Ordering markers in the region of the ataxia-telangiectasia gene (11q22-q23) by fluorescence in situ hybridization (FISH) to interphase nuclei

Fluorescence in situ hybridization (FISH) to interphase nuclei was performed to order probes corresponding to bands 11q22-q23 where the ataxia-telangiectasia (AT) gene(s) have been located. Cosmid probes and one phage probe previously localized to this chromosome 11 region by FISH to metaphase chromosomes, were hybridized to interphase nuclei of the somatic cell hybrid J1a, which contains chromosome 11 as the only human chromosome. Two-color FISH was used with a centromeric reference probe marker. The following order was obtained: cen-D11S385 (CJ52.75)-CJ52.3-D11S384 (CJ52.193) CJ52.114-D11S424 (CJ52.77)-D11S132-NCAM-D11S351 (CJ52.208)-tel. The validity of using the centromeric probe was illustrated by showing that a probe corresponding to 11p13 hybridized more closely to the centromere than a probe corresponding to 11q22-q23, and by using cosmids hybridized three by three.     

Localization of a mouse centromeric DNA repeat in interphase nuclei

The position of a mouse DNA repeat located near the centromere of mouse chromosomes X, 11, 13, and 17 was examined in interphase nuclei of bone marrow and fibroblast cells by in situ hybridization of 3H- or biotin-labeled DNA probe 70-38. In most laboratory mouse strains this probe recognizes a single repeat cluster (DXWas70) close to the centromere of the mouse X chromosome. In a few mouse strains, a second locus (D11Was70, D13Was70, or D17Was70, depending on the mouse strain) is located near the centromere of an autosome. In interphase nuclei from mouse strains with the X-linked locus only, two distinct sites of hybridization were found in female mice and one in male mice. These two sites remained separated during the different phases of the cell cycle (G1, early S, late S, and G2) as demonstrated by in situ hybridization of the probe to flow-sorted nuclei. In interphase nuclei from mouse strains with both the X-linked locus and an autosomal locus, four distinct sites of hybridization were found in female mice and three in male mice. Further analysis of loci DXWas70 and D17Was70 showed that these loci were often located in the outer region of nuclei from bone marrow and fibroblast cells.     

Sexing the human fetus and identification of polyploid nuclei by DNA-DNA in situ hybridisation in interphase nuclei

Samples of human adult lymphocytes, fetal lymphocytes, amniotic fluid cells, and chorionic villus cells were sexed independently by cytogenetics and DNA-DNA in situ hybridisation to a tritiated Y probe. For the in situ hybridisation analysis, the presence of Y bodies (hybridisation bodies) in 100 interphase nuclei were scored after autoradiography. In all, 82/83 samples were sexed in this way (one technical failure) and 78/82 were sexed by both in situ hybridisation and cytogenetics. There was complete agreement between the two methods. There was a considerable variation (40-100%) in the percentage of interphase nuclei with a hybridisation body among the male samples, but very few nuclei from female samples showed significant hybridisation. In situ hybridisation could be used to sex the conceptus when males but not females are at risk for various X-linked genetic disorders and may also be useful for detecting 45,X/46,XY mosaicism or polyploid/diploid mosaicism. This would be particularly useful for direct preparations of chorionic villus samples, which often prove difficult to analyse cytogenetically but offer the best means of avoiding maternal contamination. Some interphase nuclei had more than one hybridisation body, and this was most commonly found among amniotic fluid cells. Comparison of sizes of nuclei with one or two hybridisation bodies strongly suggested that most of the amniotic fluid cell nuclei with two hybridisation bodies were tetraploid.     

Detection of retinoblastoma gene copy number in metaphase chromosomes and interphase nuclei by fluorescence in situ hybridization.

Fluorescence in situ hybridization (FISH) was applied to detect the copy number of the retinoblastoma (RB1) tumor suppressor gene in metaphase chromosomes and interphase nuclei. We used 14 lambda phage clones spanning the whole RB1 gene region as a probe and obtained a specific hybridization signal in normal metaphase chromosomes at 13q14. Normal interphase nuclei showed two RB1 signals in about 90% of cases, whereas two cell lines with cytogenetically defined deletions involving the RB1 gene showed only one hybridization signal in about 80% of the nuclei. Analogous changes were detected in metaphase chromosomes. Multicolor FISH with subsets of the phage clones allowed visualization of subregions within the 200-kb gene in interphase nuclei. Analysis of clinical breast cancer samples showed that most of the cells contained two copies of the RB1 gene, even when restriction fragment length polymorphism analysis showed loss of heterozygosity (LOH) at the RB1 locus. This indicates that LOH at the RB1 locus in breast cancer cells probably involves mechanisms other than physical deletion.     

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)     

Aneuploidy detection in human sperm nuclei using fluorescence in situ hybridization

Fluorescence in situ hybridization (FISH) was performed on human interphase sperm nuclei to determine the utility of this technique for aneuploidy detection. Repetitive DNA sequences specific for chromosomes 1, 12 and X were biotinylated and hybridized with mature sperm, which had been treated with cetyltrimethylammonium bromide and dithiothreitol to render them accessible to the probes. Detection of bound probe was accomplished with fluoresceinated avidin and antiavidin. For each of the chromosomes studied, chromosome number was determined by counting the fluorescent signals, representing hybridized regions, within the sperm nuclei. The frequencies for disomy, that is for nuclei containing two signals, for chromosomes 1, 12 and X were 0.06%, 0.04% and 0.03%, respectively. The congruence of these results with those determined by the cross-species hamster oocyte-human sperm assay, and the high efficiency of hybridization indicate that FISH is a sensitive and reliable tool for aneuploidy detection in human sperm.     

Application of IGF2-specific identifier probe for cytogenetic study of somatic and sperm cells in horses

The development of molecular techniques with fluorochromes has had an invaluable impact on discovering the nature of chromatin structure. Here, we show the application of a locus specific identifier probe (LSI) for precise and selective visualization of the horse IGF2 gene in the metaphase, interphase nuclei and sperm cells. Our study may be helpful for interpretation of results of interphase fluorescence in situ hybridization (I-FISH). We analyze and discuss the variation in the number and localization of FISH signals in somatic and sperm cells of horse.     

Reliability and efficiency of interphase-fish with alpha-satellite probe for detection of aneuploidy

Early diagnosis is very important in pre- and postnatal diagnosis of Down syndrome. This study examines the use of fluorescence in situ hybridization (FISH) to detect trisomy 21 in interphase nuclei and metaphase chromosome obtained from fifty-four Down syndrome patients with a regular type trisomy 21. Three of them showed six hybridization signals on both interphase nuclei and metaphase spreads instead of five signals corresponding to two chromosomes 13 and three chromosomes 21 although they were cytogenetically trisomy 21. Simultaneous application of probe combination revealed that one of the extra signals of chromosomes 13/21 a-satellite probe was located on chromosome 22 in two cases and one extra signal on chromosomes 15 in one case. In addition, another case showed four hybridization signals on both interphase nuclei and metaphase spreads instead of five signals, indicating deletion of the chromosome specific alpha-satellite DNA sequence of chromosome 13/21. These centromeric sequence changes may have pathological significance in the appearance of aneuploidy because they may be involved in the important centromere function.     

Delineation of DNA replication time zones by fluorescence in situ hybridization.

Fluorescence in situ hybridization has been used to visualize specific genomic DNA sequences in interphase nuclei. In normal diploid cells, unreplicated DNA segments give singlet hybridization signals while replicated loci are characterized by doublets. The distribution of these two patterns in unsynchronized cell populations can be used to determine the S phase replication time of any DNA sequence. The validity of this approach was established by analyzing genes whose replication profiles in expressing and non-expressing cells had been determined previously by conventional methods. Using this technique it has been possible to map the replication timing topography of the DNA within and flanking the cystic fibrosis (CF) gene locus on chromosome 7. The gene itself is located within a defined time zone which is approximately 500 kb in length and is under developmental control. It is early replicating in cells which express CF but late replicating in other cell types. These time zones probably represent basic units of chromosome structure.     

Interphase cytogenetics on paraffin-embedded sections of ovary for detection of genomic constitution in a patient with Turner's syndrome and chromosomal mosaicism

The difficulty of detecting sex chromosome mosaicism cytogenetically hinders the finding of an acceptable explanation for phenotypic-genotypic discrepancy amongst those patients. Fluorescence in situ hybridization (FISH) permits the genomic identification of patients with mosaic karyotypes in interphase nuclei by utilising an X chromosome-specific DNA probe (interphase cytogenetics). We evaluated the efficiency of interphase cytogenetics in the detection of the genomic constitution of the ovary from a patient with Turner's syndrome having mosaicism (46,XX/45,X0) previously established by blood lymphocyte karyotyping. We used a biotin-labelled alphoid repetitive sequence, pBAMX5, specific for the centromeric region of the human X chromosome. Although examination of ovarian sections and blood lymphocytes by FISH showed the presence of both 46,XX and 45,X0 cell lines, the genomic constitution of the germ cells/oocytes in ovarian primordial follicles was shown to be normal (46,XX). Our results (1) show the high applicability of interphase cytogenetics on paraffin sections, (2) indicate the possibility of genomic screening of different tissues that are otherwise not amenable to routine cytogenetic investigation and (3) offer a reliable methodological approach to defining accurate by the percentage of abnormal karyotypes in mosaicism of different organs and non-dividing tissues.     

Rapid prenatal diagnosis of chromosomal aneuploidies by fluorescence in situ hybridization: clinical experience with 4,500 specimens.

Detection of chromosome aneuploidies in uncultured amniocytes is possible using fluorescence in situ hybridization (FISH). We herein describe the results of the first clinical program which utilized FISH for the rapid detection of chromosome aneuploidies in uncultured amniocytes. FISH was performed on physician request, as an adjunct to cytogenetics in 4,500 patients. Region-specific DNA probes to chromosomes 13, 18, 21, X, and Y were used to determine ploidy by analysis of signal number in hybridized nuclei. A sample was considered to be euploid when all autosomal probes generated two hybridization signals and when a normal sex chromosome pattern was observed in greater than or equal to 80% of hybridized nuclei. A sample was considered to be aneuploid when greater than or equal to 70% of hybridized nuclei displayed the same abnormal hybridization pattern for a specific probe. Of the attempted analyses, 90.2% met these criteria and were reported as informative to referring physicians within 2 d of receipt. Based on these reporting parameters, the overall detection rate for aneuploidies was 73.3% (107/146), with an accuracy of informative results for aneuploidies of 93.9% (107/114). Compared to cytogenetics, the accuracy of all informative FISH results, euploid and aneuploid, was 99.8%, and the specificity was 99.9%. In those pregnancies where fetal abnormalities had been observed by ultrasound, referring physicians requested FISH plus cytogenetics at a significantly higher rate than they requested cytogenetics alone. The current prenatal FISH protocol is not designed to detect all chromosome abnormalities and should only be utilized as an adjunctive test to cytogenetics. This experience demonstrates that FISH can provide a rapid and accurate clinical method for prenatal identification of chromosome aneuploidies.     

Identification of Alien Chromatin and Ribosomal DNA in Wheat by in Situ Hybridization

In situ hybridization was carried out to somatic cells of hexaploid Triticale “Badger”, lB/IR translocation line “Ning 8026” and IR(ID) substitution line “84056-1-36-1” using biotin-labelled total rye genomic DNA and wheat rDNA as probes, the results were as follows: 1. The probe containing the total genomic DNA from rye hybridized to the entire length of all rye chromosomes, as a result of the formation of a brown precipitate over the sites of hybridization, the rye chromosomes could be distinguished from wheat chromosomes counterstained by Wright’s solution, the distinguishable appearance of the wheat and rye chromosomes resulted in an efficient method of detecting rye chromosome or segments in wheat. 2. When the probe PTA 71 containing wheat ribosomal DNA was used to hybridize to somatic chromosomes of "Badger" and “84056-1-36-1”, six signals in “Badger” and eight in “84056-1-36-1” were observed on lB, 6B, 1R and SD, among which lB and 6B showed large in situ signals corresponding to many copies of the genes. 3. The expression behavior of wheat rDNA was found in interphase cells by in situ hybridization.     

Toward a multicolor chromosome bar code for the entire human karyotype by fluorescence in situ hybridization

A colored banding pattern for human chromosomes is described that distinguishes each chromosome in a single fluorescence in situ hybridization with a set of subregional DNA probes. Alu/polymerase chain reaction products of various human/rodent somatic cell hybrids (fragment hybrids) were pooled into two probe sets that were labeled differentially and detected by red and green fluorescence. Chromosome regions hybridized by DNA present in both pools appeared yellow. The result was a multi-color set of 110 distinct signals per haploid chromosome set for the human karyotype. Each individual chromosome showed a unique sequence of signals, a result termed the “chromosome bar code”. The reproducibility of the hybridization pattern in various labeling and hybridization experiments was analyzed by computer densitometry. We have applied the chromosome bar code both in diagnostic cytogenetics and in genome studies. The approach allows the rapid identification of chromosomes and chromosome rearrangements. Although not yet showing the resolution of classical banding patterns, the present experiments demonstrate various applications in which the present multi-color bar code can significantly add to the spectrum of cytogenetic techniques. Received: 18 December 1996 / Accepted: 10 February 1997     

Localization of tandemly repeated DMA sequences in Arabidopsis thaliana

In-situ hybridization to interphase nuclei and chromosomes of Arabidopsis thaliana (2n= 10) shows that there are four sites of rDNA in a diploid nucleus. The sites are located on chromosomes 2 and 4, and the strength of hybridization indicates that copy number is similar at both pairs of sites. Hybridization to trisomic line 4 revealed five hybridization sites. Silver staining of nucleoli demonstrates that all four loci can be active in diploid interphase nuclei. The tandemly repeated probe pAL1 hybridizes near to the centromeres of all five chromosome pairs. In diploid interphase nuclei, 10 sites of hybridization are detected, while 15 are seen in triploid nuclei. The sites of hybridization co-localize with the centromeric heterochromatin visualized by staining DNA with the fluorochrome DAPI. The results demonstrate that molecular cytogenetics can be applied to A. thaliana and high resolution physical chromosome maps can be generated. Both probes may be useful for interphase cytogenetics, where they enable chromosome number and aneuploidy to be examined in tissues without divisions. The physical localization of these hybridization sites provides a starting point for linking RFLP and physical chromosome maps.     

The DNA-based structure of human chromosome 5 in interphase

In contrast to those of metaphase chromosomes, the shape, length, and architecture of human interphase chromosomes are not well understood. This is mainly due to technical problems in the visualization of interphase chromosomes in total and of their substructures. We analyzed the structure of chromosomes in interphase nuclei through use of high-resolution multicolor banding (MCB), which paints the total shape of chromosomes and creates a DNA-mediated, chromosome-region-specific, pseudocolored banding pattern at high resolution. A microdissection-derived human chromosome 5-specific MCB probe mixture was hybridized to human lymphocyte interphase nuclei harvested for routine chromosome analysis, as well as to interphase nuclei from HeLa cells arrested at different phases of the cell cycle. The length of the axis of interphase chromosome 5 was determined, and the shape and MCB pattern were compared with those of metaphase chromosomes. We show that, in lymphocytes, the length of the axis of interphase chromosome 5 is comparable to that of a metaphase chromosome at 600-band resolution. Consequently, the concept of chromosome condensation during mitosis has to be reassessed. In addition, chromosome 5 in interphase is not as straight as metaphase chromosomes, being bent and/or folded. The shape and banding pattern of interphase chromosome 5 of lymphocytes and HeLa cells are similar to those of the corresponding metaphase chromosomes at all stages of the cell cycle. The MCB pattern also allows the detection and characterization of chromosome aberrations. This may be of fundamental importance in establishing chromosome analyses in nondividing cells.     

Comparison of metaphase and interphase FISH monitoring of minimal residual disease with MLL gene probe: case study of AML with t(9;11).

The place of FISH in the monitoring of minimal residual disease (MRD) is yet to be fully characterised. Routine bone marrow cytogenetics at diagnosis in a 22 year old patient with acute myeloid leukemia FAB type M5 detected a translocation t(9;11)(p22;q23). We report our investigations to assess residual levels of translocation using a FISH probe designed to detect a gene split by the translocation. We used MLL (Oncor), a probe which spans the MLL gene at 11q23, in both metaphase and interphase preparations. At diagnosis, metaphase FISH showed 3 distinct cell lines-normal with 2 signals, abnormal with 3 signals and abnormal with 2 signals, while interphase FISH showed only 2 cell lines, one with 2 signals (which could be normal or abnormal) and one with 3 signals (split MLL). Following treatment, with the patient in clinical remission, 7 further cytogenetic analyses and 2 further FISH analyses were compared. Our results suggest that monitoring of the t(9;11) by metaphase FISH is feasible and straightforward compared to cytogenetics but interphase FISH may be problematic.     

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.     

Disproportionate numbers of rDNA loci in diploid and polyploid testis nuclei of gerris najas detected by fluorescence in situ hybridization

The replication state of rDNA in testes nuclei undergoing polyploidization by classical-type endomitosis was investigated in Gerris najas (Heteroptera) by means of fluorescence in situ hybridization. The number of just one rDNA locus per haploid genome was determined by in situ hybridization on meiotic nuclei. Additionally, DNA measurements of spermatids and testes nuclei were performed. Although regular duplication levels of nuclear DNA were found within the limits of the accuracy of the method, these did evidently not apply to the ribosomal genes. The comparison of the number of rDNA signals with the DNA content of 106 testis nuclei revealed drastic variations of the number of rDNA loci between individual nuclei with similar DNA content. Polyploid nuclei of the testis epithelium showed too low numbers of rDNA loci in relation to those expected from the levels of ploidy, while cyst cell nuclei displayed increased numbers of rDNA loci. The results indicate that the ribosomal genes are either underreplicated, or in part eliminated, during the endomitotic cycles of epithelium cell nuclei, but amplified in the cyst cell nuclei, probably already at their diploid stage.