Chromosome heteromorphism quantified by high-resolution bivariate flow karyotyping.

Maternal and paternal homologues of many chromosome types can be differentiated on the basis of their peak position in Hoechst 33258 versus chromomycin A3 bivariate flow karyotypes. We demonstrate here the magnitude of DNA content differences among normal chromosomes of the same type. Significant peak-position differences between homologues were observed for an average of four chromosome types in each of the karyotypes of 98 different individuals. The frequency of individuals with differences in homologue peak positions varied among chromosome types: e.g., chromosome 15, 61%; chromosome 3, 4%. Flow karyotypes of 33 unrelated individuals were compared to determine the range of peak position among normal chromosomes. Chromosomes Y, 21, 22, 15, 16, 13, 14, and 19 were most heteromorphic, and chromosomes 2-8 and X were least heteromorphic. The largest chromosome 21 was 45% larger than the smallest 21 chromosome observed. The base composition of the variable regions differed among chromosome types. DNA contents of chromosome variants determined from flow karyotypes were closely correlated to measurements of DNA content made of gallocyanin chrome alum-stained metaphase chromosomes on slides. Fluorescence in situ hybridization with chromosome-specific repetitive sequences indicated that variability in their copy number is partly responsible for peak-position variability in some chromosomes. Heteromorphic chromosomes are identified for which parental flow karyotype information will be essential if de novo rearrangements resulting in small DNA content changes are to be detected with flow karyotyping.     

Application of flow karyotyping in prenatal detection of chromosome aberrations

This paper describes the application of bivariate flow karyotyping to (1) classification of chromosomes isolated from cultures of cells taken by amniocentesis and (2) detection of numerical and structural aberrations. Chromosomes were isolated from primary cultures 2-5 wk after amniocentesis, stained with Hoechst 33258 and chromomycin A3, and analyzed using dual beam flow cytometry. Information about chromosome DNA content and DNA base composition was derived from the locations of the peaks in the flow karyotypes, each peak being produced by one or more chromosome types with similar DNA content and DNA base composition. Information about the relative frequency of each chromosome type was determined on the basis of the relative volume of the peak for that chromosome type. Cytogenetic information determined on the basis of flow karyotypes was compared with that obtained by visual analysis following G-banding. Variability among the peak means and volumes in flow karyotypes was determined from analyses of 50 normal amniocyte cultures. Numerical aberrations involving chromosomes 21, 18, and Y were detected correctly in all of 28 analyses, including eight in a blind study. Structural aberrations involving chromosomes 1, 2, 3, 6, 9-12, 13, 14, 15, 21, and 22 were detected in all of seven cultures in a blind study. Flow karyotypes proved to be insensitive to small, normally occurring chromosome polymorphisms detected by banding analysis. In addition, a few samples were erroneously scored as having numerical aberrations.     

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

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 X 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.(ABSTRACT TRUNCATED AT 250 WORDS)     

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     

Analysis of the variation in chromosome size among diverse human populations by bivariate flow karyotyping

Chromosomes sampled from seven human populations were analyzed by flow cytometry to survey normal variation in chromosome size. The populations include two African Pygmy groups, two Amerindian tribes, Druze, Khmer Cambodians, and Melanesians. Mitotic chromosomes were isolated from cultured cells and stained with Hoechst 33 258 and chromomycin A3. The relative DNA content and base-pair composition of each homolog was quantified by bivariate flow karyotyping. Significant variation in DNA content, ranging from 10–40%, was observed for chromosomes 1, 13–16, 19, 21, 22, and Y. The measurements for each population appeared to be a random sampling of the total set of 33 individuals for the majority of chromosomes. A few significant differences in the distributions of chromosomal DNA content were observed among the populations, however. The data, when combined with an earlier study of 33 unrelated individuals of unknown ethnic origin, provide a good representation of the variation in chromosome size among humans. Received: 3 September 1996 / Accepted: 10 January 1997     

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.     

Generation of Five High-Complexity Painting Probe Libraries from Flow-Sorted Mouse Chromosomes

Mouse metaphase chromosomes were purified by flow sorting from the murine fibroblast cell line Mus spretus clone 5A. We sorted chromosomes that fell into five individual peaks based on the Hoechst 33258/chromomycin A3 DNA histogram: three peaks corresponding to the least amount of DNA and two peaks representing chromosomes with the most DNA content. This is the first example of the successful application of bivariate flow karyotyping to murine chromosome sorting. We then applied primer-directed in vitro DNA amplification using the polymerase chain reaction (PCR) to generate and label larger amounts of chromosome-specific DNA. In situ hybridization showed specific binding of the PCR products to mouse chromosomes Y, 19, 18, 3, and X as well as chromosomes 1 and 2. The combination of chromosome sorting from the M. spretus cell line and PCR proved to be highly valuable for generation of pools of DNA fragments that exhibit specific binding to mouse chromosomes and can be used to identify and delineate mouse metaphase chromosomes.     

Bivariate flow karyotyping of human chromosomes: evaluation of variation in Hoechst 33258 fluorescence, chromomycin A3 fluorescence, and relative chromosomal DNA content.

The total variation of chromosome peak positions, in bivariate distributions of Hoechst 33258 and chromomycin A3 fluorescence of 19 healthy individuals, was compared with the experimental variation, determined from 23 bivariate distributions of chromosomes prepared separately from a single cell lineage. The experimental variation in Hoechst and chromomycin fluorescence and the relative chromosomal DNA content were determined from experiments performed over several days. The additional variance contributed by time was the same as the daily variance. The accuracy by which the relative chromosomal DNA content can be calculated from bivariate peak positions was investigated. A least squares method was used to fit the distributions of relative DNA content, obtained, respectively, from mono- and bivariate flow analyses of chromosomes from the same cell lineage. In general the DNA contents match quite well, but for a few chromosomes a difference was found, statistically discernible at the 5% level. The average relative chromosomal DNA content of the chromosomes from the 19 normal individuals, calculated from bivariate peak positions, showed a linear relation with the estimates published by other investigators.     

Chromosome analysis and sorting in <Emphasis Type="Italic">Vicia sativa</Emphasis> using flow cytometry

Procedures were developed for flow cytometric analysis and sorting of mitotic chromosomes (flow cytogenetics) of common vetch (Vicia sativa L., 2n=12). Suspensions of intact chromosomes were prepared from root tips after cell cycle synchronization, formaldehyde fixation, and mechanical homogenization. On average, 3 × 10⁵ morphologically intact chromosomes could be isolated from 25 root tips. Flow cytometric analysis of DAPI-stained chromosomes resulted in histograms of relative fluorescence intensity (flow karyotypes) containing four peaks, representing particular chromosomes and/or pairs of chromosomes with similar relative DNA content. Peaks I and II were assigned to chromosomes 6 and 5, respectively. These chromosomes could be sorted with a purity exceeding 90 %. The two remaining peaks on the flow karyotype were composite, each of them representing a pair of chromosomes. Chromosomes 1 and 3 were assigned to composite peak III while chromosomes 2 and 4 were assigned to composite peak IV. The chromosomes could be sorted with a purity of 99 % from both composite peaks. Bivariate flow karyotyping after simultaneous staining of chromosomes with DAPI and mithramycin was not found helpful in discriminating additional chromosomes. This study extends the number of legume species for which flow cytogenetics is available and provides a new tool for targeted and effective analysis and mapping of common vetch genome.     

Cytofluorometric determination of the DNA base content in human chromosomes with quinacrine mustard, Hoechst 33′258, DAPI, and mithramycin

The human chromosomes 1, 9, 16, 21, and Y were analysed cytofluorometrically with the AT-specific DNA ligands quinacrine mustard (QM), Hoechst 33′258, and DAPI, and the GC-specific DNA ligand mithramycin. All three AT dyes give similar results, though QM produces more distinct banding than DAPI or Hoechst. The sum of AT and GC fluorescence is very well correlated to the amount of DNA estimated densitometrically. The AT/GC ratios of chromosomes 16, 22, and Y differ clearly from that of whole nuclei, and accord fairly well with the results obtained by flow cytometry. For the Y a significant difference in calculated base content between donors was found with all three AT dyes even though differences in the karyotypes were not distinguishable by the eye.     

Optimising human chromosome separation for the production of chromosome-specific DNA libraries by flow sorting

Summary A number of cell lines, some containing chromosomes with distinctive heteromorphisms, have been flow karyotyped using a single laser flow sorter in an attempt to select those suitable for sorting all human chromosomes individually. Using the non-base-specific DNA stain ethidium bromide, chromosomes 3,4,5, and 6 form individual peaks in practically all normal subjects, while the right combination of heteromorphisms enables chromosomes 1, 2, 8, 9, 13, 16, 17, 18, 19, 20, 21, 22, and Y to be sorted separately. Two male cell lines, one containing a duplication and one a deletion of the X, produce flow karyotypes suitable for sorting chromosomes 7 and 8. The use of numerical chromosome abnormalities to enrich the sex chromosomes and the autosomes 18 and 21 is also illustrated. The DNA stain Hoechst 33258 binds preferentially to AT base pairs. Flow karyotypes produced with this fluorochrome separate some chromosomes not well separated with ethidium bromide. Chromosomes 5, 6, 8, 13, 14, 15, 17, and 20, and Y can be sorted individually with Hoechst 33258 with the right combination of heteromorphisms. Using these techniques, all human chromosomes apart from 10, 11, and 12 have been found as individual flow karyotype peaks, suitable for sorting with a high degree of purity.     

Inheritance of chromosome heteromorphisms analyzed by high-resolution bivariate flow karyotyping.

The DNA content of the mitotic chromosomes from 10 children and their parents in four families were quantified by bivariate flow karyotyping. In all cases, each chromosome peak in the flow karyotype of the child could be traced to one of the two parents. The measured absolute difference in homologue DNA content between children and their parents averaged 0.8%, or approximately 1 Mbp over all chromosome types. This study demonstrates that flow karyotypes of a proband's parents can be an aid in detecting and quantifying the size of de novo deletions that involve heteromorphic chromosome types.     

High resolution chromosome analysis: one and two parameter flow cytometry

Isolated mammalian chromosomes have been quantitatively classified by high resolution flow cytometry. Chinese hamster chromosomes stained with 33258 Hoechst and excited in the UV showed a fluorescence distribution in which the 14 types of Chinese hamster chromosomes were resolved into 16 groups seen as distinct peaks in the distributions. Chinese hamster chromosomes were also stained with both 33258 Hoechst (HO) and chromomycin A3 (CA3); the two dye contents were measured by selective excitation in the UV and at 458 nm in a dual beam flow cytometer. The resulting two parameter distribution (HO versus CA3) showed 10 chromosome groups¹. Human strain LLL 761 chromosomes stained with HO and excited in the UV showed a fluorescence distribution in which the 23 types of human chromosomes were resolved into 12 groups. Human chromosomes stained with both HO and CA3 and measured in the dual beam flow cytometer produced two parameter fluorescence distributions which showed 20 groups. The chromosomes associated with each group were determined by quinacrine banding analysis of sorted chromosomes and by DNA cytophotometry of preidentified metaphase chromosomes. The relative HO and CA3 stain content and frequency of occurrence of chromosomes in each group were determined from the fluorescence distributions and compared to the results from DNA cytophotometry. The chromosome to chromosome variations in HO and CA3 staining are attributed to variations in chromosomal base composition.     

Immunofluorescent labeling of centromeres for flow cytometric analysis.

A procedure to stain the centromeric region of chromosomes for dual beam flow cytometric analysis is described. Serum from a CREST (Scleroderma syndrome) patient presenting a high titer of anticentromeric antibodies was chosen on the basis of specificity of labeling of cells on slides. The high affinity of the antibodies to centromeres and low binding to chromosomal arms allowed the development of an indirect immunofluorescent labeling procedure using isolated and unfixed chromosomes stabilized by Mg++ ions. Discontinuous Ficoll gradients were used to separate chromosomes from unbound antibodies. With this procedure, chromosome clumping and degradation were minimal. The chromosomes were then stained with the DNA dyes Hoechst 33258 and chromomycin A3, before dual beam flow cytometric analysis. Flow karyotypes, with good chromosome peak resolution, were obtained for both human and hamster chromosomes subjected to the immunolabeling procedure. For quantification of FITC fluorescence due to bound antibody, chromosomes were counterstained with Hoechst only. The FITC intensity of antibody-labeled human and hamster chromosomes were 4-10 and 20 times greater than control chromosomes, respectively. These results suggest that the staining procedure may be suitable for immunolabeling of chromosomes with antibodies recognizing other nuclear proteins and their subsequent quantification by flow cytometry.     

Genetic activity of the G- and R-band DNA of human mitotic chromosomes

The concept of genetic inactivity of G-band DNA had been reinvestigated using the modified approach of Korenberg et al (1978). Coefficients of correlation and partial correlation between the relative gene density (g'), the relative G-band material richness (kH/C) and the relative chromosome size (s') were calculated. The kH/C was calculated as the ratio of brightness of fluorescence of chromosomes stained by Hoechst 33258 (Hi) and by chromomycin A3(Ci). The kH/C is the characteristics of G-band chromosome richness, because G-bands become bright after Hoechst 33258 staining and R-bands are bright after chromomycin A3 staining, while no significant C-bands in chromosomes which may be stained by these fluorochromes are discovered. For the kH/C determination the flow cytometry data of Langlois et al (1982) were used. The relative size of chromosomes was determined, based on the flow cytometry data of Young et al (1979). According to Korenberg, the "gene density" (g') in a chromosome was calculated as a ratio of the number of genes located in the chromosome before 1984 (Human Gene Mapping 7) to the relative size of this chromosome. Correlation between the "gene density" and the G-band richness was rs = -0.65. Out of 107 genes located in either G- or R-bands (Human Gene Mapping 7), 90 were mapped in the R-band and only 17 were ascribed to the G-band in metaphase chromosomes. The data on gene replication time show that all genes of the general cell activity and a portion of tissue-specific genes replicate during the early S-phase, together with R-band materials. These three independent lines of evidence are consistent with the notion that the R-band DNA is more genetically active than G-band DNA. The nature of "junk" DNA of G-bands is discussed.     

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.     

Centromeric index versus DNA content flow karyotypes of human chromosomes measured by means of slit-scan flow cytometry

We have applied slit-scan flow cytometry (SSFCM) to classify human chromosomes according to their centromeric index (CI) and relative DNA content. The resulting bivariate--CI vs. DNA content--distributions shows 14 peaks for normal human chromosomes. Distinct peaks are produced by chromosomes 1, 2, 3, 4 + 5, 6 + 7 + X, 8, 13 + 14 + 15, 16, 17 + 18, 19 + 20, and 21 + 22 + Y. In addition, chromosomes 9 through 12 are resolved into three peaks. The identity of the chromosomes comprising each peak was determined by comparing CI vs. DNA content distributions measured for normal human chromosomes by means of SSFCM with CI and DNA content values measured for human chromosomes with image analysis. The accuracy of CI measurement by SSFCM was verified by measuring CIs for human chromosomes isolated from human/rodent hybrid cell lines containing only a few known human chromosomes. These studies showed CIs measured for human chromosomes 1-19 and 21 to be in close agreement with the CIs calculated by means of image analysis. We further confirmed the chromosome assignments for each peak by showing that the relative volumes of the peaks in the CI vs. DNA content distributions for chromosomes from normal cells are similar to the relative frequencies of chromosomes expected for these peaks based on the peak assignments.     

Analysis and sorting of rye (Secale cereale L.) chromosomes using flow cytometry.

Procedures for chromosome analysis and sorting using flow cytometry (flow cytogenetics) were developed for rye (Secale cereale L.). Suspensions of intact chromosomes were prepared by mechanical homogenization of synchronized root tips after mild fixation with formaldehyde. Histograms of relative fluorescence intensity obtained after the analysis of DAPI-stained chromosomes (flow karyotypes) were characterized and the chromosome content of the DNA peaks was determined. Chromosome 1R could be discriminated on a flow karyotype of S. cereale 'Imperial'. The remaining rye chromosomes (2R-7R) could be discriminated and sorted from individual wheat-rye addition lines. The analysis of lines with reconstructed karyotypes demonstrated a possibility of sorting translocation chromosomes. Supernumerary B chromosomes could be sorted from an experimental rye population and from S. cereale 'Adams'. Flow-sorted chromosomes were identified by fluorescence in situ hybridization (FISH) with probes for various DNA repeats. Large numbers of chromosomes of a single type sorted onto microscopic slides facilitated detection of rarely occurring chromosome variants by FISH with specific probes. PCR with chromosome-specific primers confirmed the identity of sorted fractions and indicated suitability of sorted chromosomes for physical mapping. The possibility to sort large numbers of chromosomes opens a way for the construction of large-insert chromosome-specific DNA libraries in rye.     

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.     

Determination of the DNA content of human chromosomes by flow cytometry

The mean relative DNA content of each human chromosome was calculated from flow karyotypes of ethidium bromide-stained chromosomes obtained from healthy, normal individuals. These values were found to correlate closely with previously published data obtained by photometric scanning of stained, fixed chromosomes. Calculations of the normal variation in DNA content of each human chromosome indicated that chromosomes 1, 9, 16, and Y (chromosomes with large centric heterochromatic regions) were the most variable, followed by the acrocentrics, 13, 14, 15, 21, and 22. Chromosomes 2, 3, 18, and 19 were also found to vary significantly in DNA content. Chromosomes from a number of subjects with extreme heteromorphisms were flow karyotyped to obtain an estimate of the extent of variation in DNA content of each chromosome. The greatest difference between extreme variants was found for chromosome 1 (which differed by 0.82% of the total genomic DNA), followed by 16 and 9. The largest Y-chromosome variant was 85.9% bigger than the smallest. The precise karyotype analysis produced by flow cytometry resolved many differences between chromosome homologs, including some that cannot be readily distinguished cytogenetically. The implications of these findings for detection of chromosome abnormalities by flow karyotype analysis are discussed.