Human and porcine correspondence of chromosome segments using bidirectional chromosome painting

The aim of this study was to determine the correspondence between human and porcine chromosome fragments using whole chromosome painting probes from both species in heterologous hybridization experiments (bidirectional heterologous chromosome painting). Bidirectional experiments allow the determination of segment-to-segment homologies between the chromosomes of these two species. Chromosome-specific painting probes from both species were, except one, obtained by DOP-PCR or PARM-PCR amplification of flow-sorted chromosomes. The probes labeled 95% of the total length of the porcine chromosomes with human painting probes and 60% of the human chromosomes in the reverse experiments. Syntenic relationships of chromosomal segments on the karyotype of both species were determined. There was close agreement between com- parative gene mapping data and the identified homologous segments; this comparison enabled orientation of the segments. We demonstrate that bidirectional heterologous chromosome painting is a highly efficient way of generating comparative cytogenetic maps.     

ZOO-FISH and R-banding reveal extensive conservation of human chromosome regions in euchromatic regions of river buffalo chromosomes

Commercially available human chromosome (HSA) painting probes were hybridized on river buffalo (Bubalus bubalis, 2n = 50) chromosomes by using FISH and R-banding techniques. Clear hybridization FITC-signals revealed extensive conservation of human chromosome regions in this species and demonstrated that human chromosome probes primarily paint euchromatic regions (R-bands). The present results are discussed in the light of previous gene mapping data obtained in river buffalo and ZOO-FISH data in cattle, and in relation to the standard bovine chromosome nomenclatures. In particular, HSA 8, HSA 10, HSA 11, and HSA 16+7 paint, respectively, BBU 1p, BBU 4p, BBU 5p, and BBU 24, which are homoeologous, respectively, to cattle chromosomes 25, 28, 29 and 27. Thus, these river buffalo chromosome arms can serve as markers to resolve discrepancies in the nomenclature of cattle and related species.     

Reciprocal chromosome painting between human and prosimians (Eulemur macaco macaco and E. fulvus mayottensis)

We used fluorescence in situ hybridisation to delineate the homology between the human karyotype and those of two lemur species (Eulemur macaco macaco and E. fulvus mayottensis). Human and lemur chromosome-specific probes were established by bivariate fluorescence-activated flow sorting (FACS) and subsequent degenerate oligonucleotide-primed PCR (DOP-PCR). Reciprocal painting of human probes to lemur chromosomes and vice versa allowed a detailed analysis of the interchromosomal rearrangements that had occurred during the evolution of these species. The results indicate that the genomes of both species have undergone only a few translocations during more that 45 million years of lemur and human evolution. The synteny of homologs to human chromosomes 3, 9, 11, 13, 14, 17, 18, 20, 21, X, and Y was found to be conserved in the two lemur species. Taking non-primate mammals as the outgroup for primates, ancestral conditions for various primate chromosomes were identified and distinguished from derived forms. Lemur chromosome painting probes were also used for cross-species hybridization between the two lemur species. The results support an earlier assumption, made on the basis of chromosome banding, that the karyotypes of the two species have evolved exclusively by Robertsonian transformations. All probes derived from E. f. mayottensis chromosomes specific for homologs involved in rearrangements in E. m. macaco exclusively painted entire chromosome arms. The results further indicate that E. f. mayottensis most probably has a more ancestral karyotype than E. m. macaco. Probes derived from prosimians will be useful in comparing the karyotypes of other lower primates, which will improve our understanding of early primate genome evolution.     

Comparative analysis of Y chromosome structure in Bos taurus and B. indicus by FISH using region-specific, microdissected, and locus-specific DNA probes

Results of fluorescence in situ hybridization (FISH) of Bos taurus and B. indicus Y chromosomes using the bovine locus-specific Y probes BC1.2 and lambda ES6.0 and region-specific probes of B. indicus and B. taurus Y chromosomes, which were generated by microdissection and DOP-PCR, indicate that the Y chromosomes of B. indicus (BIN Y) and B. taurus (BTA Y) differ by a pericentric inversion. Parts of the short and long arms of the Y chromosome in B. taurus and the distal half of the Y chromosome in B. indicus were microdissected, amplified by DOP-PCR, biotinylated, and rehybridized in situ to the corresponding metaphase chromosomes to test the chromosome fragment specificity of the DNA probes. The region-specific painting probes were used for hybridization to metaphase chromosomes of the other species. The DNA painting probes BTA Yp12 and BTA Yq12.1-ter derived from BTA Y hybridized to the distal and proximal halves of BIN Y, respectively. Complex hybridization signals on BTA Yq12.1-->qter were generated with the DNA probe BIN Yqcen-centr (centromere-central) after FISH. The results demonstrate that BTA Yp is homologous to the distal half of BIN Y and that BTA Yq corresponds to the proximal part of BIN Yq. Hybridization of the Y chromosome-specific DNA probes lambda ES6.0 to BTA Yp12-->p11 and near to the telomere of BIN Y and BC1.2 to BTA Yq12-->q13 and to the telomere of BIN Y indicate an opposite orientation of the homologous chromosome fragments BTA Yp and of the distal half of BIN Yq.     

Chromosomal rearrangements detected by FISH and G-banding

Fluorescence in situ hybridization (FISH) using chromosome-specific DNA libraries as painting probes, locus-specific unique sequence (cosmid) probes, and Y-specific repetitive sequences was applied in the analysis of eighteen cases of chromosomal rearrangements of undetermined nature. FISH clarified the origin of the extra or translocated chromosome segments in seventeen patients, one with 2q+, two with 4q+, one each with 6p+, 7p+, 9q+, 10p+, 11q+ and 12p+, two with 13q+, and one each with 15q+, 17p+, 18p+, 20p+, 21p+ and Yq+, as well as the nature of a de novo supernumerary chromosome marker in a previously reported case. By G-banding and molecular cytogenetic studies of the family members, six cases were determined to have unbalanced translocations inherited from the carrier parent. The extra translocated genetic material may cause specific trisomic syndromes, including partial 6p21.3-p23, 9q32-q34.3, 13q32-q34, 15q24-q26, and 17p11.2-p13 trisomies in those patients. A translocated 21q segment on 12p was shown by a painting probe in a patient with Down features. A patient with cat cry syndrome resulting from a loss of the terminal segment of the short arm of chromosome 5 was confirmed by a cosmid probe showing de novo reciprocal translocation between chromosomes 5 and 18:t(5;18) (p13.3;p11.31). With FISH, the extra material on the rearranged chromosome could also be identified as duplicated or translocated. The FISH technique thus provides a method for the analysis of extra structurally abnormal chromosomes (especially in de novo cases), recognizable syndromes (contiguous gene syndromes) caused by translocated deletion from parental balanced chromosome rearrangements, and supernumerary marker chromosomes. FISH subsequent to G-banding is also of great help in the confirmation of preliminary abnormal G-banded karyotypes after a modified destaining procedure. In conclusion, the combination of G-banding and FISH is very useful in the accurate diagnosis of chromosomal rearrangements.     

Assignment of rat Jun family genes to chromosome 19 (Junb), chromosome 5q31-33 (Jun), and chromosome 16 (Jund)

By means of somatic cell hybrids segregating rat chromosomes, we determined the chromosome localization of three rat genes of the Jun family: Junb (Chr 19), Jun (=c-Jun) (Chr 5) and Jund (Chr 16). The Jun gene was also localized to the 5q31-33 region by fluorescence in situ hybridization. These rat gene assignments reveal two new homologies with mouse and human chromosomes, and provide a new example of synteny conserved in the human and a rodent species (the mouse), but split between the two rodent species.     

Human c-myc onc gene is located on the region of chromosome 8 that is translocated in Burkitt lymphoma cells

Human sequences related to the transforming gene (v-myc) of avian myelocytomatosis virus (MC29) are represented by at least one gene and several related sequences that may represent pseudogenes. By using a DNA probe that is specific for the complete gene (c-myc), different somatic cell hybrids possessing varying numbers of human chromosomes were analyzed by the Southern blotting technique. The results indicate that the human c-myc gene is located on chromosome 8. The analysis of hybrids between rodent cells and human Burkitt lymphoma cells, which carry a reciprocal translocation between chromosomes 8 and 14, allowed the mapping of the human c-myc gene on region (q24 leads to qter) of chromosome 8. This chromosomal region is translocated to either human chromosome 2, 14, or 22 in Burkitt lymphoma cells.     

ZOO-FISH analysis in insectivores: "Evolution extols the virtue of the status quo"

In evolutionary terms, insectivores are thought to be close to primates. Through ZOO-FISH analysis using human chromosome-specific painting probes, the syntenic relationship between the human and common shrew, Sorex araneus, karyotypes was studied. The human karyotype was found to be conserved in the shrew, with 32 autosomal segments of common synteny. Special arrangements, already known from similar studies on other species, were noted: fusions of HSA 16 and 19, HSA 3 and 21, and HSA 14 and 15. Only 10 breaks are necessary to transform the human karyotype into the karyotype of the common shrew. Together with known ZOO-FISH data from species belonging to other orders, this puts the human karyotype arrangement near the basis of all mammalian karyotypes. Human chromosome 2 was found to be conserved in its entirety as a single chromosome arm in the shrew. Evidence is presented that the same fusion of two original chromosomal segments formed the shrew chromosome ortholog of HSA 2 as the fusion that occurred during primate evolution to form human chromosome 2. This is a remarkable example of chromosomal coevolution.     

Chromosome painting: a useful art

Chromosome 'painting' refers to the hybridization of fluorescently labeled chromosome-specific, composite probe pools to cytological preparations. Chromosome painting allows the visualization of individual chromosomes in metaphase or interphase cells and the identification of both numerical and structural chromosomal aberrations in human pathology with high sensitivity and specificity. In addition to human chromosome-specific probe pools, painting probes have become available for an increasing range of different species. They can be applied to cross-species comparisons as well as to the study of chromosomal rearrangements in animal models of human diseases. The simultaneous hybridization of multiple chromosome painting probes, each tagged with a specific fluorochrome or fluorochrome combination, has resulted in the differential color display of human (and mouse) chromosomes, i.e. color karyotyping. In this review, we will summarize recent developments of multicolor chromosome painting, describe applications in basic chromosome research and cytogenetic diagnostics, and discuss limitations and future directions.     

Comparative RFLP mapping of a wild rice, Oryza officinalis, and cultivated rice, O. sativa

A comparative RFLP map was constructed in a wild rice, Oryza officinalis, by using 139 genomic and cDNA probes that had been used previously to map RFLPs in O. sativa. Nine of the 12 chromosomes of O. officinalis were highly homosequential to those of O. sativa. A major rearrangement of gene order was detected in chromosome 1 and small inversions were found in chromosomes 3 and 11. Fourteen translocated RFLP markers were found, and chromosome 11 contained a high frequency of such translocated segments. Results were consistent with meiotic and trisomic analysis, which suggested that the genomes of O. officinalis and O. sativa were similar. Applications of comparative maps in plant breeding and gene cloning are discussed.     

Hamster origin of metaphases with multiple chromosome rearrangements in first cleavage human-hamster embryos

Laboratories using the human sperm-hamster egg fertilization system to analyse sperm chromosomes obtain, sporadically, metaphases with multiple aberrations. Due to the high number of aberrations, these metaphases cannot be fully karyotyped. In some of them, one or several human chromosomes can be identified, guaranteeing the human origin of the whole metaphase. However, in others, none of the chromosomes can be recognized as human. This latter type of grossly rearranged metaphases is characterized by complex chromatid exchanges, multifragmented chromosomes and pulverized chromosome material. Using fluorescent in-situ hybridization techniques (FISH) with either human or hamster genomic DNA probes, we examined the origin of this second type of metaphase with multiple chromatid exchanges and fragmented chromosomes. Our study demonstrates that all of them hybridize with hamster genomic DNA probes and not with human DNA, proving their hamster origin. Since some of these metaphases seem to be diploid, we suggest that they may arise from hamster eggs that have failed to complete meiosis and have not extruded the second polar body.     

Hypomethylation of classical satellite DNA and chromosome instability in lymphoblastoid cell lines

To determine possible relationships between DNA hypomethylation and chromosome instability, human lymphoblastoid cell lines from different genetic constitutions were studied with regard to 1) uncoiling and rearrangements, which preferentially affect the heterochromatic segments of chromosomes 1 and 16; 2) the methylation status of the tandemly repetitive sequences (classical satellite and alphoid DNAs) from chromosomes 1 and 16, and of the L1Hs interspersed repetitive sequences. The methylation status largely varied from cell line to cell line, but for a given cell line, the degree of methylation was similar for all the repetitive DNAs studied. Two cell lines, one obtained from a Fanconi anemia patient and the other from an ataxia telangiectasia patient were found to be heavily hypomethylated. The heterochromatic segments of their chromosomes 1 and 16 were more frequently elongated and rearranged than those from other cell lines, which were found to be less hypomethylated. Thus, in these lymphoblastoid cell lines, alterations characterized by uncoiling and rearrangements of heterochromatic segments from chromosomes 1 and 16 seem to correlate with the hypomethylation of their repetitive DNAs. Two-color in situ hybridizations demonstrated that these elongations and rearrangements involved only classical satellite-DNA-containing heterochromatin. This specificity may be related to the excess of breakages affecting the chromosomes carrying these structures in a variety of pathological conditions.     

Comparative mapping of 9 human chromosome 22q loci in the laboratory mouse

We present a comparative map of genes on human chromosome 22q and homologous loci in the mouse genome. Gene order in humans was established using a panel of somatic cell hybrids. Genetic maps spanning homologous segments on three mouse chromosomes were generated using an interspecific backcross. The conserved linkage between human chromosome 22 and mouse chromosome 16 includes two closely linked loci, Comt and IgI-1. The second conserved linkage involves human chromosome 22 and mouse chromosome 11 and contains two genetically and physically linked loci, Lif and Nfh. Finally, conserved synteny involving mouse chromosome 15 and human chromosome 22 spans 30 cM and contains five loci (Acr, Bzrp, Dia-1, Il2rb and Pdgfb). Loci within this conserved synteny have been sublocalized to different portions of human chromosome 22. The order of genes on mouse chromosome 15 and human chromosome 22 provides further evidence for chromosomal rearrangements within the conserved synteny that have occurred since the divergence of lineages leading to mice and humans.     

A molecular cytogenetic analysis of X chromosome repatterning in the Bovidae: transpositions, inversions, and phylogenetic inference

Chromosomal homologies among the X chromosomes of species representative of eight bovid subfamilies and most of the recognized tribes were established using a combination of FISH and conventional G- and C-banding. Our analyses allowed for the delimitation of three X chromosome types represented, respectively, by cattle (Bovinae, tribe Bovini), the tragelaphines (Bovinae, tribe Tragelaphini), and a large assemblage comprising all the remaining subfamilies and their tribes (the Cephalophinae, Hippotraginae, Alcelaphinae, Antilopinae, Aepycerotinae, Peleinae, and Caprinae). The use of the bacterial artificial chromosome probe BAC 101 (which maps to Xp12 in cattle) and an Xp painting probe comprising sequences specific for the short arm of cattle Xp (Xp24-->p12) allowed us to orient this region, which has moved as a conserved euchromatic block during the evolution of the bovid X chromosome. We show that the differences between the three chromosomal types are attributable to a transposition, two inversions, and heterochromatic additions/deletions. A paucity of comparative mapping data precludes the assignment of the sequences contained in cattle Xp to either the presumed conserved (XCR) or the recently added (XAR) region of the eutherian X chromosome, and the reasons for the retention of these sequences as an evolutionarily conserved unit in the intrachromosomal restructuring of the bovid X across lineages remain enigmatic.     

Der(22)t(11;22) resulting from a paternal de novo translocation, adjacent 1 segregation, and maternal heterodisomy of chromosome 22

The t(11;22) (q23;q11) translocation is the most frequently identified familial reciprocal translocation in humans. In translocation carriers, 3:1 meiotic segregation with tertiary trisomy can occur resulting in abnormal progeny with the der(22) as the supernumary chromosome. Affected children have a distinct phenotype with multiple anomalies and severe mental retardation. We have identified a child with developmental delay and multiple anomalies consistent with the der(22) phenotype. Cytogenetic analysis showed an abnormal chromosome complement of 47,XX,+der(22)t(11;22)(q23; q11) in all 50 cells analysed. FISH analysis using chromosome 11 and 22 painting probes showed a pattern consistent with a reciprocal translocation of the distal bands 11q23 and 22q11 respectively. Parental karyotypes were normal. RFLP analysis of locus D22S43, which maps above the t(11;22) breakpoint, showed that the der(22) was paternal in origin and indicated that the normal chromosomes 22 were the probable result of maternal heterodisomy. RFLP analysis of locus D22S94, which maps below the t(11;22) breakpoint, also suggested that both normal chromosomes 22 of the child represented the two maternal homologues. Non-paternity was excluded through the analysis of 10 microsatellite markers distributed on 10 different chromosomes and three VNTRs on three different chromosomes. To the best of our knowledge, this is the first reported case of a patient with an abnormal karyotype resulting from a de novo translocation in the paternal germline with probable unbalanced adjacent 1 segregation and maternal non-disjunction of chromosome 22 in meiosis I.     

Human artificial chromosomes generated by modification of a yeast artificial chromosome containing both human alpha satellite and single-copy DNA sequences

A human artificial chromosome (HAC) vector was constructed from a 1-Mb yeast artificial chromosome (YAC) that was selected based on its size from among several YACs identified by screening a randomly chosen subset of the Centre d'Etude du Polymorphisme Humain (CEPH) (Paris) YAC library with a degenerate alpha satellite probe. This YAC, which also included non-alpha satellite DNA, was modified to contain human telomeric DNA and a putative origin of replication from the human beta-globin locus. The resultant HAC vector was introduced into human cells by lipid-mediated DNA transfection, and HACs were identified that bound the active kinetochore protein CENP-E and were mitotically stable in the absence of selection for at least 100 generations. Microdissected HACs used as fluorescence in situ hybridization probes localized to the HAC itself and not to the arms of any endogenous human chromosomes, suggesting that the HAC was not formed by telomere fragmentation. Our ability to manipulate the HAC vector by recombinant genetic methods should allow us to further define the elements necessary for mammalian chromosome function.     

Physics and technology of cardiovascular MR imaging

PURPOSE: Analysis of chromosomal aberrations by fluorescence in situ hybridization using a combination of chromosome painting and telomere detection in order to get more insight into: (a) the extent of incompleteness of exchanges and (b) the frequencies of interstitial fragments. MATERIALS AND METHODS: Isolated mouse splenocytes were exposed in vitro to X-rays at a dose of 2 Gy. Aberrations involving chromosomes 2 and 3 were analysed by FISH using simultaneous chromosome painting and telomere detection. RESULTS: At 2 Gy, about 10% of apparently simple exchanges are incomplete. A striking observation was the high induction of interstitial fragments, with frequencies nearly as high as that of dicentrics. Assuming, that both ends of all interstitial fragments have rejoined with each other (to form acentric rings), it can be estimated that over 92% of reactive ends of detectable breakpoints have rejoined illegitimately. Overall, equal frequencies of translocation types t(Ab) and t(Ba) (according to the PAINT nomenclature) were observed. Also, the ratios between reciprocal forms of translocations and dicentrics were close to 1 for both the chromosomes studied. CONCLUSIONS: These studies have shown that many of the frequently observed 'one-way' exchanges using painting probes, are in fact reciprocal exchanges with one participating lesion so close to the telomere that no distal signal can be detected. Frequencies of true incomplete exchanges were found to be low. Intrachanges, here detected as interstitial fragments, were observed frequently.     

Application of chromosome painting to clastogenicity testing in vitro

To maximise sensitivity, protocols for testing chemicals in chromosomal aberration assays in vitro are designed so that cells are sampled when the peak frequency of aberrations might be expected to occur. They are not designed to measure the frequency of aberrations in cells which survive. Only chromosomal aberrations which are heritable, however, can have any relevance to human health, but the detection of those aberrations most likely to be tolerated (inversions, reciprocal translocations) is notoriously difficult with conventional light microscopy. Current protocol design is justified by arguing that the presence of structural aberrations of any type at early times after treatment indicates a risk that a proportion of aberrations will persist and be maintained in the population. Chromosome painting allows reciprocal exchanges to be relatively easily measured and permits the validity of these assumptions to be tested. To date, the kinetics of induction and dose-response relationships of reciprocal translocations induced by chemicals have been little investigated. We compared the frequency of chromosome-type aberrations in human lymphocytes following treatment with two powerful clastogens, streptonigrin and Trenimon, using conventional staining techniques and chromosome painting. The results show that although reciprocal translocations can be shown to arise and persist in treated populations of human lymphocytes for several days following treatment, their frequency is very low, even at concentrations where large amounts of chromosomal damage are induced, indicating that, at present, the value of using chromosome painting as an adjunct to traditional clastogenicity testing is limited.     

Ciliary beat frequency, olfaction and endoscopic sinus surgery

OBJECTIVE: This article reports that competitive hybridization using entire chromosome specific libraries as probe and human genomic DNA as the competitor allows intense and specific fluorescent staining of human chromosome in metaphase. This general approach is called "chromosome painting". METHODS: The probes comprising chromosomes 2, 5, 6, 7, 13, 14, X specific libraries were used to analyse five cases which had been suspected of subtle translocation and deletion in karyotype analysis by G-banding of metaphase cells. The authors selected entire chromosome-specific DNA libraries hybridizing with the five cases. Unlabeled human genomic DNA was used to inhibit the hybridization of sequences in the library that bind to multiple chromosome. RESULTS: The target chromosome was made at least 20 times brighter parunit length than the others. Translocations and deletions were detected clearly in metaphase and were consistent with G-banding. However, the result was clearer and the detection easier, compared with G-banding. CONCLUSION: Chromosome painting is very powerful for identification of chromosome structural aberrations. Translocation and deletion involving these chromosomes can be strikingly visualized. The hybridization intensity and specificity are such that even very small portions of the involved chromosome can be detected. This technique is especially useful in settings where high-quality banding is difficult.     

Amplification of telomeric DNA and the extent of karyotypic evolution

The distribution of telomeric DNA in the genomes of the antelope ground squirrel, Ammospermophilus harrisii (family Sciuridae; 2n = 32) and the African black-footed cat, Felis nigripes (family Felidae; 2n = 38) were compared by fluorescence in situ hybridization (FISH) technique. These two mammalian species have the highest and the lowest amount of C-banded regions, respectively. FISH preparations with the human telomeric DNA probe showed that all C-banded segments in the A. harrisii chromosomes, except a few intercalary segments, were hybridizing with this DNA. F. nigripes showed hybridization only on the termini of each chromosome, and the C-banded regions did not hybridize with telomeric DNA on FISH analysis. The C-banded chromosomal arms in another rodent species, Peromyscus eremicus (family Cricetidae; 2n = 48), when hybridized with human telomeric DNA showed signals only in the termini of chromosomes but not in the heterochromatic arms. These observations indicate that not all C-banded regions in rodent species are telomeric DNA. The amplification of telomeric DNA in relation to speciation is discussed.