The binding kinetics and interaction of DNA fluorochromes used in the analysis of nuclei and chromosomes by flow cytometry

Summary The interactions and binding characteristics of DNA dyes used in the flow cytometric analysis of chromatin were studied using human chromosomes and mouse thymocyte nuclei. The kinetics of dye binding and the relationship between fluorescence intensity and dye concentration are presented. Under the conditions used, Hoechst 33258, propidium iodide and chromomycin A3 reach an equilibrium with thymocyte nuclei after approximately 5 min, 20 min and more than 1 h, respectively. The same binding kinetics are observed with Hoechst 33258 and chromomycin when nuclei are stained with a mixture of the two dyes. Sodium citrate, which improves the resolution of flow karyotypes, causes a rapid increase in Hoechst and propidium iodide fluorescence, but a decrease in the fluorescence of chromomycin. The relative peak positions of chromosomes in a flow karyotype are unaffected by sodium citrate addition. The spectral interaction between Hoechst and chromomycin is quantified. There is variation among the human chromosome types in the amount of energy transferred from Hoechst to chromomycin. By measuring the Hoechst and chromomycin fluorescence of each chromosome after Hoechst excitation, it is shown that the amount of energy transferred is correlated to the ratio of the amount of Hoechst to chromomycin bound. Although the energy transfer between the two dyes is considerable, this has little effect on the reproducibility of flow karyotype measurements. The relative peak positions of all human chromosomes in a 64×64 channel flow karyotype, except for the 13 and Y chromosomes, vary in the order of 0.5 channel over a 16-fold change in either Hoechst or chromomycin concentration. This implies that, with the present flow cytometers, variation in staining conditions will have minimal effects on the reproducibility of the relative peak positions in flow karyotypes.In honour of Prof. P. van Duijn     

Preparation and bivariate analysis of suspensions of human chromosomes

Chromosomes were isolated from a variety of human cell types using a HEPES-buffered hypotonic solution (pH 8.0) containing KCl, MgSO4, dithioerythritol, and RNase. The chromosomes isolated by this procedure could be stained with a variety of fluorescent stains including propidium iodide, chromomycin A3, and Hoechst 33258. Addition of sodium citrate to the stained chromosomes was found to improve the total fluorescence resolution. High-quality bivariate Hoechst vs. chromomycin fluorescence distributions were obtained for chromosomes isolated from a human fibroblast cell strain, a human colon carcinoma cell line, and human peripheral blood lymphocyte cultures. Good flow karyotypes were also obtained from primary amniotic cell cultures. The Hoechst vs. chromomycin flow karyotypes of a given cell line, made at different times and at dye concentrations varying over fourfold ranges, show little variation in the relative peak positions of the chromosomes. The size of the DNA in chromosomes isolated using this procedure ranges from 20 to over 50 kilobases. The described isolation procedure is simple, it yields high-quality flow karyotypes, and it can be used to prepare chromosomes from clinical samples.     

Four fluorochromes for the demonstration and microfluorometric estimation of RNA

Microfluorometric estimates of total RNA were made in selected test material stained with berberine sulfate, acridine orange, and Hoechst 33258. These measurements were compared with those obtained with propidium iodide, which is known to interact only with double-stranded nucleic acids. It was observed that all of the fluorochromes, including propidium iodide, yielded very similar patterns of fluorescence in the various types of material tested. In isolated thymocyte and hepatocyte nuclei stained with either propidium iodide or Hoechst 33258 at pH 2, it was evident that RNA could be estimated only indirectly by measuring the amount of fluorescence before and after extraction with RNase. It was apparent that the total fluorescence of small thymocyte nuclei was affected much less by RNase extraction than that of 2c hepatocyte nuclei. Attempts to obtain direct estimates of RNA by exposing the preparations to DNase were not successful: the fluorescence of thymocyte nuclei dropped almost to zero, and hepatocyte nuclei could no longer be assigned to distinct ploidy classes. In addition, since the highly condensed chromatin of thymocyte nuclei was stained much more prominently than the looser chromatin of hepatocyte nuclei with Hoechst 33258, it was apparent that this fluorochrome - when used at pH 2 - has potential usefulness as a "probe" of organizational differences in chromatin.     

Four fluorochromes for the demonstration and microfluorometric estimation of RNA

Summary Microfluorometric estimates of total RNA were made in selected test material stained with berberine sulfate, acridine orange, and Hoechst 33258. These measurements were compared with those obtained with propidium iodide, which is known to interact only with double-stranded nucleic acids. It was observed that all of the fluorochromes, including propidium iodide, yielded very similar patterns of fluorescence in the various types of material tested. In isolated thymocyte and hepatocyte nuclei stained with either propidium iodide or Hoechst 33258 at pH 2, it was evident that RNA could be estimated only indirectly by measuring the amount of fluorescence before and after extraction with RNase. It was apparent that the total fluorescence of small thymocyte nuclei was affected much less by RNase extraction than that of 2c hepatocyte nuclei. Attempts to obtain direct estimates of RNA by exposing the preparations to DNase were not successful: the fluorescence of thymocyte nuclei dropped almost to zero, and hepatocyte nuclei could no longer be assigned to distinct ploidy classes. In addition, since the highly condensed chromatin of thymocyte nuclei was stained much more prominently than the looser chromatin of hepatocyte nuclei with Hoechst 33258, it was apparent that this fluorochrome — when used at pH 2 — has potential usefulness as a probe of organizational differences in chromatin.     

Energy transfer and binding competition between dyes used to enhance staining differentiation in metaphase chromosomes

The ability of electronic energy transfer and direct binding competition between pairs of dyes to enhance contrast in human or bovine metaphase chromosome staining patterns is illustrated, and the relative effectiveness of these two mechanisms compared. The existence of energy transfer between quinacrine or 33258 Hoechst and 7-amino-actinomycin D in doubly stained chromosomes is demonstrated directly by microfluorometry. The ability of the dyes 7-amino-actinomycin D, methyl green, or netropsin, acting as counterstains, to displace quinacrine, 33258 Hoechst, or chromomycin A₃ from chromosomes, is estimated by quantitative analysis of energy transfer data, by photobleaching of the counterstains, or by selective removal of counter-stains by appropriate synthetic polynucleotides. Effects on the fluorescence of soluble 33258 Hoechst-DNA complexes due to energy transfer or binding displacement, by actinomycin D or netropsin, respectively, are further differentiated by nanosecond fluorescence decay measurements. Examples are presented of dye combinations for which (a) energy transfer is the primary mechanism operative, (b) binding competition exists, with consequences reinforcing those due to energy transfer, or (c) binding competition is the most important interaction. These analyses of mechanisms responsible for contrast enhancement in doubly stained chromosomes are used to derive information about the relationship between chromosome composition and banding patterns.     

Improved resolution of flow cytometric measurements of Hoechst- and chromomycin-A3-stained human chromosomes after addition of citrate and sulfite

The resolution of bivariate flow karyotypes of human chromosomes stained with Hoechst 33258 and chromomycin A3 can be increased by adding sodium citrate and sodium sulfite to the chromosomes shortly before measurement. A flow karyotype of a patient with chronic myelocytic leukemia is shown to illustrate that the addition of these compounds allows high-resolution measurements to be made and evaluated reliably from clinical samples.     

Counterstaining human chromosomes for flow karyology

Isolated human metaphase chromosomes stained with the fluorochromes 4'-6-diamidino-2-phenylindole (DAPI) and chromomycin A3(CA3), and counterstained with nonfluorescent netropsin (NTR), have been analyzed by dual-laser flow cytometry. Counterstaining with NTR reduces DAPI fluorescence except at regions on chromosomes 1,9,15,16, and Y, corresponding to C-band heterochromatin. Bivariate flow karyology of human chromosomes treated with this triple-stain combination resolves chromosomes 1,9, and Y distinctly from the remaining chromosomes and resolves variations between chromosome homologues not detected by staining with propidium iodide (PI) or with the double stain combination Hoechst 33258(HO) and CA3.     

Cytochemical studies of metaphase chromosomes by flow cytometry

The cytochemical properties of metaphase chromosomes from Chinese hamster and human cells were studied by flow cytometry. This technique allows precise quantitation of the fluorescence properties of individual stained chromosome types. Chromosomes were stained with the following fluorescent DNA stains: Hoechst 33258, DAPI, chromomycin A₃, ethidium bromide, and propidium iodide. The relative fluorescence of individual chromosome types varied depending on the stain used, demonstrating that individual chromosome types differ in chemical properties. Flow measurements were performed as a function of stain and chromosome concentration to characterize the number and distribution of stain binding sites. Flow analysis of double stained chromosomes show that bound stains interact by energy transfer with little or no binding competition. For most hamster chromosomes, there is a strong correlation between relative fluorescence and stain base preference suggesting that staining differences may be determined primarily by differences in average base composition. A few hamster chromosome types exhibit anomalous staining which suggests that some other property, such as repetitive DNA sequences, also may be an important determinant of chromosomal staining.     

A comparison of the effect of 5-bromodeoxyuridine substitution on 33258 Hoechst- and DAPI-fluorescence of isolated chromosomes by bivariate flow karyotyping

Application of the fluorescent DNA-intercalator propidium iodide for stabilization of the mitotic chromosome structure during isolation of chromosomes from V79 Chinese hamster cells and subsequent staining with the fluorochromes 33258 Hoechst or DAPI allowed bivariate flow karyotyping of isolated chromosomes. Fluorescence of 33258 Hoechst bound to isolated chromosomes containing 5-bromodeoxyuridine (BrdUrd) was quenched in comparison with the fluorescence of control chromosomes. Despite structural relationship and similarity of both absorption and fluorescence spectra of DAPI and 33258 Hoechst, reduction of fluorescence of DAPI-stained isolated chromosomes was not observed, by contrast with findings in conventional cytological metaphase preparations. It could be obtained, however, by preirradiation of the chromosomes with near-UV in the presence of DAPI. This led to a progressive destruction of the chromosomes. Destruction also occurred without BrdUrd, though at a slower rate. Preirradiation of chromosomes in the presence of 33258 Hoechst hardly affected the integrity of the chromosomes. Preirradiation of a 33258 Hoechst solution and its subsequent use as a stain resulted in a considerably decreased fluorescence of chromosomes. For DAPI this effect was small. Thus, whereas 33258 Hoechst itself is much more sensitive to near-UV irradiation than DAPI, DAPI bound to DNA in chromosomes renders the DNA much more sensitive to irradiation than 33258 Hoechst bound to DNA. Presumably, these differences can at least partly be reduced to the different molecular sizes of the dyes.     

A comparison of the effect of 5-bromodeoxyuridine substitution on 33258 Hoechst- and DAPI-fluorescence of isolated chromosomes by bivariate flow karyotyping

Summary Application of the fluorescent DNA-intercalator propidium iodide for stabilization of the mitotic chromosome structure during isolation of chromosomes from V79 Chinese hamster cells and subsequent staining with the fluorochromes 33258 Hoechst or DAPI allowed bivariate flow karyotyping of isolated chromosomes. Fluorescence of 33258 Hoechst bound to isolated chromosomes containing 5-bromodeoxyuridine (BrdUrd) was quenched in comparison with the fluorescence of control chromosomes. Despite structural relationship and similarity of both absorption and fluorescence spectra of DAPI and 33258 Hoechst, reduction of fluorescence of DAPI-stained isolated chromosomes was not observed, by contrast with findings in conventional cytological metaphase preparations. It could be obtained, however, by preirradiation of the chromosomes with near-UV in the presence of DAPI. This led to a progressive destruction of the chromosomes. Destruction also occurred without BrdUrd, though at a slower rate. Preirradiation of chromosomes in the presence of 33258 Hoechst hardly affected the integrity of the chromosomes. Preirradiation of a 33258 Hoechst solution and its subsequent use as a stain resulted in a considerably decreased fluorescence of chromosomes. For DAPI this effect was small. Thus, whereas 33258 Hoechst itself is much more sensitive to near-U.V irradiation than DAPI, DAPI bound to DNA in chromosomes renders the DNA much more sensitive to irradiation than 33258 Hoechst bound to DNA. Presumably, these differences can at least partly be reduced to the different molecular sizes of the dyes.In honour of Prof. P. van Duijn     

Comparison of Hoechst 33342 and propidium iodide as fluorescent markers for sperm fusion with hamster oocytes.

Hamster oocytes were loaded with the DNA dyes Hoechst 33342 or propidium iodide. Oocytes incubated in 10 mumol Hoechst 333421(-1) showed intracellular fluorescence within 10-20 s of exposure, as did hamster and guinea-pig spermatozoa. Impaled oocytes to which acrosome-intact hamster spermatozoa were bound before injection of Hoechst 33342 showed dye transfer to adhering spermatozoa within 2 min of injection. Oocytes loaded passively with Hoechst 33342 showed dye transfer to bound, acrosome-intact hamster spermatozoa within 10 min. On ultra-structural examination, no bound, acrosome-intact hamster spermatozoa (n = 311) were found to be fused. By contrast, oocytes incubated with 10 mumol propidium iodide l-1 showed no intracellular fluorescence after 2 h, although in approximately 50% of oocytes, fluorescence developed rapidly in the first polar body. Oocytes injected with propidium iodide showed intracellular fluorescence but no dye transfer to bound, acrosome-intact hamster spermatozoa. Oocytes impaled on pipettes containing propidium iodide showed no dye transfer to unlabelled oocytes with which they were brought into contact, whereas in similar experiments using Hoechst 33342 detectable dye transfer to an adjacent oocyte occurred within 10 min. Oocytes loaded with propidium iodide transferred propidium iodide to fusion-competent guinea-pig spermatozoa during in vitro fertilization. Normally, between 20 and 40 spermatozoa bound per oocyte, and the percentage of spermatozoa showing dye transfer varied between 0 and 41%. Dye transfer occurred within 5-45 min. Only those nuclei that showed propidium iodide transfer subsequently decondensed, suggesting that dye transfer is correlated with fusion. The presence of fused spermatozoa was confirmed by ultrastructural examination of oocytes. In separate experiments, hamster and guinea-pig spermatozoa showed detectable fluorescence from propidium iodide within 20 s of osmotic rupture or membrane stripping by detergent, suggesting the lag in dye transfer to sperm nuclei during fertilization reflects a delay in sperm-oocyte fusion following adhesion. This evidence suggests that Hoechst 33342 could be an unreliable marker for sperm-oocyte fusion in fertilization because of its capacity for passive movement from oocyte to spermatozoon. This problem can be overcome using oocytes injected with propidium iodide. With this technique, it was possible to show that fusion-competent guinea-pig spermatozoa that are held in pipettes will fuse with hamster oocytes when placed mechanically against the oocyte surface.     

Photo-bleaching and photon saturation in flow cytometry.

In flow cytometry, small particles travel at a high speed through a bright light spot. The high light intensity at the point of measurement causes measurable photon saturation. This observation indicates that the rate at which individual dye molecules emit photons is close to the maximum emission rate. Despite the short exposure time, individual molecules may go through a few hundred excitation cycles while they are in the light beam. The absorbed light dose causes significant dye destruction. This article presents experimental procedures to determine the extent of photon saturation and photo-bleaching of dyes bound to cell nuclei in a flow cytometer. Measurements of Hoechst and propidium iodide bound to chromatin show that the amount of dye bleached per emitted photon is the same at low and high illumination intensities. This finding indicates that photon emission and dye destruction are both the result of the absorption of single excitation photons. The experimental observations allow rough estimates of the lifetime of the excited state and the lifetime of the molecule. The lifetime of the Hoechst 33258 bound to DNA is estimated to be 100 excitation-relaxation cycles. The average propidium iodide molecule lasts approximately 200 excitation-relaxation cycles. The theoretical considerations show that the optimal illumination conditions are different for bleaching and nonbleaching dyes. An optical arrangement for high precision measurements of bleaching dyes is presented.     

Pairs of fluorescent dyes as probes of DNA and chromosomes.

If two fluorescent dyes with different binding or fluorescence specificities are used simultaneously to stain DNA or chromosomes, the ratio of their fluorescent signals can provide information about base composition or base analogue substitution. Energy transfer between such dye pairs, possible if the fluorescence spectrum of one overlaps the absorption spectrum of the other, can modify observed fluorescence. Microfluorometric measurements were used to document the occurrence of energy transfer between quinacrine or 33258 Hoechst as energy donor and ethidium or 7-aminoactinomycin D as acceptor when used jointly to stain cytologic preparations of human metaphase chromosomes. Use of 7-aminoactinomycin D, a dye with G-C binding specificity, as energy acceptor permitted the identification of human chromosome regions presumptively enriched for clusters of A-T base pairs, based on the resistance of A-T specific fluorescence, from quinacrine or 33258 Hoechst, to energy transfer dependent quenching. The results provide information about basic structural features of metaphase chromosomes, and the associated methodology may prove useful in accentuating specific fluorescent polymorphic chromosome regions.     

Multivariate chromosome analysis and complete karyotyping using dual labeling and fluorescence digital imaging microscopy

The combination of multiple dye-DNA interactions, a fluorescence digital imaging system with a scientific CCD camera, and multivariate image analysis allows the rapid karyotyping of fluorescent human metaphase chromosome spreads. Chromosomes are stained with the bisbenzimidazole dye Hoechst 33342 and chromomycin A3, a dye pair used frequently in bivariate flow analysis and sorting of metaphase chromosomes in suspension. The use of ratio functions involving the total and peak intensities of the two dyes provides increased resolution of the karyotype in the microscope, and it can be anticipated that the same approach could lead to improved performance with flow systems as well. High pass filtering with a Laplace operator yields characteristic banded images of the individual chromosomes, even with total fields that are less than 200 pixels on a side.     

Calculation of binding length of base-specific DNA dyes by comparison of sequence and flow cytometric data. Application to Oryza sativa and Arabidopsis thaliana

From biochemical experiments it has been found that AT- and GC-specific dyes need a certain number of consecutive bases of the same type for binding one dye molecule. From known base sequences the amount of bases included in dye binding can be calculated and compared with experimental data from flow cytometry. Oryza sativa and Arabidopsis thaliana are the first higher plants which are nearly completely (>90%) sequenced. From the published sequences the theoretical fluorescence intensity of base-specific dyes in relation to a base-unspecific dye is calculated for different binding lengths. These values are compared with the actual fluorescence intensities of nuclei analyzed by flow cytometry. For all investigated dyes (DAPI, Hoechst 33258, Hoechst 33342 (all AT specific) and Mithramycin A (GC specific)) a binding length of 1 bp results from the comparison of theoretical and experimental data. This is, however, in disagreement with former results on dye binding. The main reason for the discrepancy seems to be the remaining gap in the sequencing of the Arabidopsis genome.     

Quantification of the DNA content of structurally abnormal X chromosomes and X chromosome aneuploidy using high resolution bivariate flow karyotyping

Quantification of the Hoechst and chromomycin A3 fluorescence intensities of mitotic human chromosomes isolated from karyotypically normal and abnormal cells was performed with a dual beam flow cytometer. The resultant flow karyotypes contain information about the relative DNA content and base composition of chromosomes and their relative frequencies in the mitotic cell sample. The relative copy number of X and Y chromosomes was determined for 38 normal males and females and 6 cell lines with X or Y chromosome aneuploidy. Flow karyotype diagnoses corresponded with conventional cytogenetic results in all cases. We show that chromosome DNA content can be derived from peak position in Hoechst vs. chromomycin flow karyotypes. These values are linearly related to propidium iodide staining intensity as measured with flow cytometry and to the binding of gallocyanin chrome alum to phosphate groups as measured with slide-based scanning photometry. Cell lines with deleted or dicentric X chromosomes ranging in length from 0.53 to 1.95 times normal were analyzed by using flow cytometry. The measured difference in DNA content between a normal X and each of the structurally abnormal chromosomes was linearly correlated to the difference predicted from cytogenetics and/or probe analyses. Deletions of 3-5 Mb, which were at and below the detection limits of conventional cytogenetics, could be quantified by flow karyotyping in individuals with X-linked diseases such as Duchenne muscular dystrophy, choroideremia, and ocular albinism/ichthyosis. The results show that the use of flow karyotyping to quantify the size of restricted regions of the genome can complement conventional cytogenetics and other physical mapping techniques in the study of genetic disorders.     

Microfluorometric investigations of chromatin structure. I. Evaluation of nine DNA-specific fluorochromes as probes of chromatin organization

The ability of the highly condensed chromatin of small thymocyte nuclei and the more loosely organized chromatin of hepatocyte nuclei to interact with nine DNA-specific fluorochromes was assessed by microfluorometry. Although the results obtained with five of the fluorochromes - mithramycin, 7-aminoactinomycin D, Hoechst 33258, DAPI, and propidium iodide - were found to be virtually unaffected by differences in the degree of condensation of the chromatin, the values obtained with the remaining fluorochromes - proflavine, quinacrine mustard, berberine sulfate, and pyronin Y - appeared to be affected significantly by organizational differences of the chromatin. All of the latter "structural probes," except quinacrine mustard, produced fluorescence values which were higher in the 2c nuclei of hepatocytes than in the nuclei of small thymocytes. Quinacrine mustard yielded higher values in thymocyte nuclei; and in the hepatocyte polyploid series (2, 4, and 8c), it did not produce the expected multiples of the 2c value. Pretreatment of the two types of nuclei with RNase affected their total fluorescence in unpredictable ways. While RNase extraction lessened the differences between thymocyte and 2c hepatocyte nuclei stained with propidium iodide, Hoechst 33258, proflavine, and berberine sulfate, it increased the differences between nuclei stained with mithramycin, quinacrine mustard, pyronin Y, and 7-aminoactinomycin D. The ability of RNA-depleted chromatin to interact with various types of fluorochromes might be a useful parameter in subsequent studies of chromatin organization.     

Interactions between pairs of DNA-binding dyes: results and implications of chromosome analysis

A number of DNA-binding dyes, with spectral properties making them suitable as components of energy donor-acceptor pairs, are described. If such pairs are used to stain metaphase chromosomes, and if the energy acceptor (e.g., actinomycin D or methyl green) has a binding specificity opposite to the binding or fluorescence specificity of the donor (e.g., 33258 Hoechst, quinacrine or chromomycin A3), contrast in donor fluorescence can be enhanced, leading to patterns selectively highlighting standard or reverse chromosome bands or particular polymorphic regions. Such results presumably reflect chromosomal regions enriched in 10-20 base pair clusters to which the donor binds and fluoresces but to which the acceptor cannot bind. For other pairs, involving counterstains such as netropsin or echinomycin, which are not suitable as energy acceptors, specific changes observed in polymorphic region fluorescence are most likely due to binding competition between dyes. Dye pairs producing contrast by either method can be used to differentiate between homologous chromosomes or to facilitate detection of specific chromosomal rearrangements. Preliminary data indicate that contrast enhancement generated in fixed metaphase chromosomes spread on microscopic slides can also be observed in suspensions of unfixed metaphase chromosomes, reinforcing the expectation that the methodology described will be of use in flow cytometry.     

Immunofluorescent detection of histone 2B on metaphase chromosomes using flow cytometry

A monoclonal antibody against histone 2B (anti-H2B) was used as a reagent to stain isolated chromosomes for analysis using flow cytometry. Chromosome suspensions were treated with a mouse monoclonal antibody specific for the histone 2B (clone HBC-7) and then with a fluorescein-labeled goat anti-mouse-IgM antibody. The chromosomes were also stained for DNA content with either Hoechst 33258 or propidium iodide. The amount of antibody and the amount of DNA-specific stain bound to each chromosome were measured simultaneously using flow cytometry. The order of the steps in the staining protocol is important. Propidium iodide prevents anti-H2B from binding to chromosomes, and therefore must be added only after antibody labeling is completed. In contrast, the addition of Hoechst 33258 before antibody labeling reduces antibody binding by only 20%–30%. Binding of anti-H2B was proportional to the DNA content of both human and Chinese hamster chromosomes. Human chromosomes bind an average of three to four times more anti-H2B than do Chinese hamster or mouse chromosomes of the same DNA content. This was determined by analyzing mixtures of human and Chinese hamster chromosomes and human and mouse chromosomes. The results demonstrate that it is possible to label the proteins of chromosomes in suspension with fluorescent antibodies and to use these reagents for the analysis of chromosome structure by flow cytometry.     

Chromomycin A3 as a fluorescent probe for flow cytometry of human gynecologic samples.

Chemical, physical and optical properties of chromomycin A3 are examined so as to ascertain appropriate staining and analysis procedures for flow cytometry of human gynecologic samples. Fluorescence excitation and emission spectra of chromomycin A3-stained cervical cells are compared with those of chromomycin A3-stained deoxyribonucleic acid. Conditions for deoxyribonucleic acid-specific staining of cervical cells are presented, and staining specificity of cervical cells with chromomycin A3 is compared to that obtained with ethidium bromide, propidium iodide and Hoechst 33258. Also presented is a brief review of two parameter flow cytometry as a prescreening procedure for detection of cervical neoplasia. Results of flow cytometry and cell sorting are interpreted based on the deoxyribonucleic acid-specificity of chromomycin A3 staining.