. DNA analyses were performed using the nucleic acid–specific fluorescent dye SYBR Green I. Shortly after infection the fraction of algal cells with more than one genome equivalent increased for both species because of the replication of viral DNA in the infected cells. Over time, a population of algal cells with low red autofluorescence and low DNA fluorescence developed, likely representing algal cells just prior to viral lysis. The present study provides insight into basic virus–algal host cell interactions. It shows that flow cytometry can be a useful tool to discriminate between virus infected and noninfected phytoplankton cells.     

Microfluorometry analysis II. A Bayesian approach.

In flow microfluorometry (FMF) analysis cells stained with a fluorescent dye that binds specifically to DNA are passed through the instrument. The number of cells in the population having a fluorescence intensity is recorded in a single channel of a multichannel pulse height analyzer. The result is a DNA fluorescence histogram for the population.A method for decomposing an FMF histogram into its G₁, S and G₂ + M components, corresponding to similarly designated phases of the cell cycle is given. This technique can also be applied to find the parameters in all of the previous approaches. The parameters are calculated by iteration which eliminates the need for non-linear optimization procedures.     

The temporal structure of S phase.

DNA synthesis in the S phase of V79 and CHO Chinese hamster cells was examined in detail using an automated system for selection and subculturing of mitotic cells and four different assays for DNA synthesis. Flow microfluorometric (FMF) analysis showed that the selected populations were highly synchronous with few noncycling cells. In CHO cells changes in mean and modal fluorescence in the FMF suggested that DNA content increased in a saltatory fashion with 10-20% of the DNA replicated in early S, 40% in mid S, and 40-50% in late S. Pulse labeling and acid precipitation revealed a repeatable pattern of fluctuations in the rate of isotope incorporation with the maximum rate occurring late in S both V79 and CHO. Autoradiography proved to be the best means of accurately determining the beginning of S phase. Cumulative labeling from mitosis to points in S exaggerated the differences in rate between early and late S, so that significant DNA synthesis in early S might easily be overlooked using this method. In CHO cells DNA-specific fluorescence by the Kissane and Robins assay supported the isotopic incorporation data and the FMF analyses by exhibiting a stepwise increase. In V79 cells, S phase lasts only 5 or 5.5 hr, and consequently the mid S and late S steps in fluorescence are compressed. In V79, greater than 80% of the increase in DNA-specific fluorescence occurred between 4.5 and 7 hr after mitotic selection. In both cell lines, fluorescence in early S phase frequently increased transiently to maximum and then decreased.     

Application of Flow Microflorometry to the Study of Algal Cells and Isolated Chloroplasts

The applicability of flow microfluorometry (FMF) to the studyof chlorophyll-containing cells was investigated through theuse of the blue-green alga Agmenellum quadruplicatum, the greenalgae Trebouxia, Chlorella, and Euglena spp., and isolated spinachchloroplasts. When excited by laser radiation (488 nm), algalcells emitted fluorescence with intensity positively relatedto the chloro-phyll content. The chlorophyll fluorescent signalswere used further as a differential criterion in determiningrelative size based on light scattering logic and to sort mixturesof algal cells having different chlorophyll content The FMFalso was useful in estimating nucleic acid and protein contentin completely dechlorophyUized algal cells with the use of ethidiumbromide (EB) and fluoresceinisothiocyanate (FITC), respectively.     

Fluorescence polarization of six membrane probes in embryonal carcinoma cells after differentiation as measured on a FACS II cell sorter

Fluorescence polarization measurements on a FACS II cell sorter were compared with static measurements on a spectrofluorimeter using calibration solutions and Hoechst 33258-labeled cells. For the flow cytometric measurements on the FACS we used a pseudodepolarizer for normalization of the output of the two photomultipliers. The results showed that fluorescein and fluoresceinated bovine serum albumin (BSA) solutions gave identical values on both instruments. The mean value for fluorescence polarization of Hoechst 33258-labeled cells as measured on the FACS was the same as the value obtained with the spectrofluorimeter. Subsequently the fluorescence polarization of six different membrane probes was determined using differentiating embryonal carcinoma cells as a model system. Differentiation was induced by treatment of the cells with retinoic acid together with cyclic AMP. With diphenylhexatriene (DPH) the fluorescence polarization increased from I/I = 1.55 to 1.74 upon differentiation. With a charged analog of DPH (TMA-DPH) fluorescence polarization increased from I/I = 1.87 to 2.02. No appreciable changes in fluorescence polarization were observed in this cell system when anthroyloxysterate probes (12-AS, 9-AS, 6-AS, 2-AS) were used.     

Separation of algal mixtures and bacterial mixtures with flow-microfluorometer using chlorophyll and ethidium bromide fluorescence

The applicability of flow-microfluorometer to separate microbial cells was demonstrated with algal and bacterial cells. Algal mixtures were sorted according to the natural chlorophyll fluorescence and the bacterial mixtures were sorted according to the fluorescence of ethidium bromide-stained nucleic acid.Abbreviation FMF Flow-microfluorometer     

Analysis of fermentation processes using flow microflourometry: Single-parameter observations of batch bacterial growth

The laser flow microfluorometer (FMF) can determine the amounts of certain components in single cells at sample rates of several thousand cells per second. This technique has been employed to characterize Bacillus subtilis populations in batch fermentations with different inocula. Protein and distributions obtained by FMF analyses at different times during the batch have been decomposed using an optimized fit of summed subpopulation distributions. The results of these decomposition calculations, some of which have been approximately confirmed by independent microscopic observations, indicate cells relative numbers of single rods, cell chains, spores, and swollen rounded cells change dramatically during the entire fermentation including the stationary phase. The dynamics of these subpopulations may be related to secondary metabolite production.     

Flow microfluorometric and light-scatter measurement of nuclear and cytoplasmic size in mammalian cells.

A technique for rapid measurement of nuclear and cytoplasmic size relationships in mammalian cell populations has been developed. Based on fluorescence staining of either the nucleus alone or in combination with the cytoplasm using two-color fluorescence methods, this technique permits the simultaneous determination of nuclear and cytoplasmic diameters from fluorescence and light-scatter measurements. Cells stained in liquid suspension pass through a flow chamber at a constant velocity, intersecting a laser beam which excites cell fluorescence and causes light scatter. Depending upon which analysis procedure is used, optical sensors measure nuclear fluorescence and light scatter (whole cell size) or two-color nuclear and cytoplasmic fluorescence from individual cells crossing the laser beam. The time durations of signals generated by the nucleus and cytoplasm are converted electronically into signals proportional to the respective diameters and are displayed as frequency distribution hitograms. Illustrative examples of measurements on uniform microspheres, cultured mammalian cells and human exfoliated gynecologic cells are presented.     

THE DISCRETE–TIME KINETIC MODEL ANALYSIS OF DNA CONTENT DISTRIBUTIONS IN EXPERIMENTAL TUMOUR CELLS

A method was developed to analyse and characterize FMF measurements of DNA content distribution, utilizing the discrete time kinetic (DTK) model for cell kinetics analysis. The DTK model determines the time sequence of the cell age distribution during the proliferation of a tumor cell population and simulates the distribution pattern of the DNA content of cells in each age compartment of the cell cycle. The cells in one age compartment are distributed and spread into several compartments of the DNA content distribution to allow for different rates of DNA synthesis and instrument dispersion effects. It is assumed that the DNA content of cells in each age compartment has a Gaussian distribution. Thus, for a given cell age distribution the DNA content distribution depends on two parameters of the cells in each age compartment: the average DNA content and its coefficient of variation. As the DTK model generates the best fit DNA content distribution to the FMF measurement data, it enables one to estimate specific values of these two parameters in each stage of the cell cycle and to determine the fraction of cells in each cycle phase. The method was utilized to fit FMF measurements of DNA content distributions and to analyse their relationship to the cell kinetic parameters, namely cell loss rate, cell cycle times and growth fraction of exponentially growing Chinese hamster ovary cells in vitro and, also, with a wide range of coefficients of variation, of the L1210 ascites tumour during the growth period.     

Flow cytometry of mammalian sperm: progress in DNA and morphology measurement.

Variability in DNA content and head shape of mammalian sperm are potentially useful markers for flow cytometric monitoring of genetic damage in spermatogenic cells. The high refractive index and extreme flatness of the sperm heads produce an optical effect which interferes with DNA measurements in flow cytometers which have dye excitation and fluorescence light collection normal to the axis of flow. Orientation of sperm in flow controls this effect and results in coefficients of variation of 2.5% and 4.2%, respectively, for DNA measurements of mouse and human sperm. Alternatively, the optical effect can be used to generate shape-related information. Measurements on randomly oriented sperm from three mammalian species using a pair of fluorescence detectors indicate that large shape differences are detectable. Acriflavine-Feulgen stained sperm nuclei are significantly bleached during flow cytometric measurements at power levels routinely used in many flow cytometers. Dual beam studies of this phenomenon indicate it may be useful in detecting abnormally shaped sperm.     

Stability‐indicating spectrofluorimetric method for the assay of riboflavin and photoproducts: Kinetic applications

A stability‐indicating spectrofluorimetric method has been developed for the simultaneous assay of riboflavin (RF) and photoproducts, formylmethylflavin (FMF), lumichrome (LC) and lumiflavin (LF) in aqueous solution. The method is based on the extraction of LC formed in acid solution and LC and LF formed in alkaline solution with chloroform at pH 2.0 and their assay by fluorescence measurements at 478 and 530 nm, respectively. The aqueous phase, on readjustment of the pH to 6.5, is used to extract FMF with chloroform and its assay is carried out at 530 nm. The aqueous phase is then used for the assay of RF at 530 nm. The proposed method gives more accurate results for the assay of RF compared to those of the United States Pharmacopeia (USP) spectrofluorimetric method which does not take into account the presence of RF photoproducts having similar fluorescence characteristics. The proposed method along with the USP method has been applied to the study of the kinetics of photolysis of RF, assay of stored commercial vitamin preparations and their radiated samples. The results show that the USP method does not distinguish between the fluorescence of RF and its photoproducts, and, therefore, gives erroneous results with about 11% excess in the quantity of the vitamin compared to that of the proposed method. This is due to the interference of the fluorescence of photoproducts in the assay of RF. The method has been validated for various analytical parameters according to the guideline of the International Council for Harmonization (ICH).     

Dye exclusion artifact in flow cytometers

BACKGROUND: Cells exclude their own volume of dye solution in the sample flow which carries them through the flow chamber of the flow cytometer, thereby affecting the otherwise constant signal arising from the fluorescence of this solution. Under certain conditions, this phenomenon may significantly influence the fluorescence signal of the cells. MATERIALS AND METHODS: Using the slit scan technique, we studied this phenomenon as observed for monodisperse polystyrene particles in fluorescein solution. RESULTS: The measurements show that dye solution accumulates just in front of the particle and just behind it, with a relative void in between. This phenomenon is most likely caused by the rapid constriction of the flow as it enters the orifice of the nozzle or flow chamber, giving rise to a pulse of fluorescence which adds to that of the particle or cell itself. The magnitude of this artifact depends on the design and dimensions of the nozzle/flow chamber as well as on the rate of sample flow. CONCLUSIONS: The dye exclusion artifact may affect measurements of cells when they are in a dye solution having a fluorescence per unit volume which is significant compared to that of the cells, especially at low sample flow rates.     

Quantation by flow microfluorometry of total cellular DNA in Acanthamoeba.

The DNA content of five species of Acanthamoeba was determined by flow microfluorometry. Acanthamoeba castellanii (AC-30), acanthamoeba polyphaga (APG and P-23), acanthamoeba rhysodes, acanthamoeba culbertsoni (A-1), and acanthamoeba royreba were grown in a casitone based medium 24-48 HR. The trophozoites were harvested, and evaluated for DNA-bound fluorescence. All species tested has DNA values between 2.0-5.0 pg/cell. These results placed DNA/cell values of Acanthamoeba slightly lower than DNA/cell values of other eucaryotic cells and much lower than Amoeba proteus values. These results indicate that FMF may be a useful adjunct in distinguishing Acanthamoeba cells from either eucaryotic cells or some other amoeba. However, differences in DNA/cell between species of Acanthamoeba are small and would not be useful in identification of species.     

Analysis of fermentation processes using flow microfluorometry: Single-parameter observations of batch bacterial growth

The laser flow microfluorometer (FMF) can determine the amounts of certain components in single cells at sample rates of several thousand cells per second. This technique has been employed to characterize Bacillus subtilis populations in batch fermentations with different inocula. Protein and nucleic acid distributions obtained by FMF analyses at different times during the batch have been decomposed using an optimized fit of summed subpopulation distributions. The results of these decomposition calculations, some of which have been approximately confirmed by independent microscopic observations, indicate that the relative numbers of single rods, cell chains, spores, and swollen rounded cells change dramatically during the entire fermentation including the stationary phase. The dynamics of these subpopulations may be related to secondary metabolite production.     

Simulating flow microfluorometry experiments with the computer language cellsim

CELLSIM is a digital simulation language specifically designed for simulating cell kinetics models. Recently a flow microfluorometry (FMF) command has been added to the language. In the command, the modeler indicates when his simulated FMF analyses are to take place, and what cell states are to be included. He may specify different coefficients of variance and a non-linear DNA synthesis rate for S phase cells. The FMF capability of the language has proved to be a useful tool in several applications.     

Density Centrifugation of Murine Fibrosarcoma Cells Following In Situ Labelling With Tritiated Thymidine

Murine fibrosarcoma (FSa) cells form at least five unique subpopulations after centrifugation in linear Renografin density gradients. Each of these subpopulations has been characterized with respect to selected kinetic parameters using pulse-labelling techniques and flow microfluorometry (FMF) analysis. Tumour-bearing mice were first injected intraperitoneally with a pulse label of tritiated thymidine ([³H]TdR, 50 μCi). Following 15, 30, 60 min or 24 hr these animals were injected with cold thymidine. Animals were killed, their tumours removed and made into suspension, and separated by density gradient centrifugation. Each gradient was fractionated and the density, cell number, tritium activity, and labelling index (LI) per fraction were determined. These data were then compared to FMF data for selected cell density bands. the results indicated a relatively higher uptake of [³H]TdR in the cells recovered at the lighter (1.06–1.12 g/cm³) as compared to the heavier (>1.12 g/cm³) densities. Following a 30-min pulse, the LI's of light cells (<1.12 g/cm³) ranged from 25 to 30%, while the heavier cells (>1.12 g/cm³) had LI's between 10 and 15%. the unseparated control cells had an LI of 19%. Comparable results were found at the other times tested. In contrast, the FMF profiles describing the DNA contents of the cells banding in the gradient showed no difference in proportion of S-phase cells among the separated subpopulations. This lack of correlation between the FMF determination of S-phase cells and labelling index for the denser cell populations implies that DNA content alone is not an effective measurement of the functional activity of cells in solid tumours. Finally, the relatively reduced uptake of [³H]TdR by these denser cells suggests that they may have resided at relatively large distances from the functional vasculature in the tumour.     

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.     

Analysis of phytoplankton by flow cytometry

Optical properties of eight algae species were measured on a flow cytometer. Forward and perpendicular light scatter measurements provide information on the size and shape of algae cells. The intensity of chlorophyll fluorescence varies greatly among the studied algae species and can be used to distinguish them. Measurements of chlorophyll fluorescence after excitation with different wavelengths provide a fluorescence excitation spectrum for each species over the available wavelength range. These spectra reflect the different photosynthetic pigment contents of the species. Staining algae cells with the DNA stains, Hoechst 33342 and DAPI, provides two additional optical parameters to distinguish algae populations: blue nuclear fluorescence and yellow granular fluorescence. The combination of these optical measurements enables the distinction of each algae species into a small cluster in a hyperspace of parameters. The automation of phytoplankton analysis on the flow cytometer may lead to the rapid and objective assessment of water quality.