Intracellular pH, esterase activity, and DNA measurements of human lung carcinomas by flow cytometry

An important intention of flow cytometric investigations is to obtain biochemical and biophysical information about cells which is suitable for automated tumor diagnosis. In this study, the ploidy status, the intracellular pH value, the intracellular esterase activity, and the cell volume of vital cells and the DNA and cell volume of dead cells were measured in cancerous tissue and normal lung tissue of 30 patients by flow cytometry. The cell samples were simultaneously stained with the pH and esterase indicator dye 1.4-diacetoxy-2,3-dicyanobenzene (ADB) and propidium iodide (PI). The flow cytometric measurements were performed in three-parameter list mode. The data were evaluated on an AT-compatible personal computer with the DIAGNOS1 program system for automated diagnosis of flow cytometric list mode data. Significant differences were found between normal and malignant tissue in DNA ploidy, in the intracellular esterase activity, in the cell, volume and in the percentage of inflammatory cells and parameters of necrosis. DNA-aneuploidy was observed in 38% of the lung carcinomas. The simultaneous detection of DNA-aneuploidy and tumor-associated properties in a multifactorial analysis led to correct automatic tumor diagnosis in 85% of cases. DNA-aneuploidy was found at a significant higher frequency in advanced tumors. Adenocarcinomas displayed DNA-aneuploidy more often (80%) than squamous cell carcinomas (33%).     

Intracellular pH distribution in Saccharomyces cerevisiae cell populations, analyzed by flow cytometry

Intracellular pH has an important role in the maintenance of the normal functions of yeast cells. The ability of the cell to maintain this pH homeostasis also in response to environmental changes has gained more and more interest in both basic and applied research. In this study we describe a protocol which allows the rapid determination of the intracellular pH of Saccharomyces cerevisiae cells. The method is based on flow cytometry and employs the pH-dependent fluorescent probe carboxy SNARF-4F. The protocol attempts to minimize the perturbation of the system under study, thus leading to accurate information about the physiological state of the single cell. Moreover, statistical analysis performed on major factors that may influence the final determination supported the validity of the optimized protocol. The protocol was used to investigate the effect of external pH on S. cerevisiae cells incubated in buffer. The results obtained showed that stationary cells are better able than exponentially grown cells to maintain their intracellular pH homeostasis independently of external pH changes. Furthermore, analysis of the intracellular pH distribution within the cell populations highlighted the presence of subpopulations characterized by different intracellular pH values. Notably, a different behavior was observed for exponentially grown and stationary cells in terms of the appearance and development of these subpopulations as a response to a changing external pH.     

Chlorophyll a fluorescence measurements of isolated spinach thylakoids obtained by using single-laser-based flow cytometry

Flow cytometry data of spinach thylakoid membrane preparations indicate the presence of a homogeneous thylakoid population. Fluorescence data from a flow cytometer and comparison with data from two other fluorometers show that chlorophyll a fluorescence detected with a flow cytometer has the character of maximum fluorescence (Fmax), not of the constant component (Fo). This conclusion is important since Fo measures fluorescence that is affected mostly by changes in excitation energy transfer and Fmax-Fo (the variable fluorescence) by changes in photochemistry. This was demonstrated by: 1) The light intensity as well as diffusion rate dependence of the quenching effect of various quinones (p-benzoquinone, phenyl-benzoquinone, and 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone, DBMIB) on fluorescence yield; quenching for the same concentration of these quinones was lower at the higher than at the lower light intensities. 2) Temperature dependence of the fluorescence yield; increasing the temperature from 20 to 70 degrees C did not show an increase in fluorescence yield using a flow cytometer in contrast to measurements with weak excitation light, but similar to those obtained for Fmax. 3) Addition of an inhibitor diuron up to 100 microM did not change the fluorescence intensity. A comparison of quenching of fluorescence by various quinones obtained by flow cytometry with those by other fluorometers suggests that the high intensity used in the cytometry produces unique results: the rate of reduction of quinones in much larger than the rate of equilibration with the bulk quinones.     

Coincidence in high-speed flow cytometry: models and measurements

In flow cytometry, the coincident arrival of particles becomes a major problem when high sample rates are required. For the development of our high-speed photodamage flow cytometer (ZAPPER), it was of importance to understand the behavior of cells at flow rates of around 50,000-250,000 event/s. We developed and compared two models that describe the relation between the real cell rate and the detectable single cell rate. Both the Computer Simulation model and the Input/Output Device model show distinct optima for the cell rate. The models were compared to measurements performed on the ZAPPER-prototype. Fits of the two models to the experimental data were excellent for cycle times of 4 and 15 microseconds and acceptable for a 2 microseconds cycle time. A third model (Mercer WB, Rev. Sci. Instr. 37:1515-1521,1966) could be fitted to the experimental data, after the proportionality constant k was adapted to the experimental data. At a yield of detectable single cells of 70%, the maximum cell rates are 180,000, 100,000, and 40,000 cells/s for cycle times of 2, 4, and 15 microseconds, respectively. Based on these results we can now select an optimal cell rate for analysis and sorting based on criteria such as accepted cell loss. In addition, the advantages of reducing the cycle time can now be evaluated with respect to the costs of that modification.     

Ratiometric measurement of intracellular pH in cultured human keratinocytes using carboxy-SNARF-1 and flow cytometry

In this study we describe a method to measure intracellular pH in cultured human keratinocytes using flow cytometry. Keratinocytes pose a technical problem because the population is heterogeneous with respect to size and metabolic activity (nonspecific esterase activity), resulting in variability in dye uptake. In order to compensate for this, dyes were selected that change colour with pH. The ratio of fluorescence intensities at two wavelengths was recorded and used as a measure of intracellular pH by reference to the pH in the presence of the proton ionophore nigericin. However, methods published till now do not routinely combine the ratiometric technique and excitation with an argon ion laser set at 488 nm. Therefore we have tested the recently developed pH-sensitive dye carboxyseminaphthorhodafluor-1 (SNARF-1) as a possible candidate for flow cytometric pH measurements and compared it with 2',7'-bis(carboxyethyl)-5,6-carboxyfluorescein (BCECF) and 2,3-dicyanohydroquinone (DCH) with respect to emission spectra, resolution, range, and stability of cellular fluorescence. SNARF-1 had a practical and stable excitation wavelength of 488 nm rather than UV, it offered the possibility of ratiometric measurements on the basis of a real emission shift, and had superior resolution for the pH range 7-8. With SNARF-1 we found that keratinocytes cultured under low serum conditions (0.2%) contain a higher proportion of cells with relatively low intracellular pH compared to high serum cultures (6%). Furthermore, pH changes were followed by changes in relative DNA content. These findings suggest that intracellular pH can be an early functional proliferation marker for human keratinocytes.     

Intracellular HSP72 detection in HL60 cells using a flow cytometry system based on microfluidic analysis

HSP72 is an important marker for various environmental stresses and diseases, and many researchers need to detect HSP72 levels in various cells. We have therefore developed an assay to monitor intracellular heat-shock protein 72 expression on a microfluidic Lab-on-a-chip platform. We established this method to detect HSP72 intracellularly by antibody staining with DNA counterstaining. The Lab-on-a-chip technology is simple and efficient when performing flow cytometric assays. By permeabilizing the cells for the delivery of antibodies, we were able to show HSP72 expression after 30 min heat-shock at 44 degrees C and then at various post-incubation times at 37 degrees C. We compared our method to a conventional flow cytometer and an enzyme immunoassay technique.     

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.     

Double-beam autocompensation for fluorescence polarization measurements in flow cytometry.

The degree of depolarization of fluorescent light emitted from an organic dye, which is used as molecular probe, is a powerful tool in probing the microenvironment. By fluorescence depolarization the macromolecular structure can be investigated as well as the the mobility of the marker molecule itself or of the complex formed by the probe. Additional information such as energy transfer rates, donor-acceptor distances, and orientations are also measurable. These data are of particular interest if they can be measured from whole cells. Using flow cytometry, we can analyze a large number of cells with high statistical significance in a short period of time. We describe a newly developed double-beam epi-illumination arrangement for fluorescence polarization measurements that uses an autocompensation technique. This new technique permits the various depolarizing effects within the optical as well as the electronic components of the system to be continually compensated for on a cell by cell basis. Simultaneous measurements of other cell parameters for cell cycle analysis by total fluorescence intensity remains possible. The sensitivity of the system to measure polarization was determined as +/- 0.006 p (0 less than or equal to p less than or equal to 0.5 in isotropic media), which amounts to +/- 1.2% of the maximum p value. Polarization data for latex microspheres plotted in the histogram mode were measured with a standard deviation of 0.006, which proved the high resolution and the high performance of the system.     

Light-scattering polarization measurements as a new parameter in flow cytometry

Polarization measurement of orthogonal light scattering is introduced as a new optical parameter in flow cytometry. In the experimental setup, the electrical field of the incident laser beam is polarized in the direction of the sample flow. The intensity of the orthogonal light scattering polarized along the direction of the incoming laser beam is called depolarized orthogonal light scattering. Theoretical analysis shows that for small values of the detection aperture, the measured depolarization is caused by anisotropic cell structures and multiple scattering processes inside the cell. Measurements of the orthogonal depolarized light scattering in combination with the normal orthogonal light scattering of human leucocytes revealed two populations of granulocytes. By means of cell sorting it was shown that the granulocytes with a relatively high depolarization are eosinophilic granulocytes. Similar experiments with human lymphocytes revealed a minor subpopulation of yet-unidentified lymphocytes with a relative large orthogonal light-scattering depolarization. The results were obtained with an argon ion laser tuned at different wavelengths as well as with a 630-nm helium neon laser. These results show that measurement of depolarized orthogonal light scattering is a useful new parameter for flow-cytometric cell differentiation.     

Single- and double-stranded RNA measurements by flow cytometry in solid neoplasms

We investigated the ability of single- and double-stranded RNA measurements to discriminate between neoplastic and non-neoplastic solid tissues. Sixty-one solid nonhematopoietic neoplasms, 10 reactive non-neoplastic lesions, and 26 normal tissue samples were the test materials. Single-stranded ribonucleic acid (s-RNA) levels and double-stranded ribonucleic acid (ds-RNA) excess in these specimens were defined in relationship to normal human lymphocytes. The mean s-RNA index in normal, reactive, benign, and diploid and aneuploid malignant tissue samples was 0.90, 1.54, 1.9, 1.2, and 2.2, respectively. For ds-RNA, the mean excess level for normal, reactive, benign, and diploid and aneuploid malignant specimens was 8.5%, 18.5%, 51.0%, 36.0%, and 41.3%, respectively. No statistical differences in s-RNA level were found between non-neoplastic and neoplastic tissue samples. A significant difference in ds-RNA excess was found between non-neoplastic and benign, and diploid and aneuploid malignant neoplastic tissue (P less than 0.001). The specificity of s-RNA level and ds-RNA excess was 94.4% and 100%, and the sensitivity was 29.5% and 67.2%, respectively. Notably, ds-RNA determinations identified 70.0% of the diploid neoplastic samples, in contrast to 20% by s-RNA. Our preliminary data suggest that ds-RNA may be a useful parameter and may complement DNA ploidy in identification of solid neoplasms, especially if the yield of intact cells is improved.     

Enrichment for submitotic cell populations using flow cytometry

BACKGROUND: One of the most dramatic events during the course of the mammalian cell cycle is mitosis, when chromosomes condense and segregate, the nuclear envelope breaks down, and the cell divides into two daughter cells. Although cells undergoing mitosis are cytologically distinguishable from nonmitotic cells, few molecular markers are available to specifically identify mitotic cells, especially cells within different stages of mitosis. METHODS: We applied the flow cytometric method of Juan et al. (Cytometry 32:71-77, 1998) to obtain cells with various levels of the molecular markers cyclin B1 and phosphorylated histone H3; fluorescence microscopy was then used to identify sorted cells in different stages of mitosis. RESULTS: We observed the substantial enrichment of submitotic cell populations. CONCLUSIONS: This method represents an effective approach to obtain an enriched population of submitotic cells without the use of drug treatments or prior synchronization.