Characteristic chromosome abnormalities,including rearrangements of 6p,del(7q), +12, and t(12;14), in 44 uterine leiomyomas

Summary The cytogenetic analysis of 224 leiomyomas from 138 patients is presented. An insufficient number of mitoses was found in 35 tumors, normal karyotypes in 145, and clonal chromosome aberrations were detected in 44. The three previously identified cytogenetic subgroups were all represented in this series: del(7) (q21.2q31.2) was found in 11, trisomy 12 in five, and t(12;14)(q14-15;q23-24) in one leiomyoma. Rearrangements of 6p, including deletions, inversions, and various translocations, were found in eight tumors, thus delineating a new cytogenetic subgroup of uterine leiomyoma. The remaining 21 karyotypically abnormal tumors had nonrecurrent changes. One leiomyoma had two cytogenetically unrelated clones characterized by del(7)(q21.2 q31.2) and +12. Karyotypic changes in two separate leiomyomas from the same uterus were identified in five patients; in three of them, different anomalies were found in the two tumors, whereas cytogenetically identical aberrations – del(7q) and dic(21;22) – were detected in two macroscopically discrete tumors. These findings suggest that whereas some multiple leiomyomas originate independently, others may be derived from the same neoplastic clone.     

Cytogenetic relationship between uterine lipoleiomyomas and typical leiomyomas

The chromosomes from two human uterine lipoleiomyomas, L25 and L26, from the same patient, were studied by a banding technique applied to preparations from short-term cultures. Both tumors displayed the same pseudodiploid stemline characterized by the reciprocal translocation t (5; 12) (q12; q24). These observations coincide with the previous finding that the largest subgroup of typical leiomyomas with an abnormal stemline are characterized by a long-arm change of one chromosome No. 12. The combined results support the previously advanced hypothesis that different histologic subtypes of uterine leiomyomas are derived from a common totipotential stem cell. This interpretation also fits with a proposed theory about the derivation of malignant leiomyomatous uterine neoplasms.     

Intragenic breakpoint within RAD51L1 in a t(6;14)(p21.3;q24) of a pulmonary chondroid hamartoma

Rearrangements involving chromosome region 14q23-->q24 represent a main cytogenetic subgroup in a variety of benign solid tumors. Recently, in uterine leiomyomas containing the classical t(12;14)(q15;q23-->q24), the primary chromosome 14 target gene was identified as the protein kinase-encoding gene RAD51L1. In this report we show that RAD51L1 is also involved in the frequently occurring t(6;14) (p21;q23-->q24) in pulmonary chondroid hamartomas.     

Karyotype pecularities of human colorectal adenocarcinomas

Summary The data of the chromosome abnormalities in 15 colorectal tumors are presented. Rearrangements of the short arm of chromosome 17, leading to deletions of this arm or its part were noted in 12 tumors; in 2 other cases, one of the homologs of pair 17 was lost. The losses of at least one homolog of other chromosomal pairs were also found: chromosome 18, in 12 out of 13 cases with fully identified numerical abnormalities; chromosome 5, in 6 tumors; chromosome 21, in 5 cases; chromosomes 4, 15, and 22, in 4 cases each. Additional homologs of pair 20 were observed in 6 tumors, extra 8q was found in 5 tumors, and extra 13q in 6 cases. Rearrangements of the short arm of chromosome 1 and the long arm of chromosome 11 characterized 6 tumors each. The data recorded in our series differ from the data of other authors in two respects: the high incidence of the loss of sex chromosomes and the rearrangements of the long arm of chromosome 9. X chromosomes were missing in 4 out of 7 tumors in females, and Y chromosomes were absent in 5 out of 8 tumors in males. The long arm of chromosome 9 was rearranged in 8 cases, in 5 of them the breakpoint being at 9q22. Cytological manifestations of gene amplification (double minutes or multiple microchromosomes) were noted in 6 tumors.     

Chromosome banding and gene localizations support extensive conservation of chromosome structure between cattle and sheep.

By using three gene probes, one derived from the porcine major histocompatibility complex (MHC) and two from bovine cytokeratin genes, type I (KRTA) and type II (KRTB), the hypothesis of conservation of genome structure in two members of the family Bovidae was examined. Gene mapping data revealed the MHC to be in chromosome region 23q15----q23 in cattle (BOLA) and 20q15----q23 in sheep (OLA). KRTA was localized to chromosome region 19q25----q29 in cattle and 11q25----q29 in sheep and KRTB to 5q14----q22 in cattle and 3q14----q22 in sheep. The banding patterns of the chromosome arms to which the loci were assigned were identical in both species. Moreover, the resemblances of GTG- or QFQ-banding patterns between the cattle and sheep karyotypes illustrated further chromosome homologies. These studies, based on gene mapping comparisons and comparative cytogenetics, document that within bovid chromosomes, homology of banding patterns corresponds to a homologous genetic structure. Hence, we propose that gene assignments on identified chromosomal segments in one species of the Bovidae can be extrapolated, in general, to other bovid species based on the banding homologies presented here.     

Closely linked loci on the long arm of chromosome 13 flank a specific 2;13 translocation breakpoint in childhood rhabdomyosarcoma

A specific chromosomal translocation, t(2;13)(q35;q14), is present in tumor cells from about one-half of children with alveolar rhabdomyosarcoma, who generally have widely disseminated disease at diagnosis. Using a series of six DNA probes from five loci previously assigned to bands 13q12----q14, we have localized the translocation breakpoint on chromosome 13 by in situ hybridization. Each probe was used to examine metaphase spreads from two or more rhabdomyosarcoma cell lines that have the t(2;13), as well as from control lymphoblastoid cell metaphases. All six probes bound to chromosome 13q12----q14 in the control cell line, but showed no appreciable hybridization to other sites. With rhabdomyosarcoma metaphases, cDNA clones of the retinoblastoma susceptibility gene (RB1) and the esterase D gene (ESD), as well as the arbitrary genomic fragment 7D2 (D13S10), showed specific hybridization to the normal chromosome 13 and the der(2) marker, but not to the der(13). By contrast, the genomic fragments HU10 (D13S6) and 7F12 (D13S1) hybridized specifically to the normal chromosome 13 and the der(13), but not to the der(2). Thus, the breakpoint of this translocation lies distal to D13S6 and D13S1 and proximal to ESD, RB1, and D13S10. Our data indicate that the locus affected by the translocation breakpoint on chromosome 13, which we have termed RMS, is physically distinct from the RB1 locus and is, in fact, proximal to ESD, which others have placed at least 10(6) bp proximal to RB1. The consistent presence of the der(2) marker chromosome, coupled with occasional loss of the der(13), suggests that the RMS gene, or at least a critical component, moves to chromosome 2 in tumors with this translocation.     

Chromosome localization of the human oncogene INT1 to 12q13 by in situ hybridization

The human oncogene INT1 has been mapped to chromosome band 12q13 by in situ hybridization. The precise localization of this gene is of particular interest, since the region 12q13----q14 has been reported to be involved in chromosomal rearrangements in lipomas, myxoid liposarcomas, pleomorphic adenomas, and myomas. The involvement of this region in both benign and malignant tumors suggests a common pathogenetic pathway in which changes affecting INT1 may be an important step.     

Relationship between cytogenetic aberrations by CGH coupled with tissue microdissection and DNA ploidy by laser scanning cytometry in head and neck squamous cell carcinoma

BACKGROUND: The relationship between DNA sequence copy number aberrations (DSCNAs) and DNA ploidy in head and neck squamous cell carcinomas (HNSCCs) is still controversial. Materials and Methods We analyzed DSCNAs by comparative genomic hybridization (CGH) combined with microdissection and DNA ploidy by laser scanning cytometry (LSC) in 18 surgically removed HNSCCs and compared the data. RESULTS: Copy number increases were most frequently observed on chromosomes 3q (16 cases), 8q (13 cases), and 12p (11 cases). Copy number decreases were observed on chromosome 3p (14 cases). LSC revealed DNA aneuploidy in 10 of the 18 cases. All DNA aneuploid tumors exhibited gain or amplification of DNA copy number at 12p11-12.1, whereas gain of DNA copy number was found in only 1 of 8 diploid tumors. DSCNAs were more frequent in DNA aneuploid tumors than in diploid tumors (P < 0.005). CONCLUSIONS: The present observations indicate a close relationship between DSCNAs and DNA ploidy in HNSCCs.     

Assignment of the human calpastatin gene (CAST) to chromosome 5 at region q14----q22

The human calpastatin gene (CAST) was assigned to chromosome 5 by spot-blot hybridization analysis with flow-sorted chromosomes, and it was further sublocalized to bands 5q14----q22 using in situ hybridization to metaphase chromosomes.     

Mapping of the MYC gene to band 8q24.12----q24.13 by R-banding and distal to fra(8)(q24.11), FRA8E, by fluorescence in situ hybridization

The MYC gene was mapped to R-banded human prometaphase chromosomes and to chromosomes expressing fra(8)(q24.11) by fluorescence in situ hybridization. By high-resolution banding analysis, the fluorescent signals were localized to R-positive band q24.12----q24.13 of the long arm of chromosome 8. Furthermore, the signals were localized near the middle part, q24.12----q24.13, of the distal portion of fra(8)(q24.11) expression. Thus, the precise localization of MYC was to the subband 8q24.12----q24.13.     

The thyroglobulin gene is syntenic with the MYC and MOS protooncogenes and carbonic anhydrase II and maps to chromosome 14 in cattle

Using a panel of bovine x Chinese hamster hybrid somatic cells, sequences homologous to genes spanning human chromosome arm 8q have been syntenically assigned in cattle. Thyroglobulin (TG), carbonic anhydrase II (CA2), and the protooncogenes MYC and MOS were assigned to a newly identified bovine syntenic group, U23. Additionally, in situ hybridization of the thyroglobulin probe to bovine metaphase chromosomes revealed this syntenic group to be on bovine chromosome 14 and the bovine thyroglobulin gene to reside at 14q12----q15.     

A detailed analysis of chromosomal changes in heritable and non-heritable retinoblastoma

Summary Full cytogenetic analysis of 27 different retinoblastoma tumors is presented. Gross aneuploidy of chromosome arms 6p and 1q were very common, being observed in 15/27 and 21/27 tumors, respectively. However, we found that chromosome 13 was rarely missing: only 3/27 had a detectable monosomy affecting 13q14. Monosomy of chromosome 13 by small deletion or rearrangement was also not observed in any of 12 retinoblastoma tumor lines analyzed detail at the 300–400 chromosome band level. A novel observation in retinoblastoma was the discovery of non-random translocations at three specific breakpoints, 14q32 (4/12), 17p12 (5/12), and 10q25 (3/12). Genomic rearrangements similar to those described involving C-myc in Burkitt lymphoma 14q+ cells could not be demonstrated in the four 14q+ retinoblastoma lines using molecular techniques, and a probe mapping to the site implicated to have an activating role in lymphoma. These data suggest that there is a target for rearrangement at 14q32 but it is not the same sequence used in some Burkitt lymphomas. Two other breakpoints (2p24 and 8q24) coincided with the mapped position of cellular oncogenes, but also failed to show a molecular rearrangement with the oncogene probes. The breakpoints, 10q25 and 17p12, are constitutional fragile sites which may predispose these regions to act as acceptors of translocations in malignant cells. One line had double minute chromosomes, and was the only one of 16 (6%) tested with the N-myc probe which had an amplification. Different tumors from single patients with multifocal heritable retinoblastoma showed independent karyotype evolution. Unilateral non-heritable tumors exhibited a high level of karyotype stability throughout both in vivo and in vitro growth. The various common patterns of aneuploidy and translocations probably confer an early selective advantage to malignant cells, rather than induce malignant transformation.     

Regional assignment of six polymorphic DNA sequences on chromosome 21 by in situ hybridization to normal and rearranged chromosomes.

We have assigned six polymorphic DNA segments to chromosomal subregions and have established the physical order of these sequences on the long arm of chromosome 21 by in situ hybridization of cloned probes to normal metaphase chromosomes and chromosomes 21 from individuals with three different structural rearrangements: an interstitial deletion, a ring chromosome, and a reciprocal translocation involving four different breakpoints in band 21q22. Segments D21S1 and D21S11 map to region 21q11.2----q21, D21S8 to 21q21.1----q22.11, and D21S54 to 21q21.3----q22.11; D21S23 and D21S25 are both in the terminal subband 21q22.3, but they are separated by a chromosomal breakpoint in a ring 21 chromosome, a finding that places D21S23 proximal to D21S25. The physical map order D21S1/D21S11-D21S8-D21S54-D21S23-D21S25 agrees with the linkage map, but genetic distances are disproportionately larger toward the distal end of 21q.     

Characterization of supernumerary rings and giant marker chromosomes in well-differentiated lipomatous tumors by a combination of G-banding,CGH, M-FISH,and chromosome- and locus-specific FISH

Supernumerary ring chromosomes and/or giant marker chromosomes are often seen in soft-tissue tumors of low-grade or borderline malignancy, such as well-differentiated liposarcomas or atypical lipomas. Classic cytogenetic banding techniques have proved insufficient to identify the genomic composition and structure of such rings and markers, but fluorescent in situ hybridization (FISH) studies have shown that they consist mainly of amplified material from chromosome 12, more specifically from bands 12q13-->q15. We have used the new FISH-based screening techniques comparative genomic hybridization (CGH) and multicolor-FISH (M-FISH) in combination with G-banding and analysis by chromosome- and locus-specific fluorescent in situ probes to examine in detail the karyotypic characteristics of 22 lipomatous tumors, most of them classified histologically as well-differentiated liposarcomas, selected because they had been shown to harbor rings and/or marker chromosomes. M-FISH, in contrast to G- banding, was found to be informative with regard to the chromosomal origin of the rings and other markers present, whereas CGH and hybridizations with locus-specific probes helped identify which subchromosomal regions were involved. We found that chromosome bands 12q15-->q21 were always gained, with 12q15-->q21 being amplified (i.e., a green-to-red ratio >2 by CGH) in 14 of 22 tumors. In three tumors, two distinct but close amplicons in 12q could be identified, corresponding to bands 12q13-->q15 and 12q21. The genomic segment 1q21-->q23 was gained in 12 cases, reaching the level of amplification in seven. Bands 6q24 and 7p15, whose pathogenetic involvement in liposarcomas has not been reported previously, were gained in three cases each. In addition, the rings and giant markers often contained interspersed sequences from several other chromosomes that did not give an equally clear impression of being nonrandomly involved.     

Amplification at 9p in cervical carcinoma by comparative genomic hybridization.

DNA copy number changes were studied by comparative genomic hybridization on 10 tumor specimens of squamous cell carcinoma of cervix obtained from Korean patients. DNA was extracted from paraffin-embedded sections after removal of non-malignant cells by microdissection technique. Copy number changes were found in 8/10 tumors. The most frequent changes were chromosome 19 gains (n=6) and losses on chromosomes 4 (n=4), 5 (n=3), and 3p (n=3). A novel finding was amplification in chromosome arm 9p21-pter in 2 cases. Gains in 1, 3q, 5p, 6p, 8q, 16p, 17, and 20q and losses at 2q, 6q, 8p, 9q, 10p, 11, 13, 16q, and 18q were observed in at least one of the cases.     

无精和严重少精症患者的遗传缺陷分析——-附2例世界首报染色体异常核型

对217例无精和严重少精症患者外周血淋巴细胞染色体核型进行分析,并采用聚合酶链反应对7例Y染色体结构异常患者的AZFc区进行检测。发现187例无精症患者中检出异常核型77例（41.18%）（其中46,XY,t(6;14)(p21;p13),46,XY,t(8;12)(p21;q24)为世界首报核型）,主要涉及染色体异常（数目异常和结构异常）;染色体异态（Y染色体异态和9号染色体臂间倒位）及46,XX性反转;30例严重少精症患者中检出异常核型4例（13.33%）（结构异常和46,XX性反转）。由此可见,性染色体数目和结构异常是精子发生障碍的主要原因,其次常染色体的某些断裂点也可能影响精子发生。AZFc区的缺失与否与精子发生也有直接关系。     

A specific chromosomal abnormality in rhabdomyosarcoma

A specific chromosomal abnormality, t(2;13)(q35;q14), was discovered in five cases of advanced rhabdomyosarcoma. It was identified directly in cells that had metastasized from bone marrow in one patient and in xenografts derived from the tumors of four other patients. The translocation was not restricted by histologic subtype, but was found in cases classified as alveolar, undifferentiated, or embryonal. Cytogenetic hallmarks of gene amplification (double minute chromosomes and homogeneously staining regions) were apparent in three cases. Other frequent abnormalities included rearrangements of chromosomes lp and trisomy of chromosome 8. The absence of the t(2;13) in more than 100 cases of other pediatric solid tumors investigated in our laboratory indicates its specificity for rhabdomyosarcoma. These cytogenetic findings suggest directions for further investigation of the molecular events underlying the genesis of this tumor.     

Chromosomal localization of human endogenous retroviral element ERV1 to 18q22----q23 by in situ hybridization

From a clone containing the entire locus of human endogenous retroviral element ERV1, we have obtained a DNA probe that is specific for the 3' long terminal repeat (LTR) sequence. This probe was used to map the LTR of ERV1 by in situ hybridization to chromosomes from normal human blood lymphocytes. The LTR was found to be localized to the distal portion of the long arm of human chromosome 18, within bands q22----q23. This chromosome locus is near the constitutive fragile site at band q21.3 on chromosome 18 associated with the 14;18 translocations seen in follicular lymphomas.     

Incidence of numerical chromosome aberrations in meningioma tumors as revealed by fluorescence in situ hybridization using 10 chromosome-specific probes

OBJECTIVE: Although information on the cytogenetic characteristics of meningioma tumors has accumulated progressively over the past few decades, information on the genetic heterogeneity of meningiomas is still scanty. The aim of the present study was to analyze by interphase fluorescence in situ hybridization (FISH) the incidence of numerical abnormalities for chromosomes 1, 9, 10, 11, 14, 15, 17, 22, X, and Y in a group of 70 consecutive meningioma tumors. Another goal was to establish the potential associations among the altered chromosomes, as a way to assess both intertumoral and intratumoral heterogeneity. METHODS: For the purpose of the study, 70 patients diagnosed with meningioma were analyzed. Interphase FISH for the detection of numerical abnormalities for chromosomes 1, 9, 10, 11, 14, 15, 17, 22, X, and Y was applied to fresh tumor samples from each of the patients studied. RESULTS: The overall incidence of numerical abnormalities was 76%. Chromosome Y in males and chromosome 22 in the whole series were the most common abnormalities (46% and 61%, respectively). Despite the finding that monosomy of chromosome 22/22q(-) deletions are the most frequent individual abnormality (53%), we have observed that chromosome gains are significantly more common than chromosome losses (60% versus 40%). Chromosome gains corresponded to abnormalities of chromosomes 1 (27%), 9 (25%), 10 (23%), 11 (22%), 14 (33%), 15 (22%), 17 (23%), and X in females (35%) and males (23%) whereas chromosome losses apart from chromosome 22 frequently involved chromosomes 14 (19%), X in males (23%), and Y in males (32%). Although an association was found among most gained chromosomes on one side and chromosome losses on the other side, different association patterns were observed. Furthermore, in the latter group, monosomy 22/22q(-) was associated with monosomy X in females and monosomy 14/14q(-) was associated with nulisomy Y in males. In addition, chromosome losses usually involved a large proportion of the tumor cells whereas chromosome gains were restricted to small tumor cell clones, including tetraploid cells. CONCLUSIONS: Our results show that meningiomas are genetically heterogeneous tumors that display different patterns of numerical chromosome changes, as assessed by interphase FISH.     

Modulating crossover positioning by introducing large structural changes in chromosomes

Background

Crossing over assures the correct segregation of the homologous chromosomes to both poles of the dividing meiocyte. This exchange of DNA creates new allelic combinations thus increasing the genetic variation present in offspring. Crossovers are not uniformly distributed along chromosomes; rather there are preferred locations where they may take place. The positioning of crossovers is known to be influenced by both exogenous and endogenous factors as well as structural features inherent to the chromosome itself. We have introduced large structural changes into Arabidopsis chromosomes and report their effects on crossover positioning.

Results

The introduction of large deletions and putative inversions silenced recombination over the length of the structural change. In the majority of cases analyzed, the total recombination frequency over the chromosomes was unchanged. The loss of crossovers at the sites of structural change was compensated for by increases in recombination frequencies elsewhere on the chromosomes, mostly in single intervals of one to three megabases in size. Interestingly, two independent cases of induced structural changes in the same chromosomal interval were found on both chromosomes 1 and 2. In both cases, compensatory increases in recombination frequencies were of similar strength and took place in the same chromosome region. In contrast, deletions in chromosome arms carrying the nucleolar organizing region did not change recombination frequencies in the remainder of those chromosomes.

Conclusions

When taken together, these observations show that changes in the physical structure of the chromosome can have large effects on the positioning of COs within that chromosome. Moreover, different reactions to induced structural changes are observed between and within chromosomes. However, the similarity in reaction observed when looking at chromosomes carrying similar changes suggests a direct causal relation between induced change and observed reaction.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1276-z) contains supplementary material, which is available to authorized users.