Using multi-parameter flow cytometry as a novel approach for physiological characterization of bacteria in microbial fuel cells

This work demonstrates, for the first time, the potential of using multi-parameter flow cytometry to monitor changes in the microbial cytoplasmic membrane integrity and polarization during microbial fuel cells (MFC) operation. Such information is crucial to follow the dynamics of bacteria colonization of the electrodes and their viability maintenance during electrical current production. Interestingly, the results show that during voltage production, the electrostatic gradients of the bacteria cytoplasmic membrane are disturbed, leading to depolarization of a subpopulation (where less than 40% of the cells were polarized). Once the voltage dropped, due to substrate limitation, several cells in the anode supernatant restored their polarized state. This process was reversible and observed over more than 4 cycles of fresh substrate addition. Similar power outputs induced similar membrane polarization results, regardless of the substrate used. The percentage of non-viable cells was maintained constant during current production. This study opens new opportunities to monitor cell behavior, and thus increase the knowledge of dynamic mechanisms responsible for current production at the individual cell level. This technique could be of great interest for the development of new MFC configurations and optimization of MFC operation conditions toward increased performance.     

The basophil activation test by flow cytometry: recent developments in clinical studies, standardization and emerging perspectives

BACKGROUND: Beauveria bassiana is an important entomopathogenic fungus currently under development as a bio-control agent for a variety of insect pests. Although reported to be non-toxic to vertebrates, the potential allergenicity of Beauveria species has not been widely studied. METHODS: IgE-reactivity studies were performed using sera from patients displaying mould hypersensitivity by immunoblot and immunoblot inhibition. Skin reactivity to B. bassiana extracts was measured using intradermal skin testing. RESULTS: Immunoblots of fungal extracts with pooled as well as individual sera showed a distribution of IgE reactive proteins present in B. bassiana crude extracts. Proteinase K digestion of extracts resulted in loss of IgE reactive epitopes, whereas EndoH and PNGaseF (glycosidase) treatments resulted in minor changes in IgE reactive banding patterns as determined by Western blots. Immunoblot inhibitions experiments showed complete loss of IgE-binding using self protein, and partial inhibition using extracts from common allergenic fungi including; Alternaria alternata, Aspergillus fumigatus, Cladosporium herbarum, Candida albicans, Epicoccum purpurascens, and Penicillium notatum. Several proteins including a strongly reactive band with an approximate molecular mass of 35 kDa was uninhibited by any of the tested extracts, and may represent B. bassiana specific allergens. Intradermal skin testing confirmed the in vitro results, demonstrating allergenic reactions in a number of individuals, including those who have had occupational exposure to B. bassiana. CONCLUSIONS: Beauveria bassiana possesses numerous IgE reactive proteins, some of which are cross-reactive among allergens from other fungi. A strongly reactive potential B. bassiana specific allergen (35 kDa) was identified. Intradermal skin testing confirmed the allergenic potential of B. bassiana.     

Differential fluorochromasia of human lymphocytes as measured by flow cytometry.

Peripheral human lymphocytes reacted with fluorescein diacetate and analyzed by flow cytometry produced a bimodal fluorescence distribution that was shown to be attributable to the differential staining of T and B lymphocytes. Lymphocytes were fractionated into rosetting (T cell) and nonrosetting (B cell) populations. Both subfractions were reacted with fluorescein diacetate and analyzed by flow cytometry. The rosetting fraction was more fluorescent than the nonrosetting fraction, and the analysis of an appropriate mixture of the subfractionated populations produced a fluorescence distribution very similar to that obtained with unfractionated lymphocytes.     

Applications and perspectives of multi-parameter flow cytometry to microbial biofuels production processes

Conventional microbiology methods used to monitor microbial biofuels production are based on off-line analyses. The analyses are, unfortunately, insufficient for bioprocess optimization. Real time process control strategies, such as flow cytometry (FC), can be used to monitor bioprocess development (at-line) by providing single cell information that improves process model formulation and validation. This paper reviews the current uses and potential applications of FC in biodiesel, bioethanol, biomethane, biohydrogen and fuel cell processes. By highlighting the inherent accuracy and robustness of the technique for a range of biofuel processing parameters, more robust monitoring and control may be implemented to enhance process efficiency.     

Induction studies with Escherichia coli expressing recombinant interleukin-13 using multi-parameter flow cytometry

The expression of interleukin-13 (IL13) following induction with IPTG in Escherichia coli results in metabolic changes as indicated by multi-parameter flow cytometry and traditional methods of fermentation profiling (O₂ uptake rate, CO₂ evolution rate and optical density measurements). Induction early in the rapid growth phase was optimal although this led to lower overall biomass concentrations and lower maximum specific growth rates. In contrast, induction in the mid-rapid growth phase was the most detrimental to cell quality as measured by cytoplamsic membrane depolarisation.     

Monitoring Rhodotorula glutinis CCMI 145 physiological response and oil production growing on xylose and glucose using multi-parameter flow cytometry

Flow cytometry was used to monitor the lipid content, viability and intrinsic light scatter properties of Rhodotorula glutinis CCMI 145 cells growing on batch cultures using xylose and glucose as carbon sources. The highest lipid content was observed for cells grown on glucose, at the end of the exponential phase (17.8% w/w). The proportion of cells stained with PI attaining 77% at the end of the glucose growth. Cells growing on xylose produced a maximum lipid content of 10.6% (w/w), at the stationary phase. An increase in the proportion of cells stained with PI was observed, reaching 29% at the end of xylose growth. Changes in the side and forward light scatter detected during the yeast batch cultures supported that R. glutinis cells grown on glucose experienced harsher conditions, resulting in a high level of cytoplasmic membrane damage, which did not occur when R. glutinis cells grew on xylose.     

An evaluation of the anti-bacterial action of ceramic powder slurries using multi-parameter flow cytometry

Multi-parameter flow cytometric techniques have been used to study the effects of three ceramic powders CaO, MgO and ZnO on the physiology of individual, exponentially growing E. coli cells. Whilst all three powders inhibited reproductive growth, depending on their concentration, the mechanism of action of CaO and MgO was different to that of ZnO as shown by fluorescent staining techniques developed in our laboratory.     

Cytokine flow cytometry: multiparametric approach to immune function analysis

More precise quantitation of cellular immune responses has become possible with the advent of single-cell assays of immune function, such as cytokine flow cytometry, enzyme-linked immunospot (ELISPOT), and MHC-peptide multimers. Cytokine flow cytometry is an attractive technique because it allows the detection of responses to whole antigens without regard to MHC restriction, while also collecting additional information on responding cells via multiparameter flow cytometry. In this review, we compare cytokine flow cytometry with other assays of immune function, summarize some of that data that have been collected in various disease states using cytokine flow cytometry, and describe some methodological improvements designed to increase the robustness, throughput, and information content of this technique. We hypothesize that a new generation of automated cytokine flow cytometry assays will allow elucidation of the correlates of protection for diseases involving cellular immunity, through application of these assays in more and large clinical trials.     

A study into the anti-microbial properties of an amino functionalised polymer using multi-parameter flow cytometry

Fluorescent staining techniques were used to study the anti-microbial properties of aqueous suspensions of a novel, water insoluble amino functionalised polymer on three micro-organisms Pseudomonas fluorescens, Staphylococcus epidermidis and Saccharomyses cerevisiae. The mechanism of action was similar for each organism in that, after various contact times with the polymer, a progressive change in individual cell physiological state was measured using multi-parameter flow cytometry. The microbiocidal activity of this polymer may be similar to that of substances referred to as polycationic, amphipathic compounds (peptides, peptide derivatives and other polyamines).     

Measurement of platelet activation by fluorescence-activated flow cytometry.

Platelet activation is postulated to play a critical role in the pathogenesis of thrombotic and hemorrhagic disorders. Previous assays for detection of activated platelets were cumbersome and provided only nonspecific information with limited sensitivity. The recent introduction of fluorescence-activated flow cytometric techniques for platelet analysis used in combination with monoclonal antibodies for detection of specific platelet-activation antigens has introduced the possibility of improved assays to detect activated platelets. The monoclonal antibody S12, directed against the unique platelet-activation antigen GMP-140, has been used to develop a fluorescence-activated flow cytometric assay. Patient samples for this assay can be easily prepared and maintained until analyzed in batch mode. Peripheral blood obtained from normal subjects exhibited low levels of activated platelets, and the assay had sufficient sensitivity to detect as few as 2% to 3% activated platelets among normal platelets. Patients undergoing cardiopulmonary bypass had transiently increased numbers of circulating activated platelets. Evaluation of standard blood bank platelet concentrates has shown the presence of significant numbers of activated platelets. Other studies have suggested that the degree of platelet activation correlated with poor posttransfusion increments and survival. Thus, this assay may also be useful for quality control of platelet concentrates. Future development of the GMP-140 and other platelet-activation antigen assays should improve detection of disorders characterized by inappropriate platelet activation.     

Application of multi-parameter flow cytometry using fluorescent probes to study substrate toxicity in the indene bioconversion

The bioconversion of indene to cis-(1S,2R) indandiol, a potential key intermediate in the synthesis of Merck's HIV protease inhibitor, CRIXIVAN trade mark, can be achieved using a Rhodococcus strain. This study using Rhodococcus I24 reports on the application of multiparameter flow cytometry for the measurement of cell physiological properties based on cytoplasmic membrane (CM) integrity and membrane depolarization as indicators of toxic effects of the substrate, indene. Quantification of intact polarized CM, intact depolarized CM and permeabilized CM of a large population of bacterial cells has been conducted using specific intracellular and membrane-binding fluorescent stains. Measurements of oxygen uptake rate (OUR) and optical density (OD) as indicators of metabolic activity and biomass growth, respectively, were also made. Indene concentrations of up to 0.25 g/L (0.037 g indene/g dry cell weight) did not significantly (<5% compared to control) affect cell light-scattering properties, intact CM, membrane polarization, respiratory activity, or biomass growth. Between this value and 1.5 g/L (0.221 g indene/g dry cell weight), the changes in intact CM, respiratory activity and biomass growth were relatively insignificant (<5% compared to control), although dissipation of the membrane potential of a significant proportion of the cell population occurred at 0.50 g/L (0.074 g indene/g dry cell weight). At 2.5 g/L (0.368 g indene/g dry cell weight) there was a significant increase in the dead cell population, accompanied by changes in the extracellular cationic concentrations and substantial decrease in respiratory activity. The primary effect of indene toxicity was the disruption of the proton motive force across the cytoplasmic membrane which drives the formation of ATP. The disruption of the proton motive force may have been due to the measured changes in proton permeability across the membrane. In addition, indene may have directly inhibited the membrane-bound enzymes related to respiratory activity. The overall consequence of this was reduced respiratory activity and biomass growth. The cell physiological properties measured via flow cytometry are important for understanding the effects of toxicity at the cellular level which neither measurements of biomass growth or indandiol formation rates can provide since both are cell averaged measurements. The technique described here can also be used as a generic tool for measuring cell membrane properties in response to toxicity of other indene-resistant strains that may be possible to use as recombinant hosts to perform the biotransformation of indene. This study has demonstrated that flow cytometry is a powerful tool for the measurement of cell physiological properties to assess solvent toxicity on whole cell biocatalysts.     

Platelet activation as a marker for in vivo prothrombotic activity: detection by flow cytometry

Circulating platelets play a pivotal role in hemostasis. The platelet hemostatic function involves the direct interaction with damaged vessel walls, and circulating coagulation factors, primarily thrombin resulting in platelet activation, aggregation and formation of hemostatic plug. Flow cytometry is a useful technique for the study of platelet activation in circulating blood. Platelet activation markers for ex vivo analysis may include a) activation-dependent epitopes of the membrane glycoprotein (GP) IIb/IIIa (CD41a) receptor, as demonstrated by the binding of activation-specific monoclonal antibodies (MoAbs) PAC1, anti-LIBS1 and anti-RIBS); b) the expression of P-selectin (CD62p), the alpha-granule GP translocated to the platelet surface following release reaction; and c) platelet procoagulant activity, as demonstrated by the binding of i) annexin V protein to the prothrombinase-complex (prothrombin, activated factor X (Xa) and V (Va)) binding sites on the surface of activated platelets, and of ii) MoAbs against activated coagulation factors V and X bound to the surface of activated platelets. Using this method, platelet activation as a marker for in vivo prothrombotic activity can be demonstrated in various clinical conditions including coronary angioplasty, orthostatic challenge in primary depression, sickle cell disease in clinical remission and during pain episode, and in pregnancy-related hypertension with marked increase during preeclampsia. The finding of platelet procoagulant activity is corroborated by increased levels of plasma markers for thrombin generation and fibrinolytic activity.     

Differential analysis of animal bone marrow by flow cytometry.

A simple procedure was developed for rapid analysis of animal bone marrow by flow cytometry using the lipophilic cationic dye 3,3'-dihexyloxacarbocyanine iodide [DiOC6(3)]. The batch process allows differentiation of bone marrow cells into lymphoid, erythroid, and myeloid populations and enables classification of erythroid and myeloid cells into proliferating and maturing subpopulations. From these data, myeloid:erythroid (M:E) ratios and maturation indices for erythroid and myeloid cells (EMI and MMI, respectively) can be derived. This procedure provides the opportunity to analyze bone marrow quantitatively and offers distinct advantages to current manual methods in terms of simplicity, throughput, and reproducibility. The method has been tested successfully using marrow from Wistar rats, B6C3F1 mice, beagle dogs, and cynomolgus monkeys. This technique facilitates the evaluation of bone marrow samples taken from preclinical safety studies or from animal colonies of large size.     

Differential expression of H-Y antigen on lymphocyte subsets: analysis by flow cytometry

Expression of H-Y antigen in human white blood cells was measured using flow cytometry with monoclonal antibodies. In this system, lymphocytes were stained preferentially in the male, and to a lesser extent in the female. Analysis of the lymphocyte subsets with biotinylated H-Y antibody conjugated with streptavidin-fluorescein isothiocyanate (FITC) and subset-specific antibody conjugated with phycoerythrin derivative (RD1) revealed differential expression of H-Y among the subsets of the male. In samples from eight men, 41.1% +/- 21.7% of B cells (B1) were stained, compared with 20.7% +/- 12.8% of cytotoxic-suppressor T cells (T8) and 5.4% +/- 3.0% of helper-inducer T cells (T4). In samples from seven women, 12.4% +/- 10.9% of B cells were stained, but staining of T cells was negligible.     

Automated laser scanning cytometry: a powerful tool for multi-parameter analysis of drug-induced apoptosis.

BACKGROUND: Simultaneous analysis of multiple intracellular events is critical for assessing the effect of biological response modifiers, including the efficacy of chemotherapy. Here we used the automated laser scanning cytometry (LSC) for multi-parameter analysis of drug-induced tumor cell apoptosis. MATERIALS: Using 2-mercaptopyridine-N-oxide-hydrate sodium salt, or the commonly used chemotherapeutic agents etoposide and camptothecin, we performed simultaneous analyses of apoptosis-related morphological features as well as fluorescence-based biochemical changes in a 96-well format. RESULTS: We demonstrate the scope of LSC as a platform for comparing multiple variables between different cell populations, distinguishing unique events at a single cell level within a sample population, and enabling simultaneous screenings in a single assay at multiple dosages and time-points. CONCLUSION: These data underscore the power of LSC for simultaneous multi-parameter analysis, which could have implications for screening or assessing the efficacy of drug responses in heterogeneous cell populations and at the single cell level.     

Three probe flow cytometry of a human foam-cell forming macrophage.

A human cell line THP-1 was differentiated into macrophages expressing the scavenger receptor for uptake of modified lipoproteins. The cells were exposed to native low-density lipoprotein (n-LDL), acetylated-low-density lipoprotein (Ac-LDL), oxidised-LDL, or 25-OH cholesterol, leading to the accumulation of cholesteryl esters within the cells. Harvested macrophages were studied using three separate probes: 1) 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (diI)-labelled LDL to study lipoprotein uptake; 2) the lipophilic fluorescent dye Nile Red to study cholesteryl ester accumulation within the cells; and 3) the polyene antibiotic Filipin III to study free cholesterol homeostasis. Cells were analysed using fluorescence flow cytometry and the three signals analysed separately. THP-1 macrophages incubated with diI-labelled modified lipoproteins produced a concentration dependent increase in the fluorescence emissions, consistent with accumulation of the labelled particles. Macrophages exposed to unlabelled modified LDLs were demonstrated, by staining with Nile Red, to accumulate cholesteryl esters within their cytoplasm and to alter their cholesterol content as judged by staining with Filipin. The foam-cell forming macrophage and its response to modified lipoproteins is considered a key step in the development of atherosclerosis. The use of these three probes during the formation of foam-cells in vitro offers a way of studying their behaviour at the single cell level.     

Bleaching response of Symbiodinium (zooxanthellae): Determination by flow cytometry

Coral bleaching is of increasing concern to reef management and stakeholders. Thus far, quantification of coral bleaching tends to be heavily reliant on the enumeration of zooxanthellae, with less emphasis on assessment of photosynthetic or physiological condition, these being often assessed separately by techniques such as liquid chromatography. Traditional methods of enumeration using microscopy are time consuming, subjected to low precision and great observer error. In this study, we presented a method for the distinction of physoiological condition and rapid enumeration of zooxanthellae using flow cytometry (FCM). Microscopy verified that healthy looking/live versus damaged/dead zooxanthellae could be reliably and objectively distinguished and counted by FCM on the basis of red and green fluorescence and light scatter. Excellent correlations were also determined between FCM and microscopy estimates of cell concentrations of fresh zooxanthellae isolates from Pocillopora damicornis. The relative intensities of chlorophyll and β-carotene fluorescences were shown to be important in understanding the results of increased cell counts in freshly isolated zooxanthellae experimentally exposed to high temperatures (34, 36, and 38°C) over 24 h, with ambient temperature (29°C) used as controls. The ability to simultaneously identify and enumerate subpopulations of different physiological states in the same sample provides an enormous advantage in not just determining bleaching responses, but elucidating adaptive response and mechanisms for tolerance. Therefore, this approach might provide a rapid, convenient, and reproducible methodology for climate change studies and reef management programs. ? 2012 International Society for Advancement of Cytometry.     

Improved detection of bacteria by flow cytometry using a combination of antibody and viability markers

A proprietary fluorogenic marker for cell viability (Chemchrome) was investigated for the detection of bacteria using flow cytometry. This marker was used in combination with fluorescently labelled monoclonal antibodies (against Salmonella typhimurium ). Owing to the former's broad band emission spectrum, it was necessary to use the novel dye RED613 for the antibodies. This combined protocol, being sensitive only to the live Salm. typhimurium cells, reduced errors due to intrinsic fluorescence and non-specific binding. Detection of the order of 100 cells ml⁻¹ was achieved in 30 min. This level was achieved even in the presence of large numbers of non-target or dead organisms.     

Bimodal IgG4-mediated human basophil activation. Role of eosinophils.

The role of IgG4 antibodies in allergic disorders is suspected. Yet, their presence on human basophil membrane has not been demonstrated and the mechanism of the degranulation induced by anti-IgG4 antibodies remains unclear. As previously reported, we observed that monoclonal anti-IgG4 (10 to 100 micrograms/ml) induced histamine release in the presence of D2O from leukocytes of normal and atopic subjects. The release was accompanied by a decrease of the number of toluidine blue-positive basophils (TB+). Histamine release and TB+ decrease were also observed with lower concentrations of anti-IgG4 (1 to 100 pg/ml). Since basophil activation assessed by TB+ decrease was more sensitive than histamine release, we thus used the former method to further study the mechanisms of the anti-IgG4- vs anti-IgE-induced basophil activation. Basophil activation by anti-IgG4 at 1 to 100 pg/ml, but not by anti-IgG4 at 10 to 100 micrograms/ml or anti-IgE, required the presence of polymorphonuclear cells. Furthermore, anti-IgG4-stimulated purified eosinophils, but not neutrophils, released basophil-activating factors identified as cationic proteins from eosinophils. Thus, the human basophil can be activated by anti-IgG4 via two different mechanisms according to the antibody concentration. At high concentrations (10 to 100 micrograms/ml) basophil activation does not require the presence of polymorphonuclear cells whereas at lower concentrations (1 to 100 pg/ml) the presence of eosinophils is necessary. We propose that in the latter concentration range, basophil activation is a two-step process: 1) release by anti-IgG4 of eosinophil cationic proteins that 2) will, in turn, activate human basophils. This study lends support to the role of IgG4 and eosinophils in anaphylactic reactions.