Expression analysis of 6p22 genomic gain in retinoblastoma

To identify gene(s) targeted by 6p22 genomic gain, present in more than 50% retinoblastoma tumors, we used real-time RT-PCR to quantify the expression of seven genes in normal human retina and retinoblastoma. Six genes are located in the quantitative multiplex PCR-defined 0.6 Mb minimal region of gain at 6p22 (DEK, AOF1, TPMT, NHLRC1, KIF13A, and NUP153), and E2F3 is 2 Mb away from the minimal region of gain on 6p22. E2F3, DEK, KIF13A, and NUP153 were most frequently overexpressed in retinoblastoma with 6p genomic gain, compared with the normal adult human retina. E2F3 and DEK mRNA levels were increased in all human tumors showing 6p22 gain, as well as in mouse retinoblastoma induced by SV40 large T antigen expression in developing retina, compared with the normal controls (adult human retina and 7-day-old mouse retina, respectively). Only DEK showed statistically significant correlation of expression and genomic copy number (P = 0.019). E2F3 and DEK, but not NUP153, showed developmental regulation. E2F3 and DEK mRNA overexpression was always associated with protein overexpression, determined by immunoblotting or immunofluorescent staining of primary tumors, relative to the adjacent normal retina. E2F3 was strongly expressed in actively proliferating cells, while DEK was overexpressed in all tumor cells. Taking into account the proliferation-promoting role of E2F3, implication of E2F3 in bladder and prostate cancer, and the translocation and overexpression of DEK in leukemia, we conclude that either DEK or E2F3 (or both) are targeted by the 6p22 gain in retinoblastoma.     

Minimal regions of chromosomal imbalance in retinoblastoma detected by comparative genomic hybridization

Mutation of both alleles of the retinoblastoma gene (RB1) initiate oncogenesis in developing human retina, but other common genomic alterations are present in the tumors. In order to sublocalize the altered genomic regions, 50 retinoblastoma tumors were examined by comparative genomic hybridization (CGH). The minimal regions most frequent gained were 1q31 (52%), 6p22 (44%), 2p24-p25 (30%) and 13q32-q34 (12%). The minimal region most frequently lost was 16q22 (14%). The overall total number of gains or losses evident on CGH was significantly greater in those tumors with either or both 6p or 1q gain, than in tumors with neither 6p nor 1q gain suggesting that chromosomal instability may be associated with acquisition of these changes. Genes mapping to 6p22 and 1q31 may be important in tumor development in retina subsequent to the loss of RB1 alleles.     

One hit,two hits,three hits,more? Genomic changes in the development of retinoblastoma

The childhood eye cancer retinoblastoma is initiated by the loss of both alleles of the prototypic tumor suppressor gene, RB1. However, a large number of cytogenetic and comparative genomic hybridization (CGH) studies have shown that these M1 and M2 mutational events--although necessary for initiation--are not the only genomic changes in retinoblastoma. Some of these subsequent changes, which we have termed M3 to Mn, are likely crucial for tumor progression not only in retinoblastoma but also in other cancers. Moreover, genes showing genomic change in cancer are more stable markers and, therefore, possible therapeutic targets than genes simply differentially expressed. In this review, we provide the first comprehensive summary of the genomic evidence implicating gain of 1q, 2p, 6p, and 13q, and loss of 16q in retinoblastoma oncogenesis, including karyotype, CGH, and microarray CGH data. We discuss the search for candidate oncogenes and tumor suppressor genes within these regions, including the candidates (KIF14, MDM4, MYCN, E2F3, DEK, CDH11, and others), plus associations between genomic changes and clinical parameters. We also review studies of other regions of the retinoblastoma genome, the epigenetic changes of aberrant methylation of MGMT, RASSF1A, CASP8, and MLH1, and the roles microRNAs might play in this cancer. Although many candidate genes have yet to be functionally validated in retinoblastoma, work in this field lays out a molecular cytogenetic pathway of retinoblastoma development. Candidate cancer genes carry diagnostic, prognostic, and therapeutic implications beyond retinoblastoma.     

Detection of single-copy chromosome 17q gain in human neuroblastomas using real-time quantitative polymerase chain reaction.

Regional genomic alterations resulting from single-copy allelic loss or gain have been well characterized in many human cancers and are often of prognostic relevance. Unbalanced gain of 17q material is common in malignant human neuroblastomas and typically results from unbalanced translocations. Unbalanced 17q gain may be an independent predictor of disease outcome, but technical difficulties with quantifying such gain using fluorescent in situ hybridization gives this method limited clinical applicability. We now describe a duplex genomic DNA-based quantitative polymerase chain reaction assay to determine the presence or absence of unbalanced gain of chromosome 17q in primary neuroblastoma specimens. The technique was first refined and validated in a panel of nine human neuroblastoma-derived cell lines by direct comparison with dual-color fluorescent in situ hybridization. Prospective blinded comparison of quantitative polymerase chain reaction and fluorescence in situ hybridization in 40 human neuroblastoma primary tumor samples showed a sensitivity of 96% and 100% specificity for detecting unbalanced 17q gain when a relative 17q copy number ratio of 1.3 was used to define unbalanced gain. Tumors with ratios >1.3 were highly associated with malignant tumor phenotypic features such as metastatic disease (P <.0001) and tumor MYCN amplification (P =.008). These data suggest that quantitative polymerase chain reaction determination of 17q status is feasible and highly specific in primary tumor samples. Sensitivity may be limited because of the inherent complexity of both the chromosomal rearrangements and heterogeneity of some tumor samples. Taken together, quantitative polymerase chain reaction can be used as a high-throughput screening tool for 17q aberrations, but a subset of samples may also require fluorescence in situ hybridization analysis in an attempt to conclusively determine 17q allelic status.     

MYCN amplification and 17q in neuroblastoma: evidence for structural association

MYCN oncogene amplification in neuroblastoma is statistically associated with gain of chromosome segment 17q21-qter. In neuroblastoma cell lines and primary tumors with MYCN amplification in the form of homogeneously staining regions (hsrs), juxtaposition of chromosome 17 material with MYCN sequences has occasionally been reported, raising the possibility of a physical affinity between MYCN and chromosome arm 17q. We used FISH to test for association between chromosome 17 segments and MYCN in eight neuroblastoma cell lines and two neuroblastoma primary tumors known to include hsrs. Evidence of an association was found in the chromosomes of both primary tumors; in one, a MYCN hsr was inserted into a structurally abnormal chromosome 17, in the other, an hsr in 16p was shown to be flanked by 17 material. In cell line NCG, hsrs in 4q and 16p were flanked by 17q material. These observations confirm the juxtaposition of 17q material with MYCN sequences in some neuroblastomas, and imply that there may be a physical or functional relationship between these two features in MYCN amplified neuroblastoma.     

Novel 6p rearrangements and recurrent translocation breakpoints in retinoblastoma cell lines identified by spectral karyotyping and mBAND analyses

Gain of the short arm of chromosome 6, usually through isochromosome 6p formation, is present in approximately 50% of retinoblastoma tumors. The minimal region of gain maps to chromosome band 6p22. Two genes, DEK and E2F3, are implicated as candidate oncogenes. However, chromosomal translocations have been overlooked as a potential mechanism of activation of oncogenes at 6p22 in retinoblastoma. Here, we report combined spectral karyotyping), 4',6-diamidino-2-phenylindole banding, mBAND, and locus-specific fluorescence in situ hybridization analyses of four retinoblastoma cell lines, RB1021, RB247c, RB383, and Y79. In RB1021 and RB247c, 6p undergoes structural rearrangements involving a common translocation breakpoint at 6p22. These data imply that 6p translocations may represent another mechanism of activation of 6p oncogene(s) in a subset of retinoblastomas, besides the copy number increase. In addition to 6p22, other recurrent translocation breakpoints identified in this study are 4p16, 11p15, 17q21.3, and 20q13. Common regions of gain map to chromosomal arms 1q, 2p, 6p, 17q, and 21q.     

Comparative genomic hybridization reveals complex genetic changes in primary breast cancer tumors and their cell lines

DNA copy number changes were characterized by comparative genomic hybridization (CGH) in 18 breast cancer cell lines. In 5 of these, the results were comparable with those from the primary tumors of which the cell lines were established. All of the cell lines showed extensive DNA copy number changes, with a mean of 16.3 +/- 1.1 aberrations per sample (range 7-26). All of the cell lines had a gain at 8q22-qter. Other common gains of DNA sequences occurred at 1q31-32 (89%), 20q12-q13.2 (83%), 8q13 (72%), 3q26.1-qter (67%), 17q21-qter (67%) 5p14 (61%), 6p22 (56%), and 22pter-qter (50%). High-level amplifications were observed in all cell lines; the most frequent minimal common regions were 8q24.1 (89%), 20q12 (61%), 1q41 (39%), and 20p11.2 (28%). Losses were observed less frequently than gains and the minimal common regions of the most frequent losses were Xq11-q12 (56%), Xp11.2-pter (50%), 13q21 (50%), 8p12-pter (44%), 4p13-p14 (39%), 6q15-q22 (39%), and 18q11.2-qter (33%). Although the cell lines showed more DNA copy number changes than the primary tumors, all aberrations, except one found in a primary tumor, were always present in the corresponding cell line. High-level amplifications found both in primary tumors and cell lines were at 1q, 8q, 17q, and 20q. The DNA copy number changes detected in these cell lines can be valuable in investigation of tumor progression in vitro and for a more detailed mapping and isolation of genes implicated in breast cancer.     

Gain of chromosome 17 is the most frequent abnormality detected in neuroblastoma by comparative genomic hybridization.

Neuroblastoma behavior is variable and outcome partially depends on genetic factors. However, tumors that lack high-risk factors such as MYCN amplification or 1p deletion may progress, possibly due to other genetic aberrations. Comparative genomic hybridization summarizes DNA copy number abnormalities in a tumor by mapping them to their positions on normal metaphase chromosomes. We analyzed 29 tumors from nearly equal proportions of children with stage I, II, III, IV, and IV-S disease by comparative genomic hybridization. We found two classes of copy number abnormalities: whole chromosome and partial chromosome. Whole chromosome losses were frequent at 11, 14, and X. The most frequent partial chromosome losses were on 1p and 11q. Gains were most frequent on chromosome 17 (72% of cases). The two patterns of gain for this chromosome were whole 17 gain and 17q gain, with 17q21-qter as a minimal common region of gain. Other common gains were on chromosomes 7, 6, and 18. High level amplifications were detected at 2p23-25 (MYCN region), at 4q33-35, and at 6p11-22. Chromosome 17q gains were associated with 1p and/or 11q deletions and advanced stage. The high frequency of chromosome 17 gain and its association with bad prognostic factors suggest an important role for this chromosome in the development of neuroblastoma.     

Analysis by comparative genomic hybridization of gastric cancer with peritoneal dissemination and/or positive peritoneal cytology

Peritoneal metastasis is an important prognostic factor in cases of gastric cancer. Although studies on comparative genomic hybridization (CGH) in gastric cancer have been reported, there are few reports on the peritoneal metastasis (P) and peritoneal cytology (CY) factors in this cancer. In this study, we analyzed the chromosomal changes in the primary tumor with a combination of laser microdissection analysis and CGH in an attempt to detect the unknown abnormal chromosomal regions. We analyzed 34 primary tumors, including 13 primary tumors with peritoneal metastasis (P1) and/or positive peritoneal cytology (CY1) using a combination of laser microdissection and CGH. The minimal overlapping regions in gains were assigned to 5p14 (46.2%), 7q21.3 (61.5%), 7q31 (46.2%), 7q36 (46.2%), 8q23 (53.8%), 15q26 (46.2%), 20q12 (61.5%), 20q13.1 (53.8%), and 20q13.2 (53.8%) in primary tumors with P1 and/or CY1. The minimal regions of losses that occurred most frequently were 4q34-q35 (23.1%) and 22q11.2 (23.1%). There were significant differences in the minimal regions of 5p14 (P=0.033), 7q21.3 (P < 0.0001), 7q31 (P=0.013), 7q36 (P=0.033), and 22q11.2 (P=0.048) between primary tumors with and without P1 and/or CY1. In this study, gain/amplification of 5p14, 7q21.3, 7q31, and 7q36, and loss of 22q11.2 were significant in gastric cancer cases with peritoneal dissemination and/or positive peritoneal cytology.     

20q11.1 amplification in giant-cell tumor of bone: Array CGH, FISH, and association with outcome

The goal of this study was to identify recurrent regions of genomic gain or loss in giant-cell tumor of bone (GCTb). Array comparative genomic hybridization (aCGH) was performed for 20 frozen tumor samples of GCTb. A separate subset of 59 GCTb with outcome data was used for validation. The most frequent region of change identified by aCGH was gain of a 1-Mbp region at 20q11.1. In the validation arm of 59 cases the minimal common region of copy number gain at 20q11.1, seen in 54% of the samples, was BAC clone RP11-4O9, which contained the genes TPX2 and BCL2L1. For most cases, amplification was restricted to the mononuclear component and was not present in the multinucleated giant cells. Southern blot for TPX2 and BCL2L1 identified the former as the gene with the highest level of amplification for these two proposed candidate genes of importance. Immunohistochemistry for TPX2 expression correlated with amplification, while BCL2L1 expression was not identified. Kaplan-Meier curves for progression-free survival showed a statistically significant difference for cases with 20q11.1 amplification (P = 0.0001). Univariate analysis involving Cox proportional hazards models did not show a significant difference for initial treatment type (curettage versus resection) (P = 0.575), age (50) (P = 0.543), or sex (P = 0.268), but did correlate with 20q11.1 amplification (P = 0.001). By multivariate analysis, it was found that 20q11.1 amplification (P = 0.001) was the only factor to reach statistical significance. 20q11.1 amplification can be used as a marker of prognostic importance in GCTb. We propose TPX2 as a candidate oncogene in the core-amplified region at 20q11.1.     

Clinical significance of genetic imbalances revealed by comparative genomic hybridization in chondrosarcomas.

DNA copy number changes were studied by comparative genomic hybridization (CGH) in 50 chondrosarcoma samples from 45 patients. Mean number of genetic aberrations in primary tumors was 4.8 +/- 1.8. The most frequently gained regions were 20q12-qter (37%), 20q (32%), 8q24.1-qter (27%), 20p (24%), and 14q24-qter (24%). Losses were 5.5 times less frequent than gains and observed mainly at Xcen-q21, 6cen-q22, and 18cen-q11.2 (11% each). Recurrent and metastatic tumors showed a mean of 4.0 +/- 2.2 aberrations per sample. The most frequently gained regions were chromosome 7 (4 cases), 5q14-q32 (4 cases), 6p (3 cases), and 12q (3 cases). Losses of DNA sequences were 3.4 times less frequent than gains. Histological tumor grade was significantly associated with metastasis-free survival (P = .002) and overall survival (P = .003), being the strongest prognostic factor tested. A statistically significant correlation was found between gain at 8q24.1-qter and shorter overall survival (P = .01) but not with local recurrence or metastasis-free survival. Gain at 14q24-qter was associated with a trend to shorter overall survival (P = .05) but neither with an increased risk for local recurrence nor with metastasis-free survival. In a multivariate analysis, only the tumor grade associated with overall survival (P = .02). In a multivariate analysis together with the tumor grade, gain at 8q24.1-qter did not retain its significance (P = .44), indicating that this imbalance is not an independent prognostic factor.     

Comparative genomic hybridization in inherited and sporadic ovarian tumors in Israel

To gain an understanding of the molecular mechanisms of ovarian cancer, we analyzed 16 ovarian tumors from Jewish Israeli patients by comparative genomic hybridization: 12 invasive epithelial tumors (including three BRCA1 and one BRCA2 mutation carriers), 2 primary peritoneal carcinomatosis, 1 pseudomyxoma peritoneii tumor, and 1 sertoli cell tumor. We similarly analyzed 1 normal ovary from a BRCA1 mutation carrier, and 3 metastases. The most common abnormalities in epithelial tumors were amplification of 8q22.1-ter (8/12, 66.6%), 1q22-32.1 (5/12, 41.6%), 3q, 10p (4/12, 33.3% for each), and deletions of 9q (5/12, 41.6%) and 16q21-24 (4/12, 33.3%). All 3 BRCA1 mutation carriers and 2 of 8 sporadic cases displayed 9q deletion, and 2 of 3 BRCA1 mutation carriers, but none of the sporadic cases, had deletion of chromosome 19. The range of genetic changes in primary peritoneal tumors and epithelial ovarian cancers was similar, though the mean number of alterations in the former was less (3.5/tumor versus 8/tumor). Our preliminary results may indicate that inherited predisposition to ovarian cancer possibly entails preferential somatic deletions of chromosomes 9 and 19.     

Molecular cytogenetic abnormalities in multiple myeloma and plasma cell leukemia measured using comparative genomic hybridization

Comparative genomic hybridization (CGH) was used to identify recurrent regions of DNA sequence loss and gain in 21 multiple myeloma (MM) and plasma cell leukemia (PCL) primary tumor specimens and cell lines. Multiple regions of non-random sequence loss and gain were observed in 8/8 primary advanced stage tumors and 13/13 cell lines. Identification of sequence copy number changes was facilitated by statistical analyses that reduce subjectivity associated with identification of copy number changes and by requiring that sequence changes are visible using both red- and green-labeled tumor DNA. Loss of sequence on 13q and 14q and gain of sequence on 1q and chromosome 7 occurred in 50–60% of the population. In general, cell lines carry more and larger regions of sequence gain and loss than primary tumors. Regions of sequence copy number change that recur among MM cell lines and primary tumors include, in order of prevalence, enh(1q12qter), dim(13), enh(7), enh(3q22q29), enh(11q13.3qter), dim(14q11.2q31), enh(8q21qter), enh(3p25pter), dim(17p11.2p13), and dim(6q22.1q23). Population distributions of genome-wide changes in primary tumors reveal “hot-spots” of sequence loss from 13q12.1-q21, 13q32-q34, 14q11.2-q13, and 14q23-q31. Genomic changes detected using CGH are consistent with those identified using banding analyses, although recurrent involvement of additional regions of the genome are also evident. A higher prevalence of genomic changes is visible using CGH compared to banding. Identification of recurrent regions of sequence gain and loss provides opportunities to identify regions of the genome that may be involved in the malignant phenotype and/or disease progression. Genes Chromosom. Cancer 19:124–133, 1997. © 1997 Wiley-Liss, Inc.     

Clinical correlations of genetic changes by comparative genomic hybridization in Ewing sarcoma and related tumors.

Our previous comparative genomic hybridization (CGH) study of Ewing sarcoma and related tumors showed that DNA sequence copy number increases of 1q21-q22 and of chromosomes 8 and 12 were associated with trends toward poor survival (Armengol et al., Br J Cancer 1997, 75, 1403-1409). These trends were not statistically significant. In the present study, we analyzed 28 primary Ewing sarcomas and related tumors by CGH to study whether these (or other) changes have prognostic value in these tumors. Twenty-one tumors (75%) had changes with a mean of 1.9 changes per tumor. The most frequent aberration was gain of chromosome 8 in 10 tumors (36%). Five tumors (18%) had copy number increases at 1q21-22 and 5 had gain of 7q. Copy number increase of 6p21.1-pter, gain of chromosome 12, and loss of 16q were seen in 11%. Copy number increases of 1q21-q22 and of chromosomes 8 and 12 were associated with trends toward worse outcome, but the differences did not reach statistical significance. A novel finding is the association of copy number increase at 6p with worse distant disease-free (P = 0.04) and overall survival (P = 0.004). To confirm this finding and to see whether copy number increases of 1q21-q22 and of chromosomes 8 and 12 have definite prognostic value, a larger number of cases needs to be studied.     

High-resolution array comparative genomic hybridization analysis of human bronchial and salivary adenoid cystic carcinoma

Adenoid cystic carcinoma (ACC) is a rare but distinctive tumor. Oligonucleotide array comparative genomic hybridization has been applied for cataloging genomic copy number alterations (CNAs) in 17 frozen salivary or bronchial tumors. Only four whole chromosome CNAs were found, and most cases had 2-4 segmental CNAs. No high level amplification was observed. There were recurrent gains at 7p15.2, 17q21-25, and 22q11-13, and recurrent losses at 1p35, 6q22-25, 8q12-13, 9p21, 12q12-13, and 17p11-13. The minimal region of gain at 7p15.2 contained the HOXA cluster. The minimal common regions of deletions contained the CDKN2A/CDKN2B, TP53, and LIMA1 tumor suppressor genes. The recurrent deletion at 8q12.3-13.1 contained no straightforward tumor suppressor gene, but the MIRN124A2 microRNA gene, whose product regulates MMP2 and CDK6. Among unique CNAs, gains harbored CCND1, KIT/PDGFRA/KDR, MDM2, and JAK2. The CNAs involving CCND1, MDM2, KIT, CDKN2A/2B, and TP53 were validated by FISH and/or multiplex ligation-dependent probe amplification. Although most tumors overexpressed cyclin D1 compared with surrounding glands, the only case to overexpress MDM2 had the corresponding CNA. In conclusion, our report suggests that ACC is characterized by a relatively low level of structural complexity. Array CGH and immunohistochemical data implicate MDM2 as the oncogene targeted at 12q15. The gain at 4q12 warrants further exploration as it contains a cluster of receptor kinase genes (KIT/PDGFRA/KDR), whose products can be responsive to specific therapies.     

Comparative genomic hybridization of malignant fibrous histiocytoma reveals a novel prognostic marker.

DNA sequence copy number changes were studied by comparative genomic hybridization (CGH) along all chromosomes in 58 samples of malignant fibrous histiocytoma (MFH). The material consisted of 43 primary tumors (9 of myxoid and 34 of storiform-pleomorphic subtype), 13 local recurrences (2 myxoid and 11 storiform-pleomorphic), and 2 metastases (1 myxoid and 1 storiform-pleomorphic). Genetic aberrations, with a mean of 5.5 changes per sample (range, 0 to 22), were detected in 47 of 58 samples (81%). The minimal common regions of the most frequent gains were 1p31 (33%), 9q31 (29%), 5p14-pter (26%), 7q32 (24%), and 7p15-pter (22%). High-level amplifications were detected in 16 of the 58 samples (28%). High-level amplification of 13q31-qter was seen in four tumors (7%); other high-level amplifications were more sporadic. Losses of DNA sequences were less frequent than gains. The minimal common regions of the most common losses were 13q21 (21%) and 13q22 (21%). Statistically significant correlation was found between gain of 7q32 and the rates of worse metastasis-free survival (P = 0.01) and overall survival (P = 0.004). The gain of 7q32 retained its prognostic significance also in a multivariate analysis with tumor size and grade. Gain of 1p31 was associated with a trend to decreased overall survival. Gains of 5p14-pter and 9q31 and losses of 13q21 and/or 13q22 did not have any prognostic value; neither did the total number of aberrations, total number of gains, or total number of losses per sample.     

A novel and consistent amplicon at 13q31 associated with alveolar rhabdomyosarcoma

Rhabdomyosarcomas are the most common soft-tissue sarcoma found in children. The alveolar subtype is clinically more aggressive than the embryonal subtype. In addition to the presence of specific chromosome translocations and associated fusion gene products in a high proportion of the alveolar subtype, we previously showed that tumors with this histology frequently show evidence of genomic amplification. Here, we substantially extended the number of alveolar rhabdomyosarcoma samples examined by comparative genomic hybridization analysis. Regions of loss were noted, including the smallest overlapping regions corresponding to 16q, 17/17p, and 9q32-34, in 16%, 10%, and 10% of cases, respectively (44 primary samples/6 cell lines). Amplification or gain at 12q13-15 in the region of the MDM2/GLI1/SAS/CDK4 loci and 2p24 at the MYCN locus was found in 28% and 32% of cases, respectively. Single amplicons were found at locations that in other samples showed consistent gain, including the regions 5q15-23, 7q21-31, 11p11-14, 17q23-24, and 20q13, and amplification was found in two cases at 15q24-26. However, most striking was a novel region of amplification or gain at 13q31 in 19% of cases (51 primary samples/6 cell lines). This indicates that a gene or genes at 13q31 are significant in the development or progression of alveolar rhabdomyosarcoma.