Howard M. Shapiro

List of Tables and Figures. Preface to the Fourth Edition: Why You Should Read the Book - Or Not. Foreword to the Third Edition. Preface to the Third Edition. Preface to the Second Edition. Foreword to the First Edition. Preface to the First Edition. 1. Overture. 2. Learning Flow Cytometry. 3. History. 4. How Flow Cytometers Work. 5. Data Analysis. 6. Flow Sorting. 7. Parameters and Probes. 8. Buying Flow Cytometers. 9. Building Flow Cytometers. 10. Using Flow Cytometers: Applications, Extensions, and Alternatives. 11. Sources of Supply. 12. Afterword.

The objective of this study was to further elucidate the role of membrane potential in the mechanism of action of daptomycin, a novel lipopeptide antibiotic. Membrane depolarization was measured by both fluorimetric and flow cytometric assays. Adding daptomycin (5 micro g/ml) to Staphylococcus aureus gradually dissipated membrane potential. In both assays, cell viability was reduced by >99% and membrane potential was reduced by >90% within 30 min of adding daptomycin. Cell viability decreased in parallel with changes in membrane potential, demonstrating a temporal correlation between bactericidal activity and membrane depolarization. Decreases in viability and potential also showed a dose-dependent correlation. Depolarization is indicative of ion movement across the cytoplasmic membrane. Fluorescent probes were used to demonstrate Ca(2+)-dependent, daptomycin-triggered potassium release from S. aureus. Potassium release was also correlated with bactericidal activity. This study demonstrates a clear correlation between dissipation of membrane potential and the bactericidal activity of daptomycin. A multistep model for daptomycin's mechanism of action is proposed.

Cell-surface antigens that are induced to appear on T cells activated by the lectin phytohemagglutinin-P (PHA) can be classified both on the basis of the kinetics of their appearance and on their growth-association properties. Seven distinct T cell activation antigens, defined by monoclonal antibodies, were classified as early, intermediate, or late antigens based on their temporal appearance relative to DNA synthesis. Four antigens, the transferrin receptor, the T cell activation antigen Tac, the 4F2 antigen, and the 49.9 antigen were early antigens, whereas the OKT10 antigen appeared at intermediate times and both HLA-DR and antigen 19.2 appeared late. The use of a dye, Hoechst 33342, which stains DNA stoichiometrically, allowed the simultaneous analysis of immunofluorescence and cell cycle position of individual cells. This analysis unexpectedly revealed that essentially all cells in the proliferative phase of the cell cycle expressed each of the four early-activation antigens. The correlation between expression of the four early-activation antigens and T cell proliferation suggests that these molecules are important for the growth of all T cells. The relationship of two of these activation antigens, known to be the receptors for transferrin and interleukin 2, a T cell growth factor, is discussed with special reference to the roles of their ligands in supporting the growth of T cells.

BACKGROUND: Membrane potential (MP) plays a critical role in bacterial physiology. Existing methods for MP estimation by flow cytometry are neither accurate nor precise, due in part to the heterogeneity of size of the particles analyzed. The ratio of a size- and MP-sensitive measurement, and an MP-independent, size-sensitive measurement, should provide a better estimate of MP. METHODS: Flow cytometry and spectrofluorometry were used to detect red (488 --> 600 nm) fluorescence associated with aggregates of diethyloxacarbocyanine (DiOC2(3)), which, in the monomeric state, is normally green (488 --> 530 nm) fluorescent. RESULTS: In bacteria incubated with 30 microM dye, aggregate formation increases with the magnitude of the interior-negative membrane potential. Green fluorescence from stained bacteria predominantly reflects particle size, and is relatively independent of MP, whereas red fluorescence is highly dependent on both MP and size. The ratio of red to green fluorescence provides a measure of MP that is largely independent of cell size, with a low coefficient of variation (CV). Calibration with valinomycin and potassium demonstrates that the method is accurate over the range from -50 mV through -120 mV; it also accurately tracks reversible reductions in MP produced by incubation at 4 degrees C and washing in glucose-free medium. CONCLUSIONS: The ratiometric technique for MP estimation using DiOC2(3) is substantially more accurate and precise than those previously available, and may be useful in studies of bacterial physiology and in investigations of the effects of antibiotics and other agents on microorganisms.

The addition of RNA content estimation to flow cytometric measurement of DNA content provides valuable information concerning cells' transitions between quiescent and proliferative states. Equilibrium staining methods employing acridine orange have been used for DNA/RNA content measurement but are difficult to apply to intact cells and impractical for use in conjunction with fluorescent antibodies or ligands for demonstration of cell surface structures. I have used a combination of Hoechst 33342 (HO342) and pyronin Y (PY) to stain intact cells for DNA/RNA content estimation with a dual source flow cytometer using UV and blue-green or green excitation, measuring HO342 fluorescence at 430--470 nm and PY fluorescence at 590--650 nm. Results obtained with cultured cells and stimulated lymphocytes are in good agreement with those obtained using acridine orange for DNA/RNA staining; about half of the PY fluorescence can be removed from ethanol-fixed cells stained with HO342 and PY by RNAse digestion. The HO342/PY method can be combined with fluorescein immunofluorescence for detection of cell surface markers. HO342 can be combined with other tricyclic heteroaromatic dyes for DNA/RNA estimation; the combination of HO342 and oxazine 1 can be excited in a dual source instrument using a mercury arc lamp and a helium-neon laser. The staining procedure is simple; cells in medium are incubated with 5 microM HO342 at 37 degrees C for 45 min, 5 microM PY (or oxazine 1) is then added and cells are analyzed without washing after an additional 45 min incubation. Suitability of these dye combinations for vital cell staining and sorting remains to be determined.