Use of flow cytometry in the measurement of cell mitotic cycle

Variations in many cellular characteristics during the cell cycle can be analyzed simply and directly by flow cytometry. Using multiparameter analysis of DNA content, RNA content, cell size and 5-bromodeoxyuridine (BrdUrd) incorporation, it is now possible to define cells' positions in the cell cycle with a precision previously unimaginable. It is also possible, by using the sorting function of the flow cytometer, to separate populations in different phases of the cell cycle for biological and biochemical studies. This review describes the technical aspects of flow cytometric instrumentation, DNA staining procedures, and the cytometric applications of both in cell cycle analysis including some of the more innovative, new approaches with antibody against BrdUrd.     

Flow cytometric analysis of breast cancer resistance protein expression and function

BACKGROUND: The breast cancer resistance protein (BCRP) is an ATP-binding cassette (ABC) half-transporter that mediates energy-dependent drug efflux. Assessing the clinical relevance of the BCRP will require sensitive and specific methods for detecting its expression and function that allow high-volume specimen throughput and employ widely available instrumentation. METHODS: The BXP-34 and BXP-21 monoclonal antibodies were evaluated for flow cytometric detection of BCRP expression. The modulation of efflux of rhodamine-123, 3,3'-diethyloxacarbocyanine iodide, doxorubicin, and mitoxantrone by fumitremorgin C was studied as an assay for BCRP function in BCRP-overexpressing cell lines and controls. RESULTS: BXP-34 and BXP-21 allowed detection of BCRP expression by flow cytometry in all BCRP-expressing cell lines. Mitoxantrone was the only substrate transported by BCRP in all lines, and with mitoxantrone at a 3-microM concentration, light emission (>670 nm) caused by excitation at 488 nm was sufficiently intense to allow detection of differences in retention associated with low levels of BCRP expression. CONCLUSIONS: Immunophenotyping with BXP-21 or BXP-34 and fumitremorgin C modulation of mitoxantrone retention allow detection of BCRP expression and function by flow cytometry with standard instrumentation. These assays will facilitate determination of the role of BCRP in clinical drug resistance.     

Flow cytometry in radiation research: past, present and future

Flow cytometry is an invaluable technique in research and clinical laboratories. The technique has been applied extensively to many areas of radiation research at both the experimental and clinical level. In the past few years, there has been a significant increase in the capabilities of modern flow cytometers to undertake multicolor analysis in a user-friendly manner. The developments in cytometric technology are being matched by the rapid development of new reagents, new fluorochromes and new platforms such as bead arrays. These developments are facilitating many new applications in both basic and clinical research that have relevance for many fields of biology, including radiation research. This review provides a historical overview of the application of flow cytometry to radiobiology and an update on how technology and reagents have changed and cites examples of new applications relevant to radiation researchers. In addition, some entirely new flow instrumentation is currently under development that has significant potential for applications in radiation research.     

Flow cytometry and cell sorting: current state and prospects for use in molecular biology

A survey of the specific features of flow cytometry, principals of instrumentation and main parameters of the modern cell sorting cytometers is given. Analytical capacities of flow cytometry as well as the main directions of its applications in cell biology, clinical diagnostics, immunology, biotechnology and molecular biology are considered. Also a possible future development of flow cytometry instrumentation and applications in molecular biology are briefly discussed.     

Cytomics, the human cytome project and systems biology: top-down resolution of the molecular biocomplexity of organisms by single cell analysis

A large amount of structural and functional information is obtained by molecular cell phenotype analysis of tissues, organs and organisms at the single cell level by image or flow cytometry in combination with bioinformatic knowledge extraction (cytomics) concerning nuclei acids, proteins and metabolites (cellular genomics, proteomics and metabolomics) as well as cell function parameters like intracellular pH, transmembrane potentials or ion gradients. In addition, differential molecular cell phenotypes between diseased and healthy cells provide molecular data patterns for (i) predictive medicine by cytomics or for (ii) drug discovery purposes using reverse engineering of the data patterns by biomedical cell systems biology. Molecular pathways can be explored in this way including the detection of suitable target molecules, without detailed a priori knowledge of specific disease mechanisms. This is useful during the analysis of complex diseases such as infections, allergies, rheumatoid diseases, diabetes or malignancies. The top-down approach reaching from single cell heterogeneity in cell systems and tissues down to the molecular level seems suitable for a human cytome project to systematically explore the molecular biocomplexity of human organisms. The analysis of already existing data from scientific studies or routine diagnostic procedures will be of immediate value in clinical medicine, for example as personalized therapy by cytomics.     

一种细胞外囊泡的流式检测方案的探索与建立

该研究旨在探索细胞外囊泡(extracellular vesicles,EVs)分析的标准化流程,建立一种高效的EVs检测方法,为EVs功能及临床转化研究提供技术支撑。实验采用经典的超速离心法分离EVs,借助已知直径的聚苯乙烯微球设定并优化流式检测EVs的参数,联合应用散色光信号及荧光信号对EVs进行双参数分析鉴定,最后通过电镜观察及蛋白质免疫印迹(Western blot,WB)对鉴定结果进行验证。结果显示,参照纳米微球设定的条件可清楚地将100 nm颗粒信号与噪音信号分离,且微球稀释的梯度和检测到的浓度之间呈线性相关,可以对EVs进行定量分析;荧光染色结果显示,EVs呈CFSE(5,6-Carboxyfluorescein diacetate,succinimidyl ester,蛋白结合染料)及FM1-43(fixable analog of FM?1-43 membrane stain,亲脂性染料)双阳性,占比约3%;电镜验证其形态及直径与预期相一致。该研究通过优化流式方案及双荧光参数分析鉴定探索了EVs流式检测的标准化流程,建立了高效、准确的EVs流式检测方法。     

Emerging applications of flow cytometry in solid tumor biology

Despite considerable interest during the early clinical development of flow cytometry, its application to solid tumours has been largely ignored in recent years. However, with rapid progress in cancer biology and molecular therapeutics, linked to technical developments in the areas of flow cytometry instrumentation, reagents, and data analysis, it is timely to re-evaluate this role. This article places emphasis on the unique potential of flow cytometry to analyze heterogeneous cell populations, and to provide information on the functional status of regulatory processes by the simultaneous measurement of multiple key elements. Major obstacles to progress addressed include the acquisition of adequate clinical samples, tissue disaggregation to produce single cells suspensions suitable for flow cytometry, and protocols to label intracellular as well as cell surface antigens.     

A Method for Identification and Analysis of Non-Overlapping Myeloid Immunophenotypes in Humans

The development of flow cytometric biomarkers in human studies and clinical trials has been slowed by inconsistent sample processing, use of cell surface markers, and reporting of immunophenotypes. Additionally, the function(s) of distinct cell types as biomarkers cannot be accurately defined without the proper identification of homogeneous populations. As such, we developed a method for the identification and analysis of human leukocyte populations by the use of eight 10-color flow cytometric protocols in combination with novel software analyses. This method utilizes un-manipulated biological sample preparation that allows for the direct quantitation of leukocytes and non-overlapping immunophenotypes. We specifically designed myeloid protocols that enable us to define distinct phenotypes that include mature monocytes, granulocytes, circulating dendritic cells, immature myeloid cells, and myeloid derived suppressor cells (MDSCs). We also identified CD123 as an additional distinguishing marker for the phenotypic characterization of immature LIN^-CD33⁺HLA-DR^- MDSCs. Our approach permits the comprehensive analysis of all peripheral blood leukocytes and yields data that is highly amenable for standardization across inter-laboratory comparisons for human studies.     

Flow cytometry in the study of cell death

In this report we present a concise review concerning the use of flow cytometric methods to characterize and differentiate between two different mechanisms of cell death, apoptosis and necrosis. The applications of these techniques to clinical and basic research are also considered. The following cell features are useful to characterize the mode of cell death: (1) activation of an endonuclease in apoptotic cells results in extraction of the low molecular weight DNA following cell permeabilization, which, in turn, leads to their decreased stainability with DNA-specific fluorochromes. Measurements of DNA content make it possible to identify apoptotic cells and to recognize the cell cycle phase specificity of apoptotic process; (2) plasma membrane integrity, which is lost in necrotic but not in apoptotic cells; (3) the decrease in forward light scatter, paralleled either by no change or an increase in side scatter, represent early changes during apoptosis. The data presented indicate that flow cytometry can be applied to basic research of the molecular and biochemical mechanisms of apoptosis, as well as in the clinical situations, where the ability to monitor early signs of apoptosis in some systems may be predictive for the outcome of some treatment protocols.     

The characterization and isolation of plant heterokaryons by flow cytometry

Summary Plant heterokaryons were identified and isolated from a population of protoplasts following fusion. Endogenous chlorophyll autofluorescence and exogenously supplied fluorochromes were utilized to differentiate between parental and heterokaryon populations. Flow cytometric analysis detected heterokaryons based upon the simultaneous presence of both chlorophyll and an exogenously supplied fluorochrome within one cell. These parameters were utilized to sort large numbers of heterokaryons from the fusion mixture using modified flow instrumentation. Modifications to the instrumentation which allowed this sorting are discussed.     

Utilization of non-AUG initiation codons in a flow cytometric method for efficient selection of recombinant cell lines

Here we describe a method that couples flow cytometric detection with the attenuated translation of a reporter protein to enable efficient selection of CHO clones producing high levels of recombinant proteins. In this system, a small cell surface reporter protein is expressed from an upstream open reading frame utilizing a non-AUG initiation (alternate start) codon. Due to the low translation initiation efficiency of this alternate start codon, the majority of translation initiation events occur at the first AUG of the downstream open reading frame encoding the recombinant protein of interest. While translation of the reporter is significantly reduced, the levels are sufficient for detection using flow cytometric methods and, in turn, predictive of protein expression from the gene of interest since both ORFs are translated from the same mRNA. Using this system, CHO cells have been sorted to obtain enriched pools producing significantly higher levels of recombinant proteins than the starting cell population and clones with significantly better productivity than those generated from limiting dilution cloning. This method also serves as an effective screening tool during clone expansion to enable resources to be focused solely on clones with both high and stable expression.     

X-ray- and neutron-induced chromosome damage detected by flow cytometry compared to cell lethality and chromosome structural changes

V79 Chinese hamster cells were irradiated in G0 phase with 200 kV X rays or 14 MeV neutrons, and dose-response curves were determined for three end points: chromosome damage detected by flow cytometric analysis of chromosomes isolated from metaphase cells in irradiated cultures; loss of clonogenic capacity; and induction of dicentric, tricentric, and ring chromosomes. The changes observed in the flow karyotypes from irradiated cultures were quantitatively evaluated by computer analysis. Estimates of the frequencies of chromosome lesions were derived from an analysis of the flow cytometric measurements by means of a comparison with model calculations simulating the effect of chromosome changes on flow karyotypes. The results indicate that lesions assayed by flow cytometry occur three times more frequently than lethal lesions, while the chromosomal structural changes detected by microscopic analysis were about 10 times less frequent than the lesions detected by flow cytometry. Dose-response curves for X rays and neutrons show that cell reproductive death and changes in flow karyotypes result from damage, induced with a similar relative biological effectiveness. Dose-effect relations derived from changes in flow karyotypes, which can be obtained within 24 h after irradiation, might be of value as a predictive test for the sensitivity of cells for loss of clonogenic capacity.     

Flow cytometry in cancer stem cell analysis and separation

In recent years, a special type of cancer cell--the cancer stem cell (CSC)--has been identified and characterized for different tumors. CSCs may be responsible for the recurrence of a tumor following a primarily successful therapy and are thought to bear a high metastatic potential. For the development of efficient treatment strategies, the establishment of reliable methods for the identification and effective isolation of CSCs is imperative. Similar to their stem cell counterparts in bone marrow or small intestine, different cluster of differentiation surface antigens have been characterized, thus enabling researchers to identify them within the tumor bulk and to determine their degree of differentiation. In addition, functional properties characteristic of stem cells can be measured. Side population analysis is based on the stem cell-specific activity of certain ATP-binding cassette transporter proteins, which are able to transport fluorescent dyes out of the cells. Furthermore, the stem cell-specific presence of aldehyde dehydrogenase isoform 1 can be used for CSC labeling. However, the flow cytometric analysis of these CSC functional features requires specific technical adjustments. This review focuses on the principles and strategies of the flow cytometric analysis of CSCs and provides an overview of current protocols as well as technical requirements and pitfalls. A special focus is set on side population analysis and analysis of ALDH activity. Flow cytometry-based sorting principles and future flow cytometric applications for CSC analysis are also discussed.     

Rapid titer assay of adenovirus containing green fluorescent protein gene using flow cytometric analysis

The plaque assay has been widely used for titration of adenovirus (AdV). However, it takes usually 2-3 weeks, so this slow assay often impedes bioprocess development of large-scale AdV production. In this study, we developed a rapid AdV titration assay that can be done within a day. Further, unlike the plaque assay, this assay does not require a laborious serial dilution of samples. This rapid assay can be achieved by using green fluorescent protein (GFP) as a marker gene and flow cytometric analysis. It yields a good correlation between infectious titer of AdV harboring GFP and flow cytometric parameters such as average green fluorescence intensity or % of infected cells. Taken together, this rapid assay will facilitate bioprocess development for efficient large-scale AdV production.     

Phytoplankton monitoring by high performance flow cytometry: a successful approach?

BACKGROUND: Regular phytoplankton monitoring in Dutch coastal waters is performed as an indicator of the ecological state of these waters. The monitoring program is focused on temporal and spatial changes of species composition and abundance. Flow cytometry has been introduced to provide additional information, to improve ecosystem understanding, and to increase the efficiency of analysis and reportage. METHODS: Phytoplankton community abundance and composition were routinely determined by flow cytometry and microscopy at six locations in the North Sea over three annual cycles between 2000 and 2003. Supplementary measurements were also made for fluorescence (chlorophyll-a and other pigments) and, in combination with flow cytometric and microscopic data, were used to determine phytoplankton abundance and composition as a function of their size distribution. Real-time imaging of species was also used to identify species on the basis of their flow cytometric optical characteristics. RESULTS: Flow cytometric analysis took 15 min on average. Analysis including data processing, and Web site reportage took less than 1 h. Phytoplankton concentrations (cells/ml), biomass (fluorescence/ml), and concentration of phycoerythrin- or phycocyanin-containing cells (cells/ml) as a function of their algal size were produced every 2 weeks on average. The phytoplankton integrated annual concentration and biomass were used as ecological indicators for overall phytoplankton status. Real-time imaging of cells in flow enabled the identification of dominant species and was applied as an early warning system for Phaeocystis spp. CONCLUSIONS: The reproducibility and count precision due to the large number of observations of the flow cytometric technique provided reliable data for monitoring long-term trends. Flow cytometrically based analyses extended the lower detection limit (<0.5 microm) of analysis beyond the capabilities of other techniques such as the relation between small and larger phytoplankton, the relation between cell counts and biomass as a function of cell size, but also the ability to monitor and report on blooms of harmful algae. A good correlation was found between concentrations (cells/ml) measured by flow cytometry and microscopy. In practice, flow cytometric analysis of a single marine sample took 15 min on average.     

Technique and staining optimization leucoconcentration

In cytometric clinical application, it is important to obtain cell suspensions rapidly with as little cytological alteration as possible. A procedure has been achieved to prepare cell suspensions for flow cytometric analysis. The leucoconcentration technique, first described by Herbeuval for cytologic analysis, has been modified to be applied in cytometry. This technique involves Saponin lysis of red cells of peripheral blood or bone marrow samples that have been previously fixed with picric acid alcohol solution. Cells in suspension are not shifted and tinctorial affinity is not modified. Then cells have been stained with Mithramycin. Each parameter defined by Crissman has been analyzed to define the best staining conditions. The availability of Leucoconcentration with Mithramycin-DNA-staining permits determination of cell cycle with a fine resolution.     

Cell-by-cell flow cytometric analysis of chromosomes

The authors discuss various aspects of a recently developed method permitting a detailed flow cytometric analysis of the individual cell karyotypes such as instrumentation, histochemistry, data proceeding algorithms. Possible drawbacks of the method and the ways of their overcoming are considered. Results of analysis of the Chinese hamster cells are presented that illustrate the possibilities of the method, including the metaphase chromosome distribution according to their fluorescence intensity, the analysed cell distribution according to their chromosomes number, the table in which the individual cell karyotypes are distributed according to their fluorescence. The results obtained show that the developed method may be successfully used for investigating chromosomal iNstability and heterogeneity of the mammalian cells.     

Use of a lectin as an enterocyte-specific cell surface marker for flow cytometric analysis of isolated native small intestinal epithelial cells

Little use has been made of flow cytometry in evaluating small intestinal epithelial cells. Obtaining pure epithelial cell populations devoid of peripheral blood contaminants and intraepithelial lymphocytes contributes to the difficulties encountered in flow cytometry studies. We have investigated the use of lectins as enterocyte specific cell markers using lectin histochemistry, and have identified one lectin, UEA-1, which binds exclusively and specifically to intestinal epithelial cell brush border. Additionally, we have exploited that specificity using flow cytometry and FITC-UEA-1 to identify and separate native intestinal epithelial cells from a mixed cell population isolated by mechanical vibration. This fluorescent-lectin technique is a unique and simple method to identify native small intestinal epithelial cells in a mixed cell population; it may be exploited by flow cytometric sorting of a pure population for biochemical study or as an enterocyte specific label for surface receptor flow cytometric studies in the research or clinical setting.