Morphological and Physiological Characterization of Listeria monocytogenes Subjected to High Hydrostatic Pressure

High hydrostatic pressure is a new food preservation technology known for its capacity to inactivate spoilage and pathogenic microorganisms. That inactivation is usually assessed by the number of colonies growing on solid media after treatment. Under normal conditions the method does not permit recovery of damaged cells and may underestimate the number of cells that will remain viable and grow after a few days in high-pressure-processed foodstuffs. This study investigated the damage inflicted on Listeria monocytogenes cells treated by high pressure for 10 min at 400 MPa in pH 5.6 citrate buffer. Under these conditions, no cell growth occurred after 48 h on plate count agar. Scanning electron microscopy, light scattering by flow cytometry, and cell volume measurements were compared to evaluate the morphological changes in cells after pressurization. All these methods revealed that cellular morphology was not really affected. Esterase activity, as assessed either by enzymatic activity assays or by carboxy fluorescein diacetate fluorescence monitored by flow cytometry, was dramatically lowered, but not totally obliterated, under the effects of treatment. The measurement of propidium iodide uptake followed by flow cytometry demonstrated that membrane integrity was preserved in a small part of the population, although the membrane potential measured by analytical methods or evaluated by oxonol uptake was reduced from −86 to −5 mV. These results showed that such combined methods as fluorescent dyes monitored by flow cytometry and physiological activity measurements provide valuable indications of cellular viability.     

Oligonucleotide biological activity: Relationship to the cell cycle and nuclear transport

Previous studies suggest that oligodeoxynucleotide (ODN) cellular uptake is cell cycle-dependent which may have important implications in cancer cell targeting. To further our understanding of ODN transport and activity, this study examines the relationships between the cell cycle, ODN cellular uptake, intracellular transport, and activity. An antisense c-myc ODN 21-mer was used to study ODN cellular uptake in Rauscher erythroleukemia cells synchronized by either chemical methods or flow cytometry. ODN uptake was examined using subcellular fractionation and confocal fluorescence microscopy. Western blot analysis was used to measure ODN-mediated decreases in c-myc protein levels. Intracellular ODN distribution and extent of uptake was influenced by the phase of the cell cycle, but the mechanism of uptake was not. The relative activity of the antisense ODN was positively correlated to ODN distribution to the cytosol, but negatively correlated to total cellular uptake. Although ODN total cellular uptake is positively influenced by the cell cycle, retention of the ODN in the cytosol (presumably extra-vesicularly) appeared to be relevant in determining the activity of an antisense ODN. Novel methods to target cytosol-acting drugs to the cytoplasm may therefore be warrented.     

Membrane fluidity of halophilic ectoine-secreting bacteria related to osmotic and thermal treatment

In response to sudden decrease in osmotic pressure, halophilic microorganisms secrete their accumulated osmolytes. This specific stress response, combined with physiochemical responses to the altered environment, influence the membrane properties and integrity of cells, with consequent effects on growth and yields in bioprocesses, such as bacterial milking. The aim of this study was to investigate changes in membrane fluidity and integrity induced by environmental stress in ectoine-secreting organisms. The halophilic ectoine-producing strains Alkalibacillus haloalkaliphilus and Chromohalobacter salexigens were treated hypo- and hyper-osmotically at several temperatures. The steady-state anisotropy of fluorescently labeled cells was measured, and membrane integrity assessed by flow cytometry and ectoine distribution. Strong osmotic downshocks slightly increased the fluidity of the bacterial membranes. As the temperature increased, the increasing membrane fluidity encouraged more ectoine release under the same osmotic shock conditions. On the other hand, combined shock treatments increased the number of disintegrated cells. From the ectoine release and membrane integrity measurements under coupled thermal and osmotic shock conditions, we could optimize the secretion conditions for both bacteria.     

Endocytosis of micro- and nanosized particles in vitro by human dendritic cells

The ability of human dendritic cells (DC) to uptake synthetic micro- and nanosized particles was assessed by flow cytometry and fluorescent microscopy. DCs were differentiated in vitro from blood monocytes in the presence of recombinant cytokines. Further maturation of DC in culture after the addition of maturation factors resulted in the increased expression of HLA-DR and co-stimulatory molecules CD80, CD83, CD86, in comparison with immature DC. Active internalization of Fluoresbrite-YG fluorescent microbeads (0.2 μm) was noted for immature but not mature DCs. The decrease of endocytic activity after DC maturation correlated with the reduced expression of CD209, the surface membrane receptor participating in phagocytosis. Unlike microparticles, the uptake of nanoscale Quantum dots-655 did not depend on the stage of DC maturation and probably was mediated by a different endocytosis mechanism.     

Impact of proliferative activity and tumorigenic conversion on mitochondrial function of fibroblasts in 2D and 3D culture

The purpose of the present study was to examine mitochondrial function in differently transformed cells relative to their tumorigenic state and proliferative activity in vitro. An established two-step carcinogenesis model consisting of immortal and tumorigenic rat embryo fibroblasts that can be cultured as monolayers and multicellular spheroids was investigated. Flow cytometric measurements were carried out using the two mitochondrial-specific fluorochromes rhodamine 123 (Rh123) and 10-N-nonyl acridine orange (NAO), in combination with the DNA dye Hoechst 33342 for simultaneous cell cycle analysis. Since the accumulation of Rh123 depends on mitochondrial membrane potential, Rh123 fluorescence intensity gives an estimate of mitochondrial activity per cell, as determined by both overall mitochondrial function and mass. In contrast, NAO uptake reflects mitochondrial mass only, as it binds to cardiolipin in the inner mitochondrial membrane independently of membrane potential. Aliquots of cell suspensions derived from exponential monolayer, confluent monolayer, and a range of sizes of multicellular spheroids were stained with either Rh123 or NAO and Hoechst 33342, then mitochondrial mass and activity per unit cell volume and cellular DNA content were measured by flow cytometry. Differences in the average mitochondrial activity per cell in different cell lines and culture conditions were primarily due to alterations in cell volume. Importantly, tumorigenic conversion by ras-transfection did not consistently change mitochondrial activity per unit cell volume. The mitochondrial mass per unit cell volume increased for all cells when cellular quiescence was induced, either in monolayers or spheroids. However, mitochondrial function (activity/mass) decreased when cells became quiescent, resulting in a positive correlation between mitochondrial function and S-phase fraction, independent of transformation status or culture condition. We conclude that mitochondrial function reflects proliferative activity rather than tumorigenic conversion.     

Development of a Robust Flow Cytometric Assay for Determining Numbers of Viable Bacteria

Several fluorescent probes were evaluated as indicators of bacterial viability by flow cytometry. The probes monitor a number of biological factors that are altered during loss of viability. The factors include alterations in membrane permeability, monitored by using fluorogenic substrates and fluorescent intercalating dyes such as propidium iodide, and changes in membrane potential, monitored by using fluorescent cationic and anionic potential-sensitive probes. Of the fluorescent reagents examined, the fluorescent anionic membrane potential probe bis-(1,3-dibutylbarbituric acid)trimethine oxonol [DiBAC(inf4)(3)] proved the best candidate for use as a general robust viability marker and is a promising choice for use in high-throughput assays. With this probe, live and dead cells within a population can be identified and counted 10 min after sampling. There was a close correlation between viable counts determined by flow cytometry and by standard CFU assays for samples of untreated cells. The results indicate that flow cytometry is a sensitive analytical technique that can rapidly monitor physiological changes of individual microorganisms as a result of external perturbations. The membrane potential probe DiBAC(inf4)(3) provided a robust flow cytometric indicator for bacterial cell viability.     

Dynamic analysis of <Emphasis Type="Italic">Lactobacillus delbrueckii</Emphasis> subsp. <Emphasis Type="Italic">bulgaricus</Emphasis> CFL1 physiological characteristics during fermentation

This study aimed at examining and comparing the relevance of various methods in order to discriminate different cellular states of Lactobacillus bulgaricus CFL1 and to improve knowledge on the dynamics of the cellular physiological state during growth and acidification. By using four fluorescent probes combined with multiparametric flow cytometry, membrane integrity, intracellular esterase activity, cellular vitality, membrane depolarization, and intracellular pH were quantified throughout fermentations. Results were compared and correlated with measurements of cultivability, acidification activity (Cinac system), and cellular ability to recover growth in fresh medium (Bioscreen system). The Cinac system and flow cytometry were relevant to distinguish different physiological states throughout growth. Lb. bulgaricus cells maintained their high viability, energetic state, membrane potential, and pH gradient in the late stationary phase, despite the gradual decrease of both cultivability and acidification activity. Viability and membrane integrity were maintained during acidification, at the expense of their cultivability and acidification activity. Finally, this study demonstrated that the physiological state during fermentation was strongly affected by intracellular pH and the pH gradient. The critical pHi of Lb. bulgaricus CFL1 was found to be equal to pH 5.8. Through linear relationships between dpH and cultivability and pHi and acidification activity, pHi and dpH well described the time course of metabolic activity, cultivability, and viability in a single analysis.     

Simultaneous Monitoring of Cell Number and Metabolic Activity of Specific Bacterial Populations with a Dual gfp-luxAB Marker System

A dual marker system was developed for simultaneous quantification of bacterial cell numbers and their activity with the luxAB and gfp genes, encoding bacterial luciferase and green fluorescent protein (GFP), respectively. The bioluminescence phenotype of the luxAB biomarker is dependent on cellular energy status. Since cellular metabolism requires energy, bioluminescence output is directly related to the metabolic activity of the cells. By contrast, GFP fluorescence has no energy requirement. Therefore, by combining these two biomarkers, total cell number and metabolic activity of a specific marked cell population could be monitored simultaneously. Two different bacterial strains, Escherichia coli DH5α and Pseudomonas fluorescens SBW25, were chromosomally tagged with the dual marker cassette, and the cells were monitored under different conditions by flow cytometry, plate counting, and luminometry. During log-phase growth, the luciferase activity was proportional to the number of GFP-fluorescent cells and culturable cells. Upon entrance into stationary phase or during starvation, luciferase activity decreased due to a decrease in cellular metabolic activity of the population, but the number of GFP-fluorescing cells and culturable cells remained relatively stable. In addition, we optimized a procedure for extraction of bacterial cells from soil, allowing GFP-tagged bacteria in soil samples to be quantitated by flow cytometry. After 30 days of incubation of P. fluorescens SBW25::gfp/lux in soil, the cells were still maintained at high population densities, as determined by GFP fluorescence, but there was a slow decline in luciferase activity, implicating nutrient limitation. In conclusion, the dual marker system allowed simultaneous monitoring of the metabolic activity and cell number of a specific bacterial population and is a promising tool for monitoring of specific bacteria in situ in environmental samples.     

Selective cytotoxicity of rhodium metalloinsertors in mismatch repair-deficient cells

Mismatches in DNA occur naturally during replication and as a result of endogenous DNA damaging agents, but the mismatch repair (MMR) pathway acts to correct mismatches before subsequent rounds of replication. Rhodium metalloinsertors bind to DNA mismatches with high affinity and specificity and represent a promising strategy to target mismatches in cells. Here we examine the biological fate of rhodium metalloinsertors bearing dipyridylamine ancillary ligands in cells deficient in MMR versus those that are MMR-proficient. These complexes are shown to exhibit accelerated cellular uptake which permits the observation of various cellular responses, including disruption of the cell cycle, monitored by flow cytometry assays, and induction of necrosis, monitored by dye exclusion and caspase inhibition assays, that occur preferentially in the MMR-deficient cell line. These cellular responses provide insight into the mechanisms underlying the selective activity of this novel class of targeted anticancer agents.     

Effects of caspase inhibition on camptothecin-induced apoptosis of HL-60 cells

BACKGROUND: During camptothecin (CAM)-induced apoptosis of HL-60 cells, the external exposure of phosphatidylserine (PS) can either precede or follow DNA cleavage. The evidence suggests that cells in S-phase when CAM is added undergo rapid DNA, nuclear, and cellular disintegration before exposing PS on the outside of the plasma membrane, whereas cells moving from G1 into S-phase after CAM is added expose PS before they manifest the other phenomena. This study describes further investigations using the broad spectrum caspase inhibitor Z-VAD-FMK. The cells were cultured for a period long enough to ascertain whether a particular phenomenon was only delayed or was blocked completely. METHODS: Changes in cell light scatter, binding of annexin V-fluorescein isothiocyanate (FITC) to PS, uptake of propidium iodide (PI) as a measure of plasma membrane integrity, and DNA content after membrane fixation/permeabilization were monitored by flow cytometry during 24-h cultures. Fluorescence microscopy was used to examine cell morphology. RESULTS: Caspase inhibition blocked DNA cleavage, breakdown of the nuclear membrane, and formation of apoptotic bodies. It also revealed the existence of a CAM-activated early S-phase checkpoint. Cells arrested in early S-phase preceded the appearance of PS-positive cells. Caspase inhibition delayed both PS exposure and loss of plasma membrane integrity but did not prevent either. CONCLUSIONS: The results support the hypothesis that the sequence of apoptotic phenomena in an individual CAM-treated HL-60 cell depends on the stage of proliferation of that cell when it encounters the CAM. They are also consistent with the hypothesis that caspases are not required for PS exposure or the loss of plasma membrane integrity, but they are involved indirectly in promoting these phenomena.     

Evaluation of glucose transport and its regulation by insulin in human monocytes using flow cytometry.

BACKGROUND: We investigated the effects of insulin on glucose transport in human monocytes using flow cytometry, a method with several advantages over previously used techniques. We hypothesized that monocytes could be used as tools to study insulin action at the cellular level and facilitate the investigation of mechanisms that lead to insulin resistance. METHODS: Blood was withdrawn from 38 healthy subjects. The expression of glucose transporter (GLUT) isoforms in plasma membrane and the rates of glucose transport were determined with and without insulin (10 to 1,000 mU/L). Anti-CD14 phycoerythrin monoclonal antibody was used for monocyte gating. GLUT isoforms were determined after staining cells with specific antisera to GLUT1, GLUT3, and GLUT4. Glucose transport was monitored with 6-[N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino]-6-deoxyglucose (NBDG). RESULTS: Insulin increased the uptake of NBDG (median effective dose 20 mU/L) and the expression of GLUT3 and GLUT4 isoforms in the plasma membrane (median effective doses 20 and 35 mU/L, respectively) but had no effect on GLUT1. Maximal effects were always reached at 100 mU/L of insulin. CONCLUSIONS: Monocytes may be a valid model system to study the effects of insulin on glucose transport. Further, flow cytometry is suitable for this investigation and can be used as an alternative to radiotracer methods.     

Functional reconstitution of the gamma-aminobutyric acid transporter from synaptic vesicles using artificial ion gradients.

The gamma-aminobutyric acid transporter of rat brain synaptic vesicles was reconstituted in proteoliposomes, and its activity was studied in response to artificially created membrane potentials or proton gradients. Changes of the membrane potential were monitored using the dyes oxonol VI and 3,3'-diisopropylthiodicarbocyanine iodide, and changes of the H+ gradient were followed using acridine orange. An inside positive membrane potential was generated by the creation of an inwardly directed K+ gradient and the subsequent addition of valinomycin. Under these conditions, valinomycin evoked uptake of [3H]GABA which was saturable. Similarly, [3H]glutamate uptake was stimulated by valinomycin, indicating that both transporters can be driven by the membrane potential. Proton gradients were generated by the incubation of K(+)-loaded proteoliposomes in a buffer free of K+ or Na+ ions and the subsequent addition of nigericin. Proton gradients were also generated via the endogenous H+ ATPase by incubation of K(+)-loaded proteoliposomes in equimolar K+ buffer in the presence of valinomycin. These proton gradients evoked nonspecific, nonsaturable uptake of GABA and beta-alanine but not of glycine in proteoliposomes as well as protein-free liposomes. Therefore, transporter activity was monitored using glycine as an alternative substrate. Proton gradients generated by both methods elicited saturable glycine uptake in proteoliposomes. Together, our data confirm that the vesicular GABA transporter can be energized by both the membrane potential and the pH gradient and show that transport can be achieved by artificial gradients independently of the endogenous proton ATPase.     

Palytoxin acidifies chick cardiac cells and activates the Na+/H+ antiporter

The cardiotoxic action of palytoxin was investigated using embryonic chick ventricular cells. Under normal ionic conditions, palytoxin produced an intracellular acidification which is partially compensated for by the Na+/H+ antiporter thereby leading to an increased rate of ethylisopropylamiloride-sensitive 22Na+ uptake. Under depolarizing membrane conditions, palytoxin produced a cellular acidification, a cellular alkalinization or no change in intracellular pH depending on the value of the extracellular pH. We propose that palytoxin acidifies cardiac cells by opening preexisting H+ conducting pathways in the plasma membrane.     

Flow Cytometry Pulse Width Data Enables Rapid and Sensitive Estimation of Biomass Dry Weight in the Microalgae Chlamydomonas reinhardtii and Chlorella vulgaris

Dry weight biomass is an important parameter in algaculture. Direct measurement requires weighing milligram quantities of dried biomass, which is problematic for small volume systems containing few cells, such as laboratory studies and high throughput assays in microwell plates. In these cases indirect methods must be used, inducing measurement artefacts which vary in severity with the cell type and conditions employed. Here, we utilise flow cytometry pulse width data for the estimation of cell density and biomass, using Chlorella vulgaris and Chlamydomonas reinhardtii as model algae and compare it to optical density methods. Measurement of cell concentration by flow cytometry was shown to be more sensitive than optical density at 750 nm (OD₇₅₀) for monitoring culture growth. However, neither cell concentration nor optical density correlates well to biomass when growth conditions vary. Compared to the growth of C. vulgaris in TAP (tris-acetate-phosphate) medium, cells grown in TAP + glucose displayed a slowed cell division rate and a 2-fold increased dry biomass accumulation compared to growth without glucose. This was accompanied by increased cellular volume. Laser scattering characteristics during flow cytometry were used to estimate cell diameters and it was shown that an empirical but nonlinear relationship could be shown between flow cytometric pulse width and dry weight biomass per cell. This relationship could be linearised by the use of hypertonic conditions (1 M NaCl) to dehydrate the cells, as shown by density gradient centrifugation. Flow cytometry for biomass estimation is easy to perform, sensitive and offers more comprehensive information than optical density measurements. In addition, periodic flow cytometry measurements can be used to calibrate OD₇₅₀ measurements for both convenience and accuracy. This approach is particularly useful for small samples and where cellular characteristics, especially cell size, are expected to vary during growth.     

A quantitative method to evaluate mesenchymal stem cell lipofection using real‐time PCR

Genetic modification of human mesenchymal stem cells (MSC) is a powerful tool to improve the therapeutic utility of these cells and to increase the knowledge on their regulation mechanisms. In this context, strong efforts have been made recently to develop efficient nonviral gene delivery systems. Although several studies addressed this question most of them use the end product of a reporter gene instead of the DNA uptake quantification to test the transfection efficiency. In this study, we established a method based on quantitative real‐time PCR (RT‐PCR) to determine the intracellular plasmid DNA copy number in human MSC after lipofection. The procedure requires neither specific cell lysis nor DNA purification. The influence of cell number on the RT‐PCR sensitivity was evaluated. The method showed good reproducibility, high sensitivity, and a wide linear range of 75–2.5 × 10⁶ plasmid DNA copies per cell. RT‐PCR results were then compared with the percentage of transfected cells assessed by flow cytometry analysis, which showed that flow cytometry‐based results are not always proportional to plasmid cellular uptake determined by RT‐PCR. This work contributed for the establishment of a rapid quantitative assay to determine intracellular plasmid DNA in stem cells, which will be extremely beneficial for the optimization of gene delivery strategies. © 2010 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

Wide applicability of a flow cytometric assay to measure absolute membrane potentials on the millivolt scale

To prove the general applicability of a recently published flow cytometric method to determine the membrane potentials of cells on the absolute (mV) scale, the validity of the premises involved were analyzed individually. Experimental evidence was given for bis-oxonol, the applied membrane potential indicator being a Nernstian dye. The results of special measurements proved that extracellular dye concentrations were not affected by cellular dye uptake under the applied experimental conditions and that the dye content of the suspending medium did not contribute directly to the measured cellular fluorescence. A direct, membrane-potential-independent contribution of the extracellular dye to cellular fluorescence was also found to be negligible, as membrane potential values of the same type of cells evaluated from measurements in the presence of different extracellular oxonol concentrations were very close to each other. The transmembrane potential of B lymphoid JY cells was measured by the method as a function of cell density in the tissue culture. Cells isolated during the log phase of growth displayed a –40±4 mV membrane potential. At a high density of the culture (plateau phase), a significant increase of the membrane potential to –61±3 mV was observed and a medium value of –47±3.5 mV was measured at an intermediate density of the cells. Our observation indicates that nonadherent cells can also be hyperpolarized when optimal growth conditions are terminated. Received: 14 April 1998 / Revised version: 22 June 1998 / Accepted: 16 July 1998     

Physiological changes induced in four bacterial strains following oxidative stress

In order to study the behaviour and resistance of bacteria under extreme conditions, physiological changes associated with oxidative stress were monitored using flow cytometry. The study was conducted to assess the maintenance of membrane integrity and potential as well as the esterase activity, the intracellular pH and the production of superoxide anions in four bacterial strains (Ralstonia metallidurans, Escherichia coli, Shewanella oneidensis and Deinococcus radiodurans). The strains were chosen for their potential usefulness in bioremediation. Suspensions of R. metallidurans, E. coli, S. oneidensis and D. radiodurans were submitted to 1 h oxidative stress (H2O2 at various concentrations from 0 to 880 mM). Cell membrane permeability (propidium iodide) and potential (rhodamine-123, 3,3'-dihexyloxacarbocyanine iodide), intracellular esterase activity (fluorescein diacetate), intracellular reactive oxygen species concentration (hydroethidine) and intracellular pH (carboxyflurorescein diacetate succinimidyl ester (5(6)) were monitored to evaluate the physiological state and the overall fitness of individual bacterial cells under oxidative stress. The four bacterial strains exhibited varying sensitivities towards H2O2. However, for all bacterial strains, some physiological damage could already be observed from 13.25 mM H2O2 onwards, in particular with regard to their membrane permeability. Depending on the bacterial strains, moderate to high physiological damage could be observed between 13.25 mM and 220 mM H2O2. Membrane potential, esterase activity, intracellular pH and production of superoxide anion production were considerably modified at high H2O2 concentrations in all four strains. In conclusion, we show that a range of significant physiological alterations occurs when bacteria are challenged with H2O2 and fluorescent staining methods coupled with flow cytometry are useful for monitoring the changes induced not only by oxidative stress but also by other stresses like temperature, radiation, pressure, pH, etc....     

流式细胞术

流式细胞术是一种综合应用光学、机械学、流体力学、电子计算机、细胞生物学、分子免疫学等学科技术,对高速流动的细胞或亚细胞进行快速定量测定和分析的方法。它一秒钟能分析几千个细胞,并同时测定细胞的多个参数,广泛应用于生物医学的许多领域,如测定细胞的特征(形态、膜电位等)和细胞内pH,细胞DNA、蛋白质含量、表面受体、Ca2+等。对生物工程学来说,了解细胞的这些参数尤为重要,因为它们能比用传统技术测得的数据更好地描述细胞群体。从流式细胞仪对细胞多种参数的测定及原理,到它在生物工程学中的应用等方面进行了介绍,并讨论了流式细胞术的局限性和面临的挑战。     

Use of rhodamine 123 to investigate alterations in mitochondrial activity in isolated mouse liver mitochondria

The fluorescent dye Rhodamine-123, which selectively stains mitochondria depending on the mitochondrial membrane potential, was used with flow cytometry to evaluate alterations in activity of mitochondria isolated from mouse liver. Under in vitro conditions, with succinate and ADP present in the buffer, mitochondrial activity was affected by a variety of metabolic inhibitors that modify membrane potential. These results demonstrate clearly that flow cytometric techniques using Rhodamine-123 can be employed to study activity in isolated mitochondria.     

Assessment of bacterial viability status by flow cytometry and single cell sorting

Rapid bacterial detection and viability measurements have been greatly enhanced by recent advances in the use of fluorescent stains in cytometry. It has previously been shown that four physiological states can be distinguished : reproductively viable, metabolically active, intact and permeabilized. Previous sorting experiments have shown that not all intact cells readily grow, but some intact cells can grow even when they fail to show metabolic activity, as determined by esterase turnover. To circumvent the limitations imposed by active dye extrusion or cell dormancy on viability measurements used to date (e.g. enzyme activity or cell polarization), a fast triple fluorochrome staining procedure has been developed that takes account of these problems. This allows further cellular characterization of intact cells by : active exclusion of ethidium bromide (EB) (metabolically active cells), uptake of EB but exclusion of bis-oxonol (BOX) (de-energized but with a polarized cell membrane) and uptake of both dyes (depolarized). Permeabilized cells were identified by propidium iodide (PI) uptake. The method was validated using an electronically programmable single cell sorter (EPICS Elite^®) and aged Salmonella typhimurium cells. Reproductive viability was determined by sorting single cells to their staining pattern directly onto agar plates. Most polarized cells could be recovered as well as a significant fraction of the depolarized cells, demonstrating that depolarization is a sensitive measure of cell damage but a poor indicator of cell death.