Analysis of ovarian borderline tumors using comparative genomic hybridization and fluorescence in situ hybridization.

It is unclear whether ovarian borderline tumors (tumors of low malignant potential) are independent entities or whether they are part of a continuum of tumor progression that culminates in ovarian carcinoma. Little is known about genetic abnormalities in borderline tumors because of the difficulty of growing them in culture for chromosome studies, and because the low ratio of tumor to nontumor cells can interfere with molecular genetic examination. To circumvent these problems, we performed comparative genomic hybridization (CGH) on 10 serous borderline tumors from nine patients, using microdissection to enrich the samples for tumor DNA and reduce contamination from stromal and inflammatory cells. CGH analysis revealed that three of the tumors had detectable chromosomal imbalances, whereas seven were in a balanced state. In those tumors with imbalances, the number of abnormalities ranged from 3-6 per tumor. Additional studies by fluorescence in situ hybridization (FISH) on disaggregated nuclei confirmed the imbalances detected by CGH, revealed one tumor to be hypertriploid, and indicated that the remaining tumors were diploid and in a balanced state. All abnormalities observed in the aneuploid cases are consistent with chromosomal aberrations previously reported for ovarian carinomas, providing further evidence that some borderline tumors are part of a continuum of tumor progression. These results also suggest that there may be different mechanisms leading to borderline tumor formation, including one associated with multiple chromosomal imbalances, and others that do not involve imbalances detectable by CGH. Genes Chromosomes Cancer 25:307-315, 1999.     

Pancreatic acinar carcinoma shows a distinct pattern of chromosomal imbalances by comparative genomic hybridization

Pancreatic acinar cell carcinoma (PAC) is a rare pancreatic tumor for which no information about chromosomal anomalies is available. We examined six primary PACs by comparative genomic hybridization (CGH). All cases showed chromosomal changes. A total of 106 gains and 48 losses was detected. Consensus regions of gain were identified on chromosomes 1, 12, and X: 1q21 in four cases, 1q42 in three cases, 12p11.2 in four cases, and Xq12-21 in three cases. Recurrent losses were found at 16p13.2-p13.1 in three cases and at 16q23 in three cases. To verify these chromosomal imbalances, microsatellite analysis of matched normal and tumor DNA was performed using PCR-amplified markers for chromosomes 1, 12, and 16 in the regions showing nonrandom gains or losses. This analysis showed allelic imbalances in tumor DNA consistent with the CGH profiles. Our CGH study suggests that PAC shows a characteristic pattern of chromosomal alterations, involving gain at 1q, 12p, and Xq and loss of sequences at 16p and 16q. This pattern appears unique among solid tumors and is markedly different from that detected in pancreatic ductal carcinomas by the same technique. This suggests that PAC tumorigenesis involves different molecular pathways than those involved in the more common pancreatic ductal tumors. Genes Chromosomes Cancer 28:294-299, 2000.     

Patterns of aneuploidy in stage IV clear cell renal cell carcinoma revealed by comparative genomic hybridization and spectral karyotyping

We report the use of spectral karyotyping (SKY) and comparative genomic hybridization (CGH) to describe the numerous genomic imbalances characteristic of stage IV clear cell renal cell carcinoma (CCRCC). SKY and CGH were performed on 10 cell lines established from nephrectomy specimens, and CGH on uncultured material from five of the primary renal tumors. The mutational status of VHL (3p25) and MET (7q31), genes implicated in renal carcinogenesis, were determined for each case. Each case showed marked aneuploidy, with an average number of copy alterations of 14.6 (+/-2.7) in the primary tumors and 19.3 (+/-4.6) in the cell lines. Both whole-chromosome and chromosome-segment imbalances were noted by CGH: consistent losses or gains included +5q23-->ter (100%), -3p14-->ter (80%), and +7 (70%). All VHL mutations and 83% of the genomic imbalances found in the primary tumors were also found in the cell lines derived from them. SKY showed many complex structural rearrangements that were undetected by conventional banding analysis in these solid tumors. All cases with VHL inactivation had 3p loss and 5q gain related primarily to unbalanced translocations between 3p and 5q. In contrast, gains of chromosome 7 resulted primarily from whole-chromosome gains and were not associated with mutations of MET. SKY and CGH demonstrated that genomic imbalances in advanced RCC were the result of either segregation errors [i.e., whole chromosomal gains and losses (7.8/case)] or chromosomal rearrangements (10.7/case), of which the majority were unbalanced translocations.     

Analysis of microsatellite instability and X-inactivation in ovarian borderline tumors lacking numerical abnormalities by comparative genomic hybridization

The genetic events underlying development of ovarian borderline tumors (tumors of low malignant potential) are not well understood. In our previous studies of microdissected samples from serous borderline tumors, comparative genomic hybridization (CGH) and/or fluorescence in situ hybridization (FISH) analyses showed that 3 of 13 tumors had detectable numerical abnormalities; the remaining 10 had none. In the present study, we examined microsatellite instability (MSI) and clonality in this same set of tumors. Although absence of chromosomal imbalances has been associated with the presence of MSI in some types of solid tumors, the extent of MSI in borderline tumors, and its role in their pathogenesis, is unclear. In our set of 13 tumors, no MSI was detected despite analysis with microsatellite markers recommended by the National Cancer Institute for assessment of MSI. Quantitative X-inactivation studies were informative at the androgen receptor gene AR in 9 of the 13 tumors and revealed that each of the 9 tumors was clonal. In two patients, bilateral tumors showed identical patterns of skewed X-inactivation. These studies confirm the clonality of borderline tumors and suggest that some borderline tumors may develop through mechanisms other than chromosomal imbalances or microsatellite instability.     

软组织肿瘤的比较基因组杂交研究进展

比较基因组杂交(comparative genomic hybridization,CGH) 是1992年建立起来的重大分子细胞遗传学分析技术,它在对整个基因组DNA拷贝数变异的检测方面是一种有效的方法。通过CGH检测,可找出染色体DNA拷贝数的变异特点,即基因拷贝数的扩增或丢失,从而确定相关的癌基因和抑癌基因所在的区域,为探讨肿瘤的发病机制提供依据。在过去的十几年中,用CGH对各种软组织肿瘤进行研究,已探测到了各种各样的有不同程度特异性的基因组的不平衡性,不仅开辟了探测各种癌症相关基因的新途径,并且找到了一些与临床相关的基因改变,可用于肿瘤的发生、发展、鉴别诊断、预后以及治疗等研究。     

Analysis of chromosomal imbalances in sporadic and NF1-associated peripheral nerve sheath tumors by comparative genomic hybridization.

Peripheral nerve sheath tumors arise either sporadically or in association with neurofibromatosis type 1 (von Recklinghausen's neurofibromatosis, NF1) or type 2. In this study, comprehensive screening for relative chromosome copy number changes was performed on 10 benign and 19 malignant peripheral nerve sheath tumors (MPNSTs) by applying comparative genomic hybridization (CGH). In benign tumors, no chromosomal imbalances were found by CGH, whereas in MPNSTs chromosomal gains and losses were frequently detected. No differences regarding the frequency and distribution of chromosomal imbalances were observed between the 13 sporadic and 6 NF1-associated MPNSTs analyzed. In both, the number of gains was significantly higher than the number of losses, suggesting a predominant role of proto-oncogene activation during MPNST progression. Candidate regions with potentially relevant proto-oncogenes included chromosomal bands 17q24-q25, 7p11-p13, 5p15, 8q22-q24, and 12q21-q24; those with putative tumor suppressor genes were 9p21-p24, 13q14-q22, and 1p. High-level amplifications were restricted to sporadic tumors and affected eight different chromosomal subregions. In three of these MPNSTs, identical subregions on chromosomal arms 5p and 12q were coamplified. This study revealed a number of new characteristic chromosomal imbalances and provides a basis for molecular identification of oncogenes and tumor suppressor genes of pathogenetic relevance in both sporadic and NF1-associated MPNSTs. Genes Chromosomes Cancer 25:362-369, 1999.     

比较基因组杂交技术的应用

肿瘤发生和发育畸形与染色体的不平衡有关,包括染色体的扩增和缺失.常规的比较基因组杂交技术(conventional comparative genomic hybridization)由于能在一次试验中掌握整个基因组DNA拷贝数的变化并可以将此改变准确的定位于染色体,因而在探讨肿瘤的发生和生长发育畸形机理的研究方面得到了广泛的应用.在此基础上发展起来的微阵列比较基因组杂交技术(microarray CGH/ array-based CGH),为精确、定量地研究人类基因组微缺失和微扩增及其定位提供了有力工具.本文综述了CGH和CGHa 技术的原理及应用.     

Detection of chromosomal imbalances in transitional cell carcinoma of the bladder by comparative genomic hybridization.

Comparative genomic hybridization (CGH) was applied for a comprehensive screening of chromosomal aberrations in 14 transitional cell carcinomas of the bladder of different grade and stage. The results were compared in a number of selected cases with those obtained by restriction fragment length polymorphism analyses and targeted fluorescence in situ hybridization. Distinct amplifications, found with CGH, were located on 3p22-24, 10p13-14, 12q13-15, 17q22-23, 18p11, and 22q11-13. These high copy number amplifications and the frequency of imbalances involving chromosome 5, occurring in 4 of 14 cases, have not yet been identified in transitional cell carcinomas. Apart from these new aberrations, imbalances were detected in 3 or more cases for chromosomes 9 and 11, as already described previously in the literature. In four tumors, the copy number of specific chromosomal regions was also analyzed by interphase cytogenetics. Although in most instances the CGH data were confirmed, in one tumor, distinct differences were observed, possibly a result of heterogeneity of the tumor cell population. Furthermore, the CGH data were compared with loss of heterozygosity as revealed by restriction fragment length polymorphism analysis in the same tumors. In 80% of informative cases, no loss was detected by restriction fragment length polymorphism or by CGH. Of the 15 cases of loss of heterozygosity, 7 showed a loss also with CGH, whereas in 8 cases no loss was observed. In summary, CGH is a fast method to obtain a comprehensive picture of chromosomal imbalances in transitional cell carcinomas, including a number of previously unknown genomic alterations such as high level amplifications.     

Chromosome 7 abnormalities are common in chordomas

Chordomas are malignant bone tumors most often located in the axial skeleton. The estimated 5-year patient survival rate is between 50 and 80%. The cytogenetic and molecular genetic features of chordomas are largely unknown but, from what can be seen, appear to be complex. Near-diploid karyotypes have been detected by G-banding analysis, and comparative genomic hybridization (CGH) has revealed losses of or from chromosome arms 1p and 3p, as well as partial or whole copy number gains of chromosomes 7 and 20. We provide additional molecular cytogenetic information about six sacral chordomas examined by CGH and interphase fluorescence in situ hybridization (IP-FISH). By CGH, gains of chromosomal areas 1q23 approximately q24 (three tumors), 7p21 approximately p22 (three tumors), 7q (four tumors), and 19p13 (three tumors), as well as loss of chromosomal segment 9p22 approximately p23 (three tumors), were the most frequently observed imbalances. These results are concordant with earlier CGH data, although loss of or from chromosome arms 1p and 3p was not found as frequently in this series; both were detected in only one tumor. IP-FISH confirmed the CGH findings and showed that chromosome 7 was polysomic in four of the tumors. All these samples had trisomic and tetrasomic clones for chromosome 7, and two of them had pentasomic clones as well.     

Construction and application of a zebrafish array comparative genomic hybridization platform

The zebrafish is emerging as a prominent model system for studying the genetics of human development and disease. Genetic alterations that underlie each mutant model can exist in the form of single base changes, balanced chromosomal rearrangements, or genetic imbalances. To detect genetic imbalances in an unbiased genome-wide fashion, array comparative genomic hybridization (CGH) can be used. We have developed a 5-Mb resolution array CGH platform specifically for the zebrafish. This platform contains 286 bacterial artificial chromosome (BAC) clones, enriched for orthologous sequences of human oncogenes and tumor suppressor genes. Each BAC clone has been end-sequenced and cytogenetically assigned to a specific location within the zebrafish genome, allowing for ease of integration of array CGH data with the current version of the genome assembly. This platform has been applied to three zebrafish cancer models. Significant genomic imbalances were detected in each model, identifying different regions that may potentially play a role in tumorigenesis. Hence, this platform should be a useful resource for genetic dissection of additional zebrafish developmental and disease models as well as a benchmark for future array CGH platform development.     

Mapping of chromosomal gains and losses in prostate cancer by comparative genomic hybridization

Comparative genomic hybridization (CGH) allows detection of chromosomal imbalances in whole genomes in a comprehensive manner. With this approach, ten cases of prostate cancer (seven primary tumors and three metastases) were analyzed. Frequent chromosomal gains detected by CGH involved chromosome arms 7q, 8q, 9q, and 16p, and chromosomes 20 and 22, as well as frequent losses of chromosome arms 16q and 18q, in at least three of the ten cases. Overrepresentation of chromosome arm 9q has not been described in published reports. The CGH data were compared with results of a loss of heterozygosity (LOH) study, in which complete allelotyping was performed in the same prostate tumors with 74 different polymorphic markers. In general, a high concordance between the CGH and LOH results was observed (92%). Tumors revealing discrepancies by CGH and LOH analysis were investigated further by interphase cytogenetics, and the resulting picture regarding the genomic alterations is discussed in detail.     

Detection of chromosomal DNA gains and losses in testicular germ cell tumors by comparative genomic hybridization

To extend the results of conventional cytogenetic analysis of testicular germ cell tumors (TGCTs), we applied the new molecular cytogenetic method of comparative genomic hybridization (CGH), which enables the detection of chromosomal imbalances without the need for dividing cells. DNA from II TGCTs was studied by CGH. In all tumors examined, gain of 12p, mostly of the whole p arm, could be demonstrated. However, in three tumors, an amplification of 12p material restricted to the chromosomal bands 12p11.2-p12.1 was found. Further fluorescence in situ hybridization (FISH) analysis using a yeast artificial chromosome (YAC) that was previously mapped to that region revealed multiple copies of that chromosomal segment in interphase nuclei of these tumors. This finding is an important clue to the localization of candidate protooncogenes at 12p involved in TGCTs. Gains of small chromosomal regions at 2p, 4q, 6p, and 19p were also detected recurrently. Furthermore, gains of chromosomes 8, 14, 21, and X as well as loss of chromosome 13 were frequent findings. In conclusion, CGH provides new insights into genetic alterations of TGCTs. By using CGH, chromosomal subregions could be identified that may harbor genes involved in the pathogenesis of this malignancy. Genes Chromosom Cancer 17:78–87 (1996). © 1996 Wiley-Liss, Inc.     

Chromosomal imbalances in carcinoma showing thymus-like elements (CASTLE)

Carcinoma showing thymus-like elements (CASTLE) is a rare neoplasm of the thyroid gland resembling lymphoepithelioma-like and squamous cell carcinoma of the thymus and is thought to arise from ectopic thymic tissue within the thyroid gland or rudimentary branchial pouches along the thymic line. Using comparative genomic hybridization (CGH), chromosomal imbalances have been detected in several types of thymomas and thymic carcinomas. To evaluate whether there are hints of an underlying sequence in the pathogenesis of CASTLE analogue to those found in thymomas and thymic carcinomas, we evaluated four of these rare neoplasms for chromosomal imbalances using CGH. The most frequent gains were seen on chromosomal arm 1q (3/4), and losses were most frequently detected on 6p (4/4), 6q (3/4) and 16q (3/4). These CGH data show that CASTLE is characterized by chromosomal imbalances similar to those found in thymomas and thymic carcinomas and indicate a similar sequence in tumour development.     

Chromosomal aberrations in breast cancer: a comparison between cytogenetics and comparative genomic hybridization.

The analysis of chromosomal imbalances in solid tumors using comparative genetic hybridization (CGH) has gained much attention. A survey of the literature suggests that CGH is more sensitive in detecting copy number aberrations than is karyotyping, although careful comparisons between CGH and cytogenetics have not been performed. Here, we compared cytogenetics and CGH in 29 invasive breast cancers after converting the karyotypes into net copy number gains and losses. We found 15 tumors (56%) with a significant agreement between the two methods and 12 tumors (44%) where the methods were in disagreement (two cases failed CGH analysis). Interestingly, in 13 of the 15 tumors where the two methods were concordant, there was also a strong correlation between chromosome index and DNA index by flow cytometry. In the opposite situation, i.e., when chromosome and DNA indices were not matching, there was disagreement between cytogenetics and CGH in 10 of the 12 tumors. Of the discordant cases, all except one had a "simple" abnormal karyotype. Unresolved chromosomal aberrations (marker chromosomes, homogeneously staining regions, double minutes) could not completely explain the differences between CGH and karyotyping. A likely explanation for the discrepancies is that the methods analyzed different cell populations. Gains and losses found by CGH represented the predominant (often aneuploid) clone, whereas the abnormal, near-diploid karyotypes represented minor cell clone(s), which, for unknown reasons, had a growth advantage in vitro.     

The potential value of comparative genomic hybridization analysis in effusion-and fine needle aspiration cytology.

Comparative genomic hybridization (CGH) is a molecular cytogenetic technique that provides an overview on chromosomal imbalances within the whole tumor cell genome. This method has yet not been applied in effusion cytology. We performed CGH analysis in malignant effusions, fine needle aspirates, and imprint smears from eight ovarian adenocarcinomas, three breast carcinomas, one colon adenocarcinoma, and three malignant mesotheliomas. In part, CGH analysis from fresh frozen tissue and classic karyotyping served as controls. In this series, 14/15 cytologic specimens were suitable for extraction of high molecular weight DNA sufficient for reliable CGH analysis. CGH profiles from cytologic material were equal or even more significant in comparison with corresponding fresh frozen tumor samples. We conclude that CGH analysis from cytologic specimens may support the primary cytologic diagnosis of malignancy, especially in the differential diagnosis of benign proliferating mesothelium, malignant mesothelioma, and metastatic adenocarcinoma. CGH analysis of metastatic lesions may provide information on the site of the primary tumors and detects cytogenetic imbalances affecting oncogenes and tumor suppressor genes involved in tumor progression and metastatic spread.     

Cell proliferation and chromosomal changes in human ameloblastoma

Cell proliferation and chromosomal imbalances, important parameters in relation to tumor progression, were studied in ameloblastoma (n=20), a benign odontogenic tumor of locally recurrent nature. Immunocytochemical staining with MIB-1 antibody and comparative genomic hybridization (CGH) were performed on formalin-fixed paraffin-embedded ameloblastomas. The mean follow-up time was 12.4 years. An MIB-1-index was formed by counting 5000 tumor-cell nuclei in 10-15 randomly chosen high-power fields and calculating percentages of positively stained cells. CGH involved hybridization of FITC-dUTP-labeled tumor DNA with Texas-red-labeled normal DNA. Images were digitally analyzed. The MIB-1-index (range 0-2.51) was low for all tumors. No statistically significant correlation between MIB-1 index and tendency to recurrence was found. Chromosomal aberrations were detected in 2 of 17 cases. The results suggest that formation of an MIB-1 index is not helpful in assessing future clinical behavior of an ameloblastoma and that chromosomal imbalances are uncommon.     

Distinct genetic and epigenetic changes in medullary breast cancer

Genetic instability resulting in chromosome aneuploidy or mismatch repair deficiency characterizes cancer. Medullary carcinoma (MC) of the breast is a specific form of breast cancer with unique clinical, epidemiologic, and prognostic features, suggesting distinctive tumorigenic pathways. To investigate the nature of the genetic changes associated with MC we analyzed a series of 22 tumors. Chromosomal imbalances were assessed by comparative genomic hybridization (CGH) and mismatch repair (MMR) deficiency tested for through assessment of microsatellite instability (MSI) and expression of MLH1 and MSH2 genes. MMR deficiency was detected in only a small proportion of cases. The chromosomal copy number changes showed some similarities to BRCA1-associated tumors. A high level of BRCA1 promoter hypermethylation was detected, suggesting a possible role of this gene in MC development.     

Comparative genomic hybridization in the investigation of myeloid leukemias

Comparative genomic hybridization (CGH) was used for the examination of ten cases of myeloid leukemia (eight acute myeloid leukemias and two myelodysplastic syndromes). In five cases, genomic gains or losses were identified, which mapped to chromosomal regions known to be involved in this group of malignancies. In comparison to the results obtained by banding analysis, discrepancies were found in three of the ten cases; in two cases, chromosomal imbalances were not identified by CGH because they were present only in small subclones. In the other case, there were no evaluable metaphase cells for banding analysis; CGH revealed an overrepresentation of chromosome 8, which was confirmed by interphase cytogenetics with a chromosome 8-specific alphoid probe. All abnormalities revealed by CGH were confirmed by G-banding or subsequent interphase cytogenetic analysis, which demonstrates the high specificity of the method. Furthermore, in all cases, CGH identified the chromosomal imbalances present in the major clone as detected by banding analysis. The good correlation between CGH and chromosome banding results in myeloid leukemias makes this tumor a good model for the assessment of tools that are developed for automated and quantitative CGH analysis.     

Detection of DNA gains and losses in primary endometrial carcinomas by comparative genomic hybridization

Comparative genomic hybridization (CGH) was used in a retrospective analysis of chromosomal imbalances in frozen primary tumor specimens from 14 endometrial carcinoma patients. Chromosome changes were detected in nine cases (64%), and tumor stage and grade tended to parallel the degree of genomic imbalances. Gain of the entire long arm of chromosome I was observed in six cases (43%), three of which displayed only this chromosome change. Other common sites of copy number increases included 8q21 → qter (4 cases), 10p15 (4 cases), 10q11 → q24 (3 cases), and 13q21 → qter (3 cases, each with stage III disease). Two of the tumors with gains of chromosome 10 involved the whole chromosome, and this was the sole abnormality in one case. DNA amplification at 5p14 → p15 was identified in one specimen, a stage III tumor having numerous imbalances. DNA microsatellite analysis revealed multiple replication errors (RER), indicative of the RER⁺ phenotype, in four of 13 (31%) cases evaluated. The RER⁺ phenotype was observed in four of six stage Ia tumors but in none of seven stage Ib or stage III tumors. Multiple genomic imbalances detected by CGH were not observed in RER⁺ tumors but were detected in five of nine tumors without the RER⁺ phenotype. These investigations demonstrate the feasibility of CGH for the retrospective assessment of chromosomal changes in endometrial carcinoma specimens. Moreover, these data suggest that the etiologies in tumors with and without the RER⁺ phenotype may differ. Genes Chromosom. Cancer 18:115–125, 1997. © 1997 Wiley-Liss, Inc.     

Solid pseudopapillary neoplasms of the pancreas are associated with FLI-1 expression, but not with EWS/FLI-1 translocation.

Solid pseudopapillary neoplasms of the pancreas are rare pancreatic tumors with mostly benign behavior, affecting almost exclusively women. Their histogenetic origin is still unsolved, but a recently reported EWS/FLI-1 translocation t(11;22)(q24;q21) and the consistent expression of CD56 and the progesterone receptor, both genes located on the long arm of chromosome 11, point to chromosome 11q as a potential locus of gene aberration in solid pseudopapillary neoplasms. To further elucidate this issue, we studied 30 cases of solid pseudopapillary neoplasms by comparative genomic hybridization (CGH), fluorescent in situ hybridization (FISH) and immunohistochemistry. Immunohistochemically, 38% showed nuclear expression of FLI-1 and all cases revealed positivity for CD56 and the progesterone receptor, whereas no solid pseudopapillary neoplasm expressed CD34. No translocation of the EWS gene was found by FISH and no gross chromosomal gain or loss was detected by CGH. It is concluded that FLI-1 expression in solid pseudopapillary neoplasms is not associated with an EWS/FLI-1 translocation. In addition, there are no chromosomal gains or losses, especially on chromosome 11, where the FLI-1 gene is located adjacent to the gene for CD56 (NCAM). These data add another feature to the complex phenotypic appearance of solid pseudopapillary neoplasms.