Cytometry最新文献

Background: Removal of the nucleic acid-bound fluorochrome is desirable when stained cells have to be reanalyzed using other fluorochromes. It is also often desirable to remove DNA-bound antitumor drugs from drug-treated cells, to improve cell staining. We have previously observed that in aqueous solutions, the methylxanthine caffeine (CFN) decreases interactions between planar aromatic molecules such as intercalating dyes or antitumor drugs and nucleic acids. The aim of this study was to explore whether this property of CFN can be utilized to remove the DNA-bound intercalating dyes propidium iodide (PI) or 7-aminoactinomycin D (7-AAD) from the cells and whether the bleached cells can be restained and reanalyzed.

Methods: HL-60 cells were fixed in 70% ethanol and their DNA was stained with PI or 7-AAD. The cells were then rinsed with a 0.05 M solution of CFN in phosphate-buffered saline (PBS) or with PBS alone. The decrease in intensity of cell fluorescence during rinsing was measured by laser scanning cytometry (LSC) to obtain the bleaching kinetics of individual cells. The bleached cells were then restained with PI, 7-AAD, or the protein-specific fluorochrome sulforhodamine 101(S101). Their fluorescence was measured again by LSC. In addition, free DNA was subjected to gel electrophoresis, DNA bands in the gels were stained with ethidium bromide (EB), and the gels were rinsed with a solution of CFN or PBS to bleach the DNA band's fluorescence.

Results: Rinsing the PI or 7-AAD-stained cells with solutions of CFN led to nearly complete removal of PI and a more than 75% decrease in 7-AAD fluorescence after 10 min. The rinse with PBS decreased the PI cell fluorescence intensity by less than 30% and the 7-AAD fluorescence by about 50%. The differences in kinetics of PI or 7-AAD removal by CFN from G2/M versus G1 cells suggest that these intercalators bind more strongly to DNA in chromatin of G2/M than G1 cells. The CFN-bleached cells were then successfully stained with S101 and again with PI or 7-AAD. The bivariate analysis of the LSC merged files of the cells sequentially stained with PI and S101 revealed typical DNA/protein distributions. The fluorescence of EB-stained DNA bands in gels was also nearly completely removed by rinsing gels in 0.05 M CFN; PBS alone had a distinctly lesser effect.

Conclusion: Solutions of CFN can dissociate the DNA-bound PI, 7-AAD, EB, and possibly other intercalating fluorochromes. The bleached cells can be restained and reanalyzed by LSC. This approach can also be used to remove such fluorochromes from nucleic acids immobilized in gels and perhaps in other solid matrices. Analysis of the kinetics of fluorochrome removal from cells can possibly be used to study their binding affinities to nucleic acids in situ.

Background: In the present paper, we describe the effect of 4', 6-diamidino-2-phenylindole (DAPI) dihydrochloride concentration and pH on the resolution of DNA distribution histograms generated by dual-parametric simultaneous analysis of DNA content and electronic nuclear volume (ENV).

Methods: Nuclei from tissue culture cell lines and frozen human solid tumors were isolated in nuclear isolation media containing different concentrations of DAPI, at various pH levels, and analyzed on a NASA/American Cancer Society (ACS) flow cytometer. Samples stained with propidium iodide/hypotonic citrate and analyzed in a Coulter XL flow cytometer were used for comparison.

Results: Nuclei stained with DAPI concentration of 1-3 microg/ml, pH 6.0, gave the best resolution for the detection of the near-diploid and near-tetraploid populations. Simultaneous use of ENV and DAPI/DNA fluorescence under these conditions identified subpopulations that otherwise could not be detected by DNA analysis alone.

Conclusions: Staining at 1-3 microg/ml DAPI, pH 6.0, was optimal for the detection of aneuploid populations, especially the near-diploid and/or near-tetraploid populations in human tumors.

Background: Although the flow cytometer has become the standard in cell analysis, it has limitations. Recently, we introduced a new cell analysis method based on immunomagnetic selection and aligning of cells. No flow system is needed and cell analysis can be performed in whole blood.

Methods: Whole blood is incubated with fluorescent labels and immunomagnetic nanoparticles. The blood is injected into a capillary that is in a strong magnetic field. The immunomagnetic-labeled cells move upward and align themselves along ferromagnetic lines present on the upper surface of the capillary. An optical focus and tracking system analogous to that used in a conventional compact disk player focuses a 635-nm laser-diode on the magnetically aligned cells. The emitted fluorescence signals are projected on two photomultipliers. Allophycocyanin (APC)-labeled CD4 (CD4-APC) and Cyanin5.5 (Cy5.5)-labeled CD8 (CD8-Cy5.5) antibodies and Oxazine750, all red excited, are used as fluorescent labels.

Results: A differential white blood cell count performed in whole blood is obtained using the CD4-APC in combination with Oxazine750. The results are compared with the Technicon-H1 hematology analyzer. Correlation coefficients of 0.91 for neutrophilic granulocytes, 0.93 for lymphocytes, 0.93 for monocytes, and 0.96 for eosinophilic granulocytes were obtained. Immunofluorescence is demonstrated using CD4-APC and CD8-Cy5.5. The absolute counts obtained for CD4+ and CD8+ are compared with the Coulter Epics XL flow cytometer. Correlation coefficients of, respectively, 0.91 and 0.94 were obtained.

Conclusion: We conclude that our system is as capable as a standard flow cytometer or hematology analyzer for a reliable routine white blood cell analysis, including immunophenotyping, and can be used as an easy-to-handle disposable white blood cell test.

Background: Multiple cytokines are required for the growth and development of hematopoietic cells. The effect of many cytokines depends on the activity of other signaling pathways. These interactions are quantified using factorial experimental design and analysis.

Methods: Human umbilical cord blood (HUCB) CD34+ cells were cultured in fully defined media containing various combinations of recombinant cytokines as defined by resolution IV factorial (2(7-3)(IV)) or full factorial (2(4)) design experiments. The cytokines studied were stem cell factor (SCF), interleukin (IL)-3, megakaryocyte growth and development factor (MGDF), granulocyte-colony stimulating factor (G-CSF), Flt-3 ligand, IL-6, IL-11, and erythropoietin (EPO). In vitro cell divisions were tracked by staining CD34+ cells with 5-(and-6)-carboxyfluorescein diacetate, succinimidyl ester, followed by flow cytometric analysis at 4 days of culture. In separate experiments, lineage commitment and differentiation were determined at 7 days by immunophenotype.

Results: In addition to the main effects of single cytokines, cytokine interactions were identified. There was a negative interaction between IL-3 and MGDF that resulted in a less than additive effect of these factors on erythroid and megakaryocytic development. The effect of Flt-3 ligand and SCF factor on CD34+ cell production was also less than additive, although the response to both cytokines was greater than single cytokines. The only positive interaction that was identified was between EPO and SCF, which resulted in the synergistic production of erythroid cells.

Conclusions: Factorial analysis provides a powerful methodology to study the integration of multiple signals at the cellular and molecular level.

Laser scanning cytometry (LSC) is a relatively new slide-based technology developed for commercial use by CompuCyte (Cambridge, MA) for performing multiple fluorescence measurements on individual cells. Because techniques developed for performing four or more measurements on individual lymphoid cells based on light scatter as a triggering parameter for cell identification are not suitable for the identification of fixed epithelial tumor cells, an alternative approach is required for the analysis of such cells by LSC. Methods for sample preparation, event triggering, and the performance of multiple LSC measurements on disaggregated fixed human cells were developed using normal lymphocytes and two human breast cancer cell lines, JC-1939 and MCF-7, as test populations. Optimal conditions for individual cell identification by LSC were found to depend on several factors, including deposited cell density (cells per unit area), the dynamic range of probe fluorescence intensities, and intracellular distribution of the fluorescent probe. Sparsely deposited cells exhibited the least cell overlap and the brightest immunofluorescent staining. Major advantages of using DNA probes over a cytoplasmic immunofluorescent protein marker such as tubulin for event triggering are that the former exhibit greater fluorescence intensity within a relatively sharply demarcated nuclear region. The DNA-binding dye LDS-751 was found to be suboptimal for quantitative DNA measurements but useful as a triggering measurement that permits the performance of simultaneous fluorescein isothiocyanate-, phycoerythrin-, and indodicarbocyanine-based measurements on each cell. A major potential advantage of LSC over flow cytometry is the high yields of analyzable cells by LSC, permitting the performance of multiple panels of multicolor measurements on each tumor. In conclusion, we have developed and optimized a technique for performing multiple fluorescence measurements on fixed epithelial cells by LSC based on event triggering using the DNA-binding dye LDS 751. Although not ideal for quantitative measurements of cell DNA content, the large Stokes shift of this dye permits the performance of three or more additional fluorescence measurements on each cell.

Assay of fetal hemoglobin (HbF) and/or HbF containing red blood cells (F+ cells) is essential for monitoring sickle cell and thalassemic patients, especially during treatment with HbF stimulators. Some previous flow cytometric methods contain several washing steps. This simplified method contains no washing step and takes less than an hour to perform. The %F+ cells in five mixtures of fetal red blood cells with adult red blood cells were nonsignificantly different in the original and simplified procedure. The %F+ cells of 12 patients compared in these two procedures were also not significantly different. The intra- and interassay %CVs do not exceed 3% and 7% respectively. EDTA, citrate, or heparin is suitable as anticoagulant and the samples can be stored at 4 degrees C for up to 2 weeks. The %F+ cells and %HbF [by high-performance liquid chromatography (HPLC)] of 83 samples were highly significantly correlated regardless of diagnosis. In conclusion, this new simplified flow cytometric method for F+ cells is simple, convenient, rapid, reproducible, and could be applied for monitoring sickle cell and thalassemic patients as an alternative to HPLC, where this is unavailable. It can also be applied as a fetal cell assay in fetomaternal hemorrhage.

Background: CD14 is considered to be the major endotoxin (lipopolysaccharide [LPS]) binding molecule on human monocytes. It initiates cellular response, but its role in the clearance of LPS is not well understood. Under conditions that ensure totally CD14-dependent LPS binding on human monocytes, the internalization mechanisms of LPS and CD14 were studied.

Methods: The uptake and intracellular distribution of fluorescein isothiocyanate (FITC)-LPS and CD14 was determined by flow cytometry, trypan blue quenching, and confocal fluorescence microscopy. Incubation of surface-biotinylated cells with LPS at 37 degrees C or 4 degrees C and subsequent subfractionation was used to further characterize CD14 internalization. The amount of the intracellular CD14 was estimated by CD14 enzyme-linked immunosorbent assay (ELISA).

Results: The internalization rate of 10 ng/ml FITC-LPS with 1% human serum was 1% of bound endotoxin per minute, whereas CD14 expression did not decrease at the same time surface. We proved the presence of an intracellular CD14 pool (2.68 x 10(6) molecules per unstimulated monocyte) and could show that internalized FITC-LPS molecules can be found in different intracellular compartments than CD14. Subfractionation of LPS-treated biotinylated monocytes showed no change in biotinylated CD14 in the membrane fraction independently of the incubation temperature (37 degrees C or at 4 degrees C) used, indicating that these CD14 molecules were not taken up by an active process.

Conclusions: These data indicate the presence of a large intracellular CD14 pool in monocytes with a yet unknown function, and suggest that LPS and CD14 molecules can be internalized independently after association on the cell surface.

Background: Major histocompatibility complex (MHC)-peptide tetrameric complexes (tetramers) are valuable tools for detecting and characterizing peptide-specific T cells. Because the frequency of these cells is generally very low, it may be difficult to discriminate between nonspecific and specific tetramer binding.

Methods: A four-color flow cytometric assay that simultaneously measures tetramer, CD3, CD8, and CD14 was used to investigate the sensitivity and specificity of MHC class I tetramer staining. This was accomplished by using the influenza virus matrix protein peptide, GILGFVFTL (FLU), as a model recall antigen and the human immunodeficiency virus (HIV) reverse transcriptase peptide, ILKEPVHGV (HIV), as a model novel antigen. Peripheral blood mononuclear cells (PBMC) from 31 HLA-A2.1(+) and 10 HLA-A2.1(-) healthy individuals were stained with the tetramers.

Results: The lower limit of detection was established at approximately 1/8,000. In HLA-A2(+) PMBC, frequencies of tetramer-positive CD8(+) T cells were log normally distributed and were high for FLU (1/910) but low for HIV (1/6,067). A novel competition assay, in which tetramer binding was shown to diminish subsequent staining with anti-CD3 antibody, was used to confirm the specificity of tetramer binding to the T-cell receptor (TCR) complex. The competition assay was validated by evaluating several anti-CD3 antibodies and showing that in PBMC from HLA-A2(-) subjects, spurious tetramer-positive events (1/20,000) failed to compete with CD3 binding. For the "recall" FLU tetramer, the degree of competition was proportional to the frequency, suggesting a selection of high avidity cells. Although CD3 competition was also highly correlated with the intensity of tetramer staining, competition allowed the identification of false positive cases with relatively high tetramer staining intensity.

Conclusion: The data indicate that competition of CD3 binding allows confirmation of the specificity of tetramer binding to the TCR, extending the usefulness of tetramers in the frequency analysis of peptide-specific T lymphocytes.