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

Chromosome Analysis and Sorting Using Conventional Flow Cytometers

The fluorescent dyes Hoechst (HO) and Chromomycin A3 (CA3) are commonly used for bivariate flow karyotyping to distinguish individual chromosomes from one another based on differences in base composition and DNA content. However, analysis of chromosomes using this fluorescent dye combination requires a flow cytometer equipped with lasers of specific wavelengths and higher power than is typical of conventional flow cytometers. This unit presents a chromosome staining technique with a dye combination of DAPI and propidium iodide (PI). Chromosomes stained using this dye combination can be analyzed on conventional flow cytometers equipped with a typical configuration of lasers and optics. © 2023 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Cell culture and metaphase harvest of suspension cell line Alternate Protocol 1: Cell culture and metaphase harvest of adherent cell line Basic Protocol 2: Preparation of chromosome suspension using polyamine isolation buffer Basic Protocol 3: Staining chromosomes with DAPI and propidium iodide Alternate Protocol 2: Staining chromosomes with Hoechst and Chromomycin A3 Basic Protocol 4: Bivariate flow karyotyping on a cell analyzer Basic Protocol 5: Bivariate flow karyotyping on a cell sorter Basic Protocol 6: Purification of flow-sorted chromosomes.

High-Throughput Human Telomere Length Analysis at the Single-Chromosome Level by FISH Coupled with Nano-Flow Cytometry

Telomere length (TL) is a highly relevant biomarker for age-associated diseases and cancer, yet its clinical applications have been hindered by the inability of existing methods to rapidly measure the TL distribution and the percentage of chromosomes with critically short telomeres (CSTs, < 3 kb). Herein, we report the development of a high-throughput method to measure TL at the single-chromosome level. Metaphase chromosomes are isolated, hybridized with the Alexa Fluor 488-labeled telomeric peptide nucleic acid probe, and analyzed using a laboratory-built ultrasensitive nano-flow cytometer. The fluorescence intensity of individual chromosomes is converted to TL in kilobases upon external calibration. With an analysis rate of several thousand chromosomes per minute, a statistically robust TL distribution histogram is acquired in minutes, and the percentage of chromosomes with CSTs can be quickly assessed. By analyzing peripheral blood lymphocytes of 158 healthy donors, TL is found to shorten with age at a rate of 64 ± 3 bp/year and the percentage of chromosomes with CSTs increases with age at a rate of 0.32 ± 0.02%/year. Moreover, the data of 28 patients with chronic myeloid leukemia (CML) indicate that telomeres are significantly shorter at the time of diagnosis and the clinical phases of CML are closely associated with TL and the percentage of chromosomes with CSTs. This powerful tool could greatly deepen our understanding of telomere biology and improve the clinical utility of telomere biomarkers.

Ploidy and Proliferation Evaluated by Flow Cytometry. An Overview of Techniques and Impact in Oncology

Flow cytometric methods for the assessment of nuclear and chromosomal DNA content and of cell proliferation (including methods based on pulse-chase of bromodeoxyuridine and on monoclonal antibodies against nuclear oncoproteins and proliferation-associated antigens) are illustrated by examples and analyzed critically. The impact of most of these techniques for the study of human solid tumors, with exception of nuclear DNA content evaluation, appears still limited. In particular, new studies of cell lines and clinical material from human tumors using new proliferation markers and multiparameter flow cytometry are necessary to solve a considerable number of methodologic and scientific problems.

Downstream bioengineering of ACE chromosomes for incorporation of site-specific recombination cassettes

Advances in mammalian artificial chromosome technology have made chromosome-based vector technology amenable to a variety of biotechnology applications including cellular protein production, genomics, and animal transgenesis. A pivotal aspect of this technology is the ability to generate artificial chromosomes de novo, transfer them to a variety of cells, and perform downstream engineering of artificial chromosomes in a tractable and rational manner. Previously, we have described an alternative artificial chromosome technology termed the ACE chromosome system, where the ACE platform chromosome contains a multitude of site-specific, recombination sites incorporated during the creation of the ACE platform chromosome. In this chapter we review a variant of the ACE chromosome technology whereby site-specific, recombination sites can be integrated into the ACE chromosome following its de novo synthesis. This variation allows insertion of user-defined, site-specific, recombination systems into an existing ACE platform chromosome. These bioengineered ACE platform chromosomes, containing user-defined recombination sites, represent an ideal circuit board to which an array of genetic factors can be plugged-in and expressed for various research and therapeutic applications.

Array painting: a protocol for the rapid analysis of aberrant chromosomes using DNA microarrays

Array painting is a technique that uses microarray technology to rapidly map chromosome translocation breakpoints. Previous methods to map translocation breakpoints have used fluorescence in situ hybridization (FISH) and have consequently been labor-intensive, time-consuming and restricted to the low breakpoint resolution imposed by the use of metaphase chromosomes. Array painting combines the isolation of derivative chromosomes (chromosomes with translocations) and high-resolution microarray analysis to refine the genomic location of translocation breakpoints in a single experiment. In this protocol, we describe array painting by isolation of derivative chromosomes using a MoFlo flow sorter, amplification of these derivatives using whole-genome amplification and hybridization onto commercially available oligonucleotide microarrays. Although the sorting of derivative chromosomes is a specialized procedure requiring sophisticated equipment, the amplification, labeling and hybridization of DNA is straightforward, robust and can be completed within 1 week. The protocol described produces good quality data; however, array painting is equally achievable using any combination of the available alternative methodologies for chromosome isolation, amplification and hybridization.

Bivariate flow cytometry of farm animal chromosomes: a potential tool for gene mapping

Bivariate flow karyotypes of chromosomes from sheep, cattle and pig lymphocytes and from a cattle-mouse somatic cell hybrid line were obtained using a dual laser fluorescence-activated cell sorter (FACS). Pig chromosomes were resolved into 19-20 peaks, indicating that most, if not all, pig chromosomes could be separated by this technique. Sheep chromosomes showed incomplete separation but three clear peaks, presumably representing the three large metacentric chromosomes, plus five other clusters were obtained. Cattle chromosomes showed poor separation but about four peaks could be distinguished, indicating that certain chromosomes could be sorted in this species. The use of cattle-mouse hybrids may enable other individual cattle chromosomes to be obtained. It is concluded that FACS separation will be a useful additional tool for gene mapping.

Advanced preparative techniques to establish probes for molecular cytogenetics

The methods covered in this unit include flow cytometry of metaphase chromosomes, chromosome dissection, and the DOP-PCR amplification methods for reverse chromosome painting. Successful application in these areas requires care and attention to methodological details, and this unit is particularly comprehensive.

Factors affecting flow karyotype resolution

BACKGROUND

One of the major factors which influences the chromosome purity achievable particularly during high speed sorting is the analytical resolution of individual chromosome peaks in the flow karyotype, as well as the amount of debris and fragmented chromosomes. We have investigated the factors involved in the preparation of chromosome suspensions that influence karyotype resolution.

METHODS

Chromosomes were isolated from various human and animal cell types using a series of polyamine buffer isolation protocols modified with respect to pH, salt concentration, and chromosome staining time. Each preparation was analyzed on a MoFlo sorter (DAKO) configured for high speed sorting and the resolution of the flow karyotypes compared.

RESULTS

High resolution flow cytometric data was obtained with chromosomes optimally isolated using hypotonic solution buffered at pH 8.0 and polyamine isolation buffer (with NaCl excluded) between pH 7.50 and 8.0. Extending staining time to more than 8 h with chromosome suspensions isolated from cell lines subjected to sufficient metaphase arrest times gave the best result with the lowest percentage of debris generated, tighter chromosome peaks with overall lower coefficients of variation, and a 1- to 5-fold increase in the yield of isolated chromosomes.

CONCLUSIONS

Optimization of buffer pH and the length of staining improved karyotype resolution particularly for larger chromosomes and reduced the presence of chromosome fragments (debris). However, the most interesting and surprising finding was that the exclusion of NaCl in PAB buffer improved the yield and resolution of larger chromosomes.

Use of fluorescent sequence-specific polyamides to discriminate human chromosomes by microscopy and flow cytometry

In this paper, we demonstrate the use of synthetic polyamide probes to fluorescently label heterochromatic regions on human chromosomes for discrimination in cytogenetic preparations and by flow cytometry. Polyamides bind to the minor groove of DNA in a sequence-specific manner. Unlike conventional sequence-specific DNA or RNA probes, polyamides can recognize their target sequence without the need to subject chromosomes to harsh denaturing conditions. For this study, we designed and synthesized a polyamide to target the TTCCA-motif repeated in the heterochromatic regions of chromosome 9, Y and 1. We demonstrate that the fluorescently labeled polyamide binds to its target sequence in both conventional cytogenetic preparations of metaphase chromosomes and suspended chromosomes without denaturation. Chromosomes 9 and Y can be discriminated and purified by flow sorting on the basis of polyamide binding and Hoechst 33258 staining. We generate chromosome 9- and Y-specific 'paints' from the sorted fractions. We demonstrate the utility of this technology by characterizing the sequence of an olfactory receptor gene that is duplicated on multiple chromosomes. By separating chromosome 9 from chromosomes 10-12 on the basis of polyamide fluorescence, we determine and differentiate the haplotypes of the highly similar copies of this gene on chromosomes 9 and 11.

Comparative karyotype using bidirectional chromosome painting: how and why?

Rat is widely used in biomedical and pharmaceutical research but its genome has been significantly less studied than that of the mouse. This represents a major limitation for studying cytogenetic and molecular mechanisms in the rat model. As Muridae species underwent an intense chromosome evolution it is not possible to directly transpose knowledge of the mouse genome to that of the rat. For establishing a comparative karyotype between rat and mouse, painting probes of both species were prepared by PARM-PCR (Priming Authorizing Random Mismatches PCR) from a low copy number of sorted chromosomes, the mouse and rat specific painting probes being then hybridized on rat and mouse metaphases, respectively. The availability of rodent species chromosome painting probes as well as the information obtained by the comparative karyotype and comparative gene mapping data are of great interest to improve knowledge on species evolution but also to better understand carcinogenesis process, as illustrated by our data concerning the cytogenetic characterization of radon-induced rat lung tumors. Detailed methods for obtaining painting probes by PARM-PCR from sorted mouse and rat chromosomes and for their hybridization in homologous or heterologous conditions are described. Usefulness of chromosome painting is illustrated by the characterization of chromosomal abnormalities in a radon-induced rat lung tumor. Advantages and limitations of this technique as compared to classical cytogenetics, FISH and CGH are discussed.

Complete loss of wild-type TP53 in a nontransformed human epithelial cell line is preceded by a phase during which a heterozygous TP53 mutant effectively outgrows the homozygous wild-type cells

HMT-3522 is a spontaneously immortalized cell line derived from a fibrocystic breast lesion. After continuous accumulation of genetic changes, the cell line was transformed from a nontumorigenic to a malignant phenotype. One of the earliest genetic aberrations is a missense mutation of codon 179 (His179Asn) in the tumor suppressor gene TP53 leading to outgrowth of a cell type expressing only the mutant form of TP53. In this report, we extend earlier investigations to reveal the genetic background for the evolution from homozygous wild type to hemizygous mutated cells. The status of the TP53 alleles was followed at different stages by fluorescence in situ hybridization (FISH) and allele-specific PCR (ASPCR) on total DNA, as well as flow-sorted chromosomes--taking advantage of a size difference between the two homologues of chromosome 17 that harbor TP53 on 17p. This further allowed us to determine on which of the two chromosomes the mutated allele was located. The results presented here show that the cells have undergone an evolution from homozygous wild type for TP53 to heterozygous (His179Asn mutation in one allele), and finally to a hemizygous mutated state (deletion of the remaining wild-type allele). The finding of a transient period in which heterozygous cells dominate the population before the eventual outgrowth of hemizygous cells strongly indicates that the His179Asn mutation results in a tp53 protein with a dominant negative effect that does not totally abrogate the function of wild type TP53 in vitro.

Comparative karyotype of rat and mouse using bidirectional chromosome painting

A comparative karyotype of rat (Rattus norvegicus) and mouse (Mus musculus) based on chromosome G-banding morphology, heterologous chromosome painting results and available gene mapping data is proposed. Whole chromosome painting probes from both species were generated by PARM-PCR amplification of flow sorted chromosomes. Bidirectional chromosome painting identifies 36 segments of syntenic homology and allows us to propose a nearly complete comparative karyotype of mouse and rat (except for RNO 13 p and RNO 19 p12-13). Seven segments completely covered the RNO chromosomes 3, 5, 8, 11, 12, 15 and 18. Eight segments completely covered the MMU chromosomes 3, 4, 6, 7, 9, 12, 18 and 19. The RNO chromosomes 5, 8, 18 show complete homology with the MMU chromosomes 4, 9 and 18, respectively. Bidirectional hybridization results clearly assign 16 segments to subchromosomal regions in both species. Interpretation of the results allows subchromosomal assignment of all the remaining segments apart from seven distributed on chromosomes MMU 15, MMU 10 B2-D3 and MMU 17 E3-E5. The proposed comparative karyotype shows overall agreement with available comparative mapping data. The proposed repartition of syntenic homologous segments between the two species provides useful data for gene-mapping studies. In addition, these results will enable the reconstruction of the karyotype of the Cricetidae and Muridae common ancestor and the definition of the precise rearrangements which have occurred in both mouse and rat lineages during evolution.

Reverse chromosome painting for the identification of marker chromosomes and complex translocations in leukemia

BACKGROUND

Chromosome banding techniques and in situ hybridization reveal the majority of chromosomal aberrations. However, difficulties remain in cases of highly contracted chromosomes, poor quality of the metaphases or the presence of markers with the involvement of several chromosomes. Here, it is demonstrated that reverse painting can be applied successfully starting with bone marrow cells from primary acute myelocytic leukemias (AML).

METHODS

This was accomplished by culturing the leukemic cells with a cocktail of various growth factors, which yielded sufficient numbers of cells in cycle to harvest chromosomes for sorting. Aberrant chromosomes were flow-sorted and amplified by degenerate oligonucleotide-primed PCR. The resulting products were labeled by nick-translation and hybridized on normal metaphase spreads.

RESULTS

Two patients with marker chromosomes in their leukemia cells were analyzed in detail. The hybridization pattern displayed the composition of the aberrant sorted chromosome. Results were compared with conventional cytogenetic analyses that were performed on material obtained from the same aspirate. The reverse-painting technique enabled identification of aberrations that were not detected by conventional cytogenetic analysis.

CONCLUSIONS

Primary AML cells can be cultured in vitro, using optimal culture conditions, facilitating the production of high quality flow karyotypes, suitable for sorting of marker chromosomes to produce DOP-PCR derived chromosome painting probes for reverse painting. Valuable additional cytogenetic information can thus be obtained about complex chromosomal rearrangements or structural aberrations that could not be completely resolved by conventional cytogenetic analysis.

Assignment of markers by using polymerase chain reaction on pools of swine flow-sorted chromosomes

Gene chromosomal assignment can be realized not only by somatic hybrid panels but also by spot-blot hybridization or polymerase chain reaction (PCR) of flow-sorted chromosomes. We propose a swine chromosome assignment strategy by PCR amplification on pooled chromosomal DNA, which allows assignment despite possible chromosomal contamination during sorting. Each pool contains three different chromosomes, each chromosome being present in one or two pools. We present concordant results obtained for eight markers already mapped to different swine chromosomes and we assign the somatostatin gene to chromosome 13, a new marker in the pig genome.

The bovine bivariate flow karyotype and peak identification by chromosome painting with PCR-generated probes

A bovine bivariate flow karyotype has been established from a primary fibroblast cell culture carrying a 4;10 Robertsonian translocation. From 27 to 36 populations could be resolved by flow cytometry although the anticipated number was 31. Separation of chromosomal pairs into two populations explains this high resolution and confirms the high level of heteromorphism previously observed. We used a PARM-PCR (Priming Authorizing Random Mismatches) procedure for the production of paint probes from flow-sorted chromosome fractions. These probes were used for chromosome identification by fluorescence in situ hybridization (FISH) on R-banded metaphase spreads. We present the localization of all the bovine chromosome types on the flow karyotype. Twenty-two chromosome types including the translocated chromosome were sorted as pure fractions.

Bivariate flow karyotyping with air-cooled lasers

An experimental flow cytometer was constructed using a quartz flow cell optically coupled to a 1.22 NA lens. A pair of crossed cylindrical quartz lenses allowed multilaser excitation. Two helium-cadmium (HeCd) lasers, emitting 16 mW at 442 nm and 35 mW at 325 nm, were used to excite chromomycin A3 and Hoechst 33258 fluorescence, respectively. Bivariate flow karyotypes from normal human male chromosomes and from the Daudi cell line were obtained and were compared to those from a standard instrument using dual water-cooled lasers. The new experimental instrument exhibited comparable resolution to that from the standard instrument. In further experiments with Daudi chromosomes, the 35 mW HeCd laser was replaced with a 10 mW HeCd laser, and the system still gave good, though slightly decreased, resolution.

Cytogenetic analysis by chromosome painting

Chromosome painting is a term used to describe the direct visualisation using in situ hybridisation of specific chromosomes in metaphase spreads and in interphase nuclei. Chromosome painting, coupled with fluorescence in situ hybridisation (FISH), is now used routinely to enhance the identification of chromosomal rearrangements, the assignment of breakpoints, and the determination of the origin of extra chromosomal material. Amplification of small numbers of flow-sorted chromosomes by the polymerase chain reaction allows labelled chromosome paints to be generated in a matter of days. These technologies have enabled the development of reverse chromosome painting, in which the paint is produced from sorted aberrant chromosomes and hybridised back onto normal metaphase spreads to identify directly the composition of the aberrant chromosome. Reverse chromosome painting is able to identify not only the chromosomal origin of marker chromosomes but also the regions and breakpoints involved. In some cases, such as interstitial translocations and complex marker chromosomes, the combination of conventional (forward) chromosome painting and reverse chromosome painting combine to provide a definitive analysis of the rearrangement. With the availability of chromosome paints and painting kits from a variety of commercial sources, multicolour chromosome painting has now become a routine method of analysis in the clinical cytogenetic laboratory.

TOTO and YOYO: new very bright fluorochromes for DNA content analyses by flow cytometry

Flow cytometric (FCM) studies were performed on nuclei, ethanol-fixed CHO cells, and isolated human GM130 chromosomes stained with two new cyanine dyes, TOTO and YOYO. These fluorochromes, which are dimers of thiazole orange and oxazole yellow, respectively, have high quantum efficiencies and exhibit specificities for both DNA and RNA. Bound to dsDNA in solution, TOTO and YOYO emit at 530 and 510 nm, respectively, when excited at 488 nm and 457 nm, wavelengths available from most lasers employed in FCM. RNase-treated CHO nuclei, stained with either TOTO or YOYO, provided DNA histograms, with low coefficients of variation, that were as good as or better than those obtained with nuclei stained with propidium iodide (PI) or mithramycin (MI). In addition, by comparison on an equimolar basis, nuclei stained with YOYO fluoresced over 1,000 times more intensely than nuclei stained with MI. Fluorescence ratio analyses of nuclei stained with both YOYO and Hoechst 33258 showed that the ratio of YOYO to Hoechst fluorescence remained relatively constant for G1 and S phase cells, but decreased significantly for cells in G2/M. These results indicate that the cyanine dyes may be useful in examining specific changes in chromatin structure during G2/M phases of the cell cycle. Ethanol-fixed CHO cells stained with TOTO or YOYO did not yield reproducible DNA histograms of good quality, presumably because of the poor accessibility of DNA to these large fluorochromes. However, bivariate analyses of human GM130 chromosomes stained with TOTO or YOYO alone and excited sequentially with uv and visible wave-lengths showed resolution of many individual chromosome peaks similar to results obtained for chromosomes stained with HO and chromomycin A3. Collectively, these studies show potential advantages for the use of these new cyanine dyes in FCM studies that require the sensitive detection of DNA.

Application of molecular and cytogenetic techniques to the detection of a de novo unbalanced t(11q;21q) in a patient previously diagnosed as having monosomy 21

The occurrence of complete autosomal monosomy in man is extremely rare and generally considered to be incompatible with life. Since the introduction of banding techniques in human cytogenetics, several cases of presumptive monosomy for chromosome 21 have nevertheless been reported. However, it has been suggested that most, if not all, of these cases may represent unbalanced translocations or other structural aberrations resulting in only partial monosomy 21. Here we described a patient in whom full monosomy 21 was initially diagnosed by routine karyotyping. Re-examination with a combination of high resolution banding technique, chromosome painting and DNA polymorphism analysis demonstrated the presence of an unbalanced translocation between the long arms of chromosome 11 and 21, respectively. Consequently, the case was re-classified as a partial monosomy for the proximal long arm of chromosome 21.

Ring chromosome 20 with loss of telomeric sequences detected by multicolour PRINS

A ring chromosome 20 in a male infant with epileptic seizures, mental and somatic growth retardation, and behavioural disturbances is described. Conventional cytogenetics revealed the karyotype to be 46,XY,r(20)(pter-->qter) and no signs of mosaicism were found. Fluorescence in situ hybridisation using the clone p20Z1 identified the ring to be derived from chromosome 20. By counting 111 metaphases, only 7% were found to be missing the ring. The absence of telomeric sequences in the ring chromosome was demonstrated by multicolour PRINS: a three-step PRimed IN Situ labelling technique, using unlabelled primers. A terminal deletion of both arms thus seems to be the cause of the ring formation in the proband. Bivariate flow-analysis of chromosomes verified a deletion of the ring chromosome. The clinical and cytogenetic findings are compared with previous cases. A specific ring 20 syndrome seems justified.

Assignment of an autosomal sex reversal locus (SRA1) and campomelic dysplasia (CMPD1) to 17q24.3-q25.1

We have mapped the autosomal sex reversal locus, SRA1, associated with campomelic dysplasia (CMPD1) to 17q24.3-q25.1 by three independent apparently balanced de novo reciprocal translocations. Chromosome painting indicates that the translocated segment of 17q involves about 15% of chromosome 17 in all three translocations, corresponding to a breakpoint at the interphase between 17q24-q25. All three 17q breakpoints were localized distal to the growth hormone locus (GH), and proximal to thymidine kinase (TK1). Due to the distal location of the breakpoints, previously mentioned candidate genes, HOX2 and COL1A1, can be excluded as being involved in CMPD1/SRA1. The mouse mutant tail-short (Ts) which maps to the homologous syntenic region on mouse chromosome 11, displays some of the features of CMPD1.

Deletion analysis maps ocular albinism proximal to the steroid sulphatase locus

We describe a pedigree in which four male members are affected by a contiguous gene abnormality involving the short arm of the X chromosome (Xp22.32). Bivariate flow cytometry of lymphoblastoid cell lines from two of these individuals and a normal male showed a 6-7 megabase deletion in affected males, and high resolution chromosomal G-banding of an obligate heterozygote showed the deletion to reside in the Xp22.32 region. Affected members had X-linked ichthyosis due to steroid sulphatase deficiency, Kallmann's syndrome, but no ocular albinism. In two out of four affected individuals studied, there was unilateral renal agenesis. Deletion analysis using the Xp22.32 markers MIC2, DXS31, DXS 89, GMGX9, DXS278, DXS143, and DXS9 showed that the deletion extended from DXS31 to DXS143 (inclusive). The absence of ocular albinism in this pedigree shows conclusively that the X-linked ocular albinism gene resides proximal to the DXS143 locus. Further, the inconstant association of unilateral renal agenesis with X-linked Kallmann's syndrome, even when the latter is caused by a complete deletion of the gene, suggests that the absence of the X-linked Kallmann gene can be compensated in renal development.

Identification of a tumor marker chromosome by flow sorting, DNA amplification in vitro, and in situ hybridization of the amplified product

A method combining flow sorting and molecular cytogenetic techniques for the identification of unknown marker chromosomes is described. In this study, the bladder tumor cell line J82 was used, which was known to carry a marker chromosome of the size of chromosome 7 in every cell. From the cytogenetic analysis of Q-banded metaphase cells, it was shown to be composed of approximately 40% presumably the greater part of chromosome 20 and for the rest microscopically unidentifiable material. This marker chromosome was found using flow cytometric analysis to form an independent peak and hence was suitable for isolation using dual-parameter sorting after staining with Hoechst 33258 and chromomycin A3. Subsequently, the marker was isolated by dual-parameter sorting. DNA amplification of 300 isolated chromosomes by polymerase chain reaction (PCR) using the Alu-primer Bk33 and the LINES-primer LH5 was carried out. After purification of the amplified product, a yield of 5 microns of DNA was obtained. The DNA was labelled using Bio-11-dUTP and applied to human lymphocyte metaphase cells in a suppressive in situ hybridization procedure. Fluorescence was visible over chromosome 20 and over the distal one-half of 6p. Together the fluorescent regions accounted for only approximately 60% of the marker length, indicating a possible duplication of chromosome 20 material. This was confirmed by applying bicolor in situ hybridization using chromosome 6- and 20-specific DNA libraries to metaphase cells of the J82 cells.

Flow karyotype analysis and sorting of the Chinese hamster chromosomes: comparing the effects of the isolation buffers

The effects of different swelling solutions on the univariate flow karyotype of whole chinese hamster embryo cells (WCHE K10) and cloned chinese hamster embryo fibroblast cells (CCHE 40) were compared using four methods of chromosome isolation. Chromosomes of each cell line were prepared by the Aten, Polyamine-Digitonin, Tris-Triton, and HEPES methods and analyzed with a FACStar flow cytometer. Polyamine-Digitonin and Aten methods produced the most satisfactory flow karyotype. Structurally aberrant chromosomes in the cell lines were detected in the flow karyotype as extra peaks. CCHE 40 chromosomes 1,2,X and 3q were sorted into separate tubes and reanalyzed; and the coefficient of variation of each chromosome peak was near 5%. To apply the flow karyotype analysis to clinical cytogenetics, chromosome preparation was one of the most important factor, and it is necessary to sort the chromosome peak sharply.

Detection of recurrent chromosome abnormalities in Ewing's sarcoma and peripheral neuroectodermal tumor cells using bivariate flow karyotyping

Bivariate flow karyotyping can be used for the detection of recurrent chromosome abnormalities in tumor cells. For this purpose 2 cell lines originally derived from Ewing's sarcomas and 4 cell lines from peripheral neuroectodermal tumors were used. The characteristic t(11;22) was known to be present in 5 cell lines. The remaining cell line was known to have a variant t(2;11;22;21) translocation. Metaphase chromosomes were stained with the fluorescent dyes Hoechst 33258 and Chromomycin A3 and analyzed subsequently using bivariate flow cytometry. The resulting bivariate flow karyotypes of the tumor cells were normalized by a standardized procedure using a computerized method and compared with a reference flow karyotype of normal chromosomes. In 5 cell lines two recurring abnormal chromosome peaks were identified at positions expected for the der(11) and der(22) chromosomes characteristic for the reciprocal t(11;22)(q24;q12). In the remaining cell line with the variant t(2;11;22;21), only the peak representing the der(22) was identifiable. It is concluded that bivariate flow karyotyping can be used for the semiautomated detection of recurrent translocations and the assessment of their variability among different tumors.

Pig standard bivariate flow karyotype and peak assignment for chromosomes X, Y, 3, and 7

A standard pig flow karyotype (2N = 38 chromosomes) was defined by standardization of several flow karyotypes obtained from stimulated peripheral blood lymphocytes of normal male and female pigs. Depending on the animals under study, the flow analysis of their chromosome suspensions gave rise to bivariate flow karyotypes comprising from 15 to 17 peaks, of which 11 to 15 represented single chromosomes. The results were used to propose a peak nomenclature. In addition, a male miniature pig lymphoblastoid cell line was characterized by flow cytogenetics. A very high-resolution flow karyotype, in which all peaks but one superimposed on those of the standard karyotype, was obtained. Peaks were assigned for chromosomes X and Y. Analysis of flow karyotypes obtained from translocated t(3,7)(p1.3;q2.1) pigs combined with polymerase chain reaction (PCR) studies of major histocompatibility complex (MHC)-linked sequences on flow-sorted chromosomes allowed identification of peaks 3 and 7 of normal pig chromosomes and of the derivative chromosomes associated with the t(3,7)(p1.3;q2.1) translocation.

Clinical application of flow cytometry for DNA analysis of solid tumors

Recent developments of flow cytometry (FCM) technology which make multiple correlative biological measurements on normal and neoplastic cells is affecting areas of diagnostic pathology as well as research fields, and a general understanding of FCM techniques is essential for pathologists. Today, FCM DNA measurements of tumors also becomes routine in the clinical and/or pathological laboratory for aid in cancer diagnosis and cancer treatment. It can also contribute to diagnosis of tumors as a supplemental method to conventional histopathology, and DNA ploidy and the percentage of S-phase fraction are considered as complementary prognostic parameters independent of the stage of disease. This article reviews clinical applications of flow cytometry focusing on the DNA measurements of solid tumors, and related practical issues, such as the methodology for nuclear DNA measurement, interpretation of DNA histograms and the relationship of DNA ploidy and S-phase fraction to clinical and pathological features of human solid tumors.

Swine chromosomal DNA quantification by bivariate flow karyotyping and karyotype interpretation

Human and swine chromosomes were analyzed separately and as a mix to obtain bivariate flow karyotypes. They were normalized to each other in order to use the human chromosomal DNA content as standard. Our results led to the characterization of the "DNA line" in swine identical to the human "DNA line." Estimation of the DNA content in mega-base pairs of the swine chromosomes is proposed. Chromosomal assignment to the various resolved peaks on the bivariate swine flow karyotype is suggested from the relation between DNA content quantified by flow cytometry and chromosomal size. Swine chromosomes 1, 13, 6, 5, 10, 16, 11, 18, and Y were assigned to peaks A, B, C, K, L, N, O, Q, and Y, respectively. Peaks D and E were assumed to contain chromosomes 2 and 14, but without specific assignment. Similarly, P and M peaks were expected to correspond to chromosomes 12 and 17. Of the remaining chromosomes (3, 7, X, 8, 15, 9, and 4), chromosomes 3, 7, and X, which were assigned previously to peaks F, G, and H, respectively, led us to deduce that chromosomes 15 and 8 belonged to peaks I and J, and chromosomes 9, 4, and X to peak H.

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.

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.

Semi-automated detection of aberrant chromosomes in bivariate flow karyotypes

A method is described that is designed to compare, in a standardized procedure, bivariate flow karyotypes of Hoechst 33258 (HO)/Chromomycin A3 (CA) stained human chromosomes from cells with aberrations with a reference flow karyotype of normal chromosomes. In addition to uniform normalization of normal and abnormal flow karyotypes, the main purpose is detection of structurally abnormal chromosomes in often complex karyotypes of tumor cells. The method, which has been implemented in a computer program, consists of a comparison of individual chromosome peaks with the positions of peaks in the flow karyotype constituted by normal chromosomes and takes into account the natural variability in base composition of normal chromosomes among healthy individuals. Flow-karyotypes are normalized using an iterative fitting procedure, using corrections for (1) amplification of HO and CA fluorescence, (2) cross-talk between the fluorescence signals of HO and CA, and (3) offset of the HO and CA origin. Flow karyotypes of two cell lines, one with a simple deletion and the other with more complex karyotypic changes, were analyzed. The results of flow analysis were found to be in general agreement with the cytogenetic analysis of quinacrine banded karyotypes.

Characterization of somatic cell hybrids by bivariate flow karyotyping and fluorescence in situ hybridization

We report on the use of flow karyotyping and fluorescence in situ hybridization (FISH) to characterize the human chromosomes in somatic cell hybrids. The identity, DNA content, and relative frequency of human chromosomes are derived from flow karyotypes, i.e., measurements of Hoechst and chromomycin fluorescence intensities of chromosomes by dual beam flow cytometry. Chromosome integrity is assessed by comparing the peak position of a human chromosome in the flow karyotypes of a hybrid cell line and its human donor. When human donor cells are unavailable, the peak position of a human chromosome in a hybrid line is compared to the range of peak positions among normal individuals. The relative frequency of human chromosomes in subclones or hybrids grown in culture is monitored using the volumes of peaks in flow karyotypes. FISH with biotinylated human genomic DNA or chromosome-specific repeat sequence as probe is used in conjunction with flow karyotyping to confirm the number of human chromosomes in hybrids. Some small rearrangements are detected by flow karyotyping and not by FISH. On the other hand, translocations between human and rodent chromosomes are detected by FISH and not always by flow karyotyping. Flow karyotyping and FISH were used to characterize over 100 hybrid lines donated by other laboratories. A hybrid set useful for the construction of chromosome-enriched gene libraries is presented. In this set, each of the 24 human chromosome types is present and intact, as judged by these techniques, in a line containing little or no other human material.

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.

Anti-kinetochore staining for single laser, bivariate flow sorting of Indian muntjac chromosomes

Flow cytometric chromosome sorting typically relies upon dual-laser, bivariate analysis after staining with two different base pair-specific dyes for resolution of chromosomes with similar DNA content. The availability of FITC-conjugated antibodies offers the possibility of single-laser bivariate analysis when combined with propidium iodide (PI) DNA staining, but requires exploitable antigenic differences between chromosomes of interest. A technique was developed for indirect immunofluorescent anti-kinetochore staining of Indian muntjac chromosomes in suspension. Primary antibody binding within permeabilized whole cells minimized centrifugation-induced loss of chromosomal integrity. Subsequent FITC-conjugated second antibody binding was not affected by concurrent PI-counterstaining. Anti-kinetochore staining facilitated resolution of chromosomes No. 2 and X, which formed a doublet peak upon univariate DNA content analysis, as well as recognition of the Y2 peak which was indistinguishable from debris by univariate analysis. The technique allowed greater than 90% purification of each Indian muntjac chromosome.

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.

Study of X chromosome abnormality in XX males using bivariate flow karyotype analysis and flow sorted dot blots

We have used bivariate flow karyotype analysis to quantify aberrant X chromosome size in 11 XX males. With one exception, the patients could be grouped into those with an X homologue difference greater than normal (Group A, n = 3) and into those whose X homologue difference could not be distinguished from female controls (Group B, n = 7). The range of sizes of the aberrant X chromosome in Y-sequence positive patients agrees with the variable nature of the X-Y interchange in these individuals as determined by the use of Y-specific DNA probes and Southern blotting analysis. In one patient it was possible to sort separately the normal and the X-Y interchanged homologues for dot blot analysis. The presence of Y sequences and an increased dose of the zinc finger gene, ZFY, were detected in the X-Y interchanged homologue. In preliminary studies of 5 male and 6 female controls, it was noted that a consistent difference between the two X homologues in females was found which could not be totally explained by errors of the fitting procedure. We suggest that this difference could be due to X inactivation and that the two X homologues in females might be distinguishable.

Clinical applications of flow karyotyping in myelocytic leukemia by stimulation of different subpopulations of cells in blood or bone marrow samples

Examples are presented in which normal as well as abnormal chromosome distributions could be obtained from the same individual by means of bivariate flow karyotyping. Selective stimulation of T-lymphocytes obtained by E-rosetting from the blood of a patient with acute myelocytic leukemia resulted in a normal flow karyogram. The specific stimulation of myelocytic leukemia cells with granulocyte-macrophage colony stimulating factor (GM-CSF) and interleukin 3 (IL-3) yielded flow karyograms displaying the leukemia-associated chromosome abnormalities. The resulting flow karyograms could be used to discriminate between homolog differences, which appear normally in virtually every individual, and leukemia-associated chromosomal aberrations. In the case of a female chronic myelocytic leukemia patient who received bone marrow form an HLA-identical male donor, specific stimulation of various subsets of cells enabled to discriminate between leukemic host cells and non-leukemic donor cells. Both the leukemia-specific translocations and sex chromosomes were used as markers to analyse the flow karyograms obtained from the same sample.

A computer program for analyzing bivariate flow karyotypes

This article describes a computer program for analyzing bivariate flow karyotypes of human chromosomes stained with Hoechst 33258 (HO) and chromomycin A3 (CA). The karyotype first is divided into regions that contain chromosome peaks. The chromosomes that are associated with those areas are identified. The distributions in these areas then are fitted with mathematical functions of increasing complexity. The process starts by fitting a specified number of univariate Gauss functions to projections of the HO and CA distributions of each area. The final fit can include multiple bivariate Gauss functions, including a background function for debris subtraction. The results of one stage in the fitting process serve as seed values for the next, more complex step. Since the program autonomously estimates the starting values for the iterative fitting procedures, the fit results are insensitive to operator bias and the program will consistently converge to the same solutions. The resulting table of parameter values can be used to compare flow karyotypes to a reference data set.

Parallel processing data acquisition system for multilaser flow cytometry and cell sorting

This report describes the data acquisition electronics for a flow cytometer. The design differs from most instruments in that the signals from a large number of detectors are processed in parallel. Each of the input channels is capable of autonomously measuring and digitizing the fluorescence signals. The digitized values that belong to one particle are collected by digital circuitry and are presented as a compact data package on a special bus. In addition to the pulse values, the data package contains a time marker, information needed for sort decisions, and an error detection code. Specially designed electronic modules that read the information from the bus can take complex multiparameter sort decisions at a very high speed. All events can also be recorded as data lists by a computer. The lists can be used to reconstruct a sort or analysis run. The raw data lists can also be reduced to kinetic curves and/or (gated) multivariate histograms. As a result of the applied scheme of parallel pulse processing, the dead time of the system is independent of the number of parameters measured and the number and time separation of the excitation beams. The instrument has a cycle time of 5 microseconds, which corresponds to a throughput rate of 2 x 10(5) events/s. At this rate, the incidence of correlation errors is well below 1 in 10(8) analyzed particles. The system has proved to be reliable and convenient to use in a variety of experiments. Its high speed and low error rate make it well suited for high-resolution measurements, rare-event analysis, kinetic measurements, and high-speed cell sorting.