Analysis of UV-excited fluorochromes by flow cytometry using near-ultraviolet laser diodes.

INTRODUCTION: Violet laser diodes have become common and reliable laser sources for benchtop flow cytometers. While these lasers are very useful for a variety of violet and some ultraviolet-excited fluorochromes (e.g., DAPI), they do not efficiently excite most UV-stimulated probes. In this study, the next generation of InGaN near-UV laser diodes (NUVLDs) emitting in the 370-375-nm range have been evaluated as laser sources for cuvette-based flow cytometers. METHODS: Several NUVLDs, ranging in wavelength from 370 to 374 nm and in power level from 1.5 to 10 mW, were mounted on a BD Biosciences LSR II and evaluated for their ability to excite cells labeled with the UV DNA binding dye DAPI, several UV phenotyping fluorochromes (including Alexa Fluor 350, Marina Blue, and quantum dots), and the fluorescent calcium chelator indo-1. RESULTS: NUVLDs at the 8-10-mW power range gave detection sensitivity levels comparable to more powerful solid-state and ion laser sources, using low-fluorescence microsphere beads as measurement standards. NUVLDs at all tested power levels allowed extremely high-resolution DAPI cell cycle analysis, and sources in the 8-10-mW power range excited Alexa Fluor 350, Marina Blue, and a variety of quantum dots at virtually the same signal-to-noise ratios as more powerful UV sources. CONCLUSIONS: These evaluations indicate that near-UV laser diodes installed on a cuvette-based flow cytometer performed nearly as well as more powerful solid-state UV lasers on the same instrumentation, and comparably to more powerful ion lasers on a jet-in-air system, and. Despite their limited power, integration of these small and inexpensive lasers into benchtop flow cytometers should allow the use of flow cytometric applications requiring UV excitation on a wide variety of instruments.     

A comparison of low-power helium-cadmium and argon ultraviolet lasers in commercial flow cytometers

The feasibility of installing a low power ultraviolet (UV) laser in a commercial flow cytometer was evaluated by testing an Ortho Cytofluorograf 50HH and a Coulter Epics V. Both instruments were equipped with two argon ion lasers, one emitting at 488 nm and the other in the UV region and were tested by measuring the DNA content of cells stained with Hoechst 33342 or DAPI. The coefficient of variation (CV) of the G0/G1 peak of the DNA histograms produced by each instrument did not deteriorate markedly when results obtained at 100-125 mW were compared to those obtained at 10 mW. These tests indicated that a helium-cadmium laser (He-Cd) which can produce 10 mW at 325 nm should work well as a UV laser in these instruments. An Ortho Cytofluorograf IIs was purchased with a 10 mW He-Cd laser installed in the forward position. Studies of DNA content have confirmed that this low power UV laser can produce CVs of 2.2% with DAPI stained fixed cells and 3.6% with Hoechst 33342 stained viable lymphocytes. Thus, the He-Cd laser should provide a reasonable alternative as a UV source for flow cytometers.     

Immunofluorescence measurement in a flow cytometer using low-power helium-neon laser excitation

Helium-neon lasers are economical and efficient light sources; their utility in flow cytometry to date has been limited by the lack of fluorescent probes that can be excited at 633 nm. Allophycocyanin (APC), a highly fluorescent phycobiliprotein, can be used as an antibody label and has spectral characteristics suitable for use with He-Ne lasers; we undertook to resolve whether a low-power (7 mW) He-Ne laser could provide sufficient excitation to permit flow cytometric detection of APC-labeled antibodies on cell surfaces. We made an APC conjugate of monoclonal antibody 4F2, which reacts with an antigen abundant on the surfaces of activated human T-lymphocytes; APC-4F2 was used to stain blood mononuclear cells that had been cultured with and without phytohemagglutinin (PHA). Cells so stained were examined in a flow cytometer with orthogonal illumination at 633 nm from a 7 mW He-Ne laser; antibody-bearing cells were detectable by fluorescence emission above 665 nm. Cells from the same cultures were stained with fluorescein-labeled 4F2 antibody and examined in a flow cytometer with argon ion laser excitation at 488 nm. Percentages of antibody-bearing cells determined from APC fluorescence and from fluorescein fluorescence were in good agreement. It thus appears that He-Ne lasers and APC-antibodies are usable for immunofluorescence measurements; the sensitivity attainable with this technique remains to be determined.     

Evaluation of a green laser pointer for flow cytometry.

Flow cytometers typically incorporate expensive lasers with high-quality (TEM00) output beam structure and very stable output power, significantly increasing system cost and power requirements. Red diode lasers minimize power consumption and cost, but limit fluorophore selection. Low-cost DPSS laser pointer modules could possibly offer increased wavelength selection but presumed emission instability has limited their use. A $160 DPSS 532 nm laser pointer module was first evaluated for noise characteristics and then used as the excitation light source in a custom-built flow cytometer for the analysis of fluorescent calibration and alignment microspheres. Eight of ten modules tested were very quiet (RMS noise < or = 0.6% between 0 and 5 MHz). With a quiet laser pointer module as the light source in a slow-flow system, fluorescence measurements from alignment microspheres produced CVs of about 3.3%. Furthermore, the use of extended transit times and < or =1 mW of laser power produced both baseline resolution of all 8 peaks in a set of Rainbow microspheres, and a detection limit of <20 phycoerythrin molecules per particle. Data collected with the transit time reduced to 25 micros (in the same instrument but at 2.4 mW laser output) demonstrated a detection limit of approximately 75 phycoerythrin molecules and CVs of about 2.7%. The performance, cost, size, and power consumption of the tested laser pointer module suggests that it may be suitable for use in conventional flow cytometry, particularly if it were coupled with cytometers that support extended transit times.     

Improved BrdUrd-Hoechst bivariate cell kinetic analysis by helium-cadmium single laser excitation.

In laser based flow cytometers, UV excitation of Hoechst 33258 and propidium iodide (PI) or ethidium bromide (EB) is performed with 351/364 nm high power lines of UV-capable argon ion lasers, which are expensive and short-lived. In this paper we note for the first time that helium-cadmium lasers emitting 10 to 30 mW at 325 nm are even more superior for cell kinetic bivariate bromodeoxyuridine (BrdUrd)/Hoechst PI or EB cell cycle analysis. HeCd single laser UV excitation gives comparable CVs for cell cycle distributions, and almost normal G2M/G1 ratios of 1.9 to 2.0 for all cell cycles. This is shown for synchronous and asynchronous cell populations on a FACStar+ and an Ortho Cytofluorograf. Therefore we recommend helium-cadmium lasers as low-power, cheap, and long-lived UV excitation sources for the cytochemically simple but high resolution multiparameter BrdUrd-Hoechst cell kinetic analysis.     

UV lasers for flow cytometric analysis: HeCd versus argon laser excitation.

Applying flow cytometric single cell analysis, we compared the performance of UV excitation from argon ion and HeCd lasers using various UV-excitable fluorochromes of cell kinetic and cell physiological relevance. The AT-specific DNA fluorochromes DAPI, Hoechst 33258, and Hoechst 33342 showed no significant differences of G1-phase resolution and cell cycle distribution. With the HeCd laser, high-resolution cell kinetic analysis applying the novel BrdU/Hoechst-PI quenching technique showed superior resolution and an almost normalized G2M/G1 channel ratio of the first cell cycle. Indo-1 analysis for detection of intracellular free calcium gave similar results for both excitation sources, although the indo-1 ratio of activated cells was lower for HeCd excitation. Monochlorobimane as an indicator fluorochrome of glutathione content could not be excited sufficiently with the 325-nm line of the HeCd laser and exhibited poor resolution between positive and negative cells. However, the second glutathione-specific fluorochrome o-phtalaldehyde gave even better results with the HeCd laser. Our data indicate that air-cooled HeCd lasers are cheap and reliable UV-excitation sources for most UV-excitable fluorochromes, and might be an alternative to the expensive water-cooled argon and krypton laser.     

Discrete and reversible vacuole-like dilations induced by osmomechanical perturbation of neurons

In cultured Lymnaea stagnalis neurons, osmolarity increases (upshocks) rapidly elicited large membranous dilations that could be dislodged and pushed around inside the cell with a microprobe. Subsequent osmolarity decreases (downshocks) caused these vacuole-like dilations (VLDs) to disappear. Additional upshock/downshock perturbations resulted in repeated appearance/disappearance (formation/reversal) of VLDs at discrete sites. Confocal microscopy indicated that VLDs formed as invaginations of the substrate-adherent surface of the neuron: extracellular rhodamine-dextran entered VLDs as they formed and was expelled during reversal. Our standard VLD-inducing perturbation was: 2–4 min downshock to distilled water, upshock to normal saline. However, a wide range of other osmotic perturbations (involving osmolarities up to 3.5x normal, perturbations with or without Ca²⁺, replacement of ions by sucrose) were also used. We concluded that mechanical, not chemical, aspects of the osmo-mechanical shocks drove the VLD formation and reversal dynamics and that extracellular Ca²⁺ was not required.Following a standard perturbation, VLDs grew from invisible to their full diameter (>10 m) in just over a minute. Over the next 0.5–3 hr in normal saline, neurons recovered. Recovery eliminated any visible VLDs and was accompanied by cytoplasmic turmoil around the VLDs. Recovery was prevented by cytochalasin B, brefeldin A and N-ethylmaleimide but not by nocodazole. In striking contrast, these drugs did not prevent repeated VLD formation and reversal in response to standard osmo-mechanical perturbations; VLD disappearance during reversal and during recovery are different.The osmo-mechanical changes that elicited VLDs may, in an exaggerated fashion, mimic tension changes in extending and retracting neuntes. In this context we postulate: (a) the trafficking or disposition of membrane between internal stores and plasma membrane is mechano sensitive, (b) normally, this mechanosensitivity provides an on demand system by which neurons can accommodate stretch/release perturbations and control cell shape but, (c) given sudden extreme mechanical stimuli, it yields VLDs. Present address: Biology Department, Washington University, St Louis, MO 63130-4899This work was supported by NSERC of Canada research grants to CEM and to LRM. CR was the recipient of a postdoctoral fellowship from the Ministere francais de la Recherche et de l'Espace. We thank J-M. Trifaro for the use of his image processing equipment.     

Near-infrared dyes for six-color immunophenotyping by laser scanning cytometry

BACKGROUND: To adequately analyze the complexity of the immune system and reduce the required sample volume for immunophenotyping in general, more measurable colors for the discrimination of leukocyte subsets are necessary. Immunophenotyping by the laser scanning cytometer (LSC), a slide-based cytometric technology, combines cell detection based on multiple colors with their subsequent visualization without the need for physical cell sorting. In the present study, the filter setting of the LSC was adapted for the measurement of the far-red emitting dye cyanine 7 (Cy7), thereby increasing the number of measurable commercially available fluorochromes. METHODS: The optical filters of the LSC were replaced-photomultiplier (PMT) 3/allophycocyanin (APC): 740-nm dichroic long pass, and 670-/55-nm bandpass; PMT 4/Cy7: 810-/90-nm bandpass. Peripheral blood leukocytes were stained directly by fluorochrome-labeled antibodies or by indirect staining. The tandem dyes of Cy7 (phycoerythrin [PE]-Cy7, APC-Cy7) and the fluorochromes fluorescein isothiocyanate (FITC), PE, PE-Cy5, and APC were tested alone and in different combinations. RESULTS: With the new filter combination and tandem fluorochromes, Cy7 was measurable at 488-nm (argon laser) or 633-nm (helium-neon laser) excitation. Resolution was in the range of FITC for PE-Cy7 but approximately 30% lower for APC-Cy7; spillover into the respective donor fluorochrome channel for both tandem dyes was prominent. A six-color panel for leukocyte subtyping was designed. CONCLUSIONS: With this adaptation, it is possible to measure the tandem conjugates PE-Cy7 and APC-Cy7. This new setup opens the way for six-color immunophenotyping by LSC.     

Comparison of helium-neon and dye lasers for the excitation of allophycocyanin

Allophycocyanin (APC) has a broad absorption spectrum permitting several different lasers to be used to excite this dye in a flow cytometer. A comparison was made between a dye laser and a helium-neon (HeNe) laser for the excitation of APC as an immunofluorescent chromophore. The ratio of fluorescence of stained to unstained lymphocytes (signal to background) was used to assess differences in sensitivity. In determining the best wavelength for operating the dye laser, it was found that there was little difference in the ability to separate the positive-labelled cells from the unstained cells using 600 nm or 633 nm light for excitation of APC. A study of the effect of laser power on the signal to background identified a nonlinear relationship. It was found that the sensitivity obtained with 47 mW of 633 nm light from a HeNe laser was near the maximum attainable. This sensitivity was comparable to that obtained using phycoerythrin as an immunofluorescence chromophore. APC had the added advantage of being applicable to the study of highly autofluorescent cells. Exciting this chromophore using red light dramatically decreased the autofluorescence observed even on alveolar macrophages.     

Increased immunofluorescence sensitivity using 532 nm laser excitation.

OBJECTIVE: We evaluated the use of a high power, diode pulsed solid-state laser emitting 532 nm light for immunofluorescence applications. We compared the sensitivity and utility of this laser with the standard 488 nm excitation. METHODS: A flow cytometer was equipped with both a 488 nm and a 532 nm laser; fluorescence emissions from each laser were collected using the same filters and the same detector system. Cells or compensation beads (e.g. latex beads coated with anti-kappa antibodies) were stained with monoclonal antibodies conjugated to phycoerythrin (PE) as well as the PE tandem dyes TRPE, Cy5PE, Cy5.5PE, and Cy7PE. The sensitivity of detection of these reagents as well as those in heavily compensated channels was quantified by measuring the spreading error for a primary detector into a secondary detector. RESULTS: Measurement of the fluorescence emission of PE and PE-tandem dyes was considerably more sensitive when using 532 nm excitation (150 mW) as compared with 488 nm excitation (20 mW). In addition, as the absolute number of photoelectrons collected was greater, there was less measurement-error-induced spread into the compensated channels. As an example, when comparing the spreading error of PE labeled cells into the TRPE detector, the green laser was found to be 15-fold more sensitive as compared with the blue laser. In addition, the blue laser produced more autofluoresent signal from cells as compared with the green laser. Together, these advantages of the 532 nm excitation line provides for a significantly improved detection of immunofluorescence staining.     

Acousto-optic laser-scanning cytometer

An instrument has been developed that uses a computer-controlled rapidly scanning laser beam to make cytometric measurements on cells or particles and which can measure low levels of fluorescence when using low-power lasers (Gershman, Hoffman, and O'Connell, "Methods and Apparatus for Analysis of Particles and Cells.") The method used is based upon acousto-optic principles of light diffraction. A vertically polarized 5-mW He-Ne laser is directed into an acousto-optic Bragg cell in which a portion of the incident light undergoes a small angular variation or deflection. Suitable optics focus the beam to a 25 microns diameter spot, at the 1/e2 point, in a sample cuvette while translating the angular variation into a linear scan. The cuvette enclosing the sample is slowly moved (approximately 1 micron/ms) via a stepper drive into the scanning beam while the forward angle light scatter sensor is monitored for the presence of valid signal events. When an event occurs, appropriate software optimizes the position of the focused laser beam onto the cell. Subsequently, scanning is stopped to allow for cell interrogation times that last for milliseconds or longer.     

Cascade blue as a donor for resonance energy transfer studies of heme-containing proteins

Cascade Blue acetyl azide is an amine reactive compound with spectral properties ideally suited for fluorescence resonance energy transfer (FRET) studies in which heme prosthetic groups serve as acceptors. To demonstrate utility of the Cascade Blue-heme spectroscopic ruler, cytochrome c was employed as a test case to calibrate distance measurements obtained from FRET analysis. Following modification, stoichiometrically labeled cytochrome c was digested with trypsin and derivatized fragments were analyzed by matrix-assisted laser desorption/ionization and electrospray ionization mass spectrometry to identify Lys25 as the predominant site of covalent modification. FRET analysis on derivatized protein demonstrated nearly complete quenching of Cascade Blue fluorescence, indicating the labeled lysine residue to reside within 30 A of the heme prosthetic group. Sodium dodecyl sulfate (SDS) denaturation resulted in an approximately 28% recovery of fluorescence, demonstrating the utility of this donor-acceptor pair for evaluating distance changes of 30-90 A. Modeling the Cascade Blue donor molecule onto Lys25 of a cytochrome c NMR structure confirmed a distance of < or =30 A from the heme acceptor, as determined by FRET analysis. Further modeling of the SDS-denatured state as an extended chain suggested a maximum separation distance of 45 A, also consistent with results derived from FRET analysis.     

Cascade blue derivatives: water soluble, reactive, blue emission dyes evaluated as fluorescent labels and tracers.

Fluorescent dyes based on the pyrenyloxytrisulfonic acid (Cascade Blue) structure were prepared and evaluated. The dyes contain functional groups that react with amines, thiols, acids, aldehydes, and ketones, forming covalently bonded, fluorescent derivatives of molecules with broad biological interest. Reactive groups in the Cascade Blue dyes include carboxylic acids and activated esters, amines, hydrazides, alcohols, photoaffinity reagents, acrylamides, and haloacetamides. The dyes exhibited absorption maxima at 374-378 nm and 399-403 nm, with extinction coefficients in the range of 1.9 x 10(4)-2.4 x 10(4) M-1cm-1 and 2.3 x 10(4)-3.0 x 10(4) M-1cm-1, respectively. Emission maxima ranged from 422-430 nm. The spectral properties of the fluorescent dyes are sufficiently different from fluorescein to permit simultaneous use of both dyes with minimum spectral interference. The Cascade Blue derivatives have narrower spectral bandwidths and smaller Stokes' shifts than other reactive dyes with similar spectral properties, do not show appreciable sensitivity to pH, have higher solubilities in aqueous solution, and have good to excellent quantum yields. Cascade Blue conjugates of a number of histochemically and biologically useful molecules were prepared, including dextrans, albumins, Fc receptor binding proteins, antibodies, lectins, membrane receptor binding proteins, and biotin binding proteins, as well as biological particles and bacteria. Cascade Blue conjugates of secondary and tertiary labels yielded specific fluorescence localization in the indirect immunofluorescent staining of human epithelial cell (HEp-2) nuclei.     

A rapid analytical technique for flow cytometric analysis of cell viability using calcofluor white M2R

Analysis of dead versus live cells is shown to be possible using Calcoflour White M2R (CFW), a fluorescent brightener. Comparison of CFW with both propidium iodide (PI) and fluorescein diacetate (FDA) was performed on a FACS 440 dual laser flow cytometer on several populations of cultured rat and mouse cell lines, peripheral leukocytes, splenocytes, diatoms, and plant protoplasts. As a measure of cell viability, staining results with CFW were strongly associated with PI (correlation coefficient of 0.9886) and FDA (inverse correlation coefficient of 0.9647). With plant and algal cells, controls are necessary as CFW does stain live cells to some extent. CFW (excitation: UV, emission max: 435 nm) can be used in conjunction with two-color immunofluorescence analysis using fluorochromes excited at 488 nm with no interference.     

Flow cytometer based on triggered supercontinuum laser illumination

Multiple wavelength operation in a flow cytometer is an exciting way for cell analysis based on both fluorescence and optical scattering processing. For example, this multiparametric technique is currently used to differentiate blood cells subpopulations. The choice of excitation wavelengths matching fluorochrome spectra (it is currently the opposite) and the use of a broader range of fluorochromes can be made by taking advantage of a filtered supercontinuum white light source. In this study, we first wished to validate the use of a specific triggered supercontinuum laser in a flow cytometer based on white light scattering and electric sizing on human blood cells. Subsequently, to show the various advantages of this attractive system, using scattering effect, electrical detections, and fluorescence analysis, we realized cells sorting based on DNA/RNA stained by thiazole orange. Discrimination of white blood cells is efficiently demonstrated by using a triggered supercontinuum-based flow cytometer operating in a "one cell-one shot" configuration. The discriminated leukocyte populations are monocytes, lymphocytes, granulocytes, immature granulocytes, and cells having a high RNA content (monoblasts, lymphoblasts, and plasma cells). To the best of our knowledge, these results constitute the first practical demonstration of flow cytometry based on triggered supercontinuum illumination. This study is the starting point of a series of new experiments fully exploiting the spectral features of such a laser source. For example, the large flexibility in the choice of the excitation wavelength allows to use a larger number of fluorochromes and to excite them more efficiently. Moreover, this work opens up new research directions in the biophotonics field, such as the combination of coherent Raman spectroscopy and flow cytometry techniques.     

Flow cytometry of Escherichia coli for process monitoring

A laser flow cytometer was used to study different Escherichia coli populations under various cultivation conditions. A host strain E. coli 5K was analyzed for cell size, protein and DNA-content during continuous cultivation. Also, a recombinant E. coli 5K(pHM12) strain (used for the intracellular production of penicillin-G acylase) was studied in regard to gene expression using different cytometric techniques. An argon ion laser (30 mW) and a 100 W high-pressure mercury lamp were used as light source in the cytometer. A new fluorogenic staining technique for intracellular penicillin-G acylase is described.Recombinant E. coli temperature sensitive cells were analyzed for intracellular fusion protein production due to temperature induction.     

Four color compensation.

Four-color immunophenotyping can now be routinely performed using either a single laser or dual laser flow cytometer. When a single laser instrument is used, the fluorochromes evaluated are usually FITC, PE, PE-TR and PE-CY5 (or PerCP). For two-laser excitation APC is generally used in place of PE-TR. Since each tandem dye construct contains PE, three of the four detectors are affected and compensation can be problematic. In this report we show that each tandem conjugated antibody, whether different batches from the same supplier or conjugates from different suppliers all require unique compensation. This inconsistency results in erroneous data, negates the use of single labeled particles as a method for providing adequate compensation and requires dual and triple labeled cells of known pattern to verify compensation. It is also shown that improper compensation can reduce or eliminate completely the detection of fluorescence emission from PECY5 conjugated antibodies. These problems are caused by a variation in energy transfer between PE and either TR or CY5 because the chemistry involved in preparation and conjugation to antibodies is not sufficiently controlled to produce reagents with uniform compensation requirements. The variation in tandem dye compensation can be addressed by either using the same tandem conjugated antibody, by using the same second step tandem reagent to an appropriate first step antibody or by using software compensation. The latter provides an easy solution because a unique compensation matrix can be produced for each antibody tandem conjugate.     

Extended application of flow microfluorometry by means of dual laser excitation

Summary A dual laser beam excitation device for flow analysis of biological particles has been developed. The aid of this arrangement is to increase the range of fluorescent agents employed so far in quantitative and qualitative cytochemistry. Combining an argon ion and a helium-cadmium laser two color fluorescence measurements were performed employing propidium iodide as a DNA stain and fluorescamine which stains total protein in fixed cells. Energy transfer processes between the antibiotic and DNA specific dye mithramycin and propidium iodide both being bound to nuclear chromatin were analyzed. Utilization of energy transfer processes is generally discussed as a mean to extract information about the structure and conformation of nuclear chromatin in situ. The application of a crypton ion laser with three lines near 400 nm and a single line at 350 nm having a light output in each range of nearly one Watt gives the opportunity of utilizing DNA fluorochromes which have an excitation maximum in the deep blue region. DNA spectra are shown employing mithramycin, the benzimidazol derivative 33258 (Hoechst) and the indol compound DAPI which has a high DNA specifity combined with a great stability under UV illumination. By separating two focussed laser beams at their intereecting points with the liquid sample stream the trajectory of each flowing cell crosses the beams sequentially, which causes a solitary dual excitation of each cell. The advantages of a solitary excitation device compared with a simultaneous one is discussed.This work has been supported by the ministry of research and technology (FRG), contract No. 01VH015-B13MT 225a     

Safety assessment of near infrared light emitting diodes for diffuse optical measurements

Background  

Near infrared (NIR) light has been used widely to monitor important hemodynamic parameters in tissue non-invasively. Pulse oximetry, near infrared spectroscopy, and diffuse optical tomography are examples of such NIR light-based applications. These and other similar applications employ either lasers or light emitting diodes (LED) as the source of the NIR light. Although the hazards of laser sources have been addressed in regulations, the risk of LED sources in such applications is still unknown.     

Comparison of three commercially available antibodies for flow cytometric monitoring of P-glycoprotein expression in tumor cells.

Cellular drug resistance to natural products is often due to the presence of an efflux pump which reduces intracellular drug content and chemosensitivity. A 170 kD cell surface resident P-glycoprotein is believed to act as the efflux pump. In the present report, we have compared three commercially available antibodies C-219, JSB-1, and mdr(Ab-1) for use in flow cytometric detection of P-glycoprotein positive cells. Our data show that C219 gives uniformly good results in a variety of murine and human tumor cell lines for detection of P-glycoprotein positive cells. We have also compared data of C219 stained cells analyzed in parallel on a flow cytometer equipped with a small laser (15 mW) and a large laser (5 watt) cell sorter. Data obtained on these two instruments are comparable. A staining protocol and data on dual staining of cells for DNA content by propidium iodide and P-glycoprotein expression after FITC labeling are also presented.