Characterization of the spontaneously transformed human endothelial cell line ECV304: 1. Multiple chromosomal rearrangements in ECV304 cells

Using differential G-staining of chromosomes, the karyotype of the endothelial cell line ECV304 obtained from endotheliocytes of the human umbilical vein was studied. The cells have been shown to have a polyploid karyotype with a number of chromosomes ranging from 96 to 112, as well as multiple numerical and structural clonal chromosome abnormalities. The structural rearrangements involve almost all chromosomes of the karyotype. Several paired chromosomal rearrangements have been revealed and include del(9)(p21), as well as two derivates of chromosome 3 with a breakpoint at the p25 locus, i.e., der(3)t(3;12)(3p25;12q11～12;12q21～24.?1) and der(3)t(3;?)(3p25). The role of these rearrangements in the immortalization of endotheliocytes and in angiogenesis is discussed. A comparison of the karyotypes of the cell line ECV304 and of the bladder carcinoma T24 cell line has shown that these karyotypes differ in all of the main cytogenetic characteristics. No identical structural chromosomal rearrangements, nor rearrangements characteristic of bladder carcinoma cells have been revealed. The studied endothelial cell line ECV304 is not identical to the T24 cell line.     

Embryos of Robertsonian Translocation Carriers Exhibit a Mitotic Interchromosomal Effect That Enhances Genetic Instability during Early Development

Balanced chromosomal rearrangements represent one of the most common forms of genetic abnormality affecting approximately 1 in every 500 (0.2%) individuals. Difficulties processing the abnormal chromosomes during meiosis lead to an elevated risk of chromosomally abnormal gametes, resulting in high rates of miscarriage and/or children with congenital abnormalities. It has also been suggested that the presence of chromosome rearrangements may also cause an increase in aneuploidy affecting structurally normal chromosomes, due to disruption of chromosome alignment on the spindle or disturbance of other factors related to meiotic chromosome segregation. The existence of such a phenomenon (an inter-chromosomal effect—ICE) remains controversial, with different studies presenting contradictory data. The current investigation aimed to demonstrate conclusively whether an ICE truly exists. For this purpose a comprehensive chromosome screening technique, optimized for analysis of minute amounts of tissue, was applied to a unique collection of samples consisting of 283 oocytes and early embryos derived from 44 patients carrying chromosome rearrangements. A further 5,078 oocytes and embryos, derived from chromosomally normal individuals of identical age, provided a robust control group for comparative analysis. A highly significant (P = 0.0002) increase in the rate of malsegregation affecting structurally normal chromosomes was observed in association with Robertsonian translocations. Surprisingly, the ICE was clearly detected in early embryos from female carriers, but not in oocytes, indicating the possibility of mitotic rather than the previously suggested meiotic origin. These findings have implications for our understanding of genetic stability during preimplantation development and are of clinical relevance for patients carrying a Robertsonian translocation. The results are also pertinent to other situations when cellular mechanisms for maintaining genetic fidelity are relaxed and chromosome rearrangements are present (e.g. in tumors displaying chromosomal instability).     

Karyotypic variability of human multiple myeloma cell lines

Cytogenetic analysis of human multiple myeloma (MM) cell lines L363, Karpas 707, RPMI 8226, and U-266 was carried out. During long-term existence in vitro, the number of chromosomes in the cell lines was shown to be preserved at the near-diploid level (L363, Karpas 707, U-266) or to increase up to the hypotriploid level (RPMI 8226). There were complexly rearranged karyotypes with abnormalities of chromosomes of all pairs in all cell lines; however, no identical chromosomal translocations have been revealed. Loci of chromosomes involved in structural rearrangements in these cell lines often coincided with sites of DNA copy number imbalances characteristic for MM in vivo. Distinct types of the karyotypic structure of cell populations differing in the combination of cells with the main and additional structural variants of karyotype and of cells with nonclonal chromosome rearrangements were found in MM cell lines. In general, the karyotypic variability of the MM cell lines corresponds to the dynamics of karyotype of myeloma cells in vivo and, hence, has a tumor-specific character.     

Cytogenetic and molecular cytogenetic investigations in relapse of B-cell chronic lymphocytic leukemia

Сhromosomal abnormalities have been analyzed in bone marrow cells of 61 patients with relapse of B-cell chronic lymphocytic leukemia. The cytogenetic results have allowed the structural stratification of the obtained karyotypes into ten groups of clones: normal, normal/near tetraploid, abnormal/normal, abnormal/ near tetraploid/normal, evolution of clonal chromosome abnormalities; evolution of clonal chromosome abnormalities/normal, evolution of clonal chromosome abnormalities/near tetraploid/normal, independent clones, independent/normal clones; and independent/near tetraploid/normal clones. The identified structural rearrangements included translocations, deletions, insertions, and duplications; however, deletions with the involvement of bands 17p12, 13q12–q14, 11q14, and 11q23 dominated (63.8%). The application of i-FISH helped to show the presence of one to four abnormalities per karyotype. The identified cytogenetic and molecular cytogenetic rearrangements may signify a multilevel nature of the process underlying the development of resistant karyotypes. The results obtained under both methods have revealed the presence of a heterogenic cell population with possibly different levels of chemotherapy resistance.     

Chromosomal rearrangements and their effects in spontaneous immortalization and transformation of rat embryo cells in vitro

G-banding analysis of LRec-1 and LRec-3, spontaneously immortalized cell lines from rat embryo fibroblast, revealed diploid karyotypes with specific clonal structural rearrangements of chromosomes 7 and 19 - del(7)(q11.2q22.1), t(7;19)(q11.1;q12) in malignant stage. Both clonal abnormalities of chromosomes 7 and 19 were also revealed in LRec-1k clone and LRec-1 sf cell line. Previous study of LRec-1 and LRec-3 cells showed the presence of karyotypes with pseudodiploid modal chromosome number, partial trisomy of chromosome 7 and same clonal structural rearrangements of chromosomes 7 and 19 in immortalized stage. In malignant stage, the trisomy 6 and new clonal structural rearrangements of chromosomes 1, 2, 11, 15, 18, 19 and of chromosomes 10, 20 were also found in LRec-1 sf and LRec-1 cells, accordingly. There were no new clonal structural chromosome rearrangements in LRec-1 k and LRec-3 cells. We compared locies of chromosomes involved in rearrangements with mapped genes on these chromosomes according to RATMAP. Supposedly these genes are involved in spontaneous immortalization of rat embryo fibroblast and malignant transformation of LRec-1 and LRec-3 cells and rearrangements of chromosomes 1, 2, 11, 15 and 18 facilitate expression of growth factors of LRec-1 sf cells.     

Paint-assisted microdissection-FISH: Rapid and simple mapping of translocation breakpoints in the embryonal rhabdomyosarcoma cell line RD.

BACKGROUND: Spectral karyotyping and multiple fluorophore fluorescence in situ hybridisation (M-FISH) facilitate identification of inter-chromosomal rearrangements, but are of low cytogenetic resolution in mapping translocation breakpoints. Reverse chromosome painting yields increased cytogenetic information but isolation of aberrant chromosomes is technically difficult. We have developed the technique of paint-assisted microdissection FISH (PAM-FISH), which enables microdissection of aberrant chromosomes to be carried out easily and rapidly using relatively simple apparatus. METHODS: A selected chromosome paint is hybridised to abnormal metaphases to label a chromosome of interest, which is then microdissected, amplified, labelled by polymerase chain reaction (PCR), and reverse painted onto extended normal metaphases. RESULTS: PAM-FISH was used to reassess structural chromosomal abnormalities identified by molecular cytogenetics in the rhabdomyosarcoma cell line RD. PAM-FISH improved the analysis of virtually all structural abnormalities, identifying six novel translocations and indicating that seven previously described rearrangements were in fact not present in RD. Accuracy of the breakpoint mapping obtained was confirmed by bacterial artificial chromosome-FISH. CONCLUSIONS: PAM-FISH is ideally suited to analysis of tumour metaphases as it is not affected by poor chromosome morphology. Reagents generated by PAM-FISH are also suitable for other investigations, such as mapping using sequence tagged-site PCR or genomic microarrays. PAM-FISH is technically straightforward and could readily be adopted in a routine cytogenetics laboratory for accurate high-throughput analysis of chromosome breakpoints.     

Expression of fragile sites in human sperm and lymphocyte chromosomes

Summary Sperm and lymphocyte chromosome studies in a normal, fertile male have shown a high degree of coincidence between chromosome lesions and fragile sites in both types of cells. In this donor we also found that some fragile sites expressed in sperm chromosomes coincided with those expressed in lymphocyte chromosomes. These results indicate that the chromosome lesions expressed in sperm do not occur at random and that they are not technical artifacts. The fragility expression in sperm chromosomes could reflect in vivo conditions. The presence in some sperm metaphases of acentric fragments suggests that chromosome fragility can result in the loss of chromosome fragments or give rise to de novo structural rearrangements. However, the incidence of sperm with chromosomal abnormalities observed in this man was within the normal range.     

Promiscuous genes and chromosomal rearrangements of hematopoietic malignancies

The nonrandomness of chromosomal abnormalities of hematopoietic malignancies, which has been established twenty years ago, has evidenced a more or less close relationship between some structural chromosomal abnormalities and leukemia subtypes. The same relation was, then, shown between gene and chromosome rearrangements. It becomes now obvious that genes involved in malignant proliferations may rearrange several different partner genes, as for instance the genes MLL, localised to chromosome band 11q23, and ETV6/TEL to 12p13. The study of these rearrangements is of particular importance in order to improve our knowledge of the functions of rearranged genes as well as their normal counterparts, and to analyse mechanisms favoring the occurrence of chromosomal rearrangements in malignancies.     

Phenomenon of evolution of clonal chromosomal abnormalities in childhood acute myeloid leukemia

An analysis of chromosomal abnormalities in bone-marrow cells was performed in 116 children with diagnoses of acute myeloid leukemia (AML). The frequency of the evolution of clonal chromosomal abnormalities in AML constituted 42.3%. Quantitative abnormalities of chromosomes 8, 9, and 21, as well as the secondary structural abnormalities in the chromosomal regions 12p12, 9p22, 9q22, 9q34, 11q14–23, and 6q2, were the most abundant. Quantitative abnormalities were registered in 26.7% cases. The basic mechanism of evolution of the leukemic clone contained trisomy, deletions, and monosomy. The frequency of evolution was seven times higher in the age group of up to 2 years and twofold higher in the age group of up to 5 years. The high frequency of evolution at t(15;17)(q22;q22) was established, while its absence was revealed at inv(16)(p13q22). Patients with clonal evolution were characterized by the increased frequency of relapses and earlier death before reaching remission, which might be explained by the severe initial state of those patients. The conception of abnormalities in the evolution of the clone was proposed to occur at certain stages as follows: (1) appearance of balanced rearrangements; (2) trisomy occurrence; (3) loss of chromosomal material. The occurrence of an unbalanced genome during evolution possesses advantages in the clonal proliferate activity and may be related to its response to chemotherapy. An identity in abnormal chromosomal structure was revealed as a result of the comparison of karyotypes during diagnostics and during relapse, which could be evidence of the initial induction of some types of evolution of chromosomal abnormalities in leukemic cells in AML children by the chemical agents.     

A model for genetic complementation controlling the chromosomal abnormalities and loss of heterozygosity formation in cancer

The relationship between the apparently random chromosomal changes found in aneuploidy and the genetic instability driving the progression of cancer is not clear. We report a test of the hypothesis that aneuploid chromosomal abnormalities might be selected to preserve cell-survival genes during loss of heterozygosity (LOH) formations which eliminate tumor suppressor genes. The LOHs and structurally abnormal chromosomes present in the aneuploid LoVo (colon), A549 (lung), SUIT-2 (pancreas), and LN-18 (glioma) cancer cell lines were identified by single nucleotide polymorphisms (SNPs) and Spectral Karyotyping (SKY). The Mann-Whitney U and chi square tests were used to evaluate possible differences in chromosome numbers and abnormalities between the cell lines, with two-tailed P values of <0.01 being considered significant. The cell lines differed significantly in chromosome numbers and frequency of structurally abnormal chromosomes. The SNP analysis revealed that each cell line contained at least a haploid set of somatic chromosomes, consistent with our hypothesis that cell-survival genes are widely scattered throughout the genome. Further, over 90% of the chromosomal abnormalities seemed to be selected, often after LOH formation, for gene-dosage compensation or to provide heterozygosity for specific chromosomal regions. These results suggest that the chromosomal changes of aneuploidy are not random, but may be selected to provide gene-dosage compensation and/or retain functional alleles of cell-survival genes during LOH formation.     

利用相互染色体涂色技术分析两株人肺腺癌细胞系(A549和GLC-82)的核型特征

肺癌是全世界癌症死亡中的一个主要的原因。除吸烟外,一些肺癌患者的发病与氡气污染相关。该研究采用包括染色体分选、正向和反向染色体涂色技术,分析了两株肺腺癌细胞系A549和GLC-82的核型特征。A549和GLC-82细胞系都属于非小细胞肺癌细胞系,但诱因不同,后者来源于一个长期生活在氡气污染环境肺癌病人的癌组织。染色体涂色结果表明,这两株肺癌细胞系发生了复杂的染色体重排。在A549和 GLC-82细胞系中,除正常染色体拷贝数变化外,还分别存在13条和24条畸变染色体。约一半的畸变染色体是通过非相互易位形成的,其余的畸变染色体则是通过一些正常染色体的片段缺失或重复而产生的。尽管这两株肺癌细胞系都没有共同的畸变染色体, 但它们似共享两个染色体易位断裂点：HSA8q24和12q14。     

Human Chromosomes: II. Preparation,Analysis and Diagnostic Implications of Abnormalities

This presentation is designed to show the diagnostic implications of chromosomal abnormalities, and how in some cases chromosome analysis may be helpful in prognosis and counselling. Most males with Klinefelter''s syndrome have chromatinpositive nuclei and an abnormal sex chromosome complex (usually XXY). In Turner''s syndrome many such females have chromatin-negative nuclei and a deficient sex chromosome complex (usually XO). Multiple-X females have unusual chromatin patterns (two or three masses of sex chromatin) and abnormal sex chromosome complexes (XXX, XXXX, XO/XXX, etc.). One of the parents of a translocation mongol may carry a translocation chromosome and pass it to future children. Cytogenetic data are therefore essential for genetic counselling. Mosaic and deletion mongols may show incomplete manifestations of mongolism, which make diagnosis difficult; chromosome analysis is helpful in diagnosis, and in prognosis concerning mental development. Abnormal chromosome numbers result from non-disjunction, usually during gametogenesis. The error may occur, however, during cleavage, producing cells with different chromosome complements (mosaicism). Visible structural abnormalities of chromosomes result from deletions or translocations of chromosome fragments.     

DNA hypomethylation and unusual chromosome instability in cell lines from ICF syndrome patients

The ICF syndrome (immunodeficiency, centromeric region instability, facial anomalies) is a unique DNA methylation deficiency disease diagnosed by an extraordinary collection of chromosomal anomalies specifically in the vicinity of the centromeres of chromosomes 1 and 16 (Chr1 and Chr16) in mitogen-stimulated lymphocytes. These aberrations include decondensation of centromere-adjacent (qh) heterochromatin, multiradial chromosomes with up to 12 arms, and whole-arm deletions. We demonstrate that lymphoblastoid cell lines from two ICF patients exhibit these Chr1 and Chr16 anomalies in 61% of the cells and continuously generate 1qh or 16qh breaks. No other consistent chromosomal abnormality was seen except for various telomeric associations, which had not been previously noted in ICF cells. Surprisingly, multiradials composed of arms of both Chr1 and Chr16 were favored over homologous associations and cells containing multiradials with 3 or >4 arms almost always displayed losses or gains of Chr1 or Chr16 arms from the metaphase. Our results suggest that decondensation of 1qh and 16qh often leads to unresolved Holliday junctions, chromosome breakage, arm missegregation, and the formation of multiradials that may yield more stable chromosomal abnormalities, such as translocations. These cell lines maintained the abnormal hypomethylation in 1qh and 16qh seen in ICF tissues. The ICF-specific hypomethylation occurs in only a small percentage of the genome, e.g., ICF brain DNA had 7% less 5-methylcytosine than normal brain DNA. The ICF lymphoblastoid cell lines, therefore, retain not only the ICF-specific pattern of chromosome rearrangements, but also of targeted DNA hypomethylation. This hypomethylation of heterochromatic DNA sequences is seen in many cancers and may predispose to chromosome rearrangements in cancer as well as in ICF.     

Hairy cell leukemia: an analysis of the chromosomes of 26 patients.

We studied the chromosomes from 26 patients with hairy cell leukemia (HCL) to ascertain the frequency and types of consistent chromosomal abnormalities. Samples from 21 patients were obtained from peripheral blood cultures grown 24 and 48 h without phytohemagglutinin, or from bone marrow samples. Two male patients had similar, consistent abnormalities; one patient's karyotype was 46, X, +12; that of the second was 46, X, +C marker. In the latter case, the distal long arm of the C marker most closely resembled chromosome No. 12 from band q14 to q terminal, but the short arm and proximal long arm were of undetermined origin. Both karyotypes lacked the Y chromosome. Nine of the 21 patients had abnormalities in single cells. One patient had, in one sample, a single abnormal cell with an extra No. 3 and an extra No. 12 (48, XY, +3, +12), and in a later sample, a second cell of poor morphology which also could have been trisomic for No. 12. Another patient had one cell with an unusually bright short arm, as well as two cells, with different abnormalities, both involving the short arm of chromosome No. 1. The two patients with consistent chromosome abnormalities had rapidly progressive disease in spite of splenectomy, and their clinical course from the time of diagnosis was relatively short (5 and 7 months, respectively).     

The presence of interstitial telomeric sequences in constitutional chromosome abnormalities.

We describe a novel chromosome structure in which telomeric sequences are present interstitially, at the apparent breakpoint junctions of structurally abnormal chromosomes. In the linear chromosomes with interstitial telomeric sequences, there were three sites of hybridization of the telomere consensus sequence within each derived chromosome: one at each terminus and one at the breakpoint junction. Telomeric sequences also were observed within a ring chromosome. The rearrangements examined were constitutional chromosome abnormalities with a breakpoint assigned to a terminal band. In each case (with the exception of the ring chromosome), an acentric segment of one chromosome was joined to the terminus of an apparently intact recipient chromosome. One case exhibited apparent instability of the chromosome rearrangement, resulting in somatic mosaicism. The rearrangements described here differ from the telomeric associations observed in certain tumors, which appear to represent end-to-end fusion of two or more intact chromosomes. The observed interstitial telomeric sequences appear to represent nonfunctional chromosomal elements, analogous to the inactivated centromeres observed in dicentric chromosomes.     

Oncogenes and the mammalian X chromosome

Summary None of the up to now localized and expressed oncogenes maps to the mammalian X chromosome. This fact is discussed in the light of a trans-acting regulation mechanism for oncogenes. Such a specific regulation mechanism is demonstrated here for a qualitative change — i.e., varying timing of DNA-replication — at the putative c-myc gene locus in band 15E of murine T-cell leukemia. In intraspecific hybrids between tumor and non-tumor cells this qualitative change spreads over to all chromosomes 15 of the same cell, irrespective of their origin. This effects is thought to reflect a binary trans-acting regulation mechanism between homologous chromosomal loci. In the past specific chromosomal aberrations have been described in various tumors but none of these aberrations involve the X chromosome. For the mammalian X chromosome where there is usually only one gene copy per cell active the described kind of binary trans-acting regulation between homologous gene loci is rendered impossible.     

Cytogenetic analysis of radiation-induced leukemia in Trp53-deficient C3H/He mice

C3H/He mice develop acute myeloid leukemia (AML) after whole-body irradiation, but the strain becomes highly susceptible to stem cell leukemia (SCL) when a null mutation is introduced into the Trp53 gene. To examine the etiology of SCL and the influence of chromosomal instability on leukemogenesis, 12 SCLs and two AMLs arising from Trp53-deficient C3H/He mice were investigated cytogenetically. Each SCL demonstrated cell-to-cell variation in the number and structural integrity of their chromosomes, indicating chromosomal instability. Typical deletion of chromosome 2 was observed in the two AML cases, while most SCL cells did not display this aberration. Deletions and rearrangements of chromosome 11 were noticeable in SCLs from Trp53 heterozygotes but not in AMLs. Analysis of loss of heterozygosity revealed that aberrations involving chromosome 11 in SCLs resulted in loss of the wild-type Trp53 allele. These results suggest that loss of Trp53 function triggers the tumorigenic process leading toward SCL through the induction of chromosomal instability, and that SCL and AML are distinct varieties of leukemia.     

Characteristics of the spontaneously transformed human endothelial cell line ECV304. I. Multiple chromosomal rearrangements in endothelial cells ECV304

Karyotype of endothelial line ECV304 cells obtained from human umbilicus vein endothelial cells was studied using G-banding chromosome staining. It has been revealed that the cells have a polyploidy karyotype with 96-112 chromosomes and multiple numerical and structural clonal rearrangements. Almost all the chromosomes of the karyotype are involved in structural rearrangements. There are several double chromosome rearrangements revealed including del(9)(p21) as well as two derivatives of chromosome 3 with the breakpoint in the locus p25 - der(3)t(3;12)(3p25;12q11- 12q24.?1) and der(3)t(3;?)(3p25). The role of these rearrangements in the immortalization of endothelial cells and sighs of transformation are discussed. In connection with the information received about the fact that the cells of ECV304 line are not endothelial cells but T24, urinary bladder cancer cells (which karyotype was studied by Hurst et al., 2000), the comparative analysis of the karyotypes of these two lines was carried out. It has been revealed that these two lines differ by all cytogenetic characteristics. Neither identical structural chromosomal rearrangements nor cell characteristic of urinary bladder cancer cells were detected. Our line ECV304 is not identical to the line T24.     

Multiple Chromosome Abnormalities Following Bone Marrow Transplant for Chronic Myelogenous Leukemia

A 44-year-old female was diagnosed in the chronic phase of chronic myelogenous leukemia (CML) and was confirmed to be Philadelphia chromosome positive by a bone marrow cytogenetic study. No additional cytogenetic abnormalities were found. The patient's cell counts were initially well controlled with hydrox-yurea. She then received an unrelated 6 of 6 HLA matched allo-geneic bone marrow transplant (BMT) from a male donor. The patient underwent myeloablative therapy with thiotepa and five fractions of total body radiation prior to the transplant. About four weeks after transplantation, the patient developed biopsy-proven graft-versus-host disease of the skin and GI tract. A blood sample was drawn at that time for cytogenetic analysis. Among 34 analyzed cells, 22 were normal male donor cells. The remaining 12 cells did not have the t(9;22), but had numerous structural abnormalities. While many cells were missing an X chromosome, other abnormalities, including deletions, rearrangements, dicentrics, acentric fragments, rings and marker chromosomes were non-clonal. No clinical evidence of progression from CML chronic phase was found, suggesting that the non-clonal abnor-malities were therapy related.