Chromosomal alterations in the clonal evolution to the metastatic stage of squamous cell carcinomas of the lung

Comparative genomic hybridization (CGH) was applied to squamous cell carcinomas (SCC) of the lung to define chromosomal imbalances that are associated with the metastatic phenotype. In total, 64 lung SCC from 50 patients were investigated, 25 each with or without evidence of metastasis formation. The chromosomal imbalances summarized by a CGH histogram of the 50 cases revealed deletions most frequently on chromosomes 1p21-p31, 2q34-q36, 3p, 4p, 4q, 5q, 6q14-q24, 8p, 9p, 10q, 11p12-p14, 13q13-qter, 18q12-qter and 21q21. DNA over-representations were most pronounced for chromosomes 1q11-q25, 1q32-q41, 3q, 5p, 8q22-qter, 11q13, 12p, 17q21-q22, 17q24-q25, 19, 20q and 22q. In ten cases, paired samples of primaries and at least one metastasis were analysed. The comparison revealed a considerable chromosomal instability and genetic heterogeneity; however, the CGH pattern indicated a clonal relationship in each case. The difference in histograms from the metastatic and non-metastatic tumour groups was most useful in pinpointing chromosomal imbalances associated with the metastatic phenotype, indicating that the deletions at 3p12-p14, 3p21, 4p15-p16, 6q24-qter, 8p22-p23, 10q21-qter and 21q22, as well as the over-representations at 1q21-q25, 8q, 9q34, 14q12 and 15q12-q15, occurred significantly more often in the metastatic tumour group. The comparison of the paired samples confirmed these findings in individual cases and suggested distinct genetic changes, in particular the extension of small interstitial deletions, during tumour progression. Importantly, metastasis-associated lesions were frequently detectable in the primary tumour providing a method of identifying patients at risk for tumour dissemination. Individual profiles and histograms are accessible at our web site http://amba.charite.de/cgh.     

Molecular cytogenetic analysis of 11 new breast cancer cell lines

We describe a survey of genetic changes by comparative genomic hybridization (CGH) in 11 human breast cancer cell lines recently established in our laboratory. The most common gains took place at 8q (73%), 1 q (64%), 7q (64%), 3q (45%) and 7p (45%), whereas losses were most frequent at Xp (54%), 8p (45%), 18q (45%) and Xq (45%). Many of the cell lines displayed prominent, localized DNA amplifications by CGH. One-third of these loci affected breast cancer oncogenes, whose amplifications were validated with specific probes: 17q12 (two cell lines with ERBB2 amplifications), 11q13 (two with cyclin-D1), 8p11-p12 (two with FGFR1) and 10q25 (one with FGFR2). Gains and amplifications affecting 8q were the most common genetic alterations in these cell lines with the minimal, common region of involvement at 8q22-q23. No high-level MYC (at 8q24) amplifications were found in any of the cell lines. Two-thirds of the amplification sites took place at loci not associated with established oncogenes, such as 1q41-q43, 7q21-q22, 7q31, 8q23, 9p21-p23, 11p12-p14, 15q12-q14, 16q13-q21, 17q23, 20p11-p12 and 20q13. Several of these locations have not been previously reported and may harbour important genes whose amplification is selected for during cancer development. In summary, this set of breast cancer cell lines displaying prominent DNA amplifications should facilitate discovery and functional analysis of genes and signal transduction pathways contributing to breast cancer development.     

Genomic imbalances and patterns of karyotypic variability in mantle-cell lymphoma cell lines

Mantle-cell lymphoma (MCL) is genetically characterized by 11q13 chromosomal translocations involving the CCND1 gene. We have characterized five MCL cell lines, JVM-2, GRANTA-519, REC-1, JEKO-1, and NCEB-1, combining metaphase and array comparative genomic hybridization, multicolor-FISH, and molecular analysis. Our results revealed common gained regions at 2p14, 9q31.2-qter, 11q13.1-q21, 13q14-q21.2, 13q34-qter and 18q21.1-q22.1, and losses at 1p21.2-p31.1, 2p11.2, 8p21.2-pter, 9p21.3-pter, 11q23.3-qter, 17p11.2-pter, and 17q21.2-q22.2. All cell lines except JVM-2, displayed moderate or high numerical chromosome instability. In addition, an ongoing level of chromosome rearrangements was observed in REC-1. Surprisingly, NCEB-1 carried several stable mouse chromosomes and showed expression of both human and murine bcl-2 protein. Our findings indicate that these cell lines represent three patterns of chromosome evolution in MCL and may be useful to understand the pathogenesis of this neoplasm.     

Detailed assessment of copy number alterations revealing homozygous deletions in 1p and 13q in mantle cell lymphoma

Mantle cell lymphoma (MCL) is characterized by over-expression of cyclin Dl as a result of the characteristic t(11;14)(q13;q32). However, this translocation alone has proven not to be sufficient for lymphomagenesis, suggesting the involvement of additional alterations. We have characterized 35 cases of MCL by array comparative genomic hybridization with an average resolution of 0.97 Mb distributed over the complete human genome. The most common alterations were losses in 1p13.2-p31.1, 6q16.2-q27, 8p21.3, 9p13.2-p24.3, 9q13-q31.3, 11q14.3-q23.3, 13q14.13-q21.31, 13q33.1-q34, and 22q11.23-q13.33 and gains involving 3q21.2-q29, 7p12.1-p22.3, 8q24.13-q24.23, and 18q21.33-q22.3. Four homozygous deletions were identified in totally three patients; two overlapping at 1p32.3, and two adjacent at 13q32.3. The homozygous deletions at 1p32.3 cover the CDKN2C locus (coding for p18), while the region at 13q32.3 does not encompass any known tumor suppressor genes. A gain in 3q was significantly associated with shorter survival (P=0.047).     

Detection of chromosomal alterations in bladder transitional cell carcinomas from Northern China by comparative genomic hybridization

To identify chromosome alterations in Chinese bladder cancer, forty-six transitional cell carcinomas of the bladder were analyzed by comparative genomic hybridization. Frequent gains of DNA copy number were observed on 1p (13/46), 1q (13/46), 5p (8/46), 6p (9/46), 7p (7/46), 8q (12/46), 11q (8/46), 17q (11/46), 19q (7/46), 20q (8/46) and Yq (8/46), with minimal overlapping regions at 1p32-pter (10/46), 1q21-q24 (12/46), 5p (8/46), 6p22-p23 (7/46), 7p11.2-p14 (7/46), 8q22-q24 (12/46), 11q13-q14 (8/46), 17q22-qter (11/46), 19q11-13.2 (7/46), 20q11-q13.2 (8/46) and Yq11 (8/46). Losses were predominantly found on 2q (16/46), 5q (8/46), 8p (7/46), 9p (8/46), 9q (13/46), 11p (7/46), 13q (7/46), 17p (12/46), 18q (7/46), Xp (18/46) and Xq (19/46), with smallest overlapping regions at 2q32-qter (16/46), 5q12-q31 (8/46), 8p12-pter (7/46), 9p21-pter (10/46), 9q (13/46), 11p (7/46), 13q13-q22 (7/46), 17p (12/46), 18q21-qter (7/46), Xp (18/46) and Xq (19/46). There were significantly higher frequencies of gains of 1q21-q24 and 17q22-qter in moderately differentiated tumors as compared with those in well-differentiated tumors, indicating a possible association of these two abnormalities with the dedifferentiation of tumor cells. Gains of 1p32-pter, 5p, 6p22-p23, 11q13-q14, 17q22-qter and losses of 2q32-qter, 9q, 17p were more frequent in pT1 as compared with those in pTa carcinomas. Gains at 1q21-q24, 7p11.2-p14, 8q22-q24, 19q, 20q11-q13.2 and losses at 5q12-q31, 8p12-pter, 9p21-pter, 11p, 13q13-q22 and 18q21-qter were unique to pT1 and higher stage tumors, suggesting that genes responsible for the invasion and progression of bladder cancer might be located at these chromosomal regions. In multiple tumors from the same patients, consistent alterations such as gains of 8q, 11q13-q14, 12q13-q15, 13q12, 20q and losses of 2q32-qter, 8p, 9, 11p, 11q21-qter, 13q13-qter, X were detected. These abnormalities were possibly earlier events, which might play a critical role during the genesis of the tumors. Further detailed studies to the recurrent aberration regions may lead to the identification of oncogenes and tumor suppressor genes involved in the development and progression of Chinese bladder cancer.     

Distinct patterns of genetic alterations in adenocarcinoma and squamous cell carcinoma of the lung

Squamous cell carcinoma (SqC) and adenocarcinoma (AdC) are the two most common subtypes of non-small cell lung cancer (NSCLC). Cumulative information suggests that the SqC and AdC subtypes progress through different carcinogenic pathways, but the genetic aberrations promoting such differences remain unclear. Here we have assessed the overall genomic imbalances and structural abnormalities in SqC and AdC. By parallel analyses with comparative genomic hybridisation (CGH) on tumorous lung tissues and spectral karyotyping (SKY) on short-term cultured primary tumours, genome-wide characterisation was carried out on 69 NSCLC (35 SqC, 34 AdC). Molecular cytogenetic characterisation indicated common and distinct genetic changes in SqC and AdC. Common events of +1q21-q24, +5p15-p14, and +8q22-q24.1, and -17p13-p12 were found in both groups, although hierarchical clustering simulation on CGH findings depicted +2p13-p11.2, +3q25-q29, +9q13-q34, +12p, +12q12-q15 and +17q21, and -8p in preferential association with SqC pathogenesis (P<0.05). Corresponding SKY analysis suggested that these changes occur in simple and complex rearrangements, and further indicated the clonal presence of translocation partners leading to chromosomal over-representations. These recurring rearrangements involved chromosome pairs of t(1;13), t(1;15), t(7;8), t(8;15), t(8;9), t(2;17) and t(15;20). Of particular interest was the finding that the t(8;12) translocation partner was exclusive to AdC. The combined application of SKY and CGH has thus uncovered the genome-wide chromosomal aberrations in NSCLC. Specific chromosomal imbalances and translocation partners found in SqC and AdC have highlighted regions for further molecular investigation into gene(s) that may hold importance in the carcinogenesis of NSCLC.     

Genome-wide array-based comparative genomic hybridization of diffuse large B-cell lymphoma: comparison between CD5-positive and CD5-negative cases

Diffuse large B-cell lymphoma (DLBCL) is the most common type of non-Hodgkin's lymphoma and exhibits aggressive and heterogeneous clinical behavior. To genetically characterize DLBCL, we established our own array-based comparative genomic hybridization and analyzed a total of 70 cases [26 CD-positive (CD5+) DLBCL and 44 CD5-negative (CD5-) DLBCL cases]. Regions of genomic aberrations observed in >20% of cases of both the CD5+ and CD5- groups were gains of 1q21-q31, 1q32, 3p25-q29, 5p13, 6p21-p25, 7p22-q31, 8q24, 11q23-q24, 12q13-q21, 16p13, 18, and X and losses of 1p36, 3p14, 6q14-q25, 6q27, 9p21, and 17p11-p13. Because CD5 expression marks a subgroup with poor prognosis, we subsequently analyzed genomic gains and losses of CD5+ DLBCL compared with those of CD5-. Although both groups showed similar genomic patterns of gains and losses, gains of 10p14-p15 and 19q13 and losses of 1q43-q44 and 8p23 were found to be characteristic of CD5+ DLBCL. By focusing on the gain of 13q21-q34 and loss of 1p34-p36, we were also able to identify prognostically distinct subgroups among CD5+ DLBCL cases. These results suggest that array-based comparative genomic hybridization analysis provides a platform of genomic aberrations of DLBCL both common and specific to clinically distinct subgroups.     

Comparative genomic hybridization analysis of 38 breast cancer cell lines: a basis for interpreting complementary DNA microarray data

Breast cancer cell lines provide a useful starting point for the discovery and functional analysis of genes involved in breast cancer. Here, we studied 38 established breast cancer cell lines by comparative genomic hybridization (CGH) to determine recurrent genetic alterations and the extent to which these cell lines resemble uncultured tumors. The following chromosomal gains were observed: 8q (75%), 1q (61%), 20q (55%), 7p (44%), 3q (39%), 5p (39%), 7q (39%), 17q (33%), 1p (30%), and 20p (30%), and the most common losses were: 8p (58%), 18q (58%), 1p (42%), Xp (42%), Xq (42%), 4p (36%), 11q (36%), 18p (33%), 10q (30%), and 19p (28%). Furthermore, 35 recurrent high-level amplification sites were identified, most often involving 8q23 (37%), 20q13 (29%), 3q25-q26 (24%), 17q22-q23 (16%), 17q23-q24 (16%), 1p13 (11%), 1q32 (11%), 5p13 (11%), 5p14 (11%), 11q13 (11%), 17q12-q21 (11%), and 7q21-q22 (11%). A comparison of DNA copy number changes found in the cell lines with those reported in 17 published studies (698 tumors) of uncultured tumors revealed a substantial degree of overlap. CGH copy number profiles may facilitate identification of important new genes located at the hotspots of such chromosomal alterations. This was illustrated by analyzing expression levels of 1236 genes using cDNA microarrays in four of the cell lines. Several highly overexpressed genes (such as RCH1 at 17q23, TOPO II at 17q21-q22, as well as CAS and MYBL2 at 20q13) were involved in these recurrent DNA amplifications. In conclusion, DNA copy number profiles were generated by CGH for most of the publicly available breast cancer cell lines and were made available on a web site (http://www.nhgri.nih.gov/DIR/CGB/++ +CR2000). This should facilitate the correlative analysis of gene expression and copy number as illustrated here by the finding by cDNA microarrays of several overexpressed genes that were amplified.     

Patterns of chromosomal imbalances in invasive breast cancer

Invasive breast carcinomas are characterized by a complex pattern of chromosomal alterations. We applied comparative genomic hybridization (CGH) to analyze 105 primary breast carcinomas using histograms to indicate the incidence of DNA imbalances of tumor subgroups and difference histograms to compare invasive ductal carcinomas (IDC) with lobular carcinomas (ILC), well and poorly differentiated carcinomas (G1/G3) and estrogen receptor-positive and -negative tumors (ER(+)/ER(-)). Only single imbalances showed a higher incidence in ILC compared with IDC, i.e., gains on chromosomes 4 and 5q13-q23 as well as deletions on chromosomes 6q, 11q14-qter, 12p12-pter, 16q, 17p, 18q, 19, and 22q. Of these, particularly gains of 4 and losses at 16q21-q23, and 18q12-q21 were statistically significant. For most loci, IDC showed more alterations providing a genetic correlate to the fact that ductal carcinoma overall is associated with a worse prognosis than ILC. Of these, many imbalances showing statistical significance were also observed in G3 and ER(-) tumors, i.e., deletions at 2q35-q37, 3p12-p14, 4p15-p16, 5q, 7p15, 8p22-p23, 10q, 11p, 14q21-q31, 15q, and gains at 2p, 3q21-qter, 6p, 8q21-qter, 10p, 18p11-q11, and 20q, suggesting that they contribute to a more aggressive tumor phenotype. By contrast, gains on chromosome 5q13-q23 as well as deletions at 6q, 16q and 22q were more prevalent in G1 and ER(+) tumors. The ratio profiles of all cases as well as histograms are accessible at our CGH online tumor database at http://amba.charite.de/cgh. Our results highlight distinct chromosomal subregions for cancer-associated genes. In addition, these imbalances may serve as markers for a genetic classification of invasive breast cancer.     

Genome-wide allelotype analysis of sporadic primary nasopharyngeal carcinoma from southern China

Nasopharyngeal carcinoma (NPC) is one of the most common malignant tumors in Southern China, especially in the Guangdong area. To demonstrate a comprehensive profile of loss of heterozygosity (LOH) in NPC, we applied a large panel of 382 microsatellite polymorphism markers covering all the 22 autosomes in 98 cases of sporadic primary NPC. Of the 335 informative markers, 83 loci showed high level of LOH (presence in equal to or more than 30% cases) and most of the high frequent loci were clustered to chromosome 1p36 and 1p34, 3p14-p21, 3p24-p26, 3q25-q26 and 3q27, 4q31 and 4q35, 5q15-21 and 5q32-q33, 8p22-p23, 9p21-p23 and 9q33-q34, 11p12-p14, 13q14-q13 and 13q31-q32, 14q13-q11, 14q24-q23 and 14q32. High frequency of LOH was found in chromosomes 3, 5, 9 and 11 (>/=50%), while medium frequency of LOH was found in chromosomes 1, 4, 6, 14, 17 and 19 (40-49%). Several new regions showing high frequency of LOH were found in chromosome 1p36, 3q25-q26, 3q27, 5q15-q21, 8p22-p23 and 11p12-14. The relationship between LOH and TNM stage of NPC was evaluated. Regions 6p23 (D6S289), 8p23.1 (D8S549) and 9q34.2 (D9S1826) showed higher frequency of LOH in later stages (III and IV) than in earlier stages (I and II) (P<0.05). Thus, our study provides a global view on allelic loss in the development of NPC and should shed light on the way for localization of putative tumor suppressor genes associated with the pathogenesis of NPC.     

Multiple sites of highly amplified DNA sequences detected by molecular cytogenetic analysis in HS-RMS-2, a new pleomorphic rhabdomyosarcoma cell line

A molecular cytogenetic analysis was performed on HS-RMS-2, a cell line established in this laboratory from a rare pleomorphic type of rhabdomyosarcoma. G-banding and multicolor-FISH analyses revealed that the cells have a complex chromosomal composition. Comparative genomic in situ hybridization (CGH) detected eight highly amplified regions at 1p36.1-p36.2, 1p31-p32, 1q21-q31, 8q12-q21, 8q24-qter, 11q12-q13, 12q13-q14 and 18q12-q22, suggesting the co-existence of multiple amplified oncogenes in these tumor cells. Reverse chromosome painting, using a probe regenerated by microdissection of a long marker chromosome, revealed the native location of three of eight possible genes to be on chromosomes 1p31-32, 12q14 and 18q21. FISH using BAC and cosmid probes revealed amplification of JUN (1p31), MYC (8q24), CCND1 (11q13), INT2 (11q13.3), MDM2 (12q14.3-q15) and MALT (18q21). These findings indicate that at least eight amplified oncogenes may contribute to the pathogenesis of a rare pleomorphic type of rhabdomyosarcoma. This new cell line should prove useful for in vitro preclinical studies of molecularly targeted therapies.     

Patterns of chromosomal imbalances in muscle invasive bladder cancer

Cytogenetic investigations of bladder cancer suggested that development and progression is characterized by specific chromosomal aberrations. In order to identify genetic changes linked to muscle invasive tumors and metastatic growth we analyzed 67 bladder carcinomas (30 pT1 and 37 pT2-4) by means of comparative genomic hybridization (CGH). The most frequent changes were gains of chromosome 1q (54%), 8q (54%), 17q (49%), 2p (30%), 12 (30%), 5p (25%), 3q (24%) and 6p (24%) as well as losses of 11p (43%), 8p (42%), 9p (36%), 11q (34%), 2q, 4q, 5q (30% each), 9q (27%) and 10q (27%). Previously not described amplifications were found at 5p11-p13, 7q21-q31, 9p24 and 17q24-q25. Gains of 3q, 7p, and 18p were markedly more frequent in pT2-4 in comparison to pT1 carcinomas but the difference did not reach statistical significance. Non-metastatic tumors showed more aberrations on average than metastatic carcinomas, although no particular change was found to be predominating in either group. Our data confirm previous findings of strong genetic similarities between minimally and deeply invasive bladder carcinomas but argue for differences between metastatic and non-metastatic disease.     

Establishment of a new human pleomorphic malignant fibrous histiocytoma cell line,FU-MFH-2: molecular cytogenetic characterization by multicolor fluorescence in situ hybridization and comparative genomic hybridization

Background

Pleomorphic malignant fibrous histiocytoma (MFH) is one of the most frequent malignant soft tissue tumors in adults. Despite the considerable amount of research on MFH cell lines, their characterization at a molecular cytogenetic level has not been extensively analyzed.

Methods and results

We established a new permanent human cell line, FU-MFH-2, from a metastatic pleomorphic MFH of a 72-year-old Japanese man, and applied multicolor fluorescence in situ hybridization (M-FISH), Urovysion™ FISH, and comparative genomic hybridization (CGH) for the characterization of chromosomal aberrations. FU-MFH-2 cells were spindle or polygonal in shape with oval nuclei, and were successfully maintained in vitro for over 80 passages. The histological features of heterotransplanted tumors in severe combined immunodeficiency mice were essentially the same as those of the original tumor. Cytogenetic and M-FISH analyses displayed a hypotriploid karyotype with numerous structural aberrations. Urovysion™ FISH revealed a homozygous deletion of the p16^INK4A locus on chromosome band 9p21. CGH analysis showed a high-level amplification of 9q31-q34, gains of 1p12-p34.3, 2p21, 2q11.2-q21, 3p, 4p, 6q22-qter, 8p11.2, 8q11.2-q21.1, 9q21-qter, 11q13, 12q24, 15q21-qter, 16p13, 17, 20, and X, and losses of 1q43-qter, 4q32-qter, 5q14-q23, 7q32-qter, 8p21-pter, 8q23, 9p21-pter, 10p11.2-p13, and 10q11.2-q22.

Conclusion

The FU-MFH-2 cell line will be a particularly useful model for studying molecular pathogenesis of human pleomorphic MFH.     

Genetic aberrations detected by comparative genomic hybridization in ovarian clear cell adenocarcinomas

Genetic abnormalities were detected by comparative genomic hybridization (CGH) in 12 ovarian clear cell adenocarcinomas. DNA sequence copy number abnormalities (CNAs) occurring in more than 20% of the cancers included increased copy numbers of 8q11-q13, 8q21-q22, 8q23, 8q24-qter, 17q25-qter, 20q13-qter and 21q22-qter and reduced copy numbers of 19p. Increases in copy numbers of 8q11-q13, 8q21-q22, 8q23 and 8q24-qter occurred more frequently in disease-free patients than in recurrent/non-surviving patients (p < 0.05). However, increases in copy numbers of 17q25-qter and 20q13-qter occurred more frequently in recurrent/non-surviving patients than in disease-free patients (p < 0.05). Furthermore, increases in copy numbers of 17q25-qter and 20q13-qter occurred together (p < 0.05). Additionally, there were negative correlations between increases in copy numbers of 8q21-q22 and 17q25-qter, and between 8q21-q22 and 20q13-qter (p < 0.05). It appears that ovarian clear cell adenocarcinomas can be classified into two subtypes, one being cancer with an increase in copy numbers of 8q and the other being cancer with increases in copy numbers of 17q25-qter and 20q13-qter.     

Frequent gains and losses of specific chromosome segments in human ovarian carcinomas shown by comparative genomic hybridization

Total genomic DNA obtained from 24 ovarian carcinomas was examined for genomic imbalances by comparative genomic hybridization (CGH). A varying number of gains and losses (1 up to 31) of specific chromosomal segments was detected per tumor. Chromosomal segments which were most often present in increased copy numbers were (in decreasing order): 1q21, 8q24, 8q23, 3q26, 12p12-p13, 20q, 7q31, and 7q33-qter. Loss of material was found most frequently at 16q12, 13q13-q14, Xq, 8p21-p22, 5q13-q14, and 5q21. All these chromosomal segments involved in gains and losses may carry gene loci playing a more or less causal role in the process of ovarian malignancies. Based on these findings CGH can be regarded as a valuable tool for rapid screening of genomic imbalances in human tumors.     

Comparative genomic hybridization reveals population-based genetic alterations in hepatoblastomas

Hepatoblastoma is a malignant paediatric liver tumour. In order to approach the genetic background of this malignancy we have screened a panel of eighteen cases from Europe and Japan for chromosomal imbalances using comparative genomic hybridization (CGH). The most frequent losses included chromosomal regions 13q21-q22 (28%) and 9p22-pter (22%), while the most frequent gains occurred on 2q23-q24 (33%), 20q (28%) and 1q24-q25 (28%). A significant difference in CGH alterations between the tumours from patients of Caucasian and Japanese was revealed where loss of 13q was found only in the Japanese samples. In conclusion, the findings indicate several candidate regions for suppressor genes and oncogenes potentially involved in the hepatoblastomas of different ethnic origin.     

Chromosomal imbalances associated with response to chemotherapy and cytotoxic cytokines in human malignant glioma cell lines

The median survival for human malignant glioma patients treated with neurosurgery and postoperative radiotherapy does not exceed one year. Only a minority of patients benefit from adjuvant chemotherapy. It was the aim of our study to determine which genomic alterations in malignant gliomas modulate the sensitivity to chemotherapy or cytotoxic cytokines such as CD95 ligand (CD95L) or Apo2L/tumor necrosis factor-related apoptosis-inducing ligand (Apo2L/TRAIL). Therefore, we analyzed 12 human malignant glioma cell lines for chromosomal gains and losses by comparative genomic hybridization (CGH). The gains most commonly identified were on chromosomes 7q, 19, 1, and 20q, whereas the most frequent losses were on 13q, 11q, 18q, and 4q. By comparison with previously published data on this panel of glioma cell lines1112, we defined candidate regions which may carry genes responsible for sensitivity to chemotherapy or cytotoxic cytokines. All but one of the chromosomal regions associated with response to chemotherapy, i.e. 1p12, 3p21, 11p11.2-p13, 12q23, 17p11. 2-p13, were different from those associated with response to cytotoxic cytokines, i.e. lp12, 1q22, 12q12-q21. Genomic regions known to harbor major candidate genes, including genes encoding death ligands, death receptors, caspases and BCL-2 family proteins, were not found to be imbalanced. In addition, we identified 5q13-q14, 5q34, 10p11.2, 9q21-q34 as genomic regions associated with the proliferative activity of malignant glioma cell lines. Cell lines with gain on proximal 5q, where CCNB1 and CCNH reside, showed an increased growth rate, suggesting that cyclins activating cdc2, the dominant G2/M phase kinase, may play a role in glioma tumorigenes.     

Genomic alterations in malignant transformation of Barrett's esophagus

The incidence of adenocarcinoma in Barrett's esophagus has been increasing rapidly over the past decades. Neoplastic progression is characterized by three well-defined premalignant stages: metaplasia, low-grade dysplasia, and high-grade dysplasia. A genome-wide overview, based on comparative genomic hybridization, was performed, evaluating 30 Barrett's adenocarcinomas and 25 adjacent precursors, i.e., 6 metaplasias, 9 low-grade dysplasias, and 10 high-grade dysplasias. The frequency of losses and gains significantly increased in the subsequent stages of malignant transformation. Losses of 5q21-q23, 9p21, 17p12-13.1, 18q21, and Y were revealed in low-grade dysplasias. This was followed by loss of 7q33-q35 and gains of 7p12-p15, 7q21-q22, and 17q21 in high-grade dysplasias along with high-level amplification (HLA) of 7q21 and 17q21. In the invasive cancers, additional losses of 3p14-p21, 4p, 4q, 8p21, 13q14-q31, 14q24.3-q31, 16q21-q22, and 22q as well as gains of 3q25-q27, 8q23-24.1, 12p11.2-12, 15q22-q24, and 20q11.2-q13.1 were distinguished along with HLAs of 8p12-p22 and 20q11.2-q13.1. Approximately one-third of the alterations in the dysplasias were also found in the adjacent adenocarcinomas, illustrating that multiple clonal lineages can be present in Barrett's esophagus. Novel findings include loss on 7q, gain on 12p, and the observation of several HLAs in high-grade dysplasias. Furthermore, loss of 7q33-q35 was found to represent a significant distinction between low-grade and high-grade dysplasia (P = 0.01), whereas loss of 16q21-q22 and gain of 20q11.2-q13.1 were disclosed to significantly discriminate between high-grade dysplasia and adenocarcinoma (P = 0.02 and P = 0.03, respectively). This inventory of genetic aberrations increases our understanding of malignant transformation in Barrett's esophagus and might provide useful biomarkers for disease progression.     

Array comparative genomic hybridization reveals distinct DNA copy number differences between gastrointestinal stromal tumors and leiomyosarcomas

Leiomyosarcomas are spindle cell tumors showing smooth muscle differentiation. Until recently, most gastrointestinal stromal tumors (GIST) were also classified as smooth muscle tumors, but now GISTs are recognized as a separate entity, defined as spindle cell and/or epithelioid tumors localized in the gastrointestinal tract. Using microarray-based comparative genomic hybridization (array CGH), we have created a detailed map of DNA copy number changes for 7 GISTs and 12 leiomyosarcomas. Considerable gains and losses of chromosomal segments were observed in both tumor types. The most frequent aberration observed in GISTs was loss of chromosomes 14 and 22, with minimal recurrent regions in 14q11.2-q32.33 (71% of the tumors) and 22q12.2-q13.31 (100%). In leiomyosarcomas, frequent loss of chromosome 10 and 13q was observed, with minimal recurrent regions in 10q21.3 (75%) and 13q14.2-q14.3 (75%). Recurrent high-level amplification of 17p13.1-p11.2 was detected in leiomyosarcomas. Expression profiling using cDNA microarrays revealed four candidate genes in this region with high expression (AURKB, SREBF1, MFAP4, and FLJ10847). Altered expression of AURKB and SREBF1 has been observed previously in other malignancies. Hierarchical clustering of all samples separated GISTs and leiomyosarcomas into two distinct clusters. Statistical analysis identified six chromosomal regions, 1p36.11-p13.1, 9q21.11-9q34.3, 14q11.2-q23.2, 14q31.3-q32.33, 15q24.3-q26.3, and 22q11.21-q13.31, which were significantly different in copy number between GISTs and leiomyosarcomas. Our results show the potential of using array comparative genomic hybridization to classify histologically similar tumors such as GISTs and leiomyosarcomas.     

Molecular cytogenetic characterization of head and neck squamous cell carcinoma and refinement of 3q amplification

We applied a combination of molecular cytogenetic methods, including comparative genomic hybridization (CGH), spectral karyotyping (SKY), and fluorescence in situ hybridization, to characterize the genetic aberrations in a panel of 11 cell lines derived from head and neck squamous cell carcinoma and 1 cell line derived from premalignant oral epithelium. CGH identified recurrent chromosomal losses at 1p, 3p, 4, 8p, 10p, and 18q; gains at 3q, 5p, 8q, 9q, and 14q; and high-level amplification at 3q13, 3q25-q26, 5q22-q23, 7q21, 8q24, 11q13-q14, 12p13, 14q24, and 20q13.1. Several recurrent translocations including t(1;13)(q10;q10), t(13;13)(q10;q10), t(14;14)(q10;q10), i(8)(q10), and i(9)(q10) and breakpoint clusters at 1p11, 1q21, 3p11, 5q11, 5q13, 6q23, 8p11, 8q11, 9p13, 9q13, 10q11, 11q13, 13q10, 14q10, and 15q10 were identified by SKY. There was a good correlation between the number of aberrations identified by CGH and SKY (r = 0.69), and the analyses were both confirmatory and complementary in their assessment of genetic aberrations. Amplification at 3q26-q27 was identified in 42% of cases. Although SKY defined the derivation of 3q gain, the precise breakpoint remained unassigned. Positional cloning efforts directed at the amplified region at 3q26-q27 identified three highly overlapping nonchimeric yeast artificial chromosome clones containing the apex of amplification. The use of these yeast artificial chromosome clones as a probe for fluorescence in situ hybridization analysis allowed a detailed characterization and quantification of the 3q amplification and refinement of unassigned SKY breakpoints.