Simultaneous analysis of the cyan, yellow and green fluorescent proteins by flow cytometry using single-laser excitation at 458 nm.

BACKGROUND: Development of spectrally distinct green fluorescent protein (GFP) variants has allowed for simultaneous flow cytometric detection of two different colored mutants expressed in a single cell. However, the dual-laser methods employed in such experiments are not widely applicable since they require a specific, expensive laser, and single-laser analysis at 488 nm exhibits considerable spectral overlap. The purpose of this work was to evaluate detection of enhanced cyan fluorescent protein (ECFP) in combination with the enhanced green (EGFP) and enhanced yellow (EYFP) fluorescent proteins by flow cytometry. METHODS: Cells transfected with expression constructs for EGFP, EYFP, or ECFP were analyzed by flow cytometry using excitation wavelengths at 458, 488, or 514 nm. Fluorescence signals were separated with a custom optical filter configuration: 525 nm shortpass and 500 nm longpass dichroics; 480/30 (ECFP), 510/20 (EGFP) and 550/30 (EYFP) bandpasses; 458 nm laser blocking filters. RESULTS: All three fluorescent proteins when expressed individually or in combination in living cells were excited by the 458 nm laser line and their corresponding signals could be electronically compensated in real time. CONCLUSIONS: This method demonstrates the detection of three fluorescent proteins expressed simultaneously in living cells using single laser excitation and is applicable for use on flow cytometers equipped with a tunable argon ion laser.     

Effect of high pressure and reversed micelles on the fluorescent proteins

Two physico-chemical perturbations were applied to ECFP, EGFP, EYFP and DsRed fluorescent proteins: high hydrostatic pressure and encapsulation in reversed micelles. The observed fluorescence changes were described by two-state model and quantified by thermodynamic formalism. ECFP, EYFP and DsRed exhibited similar reaction volumes under pressure. The changes of the chemical potentials of the chromophore in bis(2-ethylhexyl)sulfosuccinate (AOT) micelles caused apparent chromophore protonation changes resulting in a fluorescence decrease of ECFP and EYFP. In contrast to the remarkable stability of DsRed, the highest sensitivity of EYFP fluorescence under pressure and in micelles is attributed to its chromophore structure.     

Expression and recombination of the EGFP and EYFP genes in lentiviral vectors carrying two heterologous promoters

BACKGROUND: Expressing two genes in the progeny of stem and progenitor cells that are transduced with a unique viral vector is desirable in certain situations. We tested the ability of two lentiviral vectors to transduce human cells of hematopoietic origin and concomitantly express two reporter genes, either EGFP (enhanced green fluorescent protein) and DsRed2, or EGFP and EYFP (enhanced yellow fluorescent protein), from two internal promoters. METHODS: The vectors were generated from the pTRIP deltaU3 EF1alpha EGFP lentiviral vector. Following transduction of hematopoietic and non-hematopoietic cell lines, we performed FACS, PCR and Southern blot analyzes to quantify transduction, integration efficiencies and size of integrated lentiviral vectors, respectively. RESULTS: The detection of DsRed2 fluorescence appeared unexpectedly low in human cells of hematopoietic origin. Alternatively, a modification in the flow cytometry assay allowed us to distinguish between the two overlapping fluorescence signals emitted by EGFP and EYFP, when transduced cells were excited with a 488-nm laser beam. However, the low frequency of double-positive EGFP+ EYFP+ cells, and the existence of single-positive, mostly EGFP- EYFP+, cells, prompted us to search for recombinations in the vector sequence. Southern blotting of DNA obtained from transduced cells indeed demonstrated that recombination had occurred between the two closely related EGFP and EYFP sequences. DISCUSSION: These observations suggest that recombination occurred within the EGFP and EYFP genes, which differ by only four amino acids. We conclude that the insertion of two highly homologous sequences into a lentiviral backbone can favor recombination.     

Live cell detection of caspase-3 activation by a Discosoma-red-fluorescent-protein-based fluorescence resonance energy transfer construct

A probe consisting of Discosoma red fluorescent protein (DsRed) and enhanced yellow fluorescent protein (EYFP) linked by a 19-amino-acid chain containing the caspase-3 cleavage site Asp-Glu-Val-Asp was developed to monitor caspase-3 activation in living cells. The expression of the tandem construct in mammalian cells yielded a strong red fluorescence when excited with 450- to 490-nm light or with a 488-nm argon ion laser line as a result of fluorescence resonance energy transfer (FRET) from donor EYFP to acceptor DsRed. The advantage over previous constructs using cyan fluorescent protein is that our construct can be used when excitation wavelengths lower than 488nm are not available. To validate the construct, murine HT-22 hippocampal neuronal cells were triggered to undergo CD95-induced neuronal death. An increase in caspase-3 activity was demonstrated by a reduction of FRET in cells transfected with the construct. This was manifested by a dequenching of EYFP fluorescence leading to an increase in EYFP emission and a corresponding decrease in DsRed fluorescence, which correlated with an increase in pro-caspase-3 processing. We conclude that CD95-induced caspase-3 activation in HT-22 cells was readily detected at the single-cell level using the DsRed-EYFP-based FRET construct, making this a useful technology to monitor caspase-3 activity in living cells.     

EFGP and DsRed expressing cultures of Escherichia coli imaged by confocal, two-photon and fluorescence lifetime microscopy

The green fluorescent protein (GFP) has become an invaluable marker for monitoring protein localization and gene expression in vivo. Recently a new red fluorescent protein (drFP583 or DsRed), isolated from tropical corals, has been described [Matz, M.V. et al. (1999) Nature Biotech. 17, 969-973]. With emission maxima at 509 and 583 nm respectively, EGFP and DsRed are suited for almost crossover free dual color labeling upon simultaneous excitation. We imaged mixed populations of Escherichia coli expressing either EGFP or DsRed by one-photon confocal and by two-photon microscopy. Both excitation modes proved to be suitable for imaging cells expressing either of the fluorescent proteins. DsRed had an extended maturation time and E. coli expressing this fluorescent protein were significantly smaller than those expressing EGFP. In aging bacterial cultures DsRed appeared to aggregate within the cells, accompanied by a strong reduction in its fluorescence lifetime as determined by fluorescence lifetime imaging microscopy.     

Two-wavelength fluorescence assay for DNA repair

A simple and reliable quantitative assay for measuring cellular DNA repair capacity has been developed. It is based on the host cell reactivation of the UV-irradiated plasmid pEGFP carrying the marker gene for the enhanced green fluorescent protein (EGFP). As a reference we used the plasmid pEYFP carrying the gene for a red-shifted fluorescent protein (EYFP). Both proteins can be excited by visible light with a maximum at 488 nm, but EGFP emits with a maximum at 509 nm, while EYFP emits with a maximum at 527 nm. This makes it possible to monitor the expression of the two genes simultaneously by measuring the fluorescence at two wavelengths. HEK293 cells were cotransfected with a mixture of UV-irradiated pEGFP and undamaged pEYFP. At different time intervals after transfection the fluorescence of EGFP was determined relative to the fluorescence of EYFP to compensate for any differences in the transfection efficiency or other experimental variables. It was used to calculate the number of UV lesions in DNA and hence the repair capacity of the host cells. It was found that HEK293 cells were able to repair approximately 1.4 UV lesions per 1000 nucleotides DNA for 12 h on the average.     

Cyclic AMP-dependent protein kinase binding to A-kinase anchoring proteins in living cells by fluorescence resonance energy transfer of green fluorescent protein fusion proteins.

A-kinase anchoring proteins tether cAMP-dependent protein kinase (PKA) to specific subcellular locations. The purpose of this study was to use fluorescence resonance energy transfer to monitor binding events in living cells between the type II regulatory subunit of PKA (RII) and the RII-binding domain of the human thyroid RII anchoring protein (Ht31), a peptide containing the PKA-binding domain of an A-kinase anchoring protein. RII was linked to enhanced yellow fluorescent protein (EYFP), Ht31 was linked to enhanced cyan fluorescent protein (ECFP), and these constructs were coexpressed in Chinese hamster ovary cells. Upon excitation of the donor fluorophore, Ht31.ECFP, an increase in emission of the acceptor fluorophore, RII.EYFP, and a decrease in emission from Ht31.ECFP were observed. The emission ratio (acceptor/donor) was increased 2-fold (p < 0.05) in cells expressing Ht31.ECFP and RII.EYFP compared with cells expressing Ht31P.ECFP, the inactive form of Ht31, and RII.EYFP. These results provide the first in vivo demonstration of RII/Ht31 interaction in living cells and confirm previous in vitro findings of RII/Ht31 binding. Using surface plasmon resonance, we also showed that the green fluorescent protein tags did not significantly alter the binding of Ht31 to RII. Thus, fluorescence resonance energy transfer can be used to directly monitor protein-protein interactions of the PKA signaling pathway in living cells.     

Use of a new violet-excitable AmCyan variant as a label in cell analysis

Here we report a new variant of AmCyan fluorescent protein that has been specifically designed for multicolor cell analysis. AmCyan is one of the existing violet fluorochromes for use in flow cytometers equipped with a violet (405 nm) laser. It is also widely used as a label in fluorescent spectroscopy. Limitations on its use are due to the significant AmCyan fluorescence spillover into the FITC detector, due to excitation of AmCyan by the blue (488 nm) laser. In order to resolve this problem, we modified the excitation profile of AmCyan. The new fluorescent protein that we developed, AmCyan100, has an emission profile similar to AmCyan with an emission maximum at 500 nm, but its excitation maximum is shifted to 395 nm, which coincides more closely with the violet laser line and decreases the excitation with the blue laser, thus reducing the spillover observed with the original AmCyan. Moreover, this new protein has a Stokes shift of more than 100 nm compared to the Stokes shift of 31 nm in its precursor. Our data also suggests that AmCyan100-mAb conjugates have brightness similar to AmCyan-mAb conjugates. In summary, AmCyan100 conjugates have minimum spillover into the FITC detector, and can potentially replace existing AmCyan conjugates in multicolor flow cytometry without any changes in instrumental setup and existing reagent panel design.     

Room temperature spectrally resolved single-molecule spectroscopy reveals new spectral forms and photophysical versatility of aequorea green fluorescent protein variants

It is known from ensemble spectroscopy at cryogenic temperatures that variants of the Aequorea green fluorescent protein (GFP) occur in interconvertible spectroscopically distinct forms which are obscured in ensemble room temperature spectroscopy. By analyzing the fluorescence of the GFP variants EYFP and EGFP by spectrally resolved single-molecule spectroscopy we were able to observe spectroscopically different forms of the proteins and to dynamically monitor transitions between these forms at room temperature. In addition to the predominant EYFP B-form we have observed the blue-shifted I-form thus far only seen at cryogenic temperatures and have followed transitions between these forms. Further we have identified for EYFP and for EGFP three more, so far unknown, forms with red-shifted fluorescence. Transitions between the predominant forms and the red-shifted forms show a dark time which indicates the existence of a nonfluorescent intermediate. The spectral position of the newly-identified red-shifted forms and their formation via a nonfluorescent intermediate hint that these states may account for the possible photoactivation observed in bulk experiments. The comparison of the single-protein spectra of the red-shifted EYFP and EGFP forms with single-molecule fluorescence spectra of DsRed suggest that these new forms possibly originate from an extended chromophoric pi-system analogous to the DsRed chromophore.     

Kinetic Analysis of Maturation and Denaturation of DsRed, a Coral-Derived Red Fluorescent Protein

The red fluorescent protein DsRed recently cloned from Discosoma coral, with its significantly red-shifted excitation and emission maxima (558 and 583 nm, respectively), has attracted great interest because of its spectral complementation to other fluorescent proteins, including the green fluorescent protein and its enhanced mutant EGFP. We demonstrated that the much slower DsRed fluorescence development could be described by a three-step kinetic model, in contrast to the fast EGFP maturation, which was fitted by a one-step model. At pH below 5.0 DsRed fluorescence gradually decreased, and the rate and degree of this fluorescence inactivation depended on the pH value. The kinetics of fluorescence inactivation under acidic conditions was fitted by a two-exponential function where the initial inactivation rate was proportional to the fourth power of proton concentration. Subsequent DsRed alkalization resulted in partial fluorescence recovery, and the rate and degree of such recovery depended on the incubation time in the acid. Recovery kinetics had a lag-time and was fitted minimally by three exponential functions. The DsRed absorbance and circular dichroism spectra revealed that the fluorescence loss was accompanied by protein denaturation. We developed a kinetic mechanism for DsRed denaturation that includes consecutive conversion of the initial state of the protein, protonated by four hydrogen ions, to the denatured one through three intermediates. The first intermediate still emits fluorescence, and the last one is subjected to irreversible inactivation. Because of tight DsRed tetramerization we have suggested that obligatory protonation of each monomer results in the fluorescence inactivation of the whole tetramer.     

Simultaneous flow cytometric analyses of enhanced green and yellow fluorescent proteins and cell surface antigens in doubly transduced immature hematopoietic cell populations

BACKGROUND: Cell transduction with multiple genes offers opportunities to investigate specific gene interactions on cell function. Detection of multiple transduced genes in hematopoietic cells requires strategies to combine measurements of gene expression with phenotypic cell discriminants. We describe simultaneous flow cytometric detection of two green fluorescent protein (GFP) variants in immunophenotypically defined human hematopoietic subpopulations using only a minor physical adjustment to a standard FACSCalibur. METHODS: The accuracy and sensitivity of enhanced GFP (EGFP) and enhanced yellow fluorescent protein (EYFP) detection in mixtures of transduced and nontransduced PG13 packaging cells were evaluated by flow cytometry. Retroviral vectors encoding EGFP or EYFP were used to transduce CD34(+) hematopoietic cells derived from umbilical cord blood. The transduction efficiency into subpopulations of hematopoietic cells was measured using multivariate flow cytometry. RESULTS: A bicistronic retroviral vector containing the EGFP and puromycin N-acetyltransferase (pac) genes afforded brighter EGFP signals in transduced cells than a retroviral vector encoding a pac-EGFP fusion protein. The sensitivity of detecting EGFP and EYFP-expressing cells among a background of nonexpressing cells was 0.01% and 0.05%, respectively. EGFP or EYFP was expressed in up to 95% of CD34(+) DR(-) or CD34(+) 38(-) subpopulations in cord blood 48 h posttransduction. Simultaneous transduction with EGFP and EYFP viral supernatants (1:1 mixture) led to coexpression of both GFP variants in 15% of CD34(+) DR(-) and 20% of CD34(+) 38(-) cells. CONCLUSIONS: These results demonstrate simultaneous detection of EGFP and EYFP in immunophenotypically discriminated human hematopoietic cells. This technique will be useful to quantify transduction of multiple retroviral constructs in discriminated subpopulations.     

Improved green and blue fluorescent proteins for expression in bacteria and mammalian cells

Fluorescent proteins have become an invaluable tool in cell biology. The green fluorescent protein variant EGFP is especially widely applied. Use of fluorescent proteins, including EGFP, however can be hindered by inefficient protein folding, resulting in protein aggregation and reduced fluorescence. This is especially profound in prokaryotic cells. Furthermore, EBFP, a blue fluorescent variant of EGFP, is rarely used because of its dim fluorescence and fast photobleaching. Thus, efforts to improve properties such as protein folding, fluorescence brightness, and photostability are important. Strongly enhanced green fluorescent (SGFP2) and strongly enhanced blue fluorescent (SBFP2) proteins were created, based on EGFP and EBFP, respectively. We used site-directed mutagenesis to introduce several mutations, which were recently shown to improve the fluorescent proteins EYFP and ECFP. SGFP2 and SBFP2 exhibit faster and more efficient protein folding and accelerated chromophore oxidation in vitro. For both strongly enhanced fluorescent proteins, the photostability was improved 2-fold and the quantum yield of SBFP2 was increased 3-fold. The improved folding efficiency reduced the extent of protein aggregation in Escherichia coli, thereby increasing the brightness of bacteria expressing SGFP2 7-fold compared to the brightness of those expressing EGFP. Bacteria expressing SBFP2 were 16-fold more fluorescent than those expressing EBFP. In mammalian cells, the improvements were less pronounced. Cells expressing SGFP2 were 1.7-fold brighter than those expressing EGFP, which was apparently due to more efficient protein expression and/or chromophore maturation. Mammalian cells expressing SBFP2 were 3.7-fold brighter than cells expressing EBFP. This increase in brightness closely resembled the increase in intrinsic brightness observed for the purified recombinant protein. The increased maturation efficiency and photostability of SGFP2 and SBFP2 facilitate detection and extend the maximum duration of fluorescence imaging.     

Three-color flow cytometry analysis of tricistronic expression of eBFP, eGFP, and eYFP using EMCV-IRES linkages.

BACKGROUND: The ability to quickly analyze and sort double or triple fluorescent reporter constructs using simultaneous analysis provides significant flexibility in the solution of analytical and process-related questions in biotechnology. METHODS: Bicistronic eBFP/eGFP and eBFP/eYFP constructs were made on two mammalian episomal plasmids using an internal ribosomal entry sequence from encephalomyocarditis virus (EMCV-IRES) to link two GFP expressions. Simultaneous two-color flow cytometry (FCM) analysis was accomplished using a dual Argon-laser multi-line configuration set at excitation wavelengths of 360 and 488 nm. Blue fluorescence emission (440 nm) and green fluorescence emission (507 nm) were detected using 405/20 (FL4) and 510/20 (FL1) bandpass filters. Dual eBFP/eYFP and three-color simultaneous analysis of eBFP/eGFP/eYFP was accomplished using the dual-laser configuration but also using a short-pass (525-nm) dichroic mirror and 550/30 bandpass filter configuration to detect yellow fluorescence emission (527 nm) in a third channel (FL2). RESULTS: Human 293 cells transfected with the bicistronic construct of eBFP-IRES-eGFP were easily detected using simultaneous analysis, and the signals were well separated with a mean blue fluorescent intensity (MFI) in the 2nd-log decade (FL4) and green MFI in the 4th-log decade (FL1). Likewise, eBFP-IRES-eYFP transfected cells were as easily detected and also demonstrated very good signal separation. A tricistronic construct of eBFP-IRES-eGFP-IRES-eYFP was also made and transfected into 293 cells. Triple-color fluorescent cells were easily detected using the cytometer configuration for simultaneous analysis. All three signals separated with only moderate compensation required for green and yellow emission spectra. The respective MFI for each of the fluorescent proteins was correlative to what had been observed with the separate bicistronic constructs. CONCLUSIONS: Our results demonstrate that we have developed a novel fluorescent flow cytometry method that can be used as a powerful tool to differentiate and analyze three colors simultaneously from either a dual or a triple cistronic construct which has been transfected into living cells.     

Resonance energy transfer in a calcium concentration-dependent cameleon protein

We report investigations of resonance energy transfer in the green fluorescent protein and calmodulin-based fluorescent indicator constructs for Ca(2+) called cameleons using steady-state and time-resolved spectroscopy of the full construct and of the component green fluorescent protein mutants, namely ECFP (donor) and EYFP (acceptor). EYFP displays a complicated photophysical behavior including protonated and deprotonated species involved in an excited-state proton transfer. When EYFP is excited in the absorption band of the protonated species, a fast nonradiative deactivation occurs involving almost 97% of the excited protonated population and leading to a low efficiency of excited-state proton transfer to the deprotonated species. ECFP displays a multiexponential fluorescence decay with a major contributing component of 3.2 ns. The time-resolved fluorescence data obtained upon excitation at 420 nm of Ca(2+)-free and Ca(2+)-bound YC3.1 cameleon constructs point to the existence of different conformations of calmodulin dependent on Ca(2+) binding. Whereas steady-state data show only an increase in the efficiency of energy transfer upon Ca(2+) binding, the time-resolved data demonstrate the existence of three distinct conformations/populations within the investigated sample. Although the mechanism of the interconversion between the different conformations and the extent of interconversion are still unclear, the time-resolved fluorescence data offer an estimation of the rate constants, of the efficiency of the energy transfer, and of the donor-acceptor distances in the Ca(2+)-free and Ca(2+)-bound YC3.1 samples.     

Simultaneous detection of bacteria expressing GFP and DsRed genes with a flow cytometer

BACKGROUND: In this study, Escherichia coli cells producing red fluorescent protein of Discosoma sp. (drFP583 DsRed) were investigated with flow cytometry by using 488 nm excitation. We also studied whether green fluorescent protein (GFP) and drFP583 could be detected simultaneously from a single bacterial cell. METHODS: Plasmids pDsRed and pEGFP were used for the production of drFP583 and enhanced GFP, respectively, in E. coli MC1061 cells. To produce enhanced GFP and drFP583 simultaneously, plasmids pG9R and pG19R were constructed. These encode tandem fusions of enhanced GFP and drFP583 to ensure similar production levels for both proteins. RESULTS: Bacteria producing enhanced GFP and drFP583 were found to be brightly green and red fluorescent, respectively. Production of enhanced GFP and drFP583 fusion proteins resulted in bacteria that emitted both green and red fluorescence, which was detected easily by a flow cytometer using single laser excitation. Previously reported tetramerization of drFP583 did not restrict its use as a reporter gene, although it maturated significantly slower than enhanced GFP. CONCLUSIONS: The results show that enhanced GFP and drFP583 proteins can be detected simultaneously from single bacteria with a standard flow cytometer with simple optical configuration.     

Intelligent yeast strains with the ability to self-monitor the concentrations of intra- and extracellular phosphate or ammonium ion by emission of fluorescence from the cell surface

Saccharomyces cerevisiae strains that respond to environmental changes and transmit the information by emission of fluorescence from the cell surface were constructed. The technique of cell surface engineering enabled the yeast cells to display enhanced cyan blue fluorescent protein (ECFP) or enhanced yellow fluorescent protein (EYFP) on the surface under the control of promoters that sense environmental changes. Two model promoters were examined in this study. For monitoring the intra- and extracellular concentrations of phosphate ion, the PHO5 promoter was chosen to display ECFP. The MEP2 promoter was used to display EYFP to sense the concentrations of ammonium ion. Fluorescence was observed by fluorescence microscopy and immunofluorescence microscopy, and the intensity was measured by a flow cytometer. The relationship between ion concentration inside and outside the cells was evaluated by the change in the rate of fluorescence. This S. cerevisiae system enables environmental changes to be transmitted as intra- and extracellular information using a suitable promoter functioning at real time and in a non-invasive manner.     

增强型青色荧光蛋白慢病毒表达载体的构建

目的：通过多点突变构建增强型青色荧光蛋白（ECFP）慢病毒表达载体。方法与结果：根据增强型绿色荧光蛋白（EGFP）和ECFP基因序列的差异设计3对引物,以pLentiLox3.7-EGFP为模板进行分段PCR扩增,再以分段PCR扩增产物为模板扩增出突变的ECFP基因片段,将其与载体连接,得到ECFP慢病毒表达载体pLentiLox3.7-ECFP,测序结果证实经过多点突变扩增的ECFP片段基因序列完全正确;磷酸钙介导pLentiLox3.7-ECFP在293T细胞中表达,48h后在荧光显微镜下观察到青色荧光蛋白。结论：通过多点突变的方法得到了ECFP慢病毒表达载体。     

A new pair for inter- and intra-molecular FRET measurement

Fluorescence resonance energy transfer between mutant green fluorescent proteins provides powerful means to monitor in vivo protein-protein proximity and intracellular signaling. However, the current widely applied FRET pair of this class (CFP/YFP) requires excitation by expensive UV lasers, thereby hindering FRET imaging on many confocal microscopes. Further challenges arise from the large spectral overlap of CFP/YFP emission. Another FRET pair GFP/DsRed could obviate such limitations. However, the use of DsRed as a FRET acceptor is hampered by several critical problems, including a slow and incomplete maturation and obligate tetramerization. A tandem dimer mutant of DsRed (TDimer2) has similar spectral properties as those of DsRed. The rapid maturation and non-oligomerization make TDimer2 a promising substitute for DsRed in FRET experiments. Here, we have explored the possibility of using TDimer2 as a FRET acceptor for the donor EGFP. FRET was demonstrated between the EGFP-TDimer2 chimeric fusion protein. By substituting CFP/YFP in the Ca2+-sensor cameleon with EGFP/TDimer2, dynamic changes in cytosolic free Ca2+ concentrations were observed with 488nm excitation under conventional wide-field microscopy. The EGFP/TDimer2 pair was further successfully employed to monitor inter-molecular interaction between Syntaxin and SNAP25. These results reveal EGFP/TDimer2 as a promising FRET pair in monitoring intra-molecular conformation change as well as inter-molecular interaction.     

A new multiparameter flow cytometer: optical and electrical cell analysis in combination with video microscopy in flow

BACKGROUND: Flow cytometers, which are commercially available, do not necessarily meet all demands of actual biomedical research. This is the case for the investigation of mechanisms involved in cell volume regulation, which requires electrical volume measurement and ratiometric multichannel fluorescence analysis for the simultaneous assessment of different physiologic parameters (intracellular pH and the intracellular concentration of calcium ions, etc). METHODS AND RESULTS: We describe the construction of a new nonsorting flow cytometer designed for the simultaneous acquisition of seven parameters including fluorescence signals, forward and perpendicular light scatter, cell volume according to the electrical Coulter principle, and flow cytometric imaging. The instrument is equipped with three different light sources. A tunable argon-ion laser generates efficient excitation of the most standard fluorescent probes in the visible spectral range, and an arc lamp provides the means for ultraviolet excitation at low cost. Because of the spatial filtering by the excitation and detection optics, two independent sets of dual fluorescence measurements can be performed, a prerequisite for flexible ratiometric fluorescence analysis. A flow video microscope integrated into the optical system optionally generates either brightfield or phase images of selected flowing particles. Only particles whose individual datasets meet predefined gating conditions are imaged in real time. To avoid smear effects, the motion of the object to be imaged (speed approximately 8 m/s) is frozen on the target of a CCD camera by flash illumination. For this purpose, a high radiance gas discharge lamp with 25-mJ electric pulse energy provides an illumination time of 18 ns (full width half maximum). Test results obtained from latex spheres and cells are shown. CONCLUSIONS: Test results indicate that our instrument can perform Coulter measurements in combination with flexible optical analysis. Moreover, integration of an adapted video microscope into a flow cytometer is an approach to overcome the gap between flow and image cytometry.