Flow cytometric quantification of human chromosome specific repetitive DNA sequences by single and bicolor fluorescent in situ hybridization to lymphocyte interphase nuclei

Fluorescent in situ hybridization allows for rapid and precise detection of specific nucleic acid sequences in interphase and metaphase cells. We applied fluorescent in situ hybridization to human lymphocyte interphase nuclei in suspension to determine differences in amounts of chromosome specific target sequences amongst individuals by dual beam flow cytometry. Biotinylated chromosome 1 and Y specific repetitive satellite DNA probes were used to measure chromosome 1 and Y polymorphism amongst eight healthy volunteers. The Y probe fluorescence was found to vary considerably in male volunteers (mean fluorescence 169, S.D. 35.6). It was also detectable in female volunteers (mean fluorescence 81, S.D. 10.7), because 5-10% of this repetitive sequence is located on autosomes. The Y probe fluorescence in males was correlated with the position of the Y chromosome cluster in bivariate flow karyotypes. When chromosome 1 polymorphism was studied, one person out of the group of eight appeared to be highly polymorphic, with a probe fluorescence 26% below the average. By means of fluorescent in situ hybridization on a glass slide and bivariate flow karyotyping, this 26% difference was found to be caused by a reduction of the centromere associated satellite DNA on one of the homologues of chromosome 1. The simultaneous hybridization to human lymphocyte interphase nuclei of biotinylated chromosome 1 specific repetitive DNA plus AAF-modified chromosome Y specific DNA was detected by triple beam flow cytometry. The bicolor double hybridized nuclei could be easily distinguished from the controls. When the sensitivity of this bicolor hybridization is improved, this approach could be useful for automatic detection of numerical chromosome aberrations, using one of the two probes as an internal control.     

Human chromosome-specific repetitive DNA sequences: novel markers for genetic analysis

Two recombinant DNA clones that are localized to single human chromosomes were isolated from a human repetitive DNA library. Clone pHuR 98, a variant satellite 3 sequence, specifically hybridizes to chromosome position 9qh. Clone pHuR 195, a variant satellite 2 sequence, specifically hybridizes to chromosome position 16qh. These locations were determined by fluorescent in situ hybridization to metaphase chromosomes, and confirmed by DNA hybridizations to human chromosomes sorted by flow cytometry. Pulsed field gel electrophoresis analysis indicated that both sequences exist in the genome as large DNA blocks. In situ hybridization to intact interphase nuclei showed a well-defined, localized organization for both DNA sequences. The ability to tag specific human autosomal chromosomes, both at metaphase and in interphase nuclei, allows novel molecular cytogenetic analyses in numerous basic research and clinical studies.     

Bi-color detection of two target DNAs by non-radioactive in situ hybridization

Summary A non-radioactive in situ hybridization technique is described which allows the simultaneous detection of different DNA sequences. To demonstrate the feasibility of the proccdure, metaphases and interphase nuclei of a human-mouse somatic cell hybrid were simultaneously hybridized with mercurated total human DNA and a biotinylated mouse satellite DNA probe. After the hybridization, the probes were detected immunocytochemically using two different and independent affinity systems. By this approach we visualized the two DNA target sequences in metaphase chromosomes and in interphase nuclei with FITC and TRITC fluorescence, or blue (alkaline phosphatase) and brown (peroxidase) precipitated enzyme products. This method not only allows detection of intact chromosomes but also the visualization of rearrangements between parts of human and mouse chromosomes. Furthermore, the technique demonstrates the high topological resolution of nonradioactive in situ hybridizations.This investigation was supported in part by FUNGO, Foundation of Medical Scientific Research in The Netherlands (grant nr 13-54-21)     

Analysis of repetitive DNA in chromosomes by flow cytometry

We developed a flow cytometry method, chromosome flow fluorescence in situ hybridization (FISH), called CFF, to analyze repetitive DNA in chromosomes using FISH with directly labeled peptide nucleic acid (PNA) probes. We used CFF to measure the abundance of interstitial telomeric sequences in Chinese hamster chromosomes and major satellite sequences in mouse chromosomes. Using CFF we also identified parental homologs of human chromosome 18 with different amounts of repetitive DNA.     

Detection of chromosome aberrations in the human interphase nucleus by visualization of specific target DNAs with radioactive and non-radioactive in situ hybridization techniques: diagnosis of trisomy 18 with probe L1.84

Summary The localization of chromosome 18 in human interphase nuclei is demonstrated by use of radioactive and nonradioactive in situ hybridization techniques with a DNA clone designated L1.84. This clone represents a distinct subpopulation of the repetitive human alphoid DNA family, located in the centric region of chromosome 18. Under stringent hybridization conditions hybridization of L1.84 is restricted to chromosome 18 and reflects the number of these chromosomes present in the nuclei, namely, two in normal diploid human cells and three in nuclei from cells with trisomy 18. Under conditions of low stringency, cross-hybridization with other subpopulations of the alphoid DNA family occurs in the centromeric regions of the whole chromosome complement, and numerous hybridization sites are detected over interphase nuclei. Detection of chromosome-specific target DNAs by non-radioactive in situ hybridization with appropriate DNA probes cloned from individual chromosomal subregions presents a rapid means of identifying directly numerical or even structural chromosome aberrations in the interphase nucleus. Present limitations and future applications of interphase cytogenetics are discussed.     

Triplex-forming DNAs in the human interphase nucleus visualized in situ by polypurine/polypyrimidine DNA probes and antitriplex antibodies

The polypurine/polypyrimidine (PuPy) tracts present in the human genome are known to be scattered among and within chromosomes. In PuPy tract sequences, triplex formation occurs readily under physiological conditions, leaving single-stranded DNAs capable of hybridization with complementary single-stranded DNAs and RNAs. The formation of single-strands and transmolecular triplexes is thought to enable sequences spaced distantly along the genome to associate with each other and organize nuclear DNA into ordered configurations. Triplex-forming DNAs in the human interphase nucleus were analyzed by combining fluorescence in situ "nondenaturing" hybridization employing PuPy tract probes and immunodetection by antitriplex antibodies. The nondenaturing hybridization technique, which has been used to detect RNA, may detect single-stranded DNAs in nondenatured nuclei, if present. Probes such as (GA/TC)(n) and (GAA/TTC)(n) sequences gave sequence-specific signals that overlapped with or were closely associated with triplexes immunolocalized by using known antitriplex antibodies. Pretreatment of nuclei with antitriplex antibodies blocked probe signal formation. Signal formation was resistant to pretreatment of nuclei with RNases but sensitive to single strand-specific nucleases. Triplexes visualized differentially with distinct PuPy tract probes were associated spatially with centromeric sequences in the interphase nucleus in a sequence-specific manner.     

Parental genomes mix in mule and human cell nuclei

Whether chromosome sets inherited from father and mother occupy separate spaces in the cell nucleus is a question first asked over 110 years ago. Recently, the nuclear organization of the genome has come increasingly into focus as an important level of epigenetic regulation. In this context, it is indispensable to know whether or not parental genomes are spatially separated. Genome separation had been demonstrated for plant hybrids and for the early mammalian embryo. Conclusive studies for somatic mammalian cell nuclei are lacking because homologous chromosomes from the two parents cannot be distinguished within a species. We circumvented this problem by investigating the three-dimensional distribution of chromosomes in mule lymphocytes and fibroblasts. Genomic DNA of horse and donkey was used as probes in fluorescence in situ hybridization under conditions where only tandem repetitive sequences were detected. We thus could determine the distribution of maternal and paternal chromosome sets in structurally preserved interphase nuclei for the first time. In addition, we investigated the distribution of several pairs of chromosomes in human bilobed granulocytes. Qualitative and quantitative image evaluation did not reveal any evidence for the separation of parental genomes. On the contrary, we observed mixing of maternal and paternal chromosome sets.     

Size-dependent positioning of human chromosomes in interphase nuclei

By using a fluorescence in situ hybridization technique we revealed that for nine different q-arm telomere markers the positioning of chromosomes in human G(1) interphase nuclei was chromosome size-dependent. The q-arm telomeres of large chromosomes are more peripherally located than telomeres on small chromosomes. This highly organized arrangement of chromatin within the human nucleus was discovered by determining the x and y coordinates of the hybridization sites and calculating the root-mean-square radial distance to the nuclear centers in human fibroblasts. We demonstrate here that global organization within the G(1) interphase nucleus is affected by one of the most fundamental physical quantities-chromosome size or mass-and propose two biophysical models, a volume exclusion model and a mitotic preset model, to explain our finding.     

Delineation of individual human chromosomes in metaphase and interphase cells by in situ suppression hybridization using recombinant DNA libraries

Summary A method of in situ hybridization for visualizing individual human chromosomes from pter to qter, both in metaphase spreads and interphase nuclei, is reported. DNA inserts from a single chromosomal library are labeled with biotin and partially preannealed with a titrated amount of total human genomic DNA prior to hybridization with cellular or chromosomal preparations. The cross-hybridization of repetitive sequences to nontargeted chromosomes can be markedly suppressed under appropriate preannealing conditions. The remaining single-stranded DNA is hybridized to specimens of interest and detected with fluorescent or enzymelabeled avidin conjugates following post-hybridization washes. DNA inserts from recombinant libraries for chromosomes 1, 4, 7, 8, 13, 14, 18, 20, 21, 22, and X were assessed for their ability to decorate specifically their cognate chromosome; most libraries proved to be highly specific. Quantitative densitometric analyses indicated that the ratio of specific to nonspecific hybridization signal under optimal preannealing conditions was at least 8:1. Interphase nuclei showed a cohesive territorial organization of chromosomal domains, and laserscanning confocal fluorescence microscopy was used to aid the 3-D visualization of these domains. This method should be useful for both karyotypic studies and for the analysis of chromosome topography in interphase cells.     

Mercurated nucleic acid probes, a new principle for non-radioactive in situ hybridization

This report describes the localization of specific nucleic acid sequences in interphase nuclei and metaphase chromosomes by a new hybridocytochemical method based on the use of mercurated nucleic acid probes. After the hybridization a sulfhydryl-hapten compound is reacted with the hybrids formed. A number of such ligands were synthesized and tested. A fluorescyl ligand could be used for the direct visualization of highly repetitive sequences. For indirect immunocytochemical visualization trinitrophenyl ligands were found to be more sensitive than biotinyl analogues. These ligands were applied for the detection of target sequences in metaphase chromosomes and interphase nuclei of somatic cell hybrids, human lymphoid cell lines and blood cell cultures. The sequences were in the range of high to low copy numbers. The lower limit of sensitivity is indicated by the visualization of two human unique DNA fragments (40 and 15.6 kb) in human metaphases. The method is rapid, gives consistent results and can be used for both RNA and DNA probes. Other potentials of the new principle are discussed.     

A degenerate alpha satellite probe, detecting a centromeric deletion on chromosome 21 in an apparently normal human male, shows limitations of the use of satellite DNA probes for interphase ploidy analysis.

A degenerate alpha satellite DNA probe specific for a repeated sequence on human chromosomes 13 and 21 was synthesized using the polymerase chain reaction (PCR). Fluorescence in situ hybridization (FISH) with this probe to normal metaphase spreads revealed strong probe binding to the centromeric regions of human chromosomes 13 and 21 with negligible cross-hybridization with other chromosomes. FISH to normal interphase cell nuclei showed four distinct domains of probe binding. However, hybridization with probe to interphase and metaphase preparations from one apparently normal human male resulted in only three major binding domains. Metaphase chromosome analysis revealed a centromeric deletion on one chromosome 21 that caused greatly reduced probe binding. The result suggest caution in the interpretation of interphase ploidy studies performed with chromosome-specific alphoid DNA probes.     

Quantitative microscopy after fluorescence in situ hybridization - a comparison between repeat-depleted and non-depleted DNA probes

Complex probes used in fluorescence in situ hybridization (FISH) usually contain repetitive DNA sequences. For chromosome painting, in situ suppression of these repetitive DNA sequences has been well established. Standard painting protocols require large amounts of an unlabeled 'blocking agent', for instance Cot-1 DNA. Recently, it has become possible to remove repetitive DNA sequences from library probes by means of magnetic purification and affinity PCR. Such a 'repeat depleted library probe' was hybridized to the q-arm of chromosome 15 of human metaphase spreads and interphase cell nuclei without any preannealing by Cot-1 DNA. Apart from this, 'standard' FISH conditions were used. After in situ hybridization, microscope images were obtained comparable to those achieved with the #15q library probe prior to depletion. The images were recorded by a true color CCD camera. By digital image analysis using 'line scan' and 'area scan' procedures, the painting efficiency expressed in terms of relative fluorescence signal intensity was quantitatively evaluated. The painting efficiency using the repeat depleted probe of chromosome 15q was compared to the painting efficiency after standard FISH. The results indicate that both types of probes are compatible to a high FISH efficiency. Using equivalent probe concentrations, no significant differences were found for FISH with standard painting probes and repeat depleted painting probes.     

Methods of molecular cytogenetics for studying interphase chromosomes in human brain cells

One of the main genetic factors determining the functional activity of the genome in somatic cells, including brain nerve cells, is the spatial organization of chromosomes in the interphase nucleus. For a long time, no studies of human brain cells were carried out until high-resolution methods of molecular cytogenetics were developed to analyze interphase chromosomes in nondividing somatic cells. The purpose of the present work was to assess the potential of high-resolution methods of interphase molecular cytogenetics for studying chromosomes and the nuclear organization in postmitotic brain cells. A high efficiency was shown by such methods as multiprobe and quantitative fluorescence in situ hybridization (Multiprobe FISH and QFISH), ImmunoMFISH (analysis of the chromosome organization in different types of brain cells), and interphase chromosome-specific multicolor banding (ICS-MCB). These approaches allowed studying the nuclear organization depending on the gene composition and types of repetitive DNA of specific chromosome regions in certain types of brain cells (in neurons and glial cells, in particular). The present work demonstrates a high potential of interphase molecular cytogenetics for studying the structural and functional organizations of the cell nucleus in highly differentiated nerve cells. Analysis of interphase chromosomes of brain cells in the normal and pathological states can be considered as a promising line of research in modern molecular cytogenetics and cell neurobiology, i. e., molecular neurocytogenetics.     

Spatial topography of a pericentromeric region (1q12) in hemopoietic cells studied by in situ hybridization and confocal microscopy

A fluorescent in situ hybridization procedure with a chromosome 1-specific (1q12) repetitive satellite DNA probe was used to label the 1q12 regions of the chromosomes 1 in spherical and polymorphic hemopoietic cell nuclei. The entire procedure was performed in suspension to preserve nuclear morphology. The result was studied by three-dimensional analysis, as provided by a scanning laser confocal microscope. The 1q12 regions of chromosome 1 were measured to be closely associated with the nuclear envelope in isolated nuclei of unstimulated diploid human lymphocytes. The relative positions to each other in the periphery of these spherical nuclei could not be distinguished from a random distribution pattern. In the diploid and tetraploid polymorphic nuclei of cells of the promyelocytic leukemia cell line HL60 these pericentromeric sequences were also associated with the nuclear surface.     

Moth sex chromatin probed by comparative genomic hybridization (CGH).

Abstract: Comparative genomic hybridization (CGH) with a probe mixture of differently labeled genomic DNA from females and males highlighted the W chromosomes in mitotic plates and the W chromatin in polyploid interphase nuclei of the silkworm Bombyx mori, the flour moth Ephestia kuehniella, and the wax moth Galleria mellonella. The overproportionate fluorescence signal indicated an accumulation of repetitive sequences in the respective W chromosomes. Measurements of the fluorescence signals revealed two components, one that is present also in male DNA (non-W chromosomes) and another one that is present only in or preponderantly in female DNA (W chromosomes). While the W chromosomes of E. kuehniella and G. mellonella had both components, that of B. mori appeared to lack the latter component. Our results show that CGH can be applied to obtain a first estimate of the sequence composition of sex chromosomes in species from which otherwise little is known on the molecular level.     

Fluorescence intensity profiles of in situ hybridization signals depict genome architecture within human interphase nuclei

An approach towards construction of two-dimensional (2D) and three-dimensional (3D) profiles of interphase chromatin architecture by quantification of fluorescence in situ hybridization (FISH) signal intensity is proposed. The technique was applied for analysis of signal intensity and distribution within interphase nuclei of somatic cells in different human tissues. Whole genomic DNA, fraction of repeated DNA sequences (Cot 1) and cloned satellite DNA were used as probes for FISH. The 2D and 3D fluorescence intensity profiles were able to depict FISH signal associations and somatic chromosome pairing. Furthermore, it allowed the detection of replicating signal patterns, the assessment of hybridization efficiency, and comparative analysis of DNA content variation of specific heterochromatic chromosomal regions. The 3D fluorescence intensity profiles allowed the analysis of intensity gradient within the signal volume. An approach was found applicable for determination of assembly of different types of DNA sequences, including classical satellite and alphoid DNA, gene-rich (G-negative bands) and gene-poor (G-positive bands) chromosomal regions as well as for assessment of chromatin architecture and targeted DNA sequence distribution within interphase nuclei. We conclude the approach to be a powerful additional tool for analysis of interphase genome architecture and chromosome behavior in the nucleus of human somatic cells. The text was submitted by the authors in English.     

Molecular cytogenetic methods for studying interphase chromosomes in human brain cells

One of the main genetic factors determining the functional activity of the genome in somatic cells, including brain nerve cells, is the spatial organization of chromosomes in the interphase nucleus. For a long time, no studies of human brain cells were carried out until high-resolution methods of molecular cytogenetics were developed to analyze interphase chromosomes in nondividing somatic cells. The purpose of the present work was to assess the potential of high-resolution methods of interphase molecular cytogenetics for studying chromosomes and the nuclear organization in postmitotic brain cells. A high efficiency was shown by such methods as multiprobe and quantitative fluorescence in situ hybridization (Multiprobe FISH and QFISH), ImmunoMFISH (analysis of the chromosome organization in different types of brain cells), and interphase chromosome-specific multicolor banding (ICS-MCB). These approaches allowed studying the nuclear organization depending on the gene composition and types of repetitive DNA of specific chromosome regions in certain types of brain cells (in neurons and glial cells, in particular). The present work demonstrates a high potential of interphase molecular cytogenetics for studying the structural and functional organizations of the cell nucleus in highly differentiated nerve cells. Analysis of interphase chromosomes of brain cells in the normal and pathological states can be considered as a promising line of research in modern molecular cytogenetics and cell neurobiology, i. e., molecular neurocytogenetics.     

Preliminary karyotype and chromosomal localization of ribosomal DNA sites in white spruce using fluorescence in situ hybridization.

We have localized the major ribosomal DNA (rDNA) loci on metaphase chromosomes and in interphase nuclei of white spruce (2n = 24) by fluorescence in situ hybridization. Hybridization sites of the biotin-labelled rDNA probe were detected using antibody-fluorochrome conjugates and a confocal laser scanning microscope. White spruce has at least 12, and possibly as many as 14, rDNA sites, 1 site present on each of seven separate chromosome pairs. This is one of the highest numbers of rDNA loci yet reported among plant species. The position of the rDNA loci together with secondary constriction patterns permit, for the first time, all homologous pairs of white spruce chromosomes to be distinguished. We discuss the application of molecular cytogenetics in studies relating to the organization and evolution of DNA sequences within conifer genomes.     

A novel source of highly specific chromosome painting probes for human karyotype analysis derived from primate homologues

We have established a series of highly specific painting probes for human acrocentric chromosomes. These chromosomes are involved in the formation of the nucleolar organizer region (NOR) and show DNA sequence homologies within their pericentric heterochromatin. To date, these chromosomes have shown considerable cross hybridization in chromosome painting experiments. Our probe set has been established from primate homologues that are not involved in the NOR in that particular species or from species in which highly repetitive sequences have undergone rapid sequence divergence. The new painting probes should be of particular value for automated microscopy, for which highly specific signals are required as they are recorded at low magnification, e.g. when scoring chromosome 21 domains in interphase nuclei. Received: 22 May 1997 / Accepted: 16 June 1997