Discrimination of viable and non-viable cells using propidium iodide in two color immunofluorescence

The relative ease with which a flow cytometer can perform simultaneous two color immunofluorescence to examine subpopulations of lymphoid cells has been well documented. Thus, flow cytometers equipped with only a single argon laser can be used to delineate various cell types by exciting both fluorescein- and phycoerythrin-conjugated antibodies to cell surface antigens. One problem that remains, however, is the artifactual staining of dead cells and clumps, which cannot be distinguished from viable cells on the basis of cell surface staining characteristics. We describe a method for simultaneous two color analysis or sorting of viable leukocytes which requires only a single laser. The method utilizes propidium iodide, which stains dead cells and thereby excludes such cells from the analysis. Using this method, as many as four viable cell types have been simultaneously analyzed in a single sample.     

High-speed photodamage cell selection using bromodeoxyuridine/Hoechst 33342 photosensitized cell killing

One of the major drawbacks of droplet sorting in a flow cytometer is the relatively low sorting speed. Thus, we have developed an alternative, faster sorting technique: photodamage cell sorting. In a photodamage cell sorter all unwanted cells, as detected with the first, measuring laser, are killed with the second, damaging laser. Thus, the cells need to be photosensitive to the second laser. In addition, a mechanism is needed to switch this laser on and off based on the sorting criteria. In our photodamage cell sorter, the ZAPPER, we use an acousto-optic crystal to switch the laser beam. Cells are made photosensitive by vital staining with photosensitizers. With cells grown in the presence of 5-bromo-2'-deoxyuridine (BrdUrd) and stained with Hoechst 33342 (H42) at least a 5-decade cell reduction is accomplished after irradiation with 400 mW UV light. With this system, sorting rates have been achieved of 30,000 cells per second. Due to the selection based on photodynamic killing, this sorting technique is restricted to the selection of viable cells. Photodamage cell sorting seems well suited for isolating viable cells occurring in low percentages or for the sorting of large numbers of cells. Another application can be the sorting of large or fragile cells.     

Purification of Specific Cell Population by Fluorescence Activated Cell Sorting (FACS)

Experimental and clinical studies often require highly purified cell populations. FACS is a technique of choice to purify cell populations of known phenotype. Other bulk methods of purification include panning, complement depletion and magnetic bead separation. However, FACS has several advantages over other available methods. FACS is the preferred method when very high purity of the desired population is required, when the target cell population expresses a very low level of the identifying marker or when cell populations require separation based on differential marker density. In addition, FACS is the only available purification technique to isolate cells based on internal staining or intracellular protein expression, such as a genetically modified fluorescent protein marker. FACS allows the purification of individual cells based on size, granularity and fluorescence. In order to purify cells of interest, they are first stained with fluorescently-tagged monoclonal antibodies (mAb), which recognize specific surface markers on the desired cell population (1). Negative selection of unstained cells is also possible. FACS purification requires a flow cytometer with sorting capacity and the appropriate software. For FACS, cells in suspension are passed as a stream in droplets with each containing a single cell in front of a laser. The fluorescence detection system detects cells of interest based on predetermined fluorescent parameters of the cells. The instrument applies a charge to the droplet containing a cell of interest and an electrostatic deflection system facilitates collection of the charged droplets into appropriate collection tubes (2). The success of staining and thereby sorting depends largely on the selection of the identifying markers and the choice of mAb. Sorting parameters can be adjusted depending on the requirement of purity and yield. Although FACS requires specialized equipment and personnel training, it is the method of choice for isolation of highly purified cell populations.     

A new fluid switching flow sorter

Conventional cell sorters produce potentially hazardous microdroplets containing dyes and radiolabeled compounds commonly used to identify and trace subpopulations of cells. Many of these substances are potential toxins, mutagens, or carcinogens constituting a risk to personal associated with the sorting device. The separation of living cells for continued study of cell growth from an "in air" sample stream includes the risk of contamination with microorganisms altering the following cultures. To avoid those risks, we have constructed a new capsular flow cytometer sorter which consists of a small chamber completely encasing the sorting mechanism. Data acquisition, analysis, and processing are accomplished by using a microcomputer-based pulse height analyser.     

Calibration of a flow cytometer against a microphotometer for morphologic cell identification

The calibration of a flow cytometer against a microphotometer, to allow the correlation of cell morphology with fluorescence intensity, is described. Using three human lymphoblastoid cell lines, the photomultiplier amplification of the microphotometer and the flow cytometer that gave optimum linearity between fluorescence intensity and DNA content for the two instruments was established. Thereafter, at these settings, there was satisfactory linear agreement between the fluorescence intensity profiles, as measured by the flow cytometer and the microphotometer, of stained cell populations. Day-to-day variation was also minimal, and it was demonstrated that the application of this procedure can provide an alternative to the employment of the sorting facility of a flow cytometer for the morphologic identification of cell subpopulations during flow cytometric analysis.     

Steroid receptors in the developing and the adult rabbit endocervix and in endocervical epithelial cells isolated by flow cytometry

Immunocytochemistry with monoclonal antibodies H222 and JZB39 was used to study nuclear estrogen (ER) and progesterone (PgR) receptors, respectively, in the cervix during differentiation and in the adult rabbit. The undifferentiated state of the cervix of 2-week-old rabbits correlates with a paucity of immunoreactive nuclear ER, while the epithelium of most of these animals showed moderate immunostaining for the nuclear PgR. The cervical epithelium, stroma and muscle cells of 1-month-old rabbits, showed weak immunostaining for the ER, while staining for PgR remained comparable to that of 2-week-old rabbits. For 2-4-month old rabbits the epithelium was characterized by moderate immunostaining for the nuclear ER and strong immunostaining for the PgR. Strong, heterogeneous immunostaining for nuclear ER and PgR receptors in endocervical epithelial cells from 6-month-old (adult), estrous rabbits suggested there are subpopulations of cells that express differential sensitivity to steroid hormones. In order to characterize such subpopulations, live endocervical epithelial cells were sorted with a flow cytometer on the basis of forward angle light scatter (FSC) and side scatter (SSC) signals which correlated with cell size and secretory granule content, respectively. Secretory cells, as verified by ultrastructural analysis and histochemical staining, expressed the highest FSC and SSC signals and were designated fraction "a". Changes in the hormonal status of the animals altered the intrinsic light scatter properties of fraction "a" cells as follows: maximum FSC and SSC signals were reported for cells from estrous animals; ovariectomy or progesterone-dominance decreased cell size (FCS) and secretory granule content (SSC), while treatment of ovariectomized rabbits with estradiol increased both parameters. When fraction "a" cells from estrous rabbits were incubated with the monoclonal antibodies, two distinct subpopulations of secretory cells were identified by intensity and pattern of nuclear staining for the ER and PgR. Changes in the hormonal status of the animals produced changes in the intensity of nuclear immunostaining, however both cell types remained distinguishable on the basis of immunostain pattern reflecting either permanent or transitory differences in them, and differential hormone sensitivity. The presence of nuclear ER and PgR proteins in these cells confirms their function is bireceptor-mediated.     

Interferometry in flow to sort unstained X- and Y-chromosome-bearing bull spermatozoa

BACKGROUND: It was found earlier that the difference in volume between unstained X- and Y-chromosome-bearing sperm heads could be detected using interference microscopy in visible light. This could be the basis for an alternative to the conventional method to sort X and Y sperm, which uses DNA staining and ultraviolet (UV)-excitation that may be harmful to sperm cells. A novel technique is introduced combining interferometry with flow cytometry. MATERIALS AND METHODS: Interference optics were built into an existing flow cytometer/cell sorter and used to sort fresh unstained bull sperm cells on the basis of their head volume. Sorted fractions were stained with a DNA stain, and reanalyzed using the conventional method. RESULTS: Purities between 60-66% were found in both X- and Y-enriched fractions. It was possible to sort up to 300 cells per second. The system was found to be less sensitive to the orientation of sperm cells than the conventional method. CONCLUSIONS: Interferometry can be combined with flow cytometry and used to obtain significantly enriched fractions of X- and Y-bearing sperm without staining and UV light. Sorting speeds and purities at this point, however, are much lower than with the conventional method.     

Flow cytometer based on triggered supercontinuum laser illumination

Multiple wavelength operation in a flow cytometer is an exciting way for cell analysis based on both fluorescence and optical scattering processing. For example, this multiparametric technique is currently used to differentiate blood cells subpopulations. The choice of excitation wavelengths matching fluorochrome spectra (it is currently the opposite) and the use of a broader range of fluorochromes can be made by taking advantage of a filtered supercontinuum white light source. In this study, we first wished to validate the use of a specific triggered supercontinuum laser in a flow cytometer based on white light scattering and electric sizing on human blood cells. Subsequently, to show the various advantages of this attractive system, using scattering effect, electrical detections, and fluorescence analysis, we realized cells sorting based on DNA/RNA stained by thiazole orange. Discrimination of white blood cells is efficiently demonstrated by using a triggered supercontinuum-based flow cytometer operating in a "one cell-one shot" configuration. The discriminated leukocyte populations are monocytes, lymphocytes, granulocytes, immature granulocytes, and cells having a high RNA content (monoblasts, lymphoblasts, and plasma cells). To the best of our knowledge, these results constitute the first practical demonstration of flow cytometry based on triggered supercontinuum illumination. This study is the starting point of a series of new experiments fully exploiting the spectral features of such a laser source. For example, the large flexibility in the choice of the excitation wavelength allows to use a larger number of fluorochromes and to excite them more efficiently. Moreover, this work opens up new research directions in the biophotonics field, such as the combination of coherent Raman spectroscopy and flow cytometry techniques.     

Flow cytometric identification of Paclitaxel-accumulating subpopulations

An immunofluorescence procedure was developed for paclitaxel quantification at the single cell level via flow cytometry in Taxus cuspidata suspension cultures. Intracellular staining was validated via fluorescence microscopy. Paclitaxel content of isolated cells and protoplasts was compared to total paclitaxel levels measured via HPLC. Paclitaxel accumulation was significantly increased by elicitation with methyl jasmonate (100 microM) on day 7 post-transfer as compared to unelicited cultures. Maximum accumulation was observed by day 12 post-transfer in both total paclitaxel (approximately 0.25 mg/L) and the percentage of paclitaxel-accumulating cells (approximately 95%). A similar trend was observed with isolated protoplasts, although protoplasts accumulated only ca. 40-75% of the paclitaxel present in single cells. In unelicited cell cultures, a small subpopulation (ca. 3-5%) of single cells was shown to accumulate paclitaxel. Although nearly all cells were observed to accumulate paclitaxel in methyl jasmonate-elicited cell cultures, a high degree of cell-to-cell variation was observed in paclitaxel content. The identified subpopulations represent targets for cell sorting, which may be applied to develop higher-accumulating cell lines. The quantification of single cell paclitaxel content is useful for characterizing production variability in cell cultures and can be utilized to develop rational strategies to increase paclitaxel production.     

Use of biocarrier beads and flow cytometry for single-cell studies of fibronectin gene regulation in dibutyryl cyclic AMP reverse transformed CHO-K1 cells

The protease sensitivity of a number of cell surface or cytoskeletal components and the relationship of these to the substratum in attached cells has prevented the quantitative measurement of their expression by flow cytometry. Using traditional cell sorting techniques, cells must be treated with a protease to detach them from a substrate in order to produce a single-cell suspension. Unfortunately, proteolytic treatment alters or destroys a number of cellular proteins. Fibronectin either on the cell surface or as part of the substratum laid down by the cell is particularly sensitive to proteases, preventing its quantitative study by flow cytometry. To circumvent these problems and produce a single cell suspension necessary for flow cytometric analysis, CHO-K1, a Chinese hamster ovary cell line, were grown in suspension on specially-treated 25 microns biocarrier beads. The CHO-K1 cell line is composed of transformed epithelial-like cells that have lost the fibronectin deposit around their cell membranes. To restore the typical fibroblastic deposit of fibronectin, the cells attached to beads were induced by dibutyryl cAMP to undergo a reverse transformation reaction to restore fibroblastic morphology and the typical fibroblastic deposite of fibronectin on the cell surface and substratum. The cells attached to beads were then immunofluorescently labeled for the protease-sensitive, extracellular matrix component, fibronectin, and examined on a flow cytometer. Cell surface fibronectin heterogeneity was then examined on a cell-by-cell basis as a function of cell cycle using Hoechst 33342 dye that binds to AT base pairs of cellular DNA. Dual laser measurement and multiparameter list mode data analysis were used to study the relationship between cell surface fibronectin of biocarrier bead attached cells and cell cycle.     

Use of biocarrier beads and flow cytometry for single-cell studies of fibronectin gene regulation in dibutyrl cyclic AMP reverse transformed CHO-K1 cells

The protease sensitivity of a number of cell surface or cytoskeletal components and the relationship of these to the substratum in attached cells has prevented the quantitative measurement of their expression by flow cytometry. Using traditional cell sorting techniques, cells must be treated with a protease to detach them from a substrate in order to produce a single-cell suspension. Unfortunately, proteolytic treatment alters or destroys a number of cellular proteins. Fibronectin either on the cell surface or as part of the substratum laid down by the cell is particularly sensitive to proteases, preventing its quantitative study by flow cytometry. To circumvent these problems and produce a single cell suspension necessary for flow cytometric analysis, CHO-K1, a Chinese hamster ovary cell line, were grown in suspension on specially-treated 25 μm biocarrier beads. The CHO-K1 cell line is composed of transformed epithelial-like cells that have lost the fibronectin deposit around their cell membranes. To restore the typical fibroblastic deposit of fibronectin, the cells attached to beads were induced by dibutyrl cAMP to undergo a reverse transformation reaction to restore fibroblastic morphology and the typical fibroblastic deposite of fibronectin on the cell surface and substratum. The cells attached to beads were then immunofluorescently labeled for the protease-sensitive, extracellular matrix component, fibronectin, and examined on a flow cytometer. Cell surface fibronectin heterogeneity was then examined on a cell-by-cell basis as a function of cell cycle using Hoechst 33342 dye that binds to AT base pairs of cellular DNA. Dual laser measurement and multiparameter list mode data analysis were used to study the relationship between cell surface fibronectin of biocarrier bead attached cells and cell cycle.     

Sorting cells for basal and induced autophagic flux by quantitative ratiometric flow cytometry

We detail here a protocol using tandem-tagged mCherry-EGFP-LC3 (C-G-LC3) to quantify autophagic flux in single cells by ratiometric flow cytometry and to isolate subpopulations of cells based on their relative levels of autophagic flux. This robust and sensitive method measures autophagic flux rather than autophagosome number and is an important addition to the autophagy researcher’s array of tools for measuring autophagy. Two crucial steps in this protocol are i) generate cells constitutively expressing C-G-LC3 with low to medium fluorescence and low fluorescence variability, and ii) correctly set up gates and voltage/gain on a properly equipped flow cytometer. We have used this method to measure autophagic flux in a variety of cell types and experimental systems using many different autophagy stimuli. On a sorting flow cytometer, this technique can be used to isolate cells with different levels of basal autophagic flux, or cells with variable induction of flux in response to a given stimulus for further analysis or experimentation. We have also combined quantification of autophagic flux with methods to measure apoptosis and cell surface proteins, demonstrating the usefulness of this protocol in combination with other flow cytometry labels and markers.     

流式细胞术在细菌快速检测中的应用

流式细胞仪(Flow cytometer)是集应用流体学、光学、电子学、生物学、免疫学等多门学科和技术于一体的新型高科技仪器。它的核心技术是流式细胞术(Flow cytometry,FCM),该技术是利用流式细胞仪,使单个细胞或其他微小生物粒子处于快速直线流动状态,且逐个通过光束,从而对单个细胞或微粒进行多参数(数量、大小、核酸含量、细胞活性、特定菌群或物种等)定量分析和分选的检测技术,具有快速、灵敏、精确以及便于操作等突出优点。本文简要介绍流式细胞仪的原理,并论述流式细胞技术在实验室研究、工业生产、临床诊断、环境评估等领域的细菌快速检测应用。     

Coupling Bacterial Activity Measurements with Cell Sorting by Flow Cytometry

Abstract A new procedure to investigate the relationship between bacterial cell size and activity at the cellular level has been developed; it is based on the coupling of radioactive labeling of bacterial cells and cell sorting by flow cytometry after SYTO 13 staining. Before sorting, bacterial cells were incubated in the presence of tritiated leucine using a procedure similar to that used for measuring bacterial production by leucine incorporation and then stained with SYTO 13. Subpopulations of bacterial cells were sorted according to their average right-angle light scatter (RALS) and fluorescence. Average RALS was shown to be significantly related to the average biovolume. Experiments were performed on samples collected at different times in a Mediterranean seawater mesocosm enriched with nitrogen and phosphorus. At four sampling times, bacteria were sorted in two subpopulations (cells smaller and larger than 0.25 μm³). The results indicate that, at each sampling time, the growth rate of larger cells was higher than that of smaller cells. In order to confirm this tendency, cell sorting was performed on six subpopulations differing in average biovolume during the mesocosm follow-up. A clear increase of the bacterial growth rates was observed with increasing cell size for the conditions met in this enriched mesocosm. Received: 21 January 1999; Accepted: 12 April 1999     

Discrete changes of the fluorescence yield from cells vitally stained with ethidium bromide (EB), as determined by flow cytometry

Cultured L cells were scraped from the glass surface and directly suspended in solutions of ethidium bromide (EB) in Tris buffer. After different staining times the fluorescence distributions were analysed with a flow cytometer. At 5 min after staining the cells yielded a normal DNA-specific histogram, but then a second peak at about 30–50% beyond the normal G1 fluorescence appeared and grew with increasing staining time. This effect of a discrete transition into a state of higher fluorescence was not dependent on the proliferative state of the cultures but was influenced by the temperature of the suspension and by serum and RNase. The effect proved not to be correlated with a G0–G1 transition and shows the possibility of artefacts in the determination of G0/G1 ratios by vital staining.     

High-resolution 3-D imaging of living cells in suspension using confocal axial tomography

Conventional flow cytometry (FC) methods report optical signals integrated from individual cells at throughput rates as high as thousands of cells per second. This is further combined with the powerful utility to subsequently sort and/or recover the cells of interest. However, these methods cannot extract spatial information. This limitation has prompted efforts by some commercial manufacturers to produce state-of-the-art commercial flow cytometry systems allowing fluorescence images to be recorded by an imaging detector. Nonetheless, there remains an immediate and growing need for technologies facilitating spatial analysis of fluorescent signals from cells maintained in flow suspension. Here, we report a novel methodological approach to this problem that combines micro-fluidic flow, and microelectrode dielectric-field control to manipulate, immobilize and image individual cells in suspension. The method also offers unique possibilities for imaging studies on cells in suspension. In particular, we report the system's immediate utility for confocal "axial tomography" using micro-rotation imaging and show that it greatly enhances 3-D optical resolution compared with conventional light reconstruction (deconvolution) image data treatment. That the method we present here is relatively rapid and lends itself to full automation suggests its eventual utility for 3-D imaging cytometry.     

基于流式细胞仪高通量分选的深海微生物单细胞培养

【目的】建立适用于海洋微生物的流式细胞分选与高通量单细胞培养的方法,通过该方法从印度洋深海样品中分离微生物纯培养菌株。【方法】利用流式细胞仪单细胞分选功能,以前向角(FSC)和侧向角(SSC)散射光信号代替荧光信号作为分选逻辑,对深海水体和沉积物样品中微生物进行单细胞高通量分选和培养。【结果】确定了流式细胞分选的区域和条件,发现所建立方法适于分离海洋水体微生物,而不是沉积物微生物。从印度洋深海水体样品中获得61个潜在新菌株,分属于6个新属种,占分离菌株总数的26.29%,其16S rRNA基因序列与已培养的模式菌株相似性为89.79%–95.37%。【结论】本研究所建立的方法有助于提高发现海洋微生物新物种的效率,获得更多新的海洋微生物资源。     

Time window analysis and sorting.

Flow cytometric hardware and procedures were developed to continuously analyse and to sort a particular time window in a kinetic response. The technique uses balanced air pressure to drive a stimulus-bead mixture from a vial to a t-junction where it mixes passively with cells. The t-junction is distanced from the flow cell and air pressure regulated so that the stimulation occurs at a fixed and adjustable time before the cells are interrogated by the laser beam. Practical applications of the device demonstrate utility with cells whose responses are seen in seconds or minutes. The device is easily implemented on any sorting flow cytometer.     

Ultra high-speed sorting.

BACKGROUND: Cell sorting has a history dating back approximately 40 years. The main limitation has been that, although flow cytometry is a science, cell sorting has been an art during most of this time. Recent advances in assisting technologies have helped to decrease the amount of expertise necessary to perform sorting. METHODS: Droplet-based sorting is based on a controlled disturbance of a jet stream dependent on surface tension. Sorting yield and purity are highly dependent on stable jet break-off position. System pressures and orifice diameters dictate the number of droplets per second, which is the sort rate limiting step because modern electronics can more than handle the higher cell signal processing rates. RESULTS: Cell sorting still requires considerable expertise. Complex multicolor sorting also requires new and more sophisticated sort decisions, especially when cell subpopulations are rare and need to be extracted from background. High-speed sorting continues to pose major problems in terms of biosafety due to the aerosols generated. CONCLUSIONS: Cell sorting has become more stable and predictable and requires less expertise to operate. However, the problems of aerosol containment continue to make droplet-based cell sorting problematical. Fluid physics and cell viability restraints pose practical limits for high-speed sorting that have almost been reached. Over the next 5 years there may be advances in fluidic switching sorting in lab-on-a-chip microfluidic systems that could not only solve the aerosol and viability problems but also make ultra high-speed sorting possible and practical through massively parallel and exponential staging microfluidic architectures.     

Flow cytometry: instrumentation and application in phytoplankton research

In flow cytometry, light scattering and fluorescence of individual particles in suspension is measured at high speed. When applied to planktonic particles, the light scattering and (auto-)fluorescence properties of algal cells can be used for cell identification and counting. Analysis of the wide size spectrum of phytoplankton species, generally present in eutrophic inland and coastal waters, requires flow cytometers specially designed for this purpose. This paper compares the performance in phytoplankton research of a commercial flow cytometer to a purpose built instrument. It reports on the identification of phytoplankton and indicates an area where flow cytometry may supersede more conventional techniques: the analysis of morphological and physiological characteristics of subpopulations in phytoplankton samples.