Increased sensitivity to bleomycin in upper aerodigestive tract mucosa of head and neck squamous cell carcinoma patients.

Previous studies on lymphocytes have suggested that patients with head and neck squamous cell carcinoma (HNSCC) have an increased susceptibility for chromosomal damage induced by bleomycin, a known radiomimetic mutagen. However, it has so far not been possible to study whether this genetic instability is present also in the epithelial component of the upper aerodigestive tract mucosa, the tissue from which HNSCC originates. In the present study, we have successfully cultured epithelial cells and fibroblasts isolated from non-neoplastic mucosa samples of 30 HNSCC patients and 56 controls. All cell cultures were exposed to bleomycin and chromosome instability was assessed by analysis of chromosome breakage in cells harvested after 2h of exposure and subsequent removal of bleomycin. Furthermore, the status of the fragile histidine triad gene (FHIT) in chromosome band 3p14.2 was studied by fluorescence in situ hybridization (FISH) in epithelial cells that had been cultured after removal of bleomycin. Chromosomal damage, in the form of chromosomal breaks and gaps, was seen in all cell cultures harvested 2h after exposure to bleomycin. In epithelial cells, the frequency of chromosome breakage was significantly higher among HNSCC patients than among controls [mean breaks per cell (b/c) 1.02 vs. 0.77, p=0.02]. When subdivided according to smoking status, age, and sex, a significantly higher frequency of chromosome breakage was still found in HNSCC patients (smokers, p=0.01, age

Papillomavirus type 16 E6/E7 and human telomerase reverse transcriptase in esophageal cell immortalization and early transformation.

Infection with high-risk human papillomavirus (HPV) has been implicated in the pathogenesis of esophageal squamous cell carcinoma, and up-regulation of telomerase in esophageal adenocarcinoma. We immortalized normal esophageal epithelial cells by over-expression of the HPV16 E6/E7 and human telomerase reverse transcriptase (hTERT) genes. HPV16 E6/E7-induced immortalization was accompanied by reduced RB and p53, but increased p16 and p21, protein expression. hTERT-immortalized cells had unaffected RB and p53, but significantly decreased p16 and p21, protein expression. Aurora-A protein was also up-regulated in E6E7 immortalized cells, and to a less extent in hTERT immortalized cells. Fluorescence in situ hybridization showed that the Aurora-A gene locus was amplified in E6E7 immortalized cells, which might account in part for the Aurora-A over-expression. These molecular changes led to an abrogation of the G2 checkpoint. E6E7 and hTERT immortalized esophageal cells recapitulated many of the molecular changes observed in esophageal carcinomas, where RB and p53 are frequently down-regulated. However, down-regulation of p16 and p21 occurred frequently in esophageal cancer, owing to aberrant gene promoter methylation. We showed in the immortalized cells that aberrant methylation had not yet set in, suggesting that promoter methylation might not be necessary for cellular immortalization. In addition to supporting the role of HPV and telomerase in esophageal carcinogenesis, our cell lines may also be useful in vitro models for further studies of esophageal carcinogenesis.

Cytogenetic abnormalities in 106 oral squamous cell carcinomas.

We report karyotypic features of 106 short-term cultured oral squamous cell carcinomas (SCC), 51 new and 55 previously reported cases, with clonal chromosome aberrations. The major cytogenetic findings were as follows: simple karyotypic changes were present in 38 cases (36%) and 68 tumors (64%) displayed complex karyotypes. The most common numerical changes were +7, +8, +9, +16, +18, +20, and -4, -10, -13, -14, -18, -19, -21, -22, and -Y. Structural rearrangements frequently (43% of the breaks) affected the centromeric regions, resulting in the formation of isochromosomes and whole-arm translocations. Among the recurrent structural aberrations identified, the most common were i(1q), i(3q), i(5p), i(8q), del(16)(q22), and hsr. With the exception of chromosomal band 11q13, which was involved in 25 tumors, only centromeric or near-centromeric bands were commonly involved: 3p11 approximately q11 (59 cases), 8p11 approximately q11 (57), 1p11 approximately q11 (48), 13p11 approximately q11 (46), 5p11 approximately q11 (41), 14p11 approximately q11 (41), and 15p11 approximately q11 (37). Losses of genetic material dominated over gains. The most frequent imbalances included loss of 2q33 approximately qter, 3p, 4p, 6q, 8p, 10p, 11q, 13p, 14p, and 15p, and chromosomes 18, 21, 22, and Y, and gain of chromosomes 7 and 20, 8q, and 11q13. No major karyotypic differences could be discerned between the present series of oral SCC and a previously reported series of laryngeal SCC, indicating that common genetic pathways are involved in the initiation and progression of SCC irrespective of site of origin.

Cytogenetic aberrations in immortalization of esophageal epithelial cells.

To define the early cytogenetic events important in esophageal carcinogenesis, we immortalized normal esophageal epithelial cells by overexpression of human papillomavirus type 16 E6/E7 (HPV16E6/E7) and human telomerase reverse transcriptase (hTERT), and characterized the chromosomal abnormalities serially before and after cellular immortalizaiton. During crisis, most cells had simple nonclonal karyotypic changes with cytogenetic divergence. Mitotically unstable chromosomes (i.e., telomere association and dicentric chromosomes) were the most common aberrations. After crisis, the karyotypic patterns were more convergent with nonrandom clonal changes. A few clones dominated the culture. Gain of chromosome 20q was consistently observed in four HPVE6/E7 immortalized esophageal lines, whereas amplification of chromosome 5q was preferentially found in hTERT immortalized cells. In addition, chromosomal aberrations of immortalized cells, including del(3p) and centromere rearrangements, were similar to those observed in esophageal cancer. Furthermore, in E6/E7-expressing cells, the frequency of negative telomere termini and anaphase bridges were high during crisis and low after crisis. These findings suggested that telomere dysfunction might be an important cause of cellular crisis, and the resultant chromosomal aberrations, mainly amplification of chromosome 20q or 5q, might be early genetic events required in esophageal cell immortalization. These alterations might be valuable models for further study of molecular mechanisms contributing to esophageal carcinogenesis.

Immortalization of human extravillous cytotrophoblasts by human papilloma virus gene E6E7: sequential cytogenetic and molecular genetic characterization.

Extravillous cytotrophoblast (EVCT) cultures from the normal placentas of three pregnant women were transfected by HPVE6E7. Sequential cytogenetic and molecular analyses were performed to delineate genetic events that may be critical for cell immortalization. One line, PE1-E6E7, was immortalized successfully, whereas 2 other lines, PE3-E6E7 and PE4-E6E7, could not be maintained beyond crisis. Before crisis, the majority of cells in all lines were karyotypically normal. During the early stages of crisis, there was progressive telomere shortening. Most cells were karyotypically abnormal, with extreme cytogenetic divergence and a predominance of telomeric association and dicentric chromosomes affecting many chromosomes. At the later stages of crisis, the karyotype became more convergent with a drastic decrease in nonclonal aberrations. In PE1-E6E7, after crisis the karyotype was complex, with frequent centromeric rearrangements in the form of isochromosomes and whole-arm translocations. There were unbalanced structural aberrations and numerical changes, including loss of chromosome 13, that could be traced throughout the evolution of the line. These findings support the concept that immortalization is a relatively rare and nonrandom event that occurs only in cells that have acquired the necessary or critical genetic alterations. Telomeric dysfunction may be an important mechanism leading to the acquisition of complex karyotypical aberrations.

Karyotypic evolution and tumor progression in head and neck squamous cell carcinomas.

Cytogenetic analysis was performed on primary tumors, and paired recurrent or metastatic lesions, in 14 patients with head and neck squamous cell carcinomas (HNSCC), in order to identify chromosomal aberrations associated with tumor initiation and progression. Abnormal karyotypes were found in 12 of the 14 patients, with distinctive karyotypic similarities shown in all informative pairs. For individual patients, the degree of karyotypic complexity was similar for the primaries and paired recurrent or metastatic lesions. All 22 samples with clonal chromosomal aberrations displayed complex karyotypes with multiple numerical and unbalanced structural rearrangements, resulting in extensive genomic imbalances. The pathway of clonal evolution could be traced in a few patients, supporting the notion that some aberrations or imbalances, particularly partial or entire loss of 3p, i(8q), and homogeneously staining regions commonly mapping to 11q13, were early genetic events in the initiation of HNSCC.

Chromosomal translocations involving 11q13 contribute to cyclin D1 overexpression in squamous cell carcinoma of the head and neck.

CCND1 amplification results in cyclin D1 overexpression. However, other unidentified genetic mechanisms contribute to enhanced gene expression. In the present study, 32 squamous cell carcinoma of the head and neck (SCCHN) were investigated regarding chromosomal abnormalities involving 11q13 by cytogenetic analysis, genomic CCND1 amplification by differential PCR and FISH, and cyclin D1 expression on the mRNA and protein level by differential RT-PCR and immunohistochemistry, respectively. CCND1 amplification, observed in 11 of 32 (34%) tumours, resulted in overexpression of cyclin D1 on the mRNA and/or protein level, in 3 cases in association with chromosomal translocations. In cytogenetic analysis, 4 tumours had hsr(11)(q13), all of which showed CCND1 amplification and cyclin D1 overexpression. Overexpression of cyclin D1 was detected at the mRNA level in 23 tumours (72%) and on the protein level in 25 tumours (78%). In one case a translocation was seen together with cyclin D1 overexpression on the mRNA level, without any cytogenetic or molecular signs of amplification. Furthermore, cases with cyclin D1 overexpression were frequently observed in the absence of any genomic rearrangement. We conclude that, besides amplifications, chromosomal translocations and other transcriptional or translational regulatory mechanisms are involved in CCND1 deregulation.

Statistical analyses of karyotypic complexity in head and neck squamous cell carcinoma.

More than 250 head and neck squamous cell carcinomas (HNSCCs) with clonal chromosomal abnormalities have been reported. Even though the pattern of aberrations is nonrandom, no specific primary or secondary karyotypic abnormalities have been identified. One explanation for the still-rudimentary understanding of the cytogenetic evolution in HNSCC could be the pronounced karyotypic complexity seen in these tumors. In an attempt to overcome this difficulty, we have applied several statistical methods such as hierarchical cluster analysis, multidimensional scaling, and k-means clustering, which allow the identification and interpretation of karyotypic pathways, as well as establishing a temporal order of chromosomal imbalances on 241 published and 70 previously unpublished HNSCC karyotypes. From the analysis of the distribution of the number of imbalances per tumor we suggest that the carcinomas evolve through three phases representing different stages of chromosomal instability. Two major cytogenetic pathways, one dominated by gains and another by losses, were identified by means of principal component analysis. These were initiated by +7 and by any of the aberrations 1p-, 3p-, or 7q-, respectively.

Karyotypic heterogeneity and clonal evolution in squamous cell carcinomas of the head and neck.

Head and neck squamous cell carcinomas (HNSCC) are often characterized by complex karyotypic changes, and a substantial proportion of the reported tumors have shown intratumor heterogeneity in the form of cytogenetically related (40%) or unrelated clones (20%). In order to study intratumor heterogeneity and to distinguish the temporal order of chromosome rearrangements in these tumors, two or more samples from different areas of the same tumor were separately examined in 19 HNSCC, yielding karyotypes from a total of 42 tumor samples. Intrasample heterogeneity was observed in 16 samples. Two samples displayed both related and unrelated multiple clones, four samples showed only multiple unrelated clones, and the remaining 10 samples had only related subclones. Intersample heterogeneity was detected in all but one tumor. Five tumors showed both cytogenetically related and unrelated multiple clones, 11 were found to have only related subclones, and the remaining two tumors showed only unrelated clones. Clonal evolution could be assessed in 13 tumors. A comparison of chromosome imbalances in different subclones from these tumors suggests that partial or entire loss of 3p, 8p, 9p, and 18q and gain of genetic material from 3q and 8q are likely to be early genetic events. In contrast, loss of 1q, 6p, 7q, and chromosome 10, as well as gain of chromosome arms 5p and 7p, are most probably later genetic events. One of the examined tumors contained two highly complex clones that were cytogenetically unrelated, indicating that this tumor had a multicellular origin.

Clonal chromosome abnormalities in premalignant lesions of the skin.

Two lesions, actinic keratosis (AK) and squamous cell carcinoma in situ (CIS), are believed to be precursors of squamous cell carcinoma (SCC) of the skin. These lesions can serve as an excellent model system for studying genetic changes associated with the inception of skin SCC. In the present study, five such lesions of the skin, three AKs and two AK+CIS, from three patients were short-term cultured and analyzed cytogenetically. One of the patients (case 3) had also an SCC in addition to three premalignant lesions. All lesions, but one, showed clonal karyotypic abnormalities. The recurrent changes identified were numerical, that is, +7 and +20. The structural rearrangements found in three AK were different, but it could be noted that the distal part of the long arm of chromosome 4 was involved in two AK and the SCC of case 3A. It was also interesting that chromosome 1 participated in structural rearrangements in three AK with band 1p31 being involved in two tumors. The karyotypic profile of these lesions is compared with that of skin SCC; it turns out that the general patterns are different in the sense that the SCC more often have complex karyotypes and display unbalanced aberrations involving the centromeric regions. Some karyotypic similarities between the SCC and their precursors are revealed. The fact that the structural rearrangements involving chromosomal band 3p13 and the centromeric region of chromosome 3 in AK are common features for many types of malignant tumors, including skin SCC, indicates that these changes are early genetic events associated with malignant transformation.

Sequential cytogenetic and molecular cytogenetic characterization of an SV40T-immortalized nasopharyngeal cell line transformed by Epstein-Barr virus latent membrane protein-1 gene.

Cytogenetic and molecular cytogenetic analyses were performed on four sublines derived from a newly established, SV40T-immortalized nasopharyngeal (NP) cell line, NP69, with two of the sublines expressing LMP1, an Epstein-Barr virus-encoded gene. A total of seven cytogenetically related subclones were identified, all having highly complex karyotypes with massive numerical and structural rearrangements. Centromeric rearrangements in the form of isochromosomes and whole-arm translocations were prevalent. A cytogenetic sign of gene amplification [i.e., homogeneously staining region (HSR)] was detected at 1q25 in all metaphase cells analyzed. Multicolor combined binary ratio labeling fluorescence in situ hybridization (COBRA-FISH) was used to confirm the karyotypic interpretations. Furthermore, multicolor COBRA-FISH also showed that part of the HSR contained chromosome 20 material. Extensive clonal evolution could be observed by the assessment of karyotypic variation among different subclones and individual metaphase cells. The evaluation of clonal evolution enabled the identification of the temporal order of chromosome aberrations during cell immortalization and malignant transformation. A striking karyotypic similarity was found between sublines expressing LMP1 and an NP carcinoma cell line, with loss of genetic material from chromosome arm 3p being an important recurrent observation. More interestingly, the karyotypic features of NP69 were also similar to those of many epithelial malignancies. Our observations suggest that serial transformation of NP cell lines might provide a useful in vitro model for the study of the multistep neoplastic transformation of NP cells.

Cytogenetic and fluorescence in situ hybridization characterization of clonal chromosomal aberrations and CCND1 amplification in esophageal carcinomas.

Cytogenetic analyses of four squamous cell carcinomas (SCC) of the esophagus showed complex numerical and structural abnormalities. Chromosomal bands or regions preferentially involved were 11q13, 8q10, 21q10, 3p10 approximately p11, 1p11 approximately q11, 5p11 approximately q11, and 14p11 approximately q11. For the first time, to our knowledge, recurrent aberrations were identified in esophageal SCC, including homogeneous staining region (hsr), isochromosomes i(3q) and i(21q), and ring chromosome. Losses of chromosomal material dominated over gains. Recurrent imbalances included under-representation of 4p13 approximately pter, 5q14 approximately qter, 9p22 approximately pter, 10p, 11p13 approximately pter, 12p13 approximately pter, 17p10 approximately pter, 18p11 approximately pter, 21p, and 22p, as well as over-representation of 1q25 approximately qter, 3q, 7q, and 8q. Interestingly, hsr at different chromosomal regions occurred in three of four cases. With the application of fluorescence in situ hybridization (FISH) and multicolor combined binary ratio labeling-FISH with specific DNA probes, it could be shown that in two cases the hsr was derived from chromosome 11 material and that the amplicon included CCND1. Our results, together with previous molecular genetic findings, indicate that CCND1might be a prime target in 11q13 amplification, and that amplification of this gene might be crucial in the tumorigenesis of esophageal SCC. These observed chromosomal aberrations and imbalances thus provide important information for further molecular genetic investigation of esophageal SCC.

Telomere-mediated mitotic disturbances in immortalized ovarian epithelial cells reproduce chromosomal losses and breakpoints from ovarian carcinoma.

Ovarian carcinomas (OCs) often exhibit highly complex cytogenetic changes. Abnormal chromosome segregation at mitosis is one potential mechanism for genomic rearrangements in tumors. In this study, OCs were demonstrated to have dysfunctional short telomeres, anaphase bridging, and multipolar mitoses with supernumerary centrosomes. When normal human ovarian surface epithelial (HOSE) cells were transfected with human papilloma virus 16 e6/e7 genes and subsequently driven into telomere crisis, the same set of mitotic disturbances occurred in a distinct sequence, initiated by telomere dysfunction, followed by anaphase bridging, and then supernumerary centrosomes and multipolar mitoses. The anaphase bridges resolved either by kinetochore-spindle detachment, corresponding to whole-chromosome losses in the HOSE karyotypes, or by extensive fragmentation of intercentromeric DNA sequences, corresponding to a high frequency of pericentromeric rearrangements. At later passages, the high degree of instability at telomere crisis was moderated by telomerase expression and centrosome coalescence, ultimately leading to a level of mitotic instability that was highly similar to that in OC cell lines and to complex karyotypes that were similar to those observed in high-grade OCs. This suggests that a significant proportion of the structural chromosome changes and genomic losses in OC are caused by a specific sequence of mitotic disturbances triggered by telomere crisis. That the model did not produce any of the whole-chromosome gains observed in OC indicates that these changes develop through a different mechanism.

Cyclin D1 amplification in chromosomal band 11q13 is associated with overrepresentation of 3q21-q29 in head and neck carcinomas.

Eight cytogenetically characterized head and neck squamous cell carcinomas (HNSCCs) with CCND1 amplification in the form of a homogeneously staining region (hsr) in 11q13 were studied by COBRA FISH and FISH with specific probes to identify and characterize chromosomal segments added to the derivative chromosomes 11. In 4 of the tumors, it could be recognized that the material added was derived from the long arm of chromosome 3. The rearrangements were interpreted as der(11)hsr(11)(q13)t(3;11)(q21;q13) in 3 cases and as der(11)hsr(11)(q13)t(3;11)(q14;q13) in 1 case. In the other 4 cases, material from chromosomes 1, 16, or 19 was added to the derivative chromosomes 11. By further FISH analysis with 14 YAC clones spanning 3q13-q21 in the 4 tumors with der(11)hsr(11)t(3;11), it could be shown that they had different breakpoints at the molecular level, excluding the possibility that a particular gene was rearranged by the translocations. More surprisingly, gain of the 3q21-q29 segment was found in all 8 tumors with hsr in 11q13 and loss of 3p was seen in 7 of the tumors. These findings strongly indicate a synergistic effect of CCND1 amplification, loss of distal 11q, 3q gain and 3p deletion in HNSCC development and also suggests a mechanistic link between intrachromosomal amplification at 11q13 and recombination with distal 3q.

Cytogenetic and molecular genetic characterization of immortalized human ovarian surface epithelial cell lines: consistent loss of chromosome 13 and amplification of chromosome 20.

OBJECTIVES: This study aimed at identifying the genetic events involved in immortalization of ovarian epithelial cells, which might be important steps in ovarian carcinogenesis. METHODS: The genetic profiles of five human ovarian surface epithelial (HOSE) cell lines immortalized by retroviral transfection of the human papillomavirus (HPV) E6/E7 genes were thoroughly characterized by chromosome banding and fluorescence in situ hybridization (FISH), at various passages pre- and post-crisis. RESULTS: In pre-crisis, most cells had simple, non-clonal karyotypic changes. Telomere association was the commonest aberration, suggesting that tolermase dysfunction might be an important genetic event leading to cellular crisis. After immortalization post-crisis, however, the karyotypic patterns were non-random. Loss of genetic materials was a characteristic feature. The commonest numerical aberrations were -13, -14, -16, -17, -18, and +5. Among them, loss of chromosome 13 was common change observed in all lines. The only recurrent structural aberration was homogeneously staining regions (hsr) observed in three lines. FISH and combined binary ratio labeling (COBRA)-FISH showed in two cases that the hsrs were derived from chromosome 20. Clonal evolution was observed in four of the lines. In one line, hsr was the only change shared by all subclones, suggesting that it might be a primary event in cell immortalization. CONCLUSION: The results of the present study suggested that loss of chromosome 13 and the amplification of chromosome 20 might be early genetic events involved in ovarian cell immortalization, and might be useful targets for the study of genomic aberrations in ovarian carcinogenesis.