Discrimination of eukaryotic phytoplankton cell types from light scatter and autofluorescence properties measured by flow cytometry

Flow cytometric methods for recognizing several groups of eukaryotic marine phytoplankton were tested using 26 laboratory cultures. Each culture was divided into three aliquots, and these samples were analyzed for 1) Coulter volume; 2) light scatter (magnitude and polarization properties of forward scattered light and magnitude of right-angle scattered light) and autofluorescence emission (phycoerythrin and chlorophyll); and 3) autofluorescence excitation (by 488 nm and 515 nm light). Three kinds of cells could be easily distinguished from others in the culture collection: 1) The two cryptophytes and the rhodophyte had high phycoerythrin/chlorophyll ratios; 2) the two coccolithophores depolarized forward scattered light; and 3) the two pennate diatoms scattered only a relatively small amount of light in the forward direction compared with that at right angles. Mean chlorophyll fluorescence excited by blue light relative to that excited by green light was highest in the four chlorophytes, but there was overlap between some of these and some other kinds of cells. Unresolved cell types included centric diatoms, dinoflagellates, and naked coccolithophores. Forward light scatter and Coulter volume were closely related (except for the pennate diatoms) over a range of about 0.01 to 30 pL (equivalent spherical diameter about 3 to 40 microns), according to a logarithmic function.     

Flow cytometric analysis of hairy cell leukemia using right-angle light scatter

We report on an easy and reliable method for the enumeration of the typical cells present in the blood, bone marrow, and spleen of patients with hairy cell leukemia. Samples of five patients were analyzed. In three patients, the hairy cells were very accurately followed during treatment with alpha-interferon, using right-angle light scatter to differentiate them from other leukocytes present in total blood. Excellent correlation was obtained with the microscopic hairy cell enumeration. Additional verification by cell sorting and immunofluorescence studies confirmed these findings.     

Human bone marrow CFU-GM and BFU-E localized by light scatter cell sorting

Flow cytometric separation was performed on the normal human bone marrow (BM) by using the low-angle (0 degrees) or high-angle (90 degrees) light scatter. Four distinct subpopulations of cells can be enriched from normal human BM and these fractions were subsequently evaluated for their morphological properties as well as their clonogenic capacity in various progenitor cell assays. Our results indicate that human erythroid and granulocyte-macrophage progenitor cells can be separated from BM low-density cells by cell sorting, and these cells show similar 0 degrees and 90 degrees light scatter properties to those observed with murine bone marrow studies. Flow cytometric analysis also suggests that the majority of sorted BFU-E and CFU-GM resides in the blast cell subset of human BM mononuclear cells.     

Automated quantitative analysis of epithelial cell scatter

Epithelial cell scatter is a well-known in vitro model for the study of epithelial-mesenchymal transition (EMT). Scatter recapitulates many of the events that occur during EMT, including the dissociation of multicellular structures and increased cell motility. Because it has been implicated in tumor invasion and metastasis, much effort has been made to identify the molecular signals that regulate EMT. To better understand the quantitative contributions of these signals, we have developed metrics that quantitatively describe multiple aspects of cell scatter. One metric (cluster size) quantifies the disruption of intercellular adhesions while a second metric (nearest-neighbor distance) quantifies cell dispersion. We demonstrate that these metrics delineate the effects of individual cues and detect synergies between them. Specifically, we find epidermal growth factor (EGF), cholera toxin (CT) and insulin to synergistically reduce cluster sizes and increase nearest-neighbor distances. To facilitate the rapid measurement of our metrics from live-cell images, we have also developed automated techniques to identify cell nuclei and cell clusters in fluorescence images. Taken together, these studies provide broadly applicable quantitative image analysis techniques and insight into the control of epithelial cell scatter, both of which will contribute to the understanding of EMT and metastasis.Key words: cell scatter, EMT, automated image analysis     

Improved bromodeoxyuridine/DNA analysis by anti-BudR monoclonal antibody versus right angle light scatter

Summary Dynamic cell cycle analysis is based on the incorporation of labelled precursors into DNA. Although antibodies to BrdU are very useful for analysing in flow cells which synthesize DNA, this approach has two main limitations. First, the detection of low incorporating cells is often difficult; second, four parameter flow cytometry is not able to correlate cell cycle to any other cellular marker. We have developed a methodology that, employing an IgG_H+L as a second antibody and side scatter instead of propidium iodide fluorescence, allows a better discrimination of BudR⁺ cells. This approach allows the collection of an extra-fluorescent signal, and the analysis of specific cellular markers within the cell cycle.     

Improved bromodeoxyuridine/DNA analysis by anti-BudR monoclonal antibody versus right angle light scatter

Dynamic cell cycle analysis is based on the incorporation of labelled precursors into DNA. Although antibodies to BrdU are very useful for analysing in flow cells which synthesize DNA, this approach has two main limitations. First, the detection of low incorporating cells is often difficult; second, four parameter flow cytometry is not able to correlate cell cycle to any other cellular marker. We have developed a methodology that, employing an IgGH + L as a second antibody and side scatter instead of propidium iodide fluorescence, allows a better discrimination of BudR+ cells. This approach allows the collection of an extra-fluorescent signal, and the analysis of specific cellular markers within the cell cycle.     

Linear correlation between bacterial overexpression of recombinant peptides and cell light scatter.

Fusion of multiple copies of a test peptide leads to insoluble inclusion bodies. Their presence within bacteria increases either forward-angle light scattering or, to a lesser extent, right-angle light scattering. A linear correlation has been established between cell forward-angle scattering and the level of overexpression of atrial natriuretic peptide. The correlation is valid only for unlysed cells and is protein product specific.     

Utility of light scatter in the morphological analysis of sperm.

We were able to differentiate the morphologically diverse sperm nuclei of four animal species by using an Ortho flow cytometer to detect the forward light scatter from a red (helium-neon) laser. Cytograms depicting the axial light loss and forward red scatter signals revealed unique, but reproducible, sigmoid distributions that reflected not only interspecies differences in shape and size, but variations in particle refractive index and orientation within the flow cell at the time of analysis. Consequently, we were able to use regional gating of the light scatter cytogram to minimize the influence of orientation on the resolution of the fluorescence signal. We also observed that sperm enlarging as a result of chemically induced decondensation exhibit over time a biphasic shift (increase, then decrease) in light scatter at a species-dependent rate. These results suggest that, without any special adaptations to the flow cytometer, light-scatter parameters can be used to discriminate morphologically different sperm, to enhance the resolution of fluorescence measurements that may otherwise be confounded by variability in radial orientation, and to detect alterations in the rate of a biochemical/biophysical process such as decondensation.     

Islet cell transplantation

Islet cell transplantation is an attractive alternative therapy to conventional insulin treatment or vascularized whole pancreas transplantation for type 1 diabetic patients. It represents a successful example of somatic cell therapy in humans based on complex procedures for islet isolation from whole pancreas. The islets, that are only 1% of the total pancreas tissue, are isolated by two steps method starting with collagenase digestion that operates a rapid dissociation of the stromal component of the gland, while preserving islet anatomical integrity. After digestion, islets are then separated from exocrine tissue by centrifugation in density gradients. Transplantation consists of a simple injection of few milliliter-purified tissue in the portal vein through a percutaneous trans-hepatic approach performed in local anesthesia. Several studies have now demonstrated that islet transplant can replace pancreatic endocrine function without major side effects and with liver viability preservation in selected patients affected by long-term type 1 diabetes. It can restore endogenous insulin secretion, achieve insulin independence in more than 80% of patients, and recover the metabolism of glucose, protein and lipids. Improved control of glycated HbA1c, reduced risk of recurrent hypoglycemia and of diabetic complications are also seen as important benefits of islet cell transplantation, irrespective of the status of insulin independence. Many protocols are now on going for reduction of immunosuppression therapy in recipients, induction of tolerance, and prolongation of graft function.     

Flow cytometric discrimination of mitotic nuclei by right-angle light scatter

Flow cytometry has been used to demonstrate alterations in protein, RNA, and DNA content of cells as they traverse the cell cycle. Employing fluorescein isothiocyanate (FITC) to stain protein and propidium iodide (PI) to stain nucleic acids, multiple regions within the G1 and G2 phases of the cell cycle, in addition to the M phase, can be distinguished. In this study, cytograms of the 90 degree light scatter signal vs. PI fluorescence were remarkably similar to those of FITC fluorescence vs. PI fluorescence, suggesting a relationship between 90 degree light scatter and protein content. M-phase nuclei can be distinguished from G2-phase nuclei on cytograms of 90 degree light scatter vs. PI fluorescence. However, the percentage of mitotic nuclei obtained by this technique is less than that found by light microscopic analysis. Flow cytometric parameters of nuclei prepared by nonionic detergent (NP40) lysis in Dulbecco's PBS, Vindelov's buffer, or Pollack's hypotonic EDTA/Tris buffer were compared. The best resolution of mitotic nuclei was obtained in Pollack's buffer. However, the stainability of the M-phase nuclei is reduced, and the nuclei are located in the late S/G2 region of the single-parameter histogram.     

Separation of non-proliferating from proliferating thymic lymphocytes based on light scatter analysis

Summary The migration of the ameloblasts in the continuously erupting incisors of the rat is accompanied by cell loss. Ameloblasts degenerate near the mesial and lateral cemento-enamel junctions in the secretory zone and in the middle two thirds of the region of postsecretory transition, degeneration being most marked where these areas merge. These findings support the hypothesis that the prism decussation in the enamel results from alternating transverse rows of secretory ameloblasts sliding past each other whilst elaborating their rods. The distribution of the degenerating cells suggests, however, that the sliding cell rows are not exactly transverse but arcuate, with the opening facing incisally. The progress of structural alterations of the nuclei in the degenerating ameloblasts appears to follow the pattern earlier described in vinblastine-damaged ameloblasts.     

Estimating cell concentration in the presence of suspended solids: a light scatter technique

A novel sensor was developed, based on light scatter, to estimate the cell concentration in the presence of suspended solids. The light scatter properties of cells in the presence of suspended solids were investigated. Two crucial observations were made: first, that the light scatter from cells is essentially a linear function of cell concentration and, second, that invariant regions are present in the light scatter spectrum of cell/solid substrate mixtures. Invariant regions are wavelength intervals of the light scatter spectrum in which the light scatter reading is independent of solid substrate concentration and only a function of cell concentration. The occurrence of invariant regions is the key behavior which allowed the quantification of cell concentration in the presence of suspended solids.An algorithm was developed for the estimation, from light scatter data, of cell concentration in the presence of solid substrate. The light scatter approach was validated by comparing cell concentrations estimated by this technique to those obtained from DNA and carbon dioxide evolution rate measurements during a series of fermentations. The model system used was Bacillus subtilis var sakainensis ATCC 21394 growing on fishmeal as the sole nitrogen source.A model was developed based on the interactions of scatter and absorbance. This model reflects the hypothesis that invariant regions are caused by changes in the absorbance of the solid substrate as a function of wavelength. (c) 1992 John Wiley & Sons, Inc.     

Size measurements on isolated rat heart cells using coulter analysis and light scatter flow cytometry

Isolated ventricular muscle cells from the adult rat heart have been examined by both Coulter analysis and light scatter flow cytometry. The dispersed cell preparations contain two main cell types: viable, rod-shaped cells and damaged, round cells. Coulter analytical techniques provided statistical data on cell volume for both cell types. The contribution of each population to the Coulter pulse height distributions were separated by a subtraction method using data obtained from digitonin-treated preparations that contain only round cells. A shape factor for cells aligned with the flow direction was computed from light microscope measurements and the effects of cell orientation within the Coulter aperture were approximately assessed. The estimated volumes for intact myocytes compare favourably with those reported in the literature. No significant size difference was observed between fresh and fixed cells.Narrow angle, forward light scatter measurements were made on individual cells flowing across a focused laser beam. Both scatter pulse height and pulse width (pulse duration) distributions were collected. Values for myocyte length calculated from pulse width information agree well with published data and confirm that the hydrodynamic forces in the flow system produced alignment of the cells with the flow direction. Scatter pulse width distributions reveal two distinct peaks assignable to either rod or round cells. Preliminary electronic gating experiments, using pulse height signals, suggest that signals derived from round cells could be eliminated entirely using a gating regime based on pulse width. This would enable flow cytometric measurements to be made on only the intact myocytes present in heterogeneous preparations.     

Correlated analysis of cellular DNA, membrane antigens and light scatter of human lymphoid cells

Flow cytometric correlated analysis of membrane antigens, DNA, and light scatter was performed on human lymphoid cells using fluorescein (FITC)-conjugated antibodies to label B- and T-cell antigens and propidium iodide (PI) to stain DNA after ethanol fixation and RNase treatment. A FACS II flow cytometer was modified to obtain digitized measurements of two color fluorescence and light scatter emissions, simultaneously. Software was written to allow single parameter analysis or correlated analysis of any two of the three parameters acquired. Ethanol fixation preserved FITC surface labeling for at least 15 weeks, but produced marked changes in light scatter. No changes in FITC distributions were observed after RNase treatment and PI staining, and the presence of FITC labeling did not affect DNA distributions. Within heterogeneous cell populations, the DNA distribution of cell subpopulations identified by a membrane antigen was clearly demonstrated.     

Using light scatter signal to estimate bacterial biovolume by flow cytometry.

BACKGROUND: In the past decade, flow cytometry has become a useful and precise alternative to microscopic bacterial cell counts in aquatic samples. However, little evidence of its usefulness for the evaluation of bacterial biovolumes has emerged in from the literature. METHODS: The light scattering and cell volume of starved bacterial strains and natural bacterial communities from the Black Sea were measured by flow cytometry and epifluorescence microscopy, respectively, in order to establish a relationship between light scattering and cell volume. RESULTS: With the arc-lamp flow cytometer, forward angle light scatter (FALS) was related to cell size in both the starved strains and natural communities, although regression parameters differed. We tested the predictive capacity of the FALS verous cell size relationship in a bacterial community from the North Sea. That analysis showed that a reliable bacterial biovolume prediction of a natural bacterial community can be obtained from FALS using a model generated from natural bacterial community data. CONCLUSIONS: Bacterial biovolume is likely to be related to FALS measurements. It is possible to establish a generally applicable model derived from natural bacterial assemblages for flow cytometric estimation of bacterial biovolumes by light scatter.     

Flow cytometric narrow-angle light scatter and cell size during starvation of Escherichia coli in artificial sea water

Flow cytometry was used to study starvation of Escherichia coli in artificial sea water. Flow cytometric narrow-angle light scatter was compared and assessed in relation to the cell sizes obtained by scanning electron microscopy at low temperature, and by image analysis. A correlation between narrow-angle light scatter and cell size was not observed, although an acceptable correlation (γ= -0.845) between narrow-angle light scatter and the starvation period was observed. On the other hand, the distribution of narrow-angle light scatter at any given moment of culture is asymmetric and may be associated with the cell size distribution at the specific moment of starvation.     

Subpopulation analysis of drug-induced cell-cycle delay in human tumor cells using 90 degrees light scatter

A mitotic cell subset has been identified with nuclear light scatter. Colcemid-treated T-47D human breast cancer cells were permeabilised, stained with ethidium bromide, and analysed by flow cytometry. Cells with G2M DNA content exhibited a unimodal distribution for DNA fluorescence and forward scatter, but two peaks were discernible with 90 degrees light scatter. A discrete low-scattering cell cluster could be distinguished from the G2 cell subset on two-dimensional contour plots of 90 degrees light scatter vs. DNA fluorescence; this cluster was reproduced by mitotic shake-off experiments and varied quantitatively with mitotic indices determined either by microscopy or by stathmokinetic cell-cycle analysis of DNA fluorescence. Cell sorting confirmed that the low-scattering cell cluster comprised predominantly metaphase and anaphase cells. Identification of mitotic cells with this one-step technique enables rapid analysis of drug-induced cell-cycle delay in cell populations with different rates of cell-cycle traverse. Hence, vincristine-induced cytostasis is shown to arise in part because of premitotic G2 arrest, whereas etoposide is shown to affect cycling cells with equal sensitivity in quiescent and activated cell populations. The use of light scatter to discriminate mitotic cells in this way facilitates analysis of drug-induced cell-cycle delay and supplements the information obtainable by conventional cell-cycle analysis.