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.     

Cryptomonad algal phycobiliproteins as fluorochromes for extracellular and intracellular antigen detection by flow cytometry

BACKGROUND: Phycobiliproteins play an important role in fluorescent labeling, particularly for flow cytometry. The spectral properties of R-phycoerythrin (R-PE) and allophycocyanin (APC) have made them the dominant reagents in this class of fluorochromes. In this study, we evaluate a lesser-known but potentially important series of low-molecular weight cryptomonad-derived phycobiliproteins (commercially termed the CryptoFluortrade mark dyes) for their applicability to flow cytometry, both in extracellular and intracellular labeling applications. METHODS: Several cell lines were labeled with biotin-conjugated antibodies against expressed extracellular surface proteins, followed by streptavidin conjugates of three cryptomonad phycobiliproteins (CryptoFluor-2, CryptoFluor-4, and CryptoFluor-5). Cells were then analyzed by flow cytometry using a variety of laser lines and emission filters to establish the optimal excitation/emission characteristics for each fluorochrome. Some cells were permeabilized and labeled for intracellular antigens, also using the cryptomonad fluorochromes. Where appropriate, parallel samples were labeled with other fluorochromes (including R-PE, APC, the cyanin dyes Cy3 and Cy5, and others) to gauge the performance of the cryptomonad fluorochromes against fluorescent labels previously evaluated for flow cytometry. RESULTS: CryptoFluor-2 possessed excitation/emission maxima similar to those of APC and Cy5, with good excitation in the red (HeNe laser 632 nm) and strong emission in the far red (660 nm). CryptoFluor-4 possessed excitation/emission maxima similar to those of Cy3, with optimal excitation in the green (Kr 530 nm) and strong emission in the yellow/orange (585 nm). CryptoFluor-5 possessed excitation/emission maxima similar to those of lissamine rhodamine, with optimal excitation in the yellow (Kr 568 nm) and emission in the orange (610 nm). All cryptomonad fluorochromes gave satisfactory results for both intracellular and extracellular labeling, with detection sensitivities that were comparable or better than traditional phycobiliproteins and low- molecular weight synthetic fluorochromes such as the cyanin dyes. CONCLUSIONS: The CryptoFluor fluorochromes were applicable to flow cytometric immunodetection, with excitation and emission conditions commonly found on multilaser instruments. Performance of several of these dyes was at least comparable to existing fluorescent labels. The low molecular weights (30-60 kd) of phycobiliproteins may make them particularly useful in intracellular antigen detection. Cytometry 44:16-23, 2001. Published 2001 Wiley-Liss, Inc.     

Human lymphocyte subpopulations identified by using three-color immunofluorescence and flow cytometry analysis: correlation of Leu-2, Leu-3, Leu-7, Leu-8, and Leu-11 cell surface antigen expression

Three-color immunofluorescence has been used to determine the co-expression of cell surface antigens on human peripheral blood lymphocytes. Monoclonal antibodies or avidin were coupled to either FITC (green), phycoerythrin (orange), or Texas Red (red) fluorochromes. These three fluorochromes could be independently measured by using a dual laser FACS IV system equipped with an argon ion laser (488 nm) and a dye laser (600 nm). Human peripheral blood lymphocytes were stained with the following combinations of reagents: (1) FITC anti-Leu-11a + PE anti-Leu-2a + TR avidin/biotin anti-Leu-7; (2) FITC anti-Leu-11a + PE anti-Leu-3a + TR avidin/biotin anti-Leu-7; (3) FITC anti-Leu-8 + PE anti-Leu-2a + TR avidin/biotin anti-Leu-7; and (4) FITC anti-Leu-11a + PE anti-Leu-2 + TR avidin/biotin anti-Leu-8. The light scatter, green fluorescence, orange fluorescence, and red fluorescence signals for each sample were stored by a Consort 40 PDP/11 computer in list mode files. Sequential reanalysis of the data directly demonstrated the existence of several unrecognized subpopulations of lymphocytes. Previously, we reported that the anti-Leu-7 and anti-Leu-11 antibodies can be used to identify discrete subsets of human NK cells with distinct functional capacities. In this report, we show that these subsets can be further subdivided on the basis of Leu-8 and Leu-2 expression. Thus, these studies illustrate how multicolor and multiparameter flow cytometry can further our understanding of cellular heterogeneity within this group of lymphocytes.     

Nine color eleven parameter immunophenotyping using three laser flow cytometry.

BACKGROUND: This study describes a three laser flow cytometer, reagents, and software used to simultaneously evaluate nine distinct fluorescent parameters on one cell sample. We compare the quality of data obtained with (1) full software compensation and (2) the use of partial spectral compensation of selected pairs of parameters in analog hardware, in combination with final software compensation. An application characterizing low frequency murine B cell subpopulations is given. METHODS: The fluorochromes used are: fluorescein (FITC), phycoerythrin (PE), Cy5PE and Cy7PE, excited at 488 nm by an argon laser; Texas Red (TR), allophycocyanin (APC), and Cy7APC excited at 595 nm by a pumped dye laser; and cascade blue (CB) and cascade yellow (CY) excited at 407 nm by a violet-enhanced krypton laser. Custom additions to commercial electronics and an extended optical bench allow the measurement of these nine parameters plus forward and side scatter light signals. RESULTS: We find the use of partial analog compensation reduces the variation in the background staining levels introduced by the compensation process. Novel B cell populations with frequencies below 1% are characterized. CONCLUSIONS: Nine color flow cytometry is capable of providing measurements with high information content. The choice of reagent-dye combinations and the ability to compensate in multi-parameter measurement space are crucial to obtaining satisfactory results.     

Automated four-color analysis of leukocytes by scanning fluorescence microscopy using quantum dots.

BACKGROUND: Scanning fluorescence microscope (SFM) is a new technique for automated motorized microscopes to measure multiple fluorochrome labeled cells (Bocsi et al., Cytometry A 2004, 61:1-8). AIMS: We developed a four-color staining protocol (DNA, CD3, CD4, and CD8) for the lymphocyte phenotyping by SFM. METHODS: Organic (Alexa488, FITC, PE-Alexa610, CyChrom, APC) and inorganic (quantum dot (QD) 605 or 655) fluorochromes were used and compared in different combinations. Measurements were performed in suspension by flow cytometer (FCM) and on slide by SFM. RESULTS: Both QDs were detectable by the appropriate Axioplan-2 and FCM filters and the AxioCam BW-camera. CD4/CD8 ratios were highly correlated (P = 0.01) between the SFM and FCM. CONCLUSION: Automated SFM is an applicable tool for CD4/CD8 ratio determination in peripheral blood samples with QDs.     

Polychromatic (eight-color) slide-based cytometry for the phenotyping of leukocyte, NK, and NKT subsets.

BACKGROUND: Natural killer (NK) and NK T (NKT) cells are important in innate immune defense. Their unequivocal identification requires at least four antigens. Based on the expression of additional antigens, they can be further divided into functional subsets. For more accurate immunophenotyping and to describe multiple expression patterns of leukocyte subsets, an increased number of measurable colors is necessary. To take advantage of the technologic features offered by slide-based cytometry, repeated analysis was combined with sequential optical-filter changing. METHODS: Human peripheral blood leukocytes from healthy adult volunteers were labeled with antibodies by direct or indirect staining. Tandem dyes of Cy7 (phycoerythrin [PE]-/allophycocyanin [APC]-Cy7), Cy5.5 (PE-/APC-Cy5.5), and PE-Cy5 and the fluorochromes fluorescein isothiocyanate (FITC), PE, and APC were tested alone and in combinations. Optical filters of the laser scanning cytometer were 555 DRLP/BP 530/30 nm for photomultiplier tube (PMT) 1/FITC, 605 DRLP/BP 580/30 nm for PMT 2/PE, 740 DCXR/BP 670/20 nm for PMT 3/Cy5/APC, and BP 810/90 nm for PMT 4/Cy7. Filter PMT 3 was replaced for detection of PE/Cy5.5 and APC/Cy5.5 by 740 LP/BP 710/20 nm and the sample was remeasured. Both data files were merged into one to combine the different information on a single-cell basis. The combination of eight antibodies against CD3, CD4, CD8, CD14, CD16, CD19, CD45, and CD56 was used to characterize NK and NKT cells and their subsets. RESULTS: In this way Cy5.5 is measurable at 488-nm and 633-nm excitation. Further, with the two different filters it is possible to distinguish Cy5 from Cy5.5 in the same detection channel (PMT 3). With this method we identified NK and NKT cells, subsets of NK (CD3-16+56+, CD3-16+56-, CD3-16-56+) and NKT (CD3+16+56+, CD3+16-56+) and their CD4+8-, CD4-8+, CD4-8- and CD4+8+ subsets. CONCLUSION: With our adaptations it is possible to discriminate tandem conjugates of Cy5, Cy5.5, and Cy7 for eight-color immunophenotyping. Using this method, novel rare subsets of NK and NKT cells that are CD4/CD8 double positive are reported for the first time.     

Hyperchromatic cytometry principles for cytomics using slide based cytometry.

BACKGROUND: Polychromatic analysis of biological specimens has become increasingly important because of the emerging new fields of high-content and high-throughput single cell analysis for systems biology and cytomics. Combining different technologies and staining methods, multicolor analysis can be pushed forward to measure anything stainable in a cell. We term this approach hyperchromatic cytometry and present different components suitable for achieving this task. For cell analysis, slide based cytometry (SBC) technologies are ideal as, unlike flow cytometry, they are non-consumptive, i.e. the analyzed sample is fixed on the slide and can be reanalyzed following restaining of the object. METHODS AND RESULTS: We demonstrate various approaches for hyperchromatic analysis on a SBC instrument, the Laser Scanning Cytometer. The different components demonstrated here include (1) polychromatic cytometry (staining of the specimen with eight or more different fluorochromes simultaneously), (2) iterative restaining (using the same fluorochrome for restaining and subsequent reanalysis), (3) differential photobleaching (differentiating fluorochromes by their different photostability), (4) photoactivation (activating fluorescent nanoparticles or photocaged dyes), and (5) photodestruction (destruction of FRET dyes). Based on the ability to relocate cells that are immobilized on a microscope slide with a precision of approximately 1 microm, identical cells can be reanalyzed on the single cell level after manipulation steps. CONCLUSION: With the intelligent combination of several different techniques, the hyperchromatic cytometry approach allows to quantify and analyze all components of relevance on the single cell level. The information gained per specimen is only limited by the number of available antibodies and sterical hindrance.     

Use of phycoerythrin and allophycocyanin for fluorescence resonance energy transfer analyzed by flow cytometry: advantages and limitations

BACKGROUND: This study validates the use of phycoerythrin (PE) and allophycocyanin (APC) for fluorescence energy transfer (FRET) analyzed by flow cytometry. METHODS: FRET was detected when a pair of antibody conjugates directed against two noncompetitive epitopes on the same CD8alpha chain was used. FRET was also detected between antibody conjugate pairs specific for the two chains of the heterodimeric alpha (4)beta(1) integrin. Similarly, the association of T-cell receptor (TCR) with a soluble antigen ligand was detected by FRET when anti-TCR antibody and MHC class I/peptide complexes () were used. RESULTS: FRET efficiency was always less than 10%, probably because of steric effects associated with the size and structure of PE and APC. Some suggestions are given to take into account this and other effects (e.g., donor and acceptor concentrations) for a better interpretation of FRET results obtained with this pair of fluorochromes. CONCLUSIONS: We conclude that FRET assays can be carried out easily with commercially available antibodies and flow cytometers to study arrays of multimolecular complexes.     

外周血T淋巴细胞亚群流式检测方法的优化及验证

为优化外周血T淋巴细胞亚群流式检测方法,采集小鼠肝素钠抗凝血,用FITC rat anti-mouse CD3、APC rat anti-mouse CD4和PE rat anti-mouse CD8a荧光抗体进行染色,裂解红细胞,通过流式细胞仪检测各亚类细胞占淋巴细胞百分比。从样本体积（50 μL和100 μL）、FITC rat anti-mouse CD3抗体的工作浓度（1.25~40.00 μg·mL^-1）、APC rat anti-mouse CD4抗体的工作浓度（0.625~20.000 μg·mL^-1）、PE rat anti-mouse CD8a抗体的工作浓度（1.25~40.00 μg·mL^-1）及红细胞裂解条件（时间和裂解次数）等方面对检测方法进行了优化,并验证方法的精密度（批内差异和批间差异）;同时对样品4 ℃放置24 h、室温放置24 h、染色处理后4 ℃放置24 h的稳定性进行验证。结果表明,50 μL抗凝血中加入终浓度1.25 μg·mL^-1 FITC rat anti-mouse CD3、1.25 μg·mL^-1 APC rat anti-mouse CD4和5.00 μg·mL^-1 PE rat anti-mouse CD8a,室温避光孵育30 min,加入红细胞裂解液,裂解5 min,用磷酸盐缓冲液（phosphate buffer saline,PBS）终止裂解后,重复裂解1次,再用PBS重悬后上机检测,批内差异和批间差异均<15%,符合标准。染色处理后样品4 ℃放置24 h可保持稳定性。对流式检测小鼠外周血T细胞亚群的基本方法进行全面优化及验证,旨在为临床前免疫毒性评价提供研究方法和实验数据,以及为流式细胞术分析临床血液淋巴细胞免疫表型的方法学研究提供参考依据。     

A unified procedure for conservative (morphology) and integral (DNA and immunophenotype) cell staining for flow cytometry

BACKGROUND: Current methods for multiparameter DNA flow cytometry suffer from several limitations. These include significant modifications of cell morphological parameters, the impossibility to counterstain cells with certain fluorochromes, and laborious tuning of the instrument that, for some procedures, must be equipped with an ultraviolet (UV) laser. To overcome these problems, we developed a novel method for the simultaneous analysis of morphological parameters, four-color immunophenotyping, and stoichiometric DNA labeling using a bench-top flow cytometer. METHODS: The method consists of a mild permeabilization/fixation treatment at room temperature, followed by labeling with fluorochrome-conjugated monoclonal antibodies (mAbs) and with the DNA dye 7-aminoactinomycin D (7-AAD) at 56 degrees C. RESULTS: Using this method, we analyzed resting peripheral blood mononucleated cells (PBMC), proliferating T cells cultured in the presence of interleukin-2 (IL-2), and lymphoblastoid B cells. Lymphocytes, monocytes, and lymphoblasts treated by this procedure retained differential light scattering (DLS) characteristics virtually identical to those of untreated cells. This allowed regions to be drawn on forward scatter (FSC) and side scatter (SSC) cytograms resolving different cell populations. DLS were preserved well enough to distinguish large lymphoblasts in the S or G2/M phases from small G0/G1 cells. Also, stainability with fluorescein-isothiocyanate (FITC), R-phycoerythrin (PE), allophycocyanin (APC)-conjugated mAbs was generally preserved. DNA labeling with 7-AAD was of quality good enough to permit accurate cell cycle analysis. CONCLUSIONS: The method described here, which we called integral hot staining (IHS), represents a very simple, reproducible, and conservative assay for multiparameter DNA analysis using a bench-top flow cytometer. Last but not least, the cytometer tuning for multiparameter acquisition is straightforward.     

Detection of very low receptor numbers on cells by flow cytometry using a sensitive staining method

We describe a staining method for flow cytometry that resolves with a high degree of sensitivity very low numbers of cell surface molecules, which are normally too few to detect using the conventional fluorescein-conjugated reagents. We took advantage of the fact that liposomes can be constructed to contain hundreds of thousands of fluorochrome molecules per vesicle; antigen specificity can be conferred by covalently conjugating them to antibodies or protein A. Unlike fluorochromes such as fluorescein isothiocyanate (FITC) that are directly conjugated to protein ligands with a fluorochrome to protein ratio of about 2 to 1 on the average, their large encapsulating capacity gives liposomes a tremendous potential for signal amplification. In an indirect immunofluorescence study using liposomes that contained the fluorochrome carboxyfluorescein (CF) and that were covalently conjugated to protein A, we were able to obtain up to 50 times the fluorescence signal over background that could be detected with FITC-conjugated protein A. Scatchard analysis showed that the thymoma cell line RDM4 expresses 23,000 and 2,600 binding sites for monoclonal antibodies (mAb) against H-2K and H-2D, respectively. When RDM4 cells were treated with anti-H-2K mAb followed by FITC-conjugated protein A, at best we were able to obtain a fluorescence signal that was only 7 times above background. However, when these cells were treated with the same antibody followed by protein A conjugated to small unilamellar liposomes or large unilamellar liposomes, the fluorescence signals were 110 and 335 times above background, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Confocal multilaser focusing and single-laser characterization of ultraviolet excitable stains of cellular preparations

BACKGROUND: The aims of this study were (1) to realign cellular preparations when spots and structures are excited by different lasers of a confocal laser scanning microscope (multilaser studies); (2) to avoid the use of realigment methods by selecting fluorochromes that can be excited by only one laser (single-laser experiments). METHODS: In multilaser studies, we used propidium iodide fluorescent beads, as well as tetramethyl rhodamine isothiocyanate (TRITC), fluorescein isothiocyanate (FITC), and 4'-6 diamidino-2-phenylindole (DAPI)-stained human cancer lines. They were excited using HeNe, argon, and ultraviolet (UV) argon laser lines of a confocal laser scanning microscope. Single-laser experiments using UV excitation only were performed using europium as a model for magnetic resonance paramagnetic contrast agents. Nuclei of human cancer lines and tissue were counterstained by DAPI and cytoplasms were labeled with ELF-97 substrates. Factor analysis of medical images (FAMIS) and correlation methods were used to realign shifted images, focus images, and characterize each fluorochrome when necessary. RESULTS: In multilaser studies, superimposition of factor images corrected Z shifts and correlation methods provided X, Y correction values. In single-laser experiments, each fluorochrome was clearly distinguished in the group of fluorochromes. Estimated images in both studies showed colocalizations of structures. CONCLUSIONS: It is possible to characterize differences in the focus and alignment of fluorescent probes and to correct them. It is also possible to study colocalization of UV excitable fluorochromes (DAPI, ELF-97, europium) in cellular and tissular preparations via multilaser or single-laser experiments.     

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.     

Increased FITC fluorescence on LPS stimulated neutrophils cultured in whole blood

Recently, it has been observed that Annexin V labelling of phosphatidylserine (PS) on non-apoptotic cells can vary in different leukocyte populations and with the activation of cells, due to differences in the absolute level of exposed PS. We have also observed changes in the absolute level of Annexin V-FITC intensity, but under conditions where absolute PS expression did not change. In the present study, we have explored the effect of neutrophil cell activation on Annexin V-FITC fluorescence intensity by comparing alternatively labelled matched antibodies against Annexin V. Human venous whole blood was cultured with and without stimulation with lipopolysaccharide (LPS). Apoptosis in the neutrophil and lymphocyte populations was analyzed by flow cytometry and the intensity of FITC labelling was compared to matched fluorochromes conjugated to the same cell surface markers. There was an increase in the intensity of Annexin V-FITC in non-apoptotic neutrophils when stimulated with LPS, which did not correlate with increased apoptosis. Furthermore, CD65-FITC intensity also increased on activated neutrophils. Activated neutrophils exhibited higher amounts of FITC fluorescence that were not associated with changes in extracellular PS expression. This effect appears to be fluorochrome related, likely due to an increase in the pH surrounding activated neutrophils.     

Fluorochrome Staining of Multilamellar Liposomes

Multilamellar liposomes can be stained with such fluorochromes as acridine orange, eosin Y, neutral red, and thiazine red. The liposomes are brought into a 1% solution of the fluorochrome; 5-10 minutes later they are centrifuged and washed by resuspending in water or phosphate buffered saline three times. The last pellet is resuspended and a drop studied with the fluorescence microscope (1000 × magnification). The fluorochrome is seen to be accumulated in the liposomal membranes.

Acridine orange could also be trapped in the aqueous compartments of the liposomes but the trapped fluorochrome was gradually lost from the liposomes. Part of the fluorochrome, however, remained associated with the liposomal membranes for a long time.

Additional experiments justify the conclusion that an equilibrium is maintained between fluorochromes in the aqueous and lipid phases.     

Quantitative histology by multicolor slide-based cytometry.

BACKGROUND: In lymphatic organs, the quantitative analysis of the spatial distribution of leukocytes by tissue cytometry would give relevant information about alterations during diseases (leukemia, HIV, AIDS) and their therapeutic regimen, as well as in experimental settings. METHODS: We have developed a semiautomated analysis method for laser scanning cytometry (LSC) termed "multiple thresholding," which is suitable for archived or fresh biopsy material of human lymph nodes and tonsils. Sections are stained with PI for nuclear DNA and up to four antigens using direct or indirect immunofluorescence staining. Measurement is triggered on DNA-fluorescence (argon laser, Ar) or on specific cell labeling. Due to the heterogeneity of cell density, measurements are performed repeatedly at different threshold levels (low threshold: regions of low cellular density, germinal center; high threshold: dense regions, mantle zone). Data are acquired by single- (Ar) or dual-laser excitation (Ar-HeNe) in order to analyze single- (FITC) up to four-color (FITC/PE/PECy5/APC) stained specimen. RESULTS: Percentage and cellular density of cell-subsets is quantified in different microanatomical regions of the specimen. These data were highly correlated with manual scoring of identical specimens (r(2) = 0.96, P < 0.0001). With LSC, semiautomated operator-independent immunophenotyping in tissue sections of lymphatic organs with up to three antibodies simultaneously is possible. CONCLUSIONS: We expect this tissue cytometric approach to yield new insight into processes during diseases and help to quantify the success of therapeutic interventions.     

Simultaneous analysis of lymphocyte markers using triple color markers

The introduction in flow cytometry of the new reagent Streptavidin Duochrome allows the simultaneous three color analysis of biological samples. Streptavidin Duochrome is a phycoerythrin-Texas red fluorochrome complex conjugated to the protein streptavidin. This novel complex exploits the principle fluorescence energy transfer when this reagent is used with FITC, PE and biotin-conjugated monoclonal antibodies; three different emissions of fluorescence are possible simultaneously using an argon laser at 488 nm (FACScan Becton Dickinson). Using Paint-a-gate software which analyses samples and displays the three colors on a screen, antigen distribution on multiple cell populations is obtained. Single, double and triple labeled cells (up to seven combinations) are visualized and quantified quickly and easily. Using a panel of normal donors we have evaluated the following combinations: CD3/CD4/CD8 to visualize T lymphocytes and their subsets; CD3/CD19/CD16 to quantify quickly the T, B, NK populations; CD4/Leu8/Leu18 to analyse the helper subset and CD3/CD8/Leu7. Our purpose is to evaluate the importance of this new kind of analysis to study the heterogeneity of several lymphocytic populations.     

Fluorochrome staining of multilamellar liposomes.

Multilamellar liposomes can be stained with such fluorochromes as acridine orange, eosin Y, neutral red, and thiazine red. The liposomes are brought into a 1% solution of the fluorochrome; 5-10 minutes later they are centrifuged and washed by resuspending in water or phosphate buffered saline three times. The last pellet is resuspended and a drop studied with the fluorescence microscope (1000 x magnification). The fluorochrome is seen to be accumulated in the liposomal membranes. Acridine orange could also be trapped in the aqueous compartments of the liposomes but the trapped fluorochrome was gradually lost from the liposomes. Part of the fluorochrome, however, remained associated with the liposomal membranes for a long time. Additional experiments justify the conclusion that an equilibrium is maintained between fluorochromes in the aqueous and lipid phases.     

Intracellular cytokine optimization and standard operating procedure

We describe here a method for optimizing the use of polychromatic flow cytometry (with up to 17 fluorochromes simultaneously) in surface and intracellular staining of human T lymphocytes. We will highlight and discuss how to procedurally optimize key steps in the experimental process before an intracellular cytokine staining assay protocol is finalized. These include but are not limited to the titration of monoclonal antibodies, use of a dead-cell discriminator and 'dump' channel, selection of a cytokine secretion inhibitor, selection of fixation and permeabilization reagents, and inclusion of compensation controls. Building on this basic protocol, we then establish a polychromatic assay designed to detect five separate functions of T lymphocytes (production of three cytokines and one chemokine, and degranulation) while simultaneously identifying multiple surface markers on the responding cells.     

Confocal analysis of phosphatidylserine externalization with the use of biotinylated annexin V revealed with streptavidin-FITC, -europium, -phycoerythrin or -Texas Red in oxysterol-treated apoptotic cells

OBJECTIVE: To analyze externalization of phosphatidylserine via annexin V on apoptotic cells by laser scanning confocal microscopy and factor analysis of biomedical image sequences (FAMIS). STUDY DESIGN: Streptavidin-fluorescein isothiocyanate (FITC), -europium (Eu), -phycoerythrin (PE) and -Texas Red (TR) were chosen to reveal the binding of biotinylated annexin V on apoptotic U937 human leukemic cells and ECV-304 human endothelial cells induced under treatment with 7-ketocholesterol or 7 beta-hydroxycholesterol. Excitation of each fluorochrome was obtained by selection of specific lines (351 + 364 nm, 488 nm) of the argon laser of a confocal microscope. Temporal and spectral series were performed to characterize each fluorochrome. FAMIS was applied to these series to estimate images corresponding to stains. RESULTS: Each fluorochrome was clearly distinguished, and images showed localization of phosphatidylserine, which was improved by image analysis. CONCLUSION: On apoptotic cells it is possible to analyze differences in the improved visualization of phosphatidylserine in series processed by FAMIS with the use of biotinylated annexin V revealed with streptavidin-FITC, -Eu, -PE or -TR.