Flow cytometric detection and quantification of heterotrophic nanoflagellates in enriched seawater and cultures

A flow cytometric protocol to detect and enumerate heterotrophic nanoflagellates (HNF) in enriched waters is reported. At present, the cytometric protocols that allow accurate quantification of bacterioplankton cannot be used to quantify protozoa for the following reasons: i) the background produced by the bacterial acquisitions does not allow the discrimination of protozoa at low abundance, ii) since the final protozoan fluorescence is much higher than the bacterioplankton fluorescence (more than 35 fold) the protozoa acquisitions lie outside the range. With an increase in the fluorescence threshold and a reduction of the fluorescence detector voltage, low fluorescence particles (bacteria) are beneath the detection limits and only higher fluorescence particles (most of them heterotrophic nanoflagellates) are detected. The main limitation for the application of the cytometric protocol developed is that a ratio of bacteria/HNF below 1000 is needed. At higher ratios, the background of larger cells of bacterioplankton makes it difficult to discriminate protozoa. The proposed protocol has been validated by epifluorescence microscopy analyzing both a mixed community and two single species of HFN: Rhynchomonas nasuta and Jakoba libera. Taking into account the required bacteria/HNF ratio cited above, the results provide evidence that the flow cytometric protocol reported here is valid for counting mixed communities of HNF in enriched seawater and in experimental micro or mesocosms. In the case of single species of HNF previous knowledge of the biological characteristics of the protist and how they can affect the effectiveness of the flow cytometric count is necessary.     

Improved method for measuring intracellular Ca++ with fluo-3

The accuracy of flow cytometric measurement of intracellular calcium with fluo-3 is compromised by variation in basal fluorescence intensity due to heterogeneity in dye uptake or compartmentalization. We have loaded cells simultaneously with fluo-3 and SNARF-1. When SNARF-1 fluorescence is collected at approximately 600 nm, its intensity does not change upon cell activation. Furthermore, fluo-3 and SNARF-1 fluorescence signals exhibit a linear relationship. The ratio of fluo-3 to SNARF-1 eliminates a significant proportion of variation in fluorescence intensity caused by variation in fluo-3 uptake and thus can be used as a sensitive parameter for measuring changes in [Ca2+]i.     

2-NBDG as a fluorescent indicator for direct glucose uptake measurement

Evaluation of glucose uptake ability in cells plays a fundamental role in diabetes mellitus research. In this study, we describe a sensitive and non-radioactive assay for direct and rapid measuring glucose uptake in single, living cells. The assay is based on direct incubation of mammalian cells with a fluorescent d-glucose analog 2-[N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl) amino]-2-deoxy-D-glucose (2-NBDG) followed by flow cytometric detection of fluorescence produced by the cells. A series of experiments were conducted to define optimal conditions for this assay. By this technique, it was found that insulin lost its physiological effects on cells in vitro meanwhile some other anti-diabetic drugs facilitated the cell glucose uptake rates with mechanisms which likely to be different from those of insulin or those that were generally accepted of each drug. Our findings show that this technology has potential for applications in both medicine and research.     

A rapid detection method for apoptosis and necrosis measurement using the Cellometer imaging cytometry

Apoptosis and necrosis play an important role in various aspects of preclinical pharmaceutical drug discovery and validation. The ability to quickly determine the cytotoxic effect of chemical compounds on cancer cells allows researchers to efficiently identify potential drug candidates for further development in the pharmaceutical discovery pipeline. Recently, a new imaging cytometry system has been developed by Nexcelom Bioscience LLC (Lawrence, MA, USA) for fluorescence-based cell population analysis. Currently, fluorescence-based cell death assays have not been demonstrated by the Cellometer system, which can potentially provide a quick, simple, and inexpensive alternative method for smaller biomedical research laboratories. In this study, we demonstrate for the first time the use of Cellometer imaging cytometry for necrosis/apoptosis detection by studying the dose–response effect of heat and drug-induced cell death in Jurkat cells labeled with annexin V-FITC (apoptotic) and propidium iodide (necrotic). The experimental results were evaluated to validate the imaging cytometric capabilities of the Cellometer system as compared to the conventional flow cytometry. Similar cell population results were obtained from the two methods. The ability of Cellometer to rapidly and cost-effectively perform fluorescent cell-based assays has the potential of improving research efficiency, especially where a flow or laser scanning cytometer is not available or in situations where a rapid analysis of data is desired.     

Flow cytometric detection of p53 protein after incubation of a pre-B cell line with antitumor agents

BACKGROUND: The study of new substances capable of counteracting tumor development has focused, in recent years, on several of the steps in a cell's initiation of the process of apoptosis. One of the crucial events is the activation of p53, leading to a cell cycle G1/S block or to programmed cell death. METHODS: We report here a parallel flow cytometric method for semiquantitative detection of p53 protein and apoptosis (percent of apoptotic cells) in a pre-B leukemic cell line (NALM-6) exposed to various antitumor agents (2.35 microg/ml etoposide; 0.175 microg/ml FCE296; 0.4 microg/ml FCE624; and 1.5 microg/ml L-PAM). RESULTS: All of the substances proved to be capable of inducing an increase of p53 after 16 or 24 h of incubation. In all experiments with antitumor agents we also found an onset of apoptosis after 24 h of incubation with the substance, as determined by the annexin V flow cytometric assay and by DNA fragmentation. CONCLUSIONS: This technique, based on flow cytometric data of both p53 intracellular content and percentage of apoptotic cells, is suitable to determine the amount of antitumor agent needed to induce p53, and thus to dose the drug in relation to the sensitivity of a defined tumor as well as choose the more efficacious drug, depending on cell responsiveness. The study of antitumor substances that induce apoptosis, bypassing p53, could also be evaluated by this method, in view of the development of substances for the treatment of p53-mutated tumors.     

New Insights into the Translocation Route of Enrofloxacin and Its Metalloantibiotics

Probing drug/lipid interactions at the molecular level represents an important challenge in pharmaceutical research, drug discovery and membrane biophysics. Previous studies showed that enrofloxacin metalloantibiotic has potential as an antimicrobial agent candidate, since it exhibits antimicrobial effect comparable to that of free enrofloxacin but a different translocation route. These differences in uptake mechanism can be paramount in counteracting bacterial resistance. In view of lipids role in bacterial drug uptake, the interaction of these compounds with different Escherichia coli model membranes were studied by fluorescence spectroscopy. Partition coefficients determined showed that lipid/antibiotic interactions were sensitive to liposomes composition and that the metalloantibiotic had a higher partition than free enrofloxacin. These results corroborate the different mechanism of entry proposed and can be rationalized on the basis that an electrostatic interaction between the metalloantibiotic positively charged species, present at physiological pH, and the lipids negatively charged head groups clearly promotes the lipid/antimicrobial association.     

Intracellular distribution of anthracyclines in drug resistant cells

The unresponsiveness of multidrug resistant tumor cells to antineoplastic chemotherapy is often associated with reduced cellular drug accumulation accomplished by overexpressed transport molecules. Moreover, intracellular drug distribution in resistant cells appears to be remarkably different when compared to their wild type counterparts. In the present paper, we report observations on the intracellular accumulation and distribution of doxorubicin, an antitumoral agent widely employed in chemotherapy, in sensitive and resistant cultured tumor cells. The inherent fluorescence of doxorubicin allowed us to follow its fate in living cells by laser scanning confocal microscopy. This study included flow cytometric analysis of drug uptake and efflux and analysis of the presence of the well known drug transporter P-glycoprotein. Morphological, immunocytochemical and functional data evidentiated the Golgi apparatus as the preferential intracytoplasmic site of drug accumulation in resistant cells, capable of sequestering doxorubicin away from the nuclear target. Moreover, P-glycoprotein has been found located in the Golgi apparatus in drug induced resistant cells and in intrinsic resistant cells, such as melanoma cells. Thus, this organelle seems to play a pivotal role in the intracellular distribution of doxorubicin. This revised version was published online in August 2006 with corrections to the Cover Date.     

Flow cytometric, phase-resolved fluorescence measurement of propidium iodide uptake in macrophages containing phagocytized fluorescent microspheres

BACKGROUND: Spectral interference (overlap) from phagocytosed green-yellow (GY) microspheres in the flow cytometric, red fluorescence emission measurement channel causes errors in quantifying damaged/dead alveolar macrophages by uptake of propidium iodide. METHODS: Particle burdens of uniform GY fluorescent microspheres phagocytosed by rat alveolar macrophages and the discrimination of damaged/dead cells as indexed by propidium iodide uptake were assessed with conventional and phase-sensitive flow cytometry. RESULTS: The fluorescence spectral emission from phagocytosed microspheres partly overlapped the propidium iodide red fluorescence emission and interfered with the measurement of damaged/dead cells when using conventional flow cytometry without subtractive compensation. This caused errors when estimating the percentage of nonviable, propidium iodide-positive, phagocytic macrophages. The interference was eliminated by employing phase-sensitive detection in the red fluorescence measurement channel based on differences in fluorescence lifetimes between the fluorescent microspheres and propidium iodide. Intrinsic cellular autofluorescence, whose fluorescence lifetime is approximately the same as that of the phagocytosed microspheres, also was eliminated in the phase-sensitive detection process. Because there was no detectable spectral interference of propidium iodide in the green fluorescence (phagocytosis) measurement channel, conventional fluorescence detection was employed. CONCLUSIONS: Phase-resolved, red fluorescence emission measurement eliminates spectral overlap errors caused by autofluorescent phagocytes that contain fluorescent microspheres in the analyses of propidium iodide uptake.Cytometry 39:45-55, 2000. Published 2000 Wiley-Liss, Inc.     

Analysis of sperm cell viability, acrosomal integrity, and mitochondrial function using flow cytometry

A triple staining procedure was developed to evaluate bull spermatozoa using flow cytometry. Flow cytometric estimates of cell viability, measured by propidium iodide (PI) exclusion, and acrosomal integrity, measured by Pisum sativum agglutinin (PSA) binding acrosomal contents, were equivalent to estimates made by using standard laboratory assays. Mitochondrial function, measured by rhodamine 123 (R123) fluorescence, was depressed by the mitochondrial inhibitors rotenone (64%) or monensin (52%), establishing that mitochondrial damage can be detected. Dilauroylphosphatidylcholine (PC12) or lysophosphatidylcholine (LPC) was used to destabilize sperm membranes. When challenged with 15-30 microM PC12, selective exposure of PSA binding sites occurred without induction of PI uptake or loss of R123 staining. However, PC12 concentrations greater than 60 microM resulted in a loss of R123 fluorescence intensity. In contrast, greater than 1200 microM LPC was required to expose PSA binding sites, which also resulted in PI uptake. By using flow cytometry, these three stains in combination can be used to correlate three different features simultaneously on individual spermatozoa and assay thousands of cells per sample without extensive preparation.     

Peculiarities of the interaction between vincristine and blood serum

The results of a study of the interaction between the pharmaceutical anticancer drug vincristine and blood serum are presented. It is shown that an increase in drug concentration is associated with a concomitant decrease in the extinction coefficient of the solute from blood serum. As the drug concentration changes, its fluorescence spectra transform; the fluorescence maximum of vincristine in blood serum is shifted to 314 and 334 nm. This can be the result of conformational changes in the vincristine molecule after the vincristine–blood protein interaction. At the same time, the fluorescence maximum at 360 nm, which can be explained by the fluorescence emission of the aromatic ring of vincristine, remains at the same level after an increase in the drug dose. These results can be useful in medicine for further investigation of the antimitotic activity of vincristine and test dosing of other pharmacological preparations during therapy.     

Rapid detection of mutagen induced micronucleated erythrocytes by flow cytometry

Summary The micronucleus test is a cytogenetic method for the screening of mutagens and carcinogens which exhibit clastogenic mechanisms of action. After application of clastogenic agents chromosomal fragments or even whole chromsomes can remain as conspicuous structures (micronuclei) in a small fraction of anucleated polychromatic erythrocytes which can be visually scored using a microscope following staining with May-Grünwald-Giemsa solutions. These time-consuming, painstaking, and tedious manual evaluations are often sources of unreliability and uncertainty. Here, a fluorescence technique is presented which applies DNA and protein fluorochromes to discriminate normal anucleated erythrocytes from micronucleated erythrocytes using a fluorescence microscope. This method is particularly tailored to be applied to flow cytometric instrumentation. Data obtained manually and automatically in flow show a strong linear correlation with high significance (r=0.96) as far as the percentage of micronucleated erythrocytes as an indicator for the mutagenicity of a given drug is concerned. These results have been obtained by means of the established clastogens cyclophosphamide and mitomycin C.     

Flow cytometric monitoring of glutathione content and anthracycline retention in tumor cells.

We have used an enzymatic (spectro-photometric) and a flow cytometric (GSH-MBCL) method to compare the glutathione (GSH) content of doxorubicin sensitive (P388) and resistant (P388/R-84) murine leukemic and human lung cancer cells. The flow cytometric analysis revealed that GSH-MBCL conjugate formation was dependent on glutathione-S-transferase (GST) activity. The human solid tumor cell lines exhibited extensive heterogeneity, high GSH content, and GST activity. In contrast to the enzymatic method, the flow cytometric method did not accurately reflect the 95% reduction in GSH content of cells treated for 24 h with 100 microM BSO. Possible reaction of MBCL with other sulfhydryl groups (other than GSH) in BSO-treated cells may be responsible for this discordance. We have also shown the feasibility of using dual parameter flow cytometry to monitor cellular anthracycline (daunorubicin) retention and GSH-MBCL conjugate fluorescence in human tumor cells. These two parameters, which measure drug retention and cellular detoxification, are believed to be the important determinants of chemoresistance in tumor cells.     

Plant natural products: Back to the future or into extinction?

Natural product substances have historically served as the most significant source of new leads for pharmaceutical development. However, with the advent of robotics, bioinformatics, high throughput screening (HTS), molecular biology-biotechnology, combinatorial chemistry, in silico (molecular modeling) and other methodologies, the pharmaceutical industry has largely moved away from plant derived natural products as a source for leads and prospective drug candidates. Can, or will, natural products ever recapture the preeminent position they once held as a foundation for drug discovery and development? The challenges associated with development of natural products as pharmaceuticals are illustrated by the Taxol^® story. Several misconceptions, which constrain utilization of plant natural products, for discovery and development of pharmaceuticals, are addressed to return natural products to the forefront.     

Characterization of human monocytic cell line, U937, in taking up acetylated low-density lipoprotein and cholesteryl ester accumulation. A flow cytometric and HPLC study

The uptake of LDL and acetylated LDL and the ability of cholesteryl ester accumulation by cells of a human monocytic cell line, U937, has been characterized by flow cytometric assay using a fluorescent probe, DiI, and by high-performance liquid chromatography (HPLC). The increase of mean fluorescence intensity of U937 incubated with DiI-labeled lipoproteins demonstrates that this cell line could incorporate DiI-AcLDL, as well as DiI-labeled LDL. Competition and saturation studies indicate that the manner of taking up DiI-AcLDL is receptor-mediated. While differentiated U937 incubated with 16 nM phorbol myristate acetate for 24 h took up little DiI-AcLDL, HPLC analysis confirmed that intracellular free and esterified cholesterols significantly increase in the U937 cells incubated with AcLDL or LDL. The ability of mouse peritoneal macrophage to abundantly accumulate at least five kinds of cholesteryl ester were also shown in this analysis. In contrast, in U937 cells, free fatty acids are incorporated into various substances rather than into cholesteryl esters (as revealed by HPLC analysis), so that the cholesterol in AcLDL taken up by U937 cells is not synthesized into cholesteryl esters to any great extent.     

Fluorescence imaging of lipid peroxidation in isolated rat lungs during nonhypoxic lung ischemia

We have shown previously that ischemia results in reactive oxygen species production by lung endothelium that occurs within 3-5 s after flow cessation and is followed by lipid peroxidation at 15-30 min as determined by assay of thiobarbituric acid-reactive substances, conjugated dienes, and protein carbonyls in lung homogenate. The present study evaluated membrane lipid peroxidation in isolated, ventilated rat lungs using a fluorescence imaging method that permits continuous observation of pulmonary subpleural microvascular endothelial cells in situ. Diphenyl-1-pyrenylphosphine (DPPP), a fluorescent probe which localizes in the plasma membrane and shows increased fluorescence emission after its oxidation by lipid hydroperoxides, was used for detection of membrane lipid peroxidation. Compared to continuously perfused control lungs, endothelial cell DPPP fluorescence increased significantly within 1 min of ischemia (i.e., flow cessation); these changes were prevented by pretreatment with 0.5 mM alpha-tocopherol succinate (vitamin E) added to the perfusate. Increased DPPP fluorescence was confirmed by spectrofluorometry of lipid extracts of lung homogenates. These data indicate that DPPP can be used for the real-time detection of lipid peroxidation in an intact organ. Ischemia results in peroxidation of the pulmonary microvascular endothelial cell membrane and this insult can be detected as early as 1 min after the onset of ischemia compatible with a radical-mediated process.     

Multiparameter flow cytometric approach for simultaneous evaluation of T lymphocyte-endothelial cell interactions.

Since vascular endothelium is now recognized as an immunologically active tissue, a better understanding of the relationship between endothelial cells and T lymphocytes is critical to the field of solid organ transplantation. Investigations of endothelial cell-T cell interactions have been limited by methodology. We developed a flow cytometric method allowing for concurrent investigation of multiple cell populations within the same culture that can be applied to these complex interactions. Allogeneic CD8+ or CD4+ T cells labeled with 5,6-carboxyfluorescein diacetate succinimidyl ester (CFSE) were added to a murine endothelial cell monolayer, in which endothelial proliferation was not inhibited by irradiation or addition of a cell cycle-blocking agent. At specific time points, the coculture was analyzed by flow cytometry. T-cell proliferation could be detected by gating on the T-cell subset and evaluating the CFSE fluorescence peaks. By directly analyzing cellular division, we minimized erroneous interpretation of the data encountered by previous studies, which utilized (3)H-thymidine incorporation as sole measure of proliferation. Further subgating on cells that divided facilitated the study of CD8+ lymphocyte activation, differentiation, and acquisition of effector function. By gating on the endothelial cell population, phenotypic changes such as upregulation of surface MHC molecules or immune-mediated apoptosis could be detected. In conclusion, we present a flow cytometric approach that could have important applications for clinical immunological monitoring in allogeneic or xenogeneic transplantation, and might provide the requisite information to better tailor immunotherapy to prevent chronic rejection.     

Discrimination of respiratory dysfunction in yeast mutants by confocal microscopy, image, and flow cytometry

Living yeast cells can be selectively stained with the lipophilic cationic cyanine dye DiOC6(3) in a mitochondrial membrane potential-dependent manner. Our study extends the use of flow cytometric analysis and sorting to DiOC6(3)-stained yeast cells. Experimental conditions were developed that prevented the toxic side effect of the probe and gave a quantitative correlation between fluorescence and mitochondrial membrane potential, without any staining of other membranes. The localization of the fluorochrome was checked by confocal microscopy and image cytometry. The mitochondrial membrane alterations were also tested through cardiolipin staining with nonyl acridine orange. Differences in light scattering and in fluorescence were detected in mutants (rho-, rho degrees, mit-, or pet-) and wild-type (rho+mit+) populations of yeast. The dye uptake of respiratory-deficient yeast strains was significantly reduced as compared to that of the wild-type. Application of an uncoupler (mCICCP), which collapsed the mitochondrial membrane potential (alphapsi(m)), led to a drastic reduction of the dye uptake. It was observed that a decrease in deltapsi(m), was usually correlated with a decrease in cardiolipin stainability by nonyl acridine orange (NAO). Quantitative flow cytometry is a fast and reproducible technique for rapid screening of yeast strains that might be suspected of respiratory dysfunction and/or mitochondrial structural changes. We give evidence that it is an adequate method to characterize and isolate respiratory mutants through sorting procedure, with selective enrichment of the population studied in respiring or non-respiring yeast cells. Confocal microscopy and image cytometry corroborate the flow cytometry results.     

Isolation of highly pure and viable primordial germ cells from rainbow trout by GFP-dependent flow cytometry

A highly pure and viable primordial germ cell (PGC) population appears to be an essential tool for establishing a cell line that can differentiate into a germ cell lineage and for studying the molecular biology and biochemistry of fish PGCs. Therefore, the aim of the present study was to establish a flow cytometric method for isolating highly pure and viable PGCs. As the material for PGC isolation, we used transgenic rainbow trout possessing the green fluorescent protein (GFP) gene driven by trout vasa-gene regulatory sequences (pvasa-GFP). Four independent transgenic strains were subjected to fluorescence microscopy and GFP-dependent flow cytometric analyses. We found that some of the pvasa-GFP transgenic strains exhibited ectopic background green fluorescence in the somatic cells aside from strong fluorescence in PGCs. Although flow cytometric analysis of genital ridge somatic cells in the four pvasa-GFP transgenic strains revealed a wide range of GFP intensities, we proved that somatic cell contamination of the GFP-positive cell population was markedly reduced if transgenic strains without the ectopic background green fluorescence were used. In addition, the forward light-scattering (FS) property, which is an indication of relative cell size, and the side light-scattering (SS) property, which is determined by cell shape and granularity, were employed to remove non-PGC contaminants from the GFP-positive cell population. By isolating GFP-positive cells with high FS/SS values, we were able to effectively remove cell blebs and the apoptotic fraction. Consequently, the purities and survival rates of isolated PGCs were greatly improved compared with those using GFP intensity as a single indicator. Thus, our flow cytometric method, in combination with the selection of suitable transgenic strains without the ectopic background green fluorescence, is capable of isolating highly pure and viable PGCs from rainbow trout. By using this method in combination with cell-cryopreservation and cell transplantation techniques, the isolated PGCs may also be used for preserving the genetic resources of endangered fish species and domesticated fish strains carrying commercially valuable traits. Mol. Reprod. Dev. 67: 91-100, 2004.     

Identification and quantification of suspended algae and bacteria populations using flow cytometry: applications for algae biofuel and biochemical growth systems

Species diversity in algae biofuel and biochemical culturing systems can affect yield; in many large-scale algae growth systems, it is not practical to maintain a monoculture. To better understand and monitor these complex systems, techniques are required which can quickly and effectively quantify the species distribution and overall growth of a mixed microbial community in suspension. A flow cytometric method has been developed which can be used to differentiate populations of three Chlorophyta species, one diatom species, cyanobacteria, and heterotrophic bacteria according to their fluorescence and morphology. The nucleic acid stain SYTO9 was used to discriminate species with similar natural autofluorescence and to identify heterotrophic bacteria. Absolute cell enumeration was performed with counting beads and validated with a hemocytometer. Species identification was validated by analyzing known mixtures of axenic cell cultures. The utility of the method was demonstrated by studying the effect of light intensity on species succession, growth, and biomass accumulation in small algae growth systems over 22 days. Flow cytometric analysis, augmented with SYTO9 stain and counting beads, can be utilized to monitor algae biofuel and biochemical growth systems involving multiple species. This method allows for monitoring of contamination, succession, and overall growth in both natural and intentionally created microbial communities.     

Solubilization and display of G protein-coupled receptors on beads for real-time fluorescence and flow cytometric analysis

G protein-coupled receptors (GPCR) and cellular signaling elements are prime targets for drug discovery. Sensitive real-time methods that expand the analytical capabilities for these elements can play significant roles in basic research and drug discovery. Here, we describe novel approaches for the real-time fluorescence analysis of GPCRs. Using the G protein-coupled N-formyl peptide receptor (FPR) as a model system in concert with a fluorescent ligand, we showed the quantitative solubilization of his-tagged FPRs in 1% dodecyl maltoside. Solubilized receptors reconstitute in dodecyl maltoside with a mixture of bovine brain Gi/Go showing an apparent Kd of 100 nM. Solubilized receptors were also bound to Ni(2+)-silica particles and were detected in a flow cytometer by the binding of fluorescent ligand. The efficiency of receptor uptake by the particles was in excess of 80% with an apparent affinity for the bead in the nM range. The receptors had largely homogeneous dissociation characteristics, an appropriate Kd for the ligand in the low nM range and a high site number, with several million receptor molecules per particle. However, the G protein reconstitution was not detected on the beads, apparently for steric reasons. These approaches for displaying receptors could prove useful in drug discovery and in the analysis of the molecular assemblies in signal transduction.