Accuracy of routine flow-cytometric bitmap selection for three leukocyte populations

A double-blind study was performed with peripheral blood of 41 human subjects to check the accuracy of determination of lymphocyte, monocyte, and granulocyte windows with which every flow cytometric analysis of leukocyte markers starts. White blood cell suspensions were prepared according to the whole blood method and analyzed on an EPICS-C flow cytometer using the two-parameter 90 degrees light scatter vs. forward angle light scatter (granularity vs. cell size) data distribution. Windows (bitmaps) for lymphocytes, monocytes, and granulocytes were drawn and numbers of cells determined in each. The proportions of lymphocytes, monocytes, and granulocytes were calculated in relation to total cell number, counted and in relation to the sum of cells in three bitmaps, and then compared with proportions determined by microscopic whole blood cell (WBC) differential and a WBC differential determined in an automated hematology analyzer. Average proportions of lymphocytes obtained by the flow cytometer were significantly lower than those obtained by either microscopic or automated differential, suggesting that some of the relevant cells were not included in the bitmaps. Granulocyte proportion related to total cell number was lower and that related to bitmap cell number higher than that obtained by microscopic and automatic differentials, suggesting that nongranulocytic cells were included in the granulocyte bitmaps. Proportions of lymphocytes and granulocytes obtained by the flow cytometer correlated well with those obtained by both microscopic and automatic differential. In contrast, the proportions of monocytes showed a poor correlation, which is probably due to their low number and delicate position in the distribution, and which makes them difficult to delineate.     

Flow cytometry of bacteria: a promising tool in experimental and clinical microbiology

The DNA and protein content of individual Escherichia coli cells were measured at a rate of 10(4) cells per second with a sensitive microscope-based flow cytometer. DNA and protein were quantified by measuring the fluorescence from cells stained with a combination of the DNA-binding drugs Mithramycin and ethidium bromide and by scattered light, respectively. Separate experiments demonstrated that the light scatter signal was proportional to protein content. Dual parameter histograms (fluorescence/scattered light) of bacterial cultures gave detailed pictures of changes dependent upon the growth conditions and of the cell cycle kinetics. Effects of antibiotics could be readily detected and characterized after a few hours. The results demonstrate that flow cytometry is a promising method for application in experimental and clinical microbiology.     

快速筛选高效表达重组蛋白毕赤酵母菌株新方法的建立及评价

毕赤酵母是当前应用最为广泛的重组蛋白表达系统之一,文中建立了一种快速筛选高效表达重组蛋白的毕赤酵母菌株的新方法。首先,对内质网转膜蛋白Sec63融合表达增强型绿色荧光蛋白EGFP的改造菌株GS115-E表达重组蛋白的能力进行检测;之后将携带不同拷贝数的植酸酶phy基因或木聚糖酶xyn基因的质粒转化进入GS115-E中,得到具有不同植酸酶或木聚糖酶表达水平的重组菌株,分别检测不同菌株的EGFP与重组蛋白的表达水平;最后,利用分选型流式细胞仪,根据绿色荧光值的高低对包含不同植酸酶表达水平的重组菌株的菌群进行分选。结果显示重组菌株中EGFP的荧光值与重组蛋白的活性表达水平之间具有良好的线性相关性(0.8|R|1),且利用流式细胞仪可高效地从混合菌群中筛选得到高产菌株,所分选得到的高荧光菌株在摇瓶发酵120 h时植酸酶表达水平是低荧光菌株的4.09倍。本方法通过检测菌株的EGFP荧光值代替检测重组蛋白的表达水平和活性,从而实现高表达菌株的筛选,大大提高了其应用的便捷性及通用性。与流式细胞仪、液滴微流控等高通量筛选仪器或技术结合将进一步提高筛选的速度与通量,为筛选获得高效表达重组蛋白的毕赤酵母菌株提供了简便、快速的新途径。     

Monitoring promoter activity in a single bacterial cell by using green and red fluorescent proteins

We investigated the possibility of monitoring promoter activity with flow cytometry by using green fluorescent protein (GFPmut2) and red fluorescent protein (drFP583) in a single bacterial cell. The drFP583 was used as an intrinsic marker of the bacterial cells, because it was expressed constantly in Escherichia coli MC1061 strain. The GFPmut2 expressed under the control of the Hg(2+) ion inducible mer promoter/operator, was used to study promoter activity. Over 75% of the cells were positive for red and green fluorescence in flow cytometric analysis. The average green fluorescence of the whole population increased from 6.7 to 1700 when the mercury concentration was increased from 0 to 1 x 10(-4) M, while the red fluorescence was unaffected by the mercury concentration. These results show that gfpmut2 and drFP583 could be expressed under different promoters in one bacterial cell and measured independently with a flow cytometer.     

Flow cytometric analysis of peripheral blood erythrocyte chimerism in alpha-thalassemic mice.

A rapid and reliable method for longitudinal studies on the degree of red cell chimerism following bone marrow transplantation of alpha-thalassemic recipient mice is presented. Blood obtained by tail clipping from transplanted mice was analyzed by measuring forward light scatter (FLS) distribution of red cells using a flow cytometer. Amplification and threshold of FLS were specifically adjusted. For flow cytometric analysis, the red cells needed to be suspended in hypotonic saline (103 mmol/l NaCl). Osmotic fragility testing showed that lysis of erythrocytes did not significantly influence the measurements. Flow cytometric measurement allowed for a rapid determination of the degree of red cell chimerism.     

Two distinct states of Escherichia coli cells that overexpress recombinant heterogeneous β-galactosidase

The mechanism by which inclusion bodies form is still not well understood, partly because the dynamic processes of the inclusion body formation and its solubilization have hardly been investigated at an individual cell level, and so the important detailed information has not been acquired for the mechanism. In this study, we investigated the in vivo folding and aggregation of Aspergillus phoenicis β-D-galactosidase fused to a red fluorescence protein in individual Escherichia coli cells. The folding status and expression level of the recombinant β-D-galactosidase at an individual cell level was analyzed by flow cytometry in combination with transmission electron microscopy and Western blotting. We found that individual E. coli cells fell into two distinct states, one containing only inclusion bodies accompanied with low galactosidase activity and the other containing the recombinant soluble galactosidase accompanied with high galactosidase activity. The majority of the E. coli cells in the later state possessed no inclusion bodies. The two states of the cells were shifted to a cell state with high enzyme activity by culturing the cells in isopropyl 1-thio-β-D-galactopyranoside-free medium after an initial protein expression induction in isopropyl 1-thio-β-D-galactopyranoside-containing medium. This shift of the cell population status took place without the level change of the β-D-galactosidase protein in individual cells, indicating that the factor(s) besides the crowdedness of the recombinant protein play a major role in the cell state transition. These results shed new light on the mechanism of inclusion body formation and will facilitate the development of new strategies in improving recombinant protein quality.     

Flow cytometric measurement of lipid peroxidation in vital cells using parinaric acid.

A method for measuring lipid peroxidation using time resolved flow cytometry is described. Because of its chemical nature, the naturally fluorescent fatty acid cis-parinaric acid is readily consumed in lipid peroxidation reactions. It could be loaded into Chinese hamster ovary cells in a time and concentration dependent manner at 37 degrees C, with 5 microM for 60' giving consistent, bright fluorescence without evidence of cytotoxicity. Examination of cells by fluorescence microscopy showed diffuse staining of surface and internal membranes. Cells were maintained at 37 degrees C while being examined in an Epics Elite flow cytometer equipped with a 325 nm HeCd laser, and parinaric acid fluorescence at 405 nm was measured over time. Addition of the oxidant tert-butyl hydroperoxide resulted in a burst of intracellular oxidation, shown by simultaneously loading the cells with dichlorofluorescein, and loss of parinaric fluorescence over time. This was followed by cell death, indicated by loss of forward light scatter and uptake of propidium iodide. Pretreatment of the cells with the antioxidant alpha-tocopherol, 200 microM, reduced the rate of loss of parinaric acid fluorescence and delayed the onset of cell death. Simultaneous biochemical determination of the lipid peroxidation breakdown product malondialdehyde confirmed a close temporal relationship with loss of parinaric acid fluorescence, both with and without alpha-tocopherol pretreatment and suggested that the flow cytometric assay for lipid peroxidation is of comparable sensitivity. The mitochondrial stain dodecyl acridine orange and the cyanine dye DiOC(6)3 were combined with cis-parinaric acid staining and could be excited by the latter using resonance energy transfer.(ABSTRACT TRUNCATED AT 250 WORDS)     

Flow cytometry of Escherichia coli for process monitoring

A laser flow cytometer was used to study different Escherichia coli populations under various cultivation conditions. A host strain E. coli 5K was analyzed for cell size, protein and DNA-content during continuous cultivation. Also, a recombinant E. coli 5K(pHM12) strain (used for the intracellular production of penicillin-G acylase) was studied in regard to gene expression using different cytometric techniques. An argon ion laser (30 mW) and a 100 W high-pressure mercury lamp were used as light source in the cytometer. A new fluorogenic staining technique for intracellular penicillin-G acylase is described.Recombinant E. coli temperature sensitive cells were analyzed for intracellular fusion protein production due to temperature induction.     

Assessment of GFP Expression and Viability Using the Tali Image-Based Cytometer

Single-cell and population information are commonly obtained either by flow cytometry or fluorescence microscopy. However, these two methods provide different information. Flow cytometry gives quantitative multi-parametric information about physical characteristics and staining or expression, but doesn''t allow for visualization. Stand-alone fluorescence microscopy provides visual data, but doesn''t allow for straightforward quantitative measurements¹.Image-based cytometry bridges the gap between these two methods, enabling the quick visualization and simultaneous quantitative analysis of thousands of cells in heterogeneous populations². Here, we present a method for performing cell viability and green fluorescent protein (GFP) expression assays using the Tali Image-Based Cytometer³. The Tali instrument is a 3-channel (bright field, green fluorescence, red fluorescence) benchtop assay platform that offers several advantages over flow cytometry and fluorescence microscopy. The Tali cytometer is less expensive, takes up less bench space, requires less maintenance, and the work flow has been simplified so that the operation and analysis is much simpler and quicker. The Tali cytometer is capable of performing a range of suspension cell-based assays, including GFP and red fluorescent protein (RFP) expression, apoptosis^4-6 and cell viability analysis with propidium iodide (PI)^7-11.Here, we demonstrate the use of the Tali instrument in performing a cell viability assay in cells expressing GFP. GFP-transduced cells are stained using the Tali Viability Kit - Dead Cell Red. The cells are then pipetted into a Tali Cellular Analysis Slide and loaded into the cytometer. Bright field, red fluorescence and green fluorescence images are captured and analyzed using assay specific algorithms. Histograms are then generated to display cell size, PI fluorescence intensity, and GFP fluorescence intensity. These parameters can then be thresholded to home in on a specific cell population.A side-by side comparison of the Tali Image-Based Cytometer and traditional flow cytometry demonstrates that the two methods provide comparable data regarding cell viability and protein expression. However, the Tali instrument provides additional visual information about the cell population that cannot be obtained using a flow cytometer.Download video file.^{(64M, mov)}     

Utility of light scatter in the morphological analysis of sperm.

We were able to differentiate the morphologically diverse sperm nuclei of four animal species by using an Ortho flow cytometer to detect the forward light scatter from a red (helium-neon) laser. Cytograms depicting the axial light loss and forward red scatter signals revealed unique, but reproducible, sigmoid distributions that reflected not only interspecies differences in shape and size, but variations in particle refractive index and orientation within the flow cell at the time of analysis. Consequently, we were able to use regional gating of the light scatter cytogram to minimize the influence of orientation on the resolution of the fluorescence signal. We also observed that sperm enlarging as a result of chemically induced decondensation exhibit over time a biphasic shift (increase, then decrease) in light scatter at a species-dependent rate. These results suggest that, without any special adaptations to the flow cytometer, light-scatter parameters can be used to discriminate morphologically different sperm, to enhance the resolution of fluorescence measurements that may otherwise be confounded by variability in radial orientation, and to detect alterations in the rate of a biochemical/biophysical process such as decondensation.     

A computer-aided measuring system for the characterization of yeast populations combining 2D-image analysis, electronic particle counter, and flow cytometry

An integrated measuring system was developed that directly compares the shape of size distributions of Saccharomyces cerevisiae populations obtained from either microscopic measurements, electronic particle counter, or flow cytometer. Because of its asymmetric mode of growth, a yeast population consists of two different subpopulations, parents and daughters. Although electronic particle counter and flow cytometer represent fast methods to assess the growth state of the population as a whole, the determination of important cell cycle parameters like the fraction of daughters or budded cells requires microscopic observation. We therefore adapted a semiautomatic and interactive 2D-image processing program for rapid and accurate determination of volume distributions of the different sub-populations. The program combines the capacity of image processing and volume calculation by contour-rotation, with the potential of visual evaluation of the cells. High-contrast images from electron micrographs are well suited for image analysis, but the necessary air drying caused the cells to shrink to 35% of their hydrated volume. As an alternative, hydrated cells overstained with the fluorochrome calcofluor and visualized by fluorescence light microscopy were used. Cell volumes calculated from length, and diameter measurements with the assumption of an ellipsoid cell shape were underestimated as compared to volumes derived from 2D-image analysis and contour rotation, because of a deviating cell shape, especially in the older parent cells with more than one bud scar. The bimodal volume distribution obtained from microscopic measurements was identical to the protein distribution measured with the flow cytometer using cells stained with dansylchloride, but differed significantly from the size distribution measured with the electronic particle counter. Compared with the flow cytometer, 2-D image analysis can thus provide accurate distributions with important additional information on, for instance, the distributions of subpopulations like parents, daughters, or budded cells.     

Formation of fluorescent proteins by the attachment of phycoerythrobilin to R-phycoerythrin alpha and beta apo-subunits

Formation of fluorescent proteins was explored after incubation of recombinant apo-subunits of phycobiliprotein R-phycoerythrin with phycoerythrobilin chromophore. Alpha and beta apo-subunit genes of R-phycoerythrin from red algae Polisiphonia boldii were cloned in plasmid pET-21d(+). Hexahistidine-tagged alpha and beta apo-subunits were expressed in Escherichia coli. Although expressed apo-subunits formed inclusion bodies, fluorescent holo-subunits were constituted after incubation of E. coli cells with phycoerythrobilin. Holo-subunits contained both phycoerythrobilin and urobilin chromophores. Fluorescence and differential interference contrast microscopy showed polar location of holo-subunit inclusion bodies in bacterial cells. Cells containing fluorescent holo-subunits were several times brighter than control cells as found by fluorescence microscopy and flow cytometry. The addition of phycoerythrobilin to cells did not show cytotoxic effects, in contrast to expression of proteins in inclusion bodies. In an attempt to improve solubility, R-phycoerythrin apo-subunits were fused to maltose-binding protein and incubated with phycoerythrobilin both in vitro and in vivo. Highly fluorescent soluble fusion proteins containing phycoerythrobilin as the sole chromophore were formed. Fusion proteins were localized by fluorescence microscopy either throughout E. coli cells or at cell poles. Flow cytometry showed that cells containing fluorescent fusion proteins were up to 10 times brighter than control cells. Results indicate that fluorescent proteins formed by attachment of phycoerythrobilin to expressed apo-subunits of phycobiliproteins can be used as fluorescent probes for analysis of cells by microscopy and flow cytometry. A unique property of these fluorescent reporters is their utility in both properly folded (soluble) subunits and subunits aggregated in inclusion bodies.     

Cell analysis system based on immunomagnetic cell selection and alignment followed by immunofluorescent analysis using compact disk technologies

BACKGROUND: Although the flow cytometer has become the standard in cell analysis, it has limitations. Recently, we introduced a new cell analysis method based on immunomagnetic selection and aligning of cells. No flow system is needed and cell analysis can be performed in whole blood. METHODS: Whole blood is incubated with fluorescent labels and immunomagnetic nanoparticles. The blood is injected into a capillary that is in a strong magnetic field. The immunomagnetic-labeled cells move upward and align themselves along ferromagnetic lines present on the upper surface of the capillary. An optical focus and tracking system analogous to that used in a conventional compact disk player focuses a 635-nm laser-diode on the magnetically aligned cells. The emitted fluorescence signals are projected on two photomultipliers. Allophycocyanin (APC)-labeled CD4 (CD4-APC) and Cyanin5.5 (Cy5.5)-labeled CD8 (CD8-Cy5.5) antibodies and Oxazine750, all red excited, are used as fluorescent labels. RESULTS: A differential white blood cell count performed in whole blood is obtained using the CD4-APC in combination with Oxazine750. The results are compared with the Technicon-H1 hematology analyzer. Correlation coefficients of 0.91 for neutrophilic granulocytes, 0.93 for lymphocytes, 0.93 for monocytes, and 0.96 for eosinophilic granulocytes were obtained. Immunofluorescence is demonstrated using CD4-APC and CD8-Cy5.5. The absolute counts obtained for CD4+ and CD8+ are compared with the Coulter Epics XL flow cytometer. Correlation coefficients of, respectively, 0.91 and 0.94 were obtained. CONCLUSION: We conclude that our system is as capable as a standard flow cytometer or hematology analyzer for a reliable routine white blood cell analysis, including immunophenotyping, and can be used as an easy-to-handle disposable white blood cell test.     

Sorting minor subpopulations of cells: use of fluorescence as the triggering signal

Flow cytometric cell sorting is commonly used to obtain purified subpopulations of cells for use in in vitro and in vivo assays. This can be time-consuming if the subpopulations of interest represent very low percentages of the cell suspension under study. Often the desired subpopulations are identified by two-color immunofluorescence staining. Generally, cell sorting is performed with a flow cytometer configured to trigger on light scatter signals, then sort windows are set based upon the signals from both fluorescent markers. We demonstrate that triggering the cytometer with the fluorescence signal from antibody staining common to both of the desired subpopulations, then sorting the subpopulations based upon staining of a second marker, substantially increases the speed of cell sorting vis-à-vis traditional methods. This is because undesired events are not analysed, allowing an increase in the throughput rate. While desired subpopulations of cells can be obtained by this method, undesired (i.e., nonstaining) cell "contaminants" increase and may require a second sort. The combined time for the initial enrichment sort and a second sort can be less than sorting once using standard methodology. Alternatively, the degree of contamination may be controlled by adjusting the concentration of the cell suspension and by the sample flow rate.     

On-line monitoring of marine cyanobacterial cultivation based on phycocyanin fluorescence.

A novel on-line fluorescence monitoring system for marine cyanobacterial cultivation was developed. This method is based on the measurement of intracellular phycocyanin content, which is the major light harvesting protein. A fluorescence spectrophotometer, equipped with a flow cell connected with a culture liquid recycling tube was used. Experiments were carried out using a marine unicellular cyanobacteria Synechococcus sp. NKBG 042902 isolated from Japanese coastal sea water. We have optimized excitation wavelength to avoid the light scattering, using non-pigmented old cells which no longer contained phycocyanin. At an excitation wavelength of 590 nm, light scattering was minimized. Viable cell concentration could be measured in the range of 2 x 10(6) to 2 x 10(8) cells per ml, without pronounced light scattering. Continuous monitoring of marine cyanobacteria cultivation was performed. Cell concentrations were determined by both culture fluorescence and by using a hemacytometer. A good linear correlation was obtained. We conclude that on-line monitoring of cyanobacterial culture fluorescence based on phycocyanin is a rapid, efficient and also versatile method for determining viable cell concentration.     

Stable expression of Anthozoa fluorescent proteins in mammalian cells

BACKGROUND: Fluorescent proteins have become invaluable reporters in many areas of cellular and developmental biology. An enhanced version of the Aequorea victoria green fluorescent protein (AvEGFP) is the most widely used fluorescent protein. For a variety of reasons, it is useful to have alternative fluorescent proteins to AvEGFP. METHODS: The cDNA sequences for enhanced variants of the Anemonia cyan fluorescent protein (AmCyan1), as well as the Zoanthus green (ZsGreen1) and yellow (ZsYellow1) fluorescent proteins, were cloned downstream of a constitutive cytomegalovirus (CMV) promoter within a retroviral expression vector. NIH3T3, HEK293, SW620, and WM35 cells were transduced with recombinant retroviruses at a low multiplicity of infection (MOI) to bias for single-copy integration. Both unselected and stably selected cells transduced with the retroviral expression constructs were characterized. Expression of each fluorescent protein in cells was detected using flow cytometry and fluorescence microscopy with filter sets typically used for AvEGFP/fluorescein isothiocyanate (FITC) detection and was compared with the expression of AvEGFP. In addition, a fluorescence plate reader with several excitation and emission filter sets was used for detection. RESULTS: Expression of each protein was observable by fluorescence microscopy. Under given conditions of flow cytometry, the ZsGreen1 mean fluorescence was approximately 3-fold, 10-fold, and 50-fold greater than that of AvEGFP, ZsYellow1, and AmCyan1, respectively. AmCyan1, ZsGreen1, and AvEGFP were detected by a fluorescence plate reader. CONCLUSION: We determined that fluorescent proteins from Anthozoa species are detectable using a standard flow cytometer and fluorescence microscope. All of the mammalian cell lines tested expressed detectable levels of fluorescent proteins from stable integrated provirus. In cell lines where the AvEGFP protein is toxic or poorly expressed, these Anthozoa fluorescent proteins may serve as alternative fluorescent reporters.     

Flow cytometric determination of circulating immune complexes with the indirect granulocyte phagocytosis test

A method for the determination of circulating immune complexes (CIC) was adapted for flow cytometric analysis. Human granulocytes were used to phagocytose IgG-bearing CIC of serum from systemic lupus erythematosus (SLE) patients. A method for labeling the phagocytosed CIC with FITC-conjugated anti-human IgG was developed where the granulocytes remain in suspension during fixation and labeling. The fluorescence per cell, measured with a flow cytometer, is a measure of the total amount of the phagocytosed IgG. The results indicate that a rapid and quantitative method for the detection and measurement of phagocytosed CIC is possible using the flow cytometer.     

Flow-cytometric determination of fluorescence ratios between differently stained particles is dependent on excitation intensity

By use of a flow cytometer, the fluorescence of cells stained with hematoporphyrin derivative and the fluorescence of plastic beads stained with different dyes were analysed as a function of the intensity of the exciting laser light. The ratios of the fluorescence values of stained and unstained cells as well as of stained cells and beads were sensitively dependent on excitation intensities. As a consequence of this finding, the normalization of cellular fluorescence by use of reference particles needs to be made on a well-defined and reproduced intensity of the exciting laser light.     

Flow cytometric discrimination between Acinetobacter calcoaceticus 69-V and Alcaligenes eutrophus JMP134 by fluorescently labelled rRNA-targeted oligonucleotide probes and DNA staining

In situ hybridization with fluorescently monolabelled rRNA-targeted oligonucleotide probes (17 to 18 nucleotides) was used to discriminate between Alcaligenes eutrophus JMP 134 and Acinetobacter calcoaceticus 69-V by flow cytometry. The strains were grown in batch experiments in a mixed population. The forward light scatter and fluorescence of each bacterial cell were measured with a single laser cytometer. The intensity of fluorescence after rRNA staining depended on the content of ribosomes, which correlated with the growth rate of bacteria. Therefore exponentially growing cells could be clearly detected. For other growth phases, signal amplification was necessary using multiple probes. The two bacterial strains were identified with differently labelled probes under an epifluorescent microscope. Using a single laser cytometer, rRNA based identification was possible nut not ideal. Better discrimination between the two strains of the mixed population was achieved by DNA staining, combined with the different forward light scatter signals. Due to the significantly different cellular DNA and GC content of both strains, the fluorescent dye DAPI (4′, 6-diamidino-2-phenylindole), preferring AT-rich regions of DNA, was found to be a supplementary tool for population analysis. The abundance ratios of the two strains in mixed culture determined by DNA or rRNA staining were similar.