Genetic changes and clonality relationship between primary colorectal cancers and their pulmonary metastases--an analysis by comparative genomic hybridization

About 10% of colorectal carcinoma patients develop pulmonary metastases during their lifetime. We address whether and how the chromosomal abnormalities differ between the primary cancers and their metastatic counterparts, what the clonality relationship (CR) is between them, and whether certain genomic aberrations contribute to this disease progression. Comparative genomic hybridization (CGH) experiments were performed on 18 paired samples of primary and pulmonary metastases obtained from patients who had undergone two consecutive surgeries and from whom clinical data had been collected. The CGH profiles also were used as indexes for determining the CR between the cancers. The overall CGH abnormality profiles were similar for the primary colorectal carcinomas and their pulmonary metastases. Frequent gains were found on chromosome arms 20q, 8q, 13q, and 7q, whereas common losses were found on 18q, 8p, and 18p. The pulmonary metastases, however, contained more CGH abnormalities than did the primary carcinomas (total aberration events per tumor: 12.6 +/- 5.0 vs. 8.3 +/- 5.7, respectively, P = 0.024; gains: 7.6 +/- 3.1 vs. 5.1 +/- 3.5, respectively, P = 0.036; losses: 5.0 +/- 2.8 vs. 3.3 +/- 2.9, respectively, P = 0.076). Comparing CGH profiles between individual primary and metastasis pairs, we found that 10 of the 18 (56%) paired samples examined exhibited a high degree of CR, indicating that they were likely to have originated from the same clone and/or that not many additional chromosomal changes had occurred in the metastases, except for 4q loss, whose incidence was much higher in the metastases than in the primaries (60% vs. 10%; P = 0.030). Also, the primary tumors of the high-CR group carried more genomic aberrations, especially 8p loss, than did the primary tumors in the low-CR group. We found more chromosomal changes associated with the pulmonary metastases of colorectal cancer compared with the corresponding primary tumors. We concluded that primary cancers containing more genomic lesions, especially 8p losses, are more likely to metastasize to the lungs. Loss of 4q is potentially a supplementary factor contributing to the dissemination of this disease.     

Genomic profiling of myeloid sarcoma by array comparative genomic hybridization

Myeloid sarcoma (MS) is a tumor mass of myeloblasts or immature myeloid cells occurring in an extramedullary site. In this study, seven cases of MS [stomach (1), testis (1), skin (2), and lymph node (3)] and 3 synchronous and 1 follow-up bone marrow (BM) samples were studied for genomic abnormalities using array comparative genomic hybridization (array-CGH). Array-CGH construction used approximately 5,400 bacterial artificial chromosome clones from the RPCI-11 library, spanning the human genome. Data were analyzed using the DNAcopy software and custom heuristics. All MS cases had genomic abnormalities detected by array-CGH. Unbalanced genomic abnormalities in five MS cases were confirmed by conventional cytogenetics (CC) and/or fluorescence in situ hybridization (FISH); these abnormalities included loss of 4q32.1-q35.2, 6q16.1-q21, and 12p12.2-p13.2 and gain of 8q21.2-q24.3, 8, 11q21-q25, 13q21.32-q34, 19, and 21. Array-CGH was also invaluable in identifying possible deletions, partner translocations, and breakpoints that were questionable by CC. The remaining two MS cases had genomic aberrations detected by array-CGH, but were not studied further by CC/FISH. Chromosome 8 was most commonly abnormal (3/7 cases). Identical genomic abnormalities were demonstrated in MS and in synchronous BM in two cases. These results demonstrate that array-CGH is a powerful tool to screen MS tissue for unbalanced genomic abnormalities, allowing identification of chromosome abnormalities when concurrent BM is nonanalyzable or nonleukemic.     

Genetic changes in intraductal breast cancer detected by comparative genomic hybridization.

Ductal carcinoma in situ (DCIS) is considered a direct precursor of invasive ductal breast cancer (IDC). We combined tissue microdissection and comparative genomic hybridization to identify genetic changes in five DCIS lesions with no invasion and in two that were adjacent to IDC. Extensive genetic changes characterized pure DCIS cases with gains of 1q, 6q, 8q, and Xq as well as losses of 17p and chromosome 22 being most often involved. Except for the Xq gain, these changes are also common to IDC. Separate analysis of DCIS and IDC components in the same tumor revealed an almost identical pattern of genetic changes in one case, whereas substantial differences were found in another. We conclude that many of the common genetic changes in IDC may take place before development of invasive growth. However, a simple linear progression model may not always account for the DCIS-IDC transition.     

Comparative genomic hybridization analysis of primary colorectal carcinomas and their synchronous metastases

We have analyzed 26 tumors from 12 patients with metastatic colorectal adenocarcinoma by comparative genomic hybridization (CGH). Primary tumors and their lymph node metastases from five Dukes' C patients as well as primary tumors and their liver metastases from seven Dukes' D patients were used to assess the extent of genetic differences between primary and secondary colorectal carcinomas from the same patients, to calculate the degree of clonal divergence and genetic heterogeneity in metastatic colorectal cancer, and to determine the differences in genetic imbalances between Dukes' C and D stage tumors. We show that the same genetic aberrations were frequently found in the primary tumors and their metastases. However, metastases often contained genetic aberrations not found in the corresponding primary tumors. The comparison of Dukes' stages C and D revealed genetic aberrations common to both. However, reduced copy number of chromosome arm 17p (5/5 vs. 0/7; P = 0.001) was significantly associated with Dukes' stage C and lymph node metastases, while increased copy number of chromosome arms 6p (6/7 vs. 0/5; P = 0.007) and 17q (5/7 vs. 0/5; P = 0.027) was associated more with Dukes' stage D and liver metastases. Our results established a repertoire of chromosomal alterations associated with metastatic colorectal cancer and suggest that Dukes' C (lymph node metastasis) tumors are not always simply an earlier stage of Dukes' D (liver metastasis) tumors and, thus, in some instances at least, they are distinct forms of the disease.     

比较基因组杂交应用于结直肠癌检测中的质量控制

比较基因组杂交（comparative genomic hybridization,CGH）是在染色体荧光原位杂交（fluorescence in situ hybridization,FISH）基础上发展起来的一种新的分子细胞遗传学技术,与其他肿瘤细胞遗传学方法相比,主要的优点是无需制备肿瘤细胞的中期分裂象,对肿瘤标本没有限制,只要能得到少量基因组DNA的标本如新鲜或冻存的或石蜡包埋的癌组织、癌细胞系均可用来分析,且只经一次实验便可得到整个基因组的扩增和丢失的情况。与FISH相比,它克服了需制备染色体特异区域的探针且仅能检测个别染色体或部分位点的局限性,它是一种全方位检测法,一次实验即可检测出待测标本整个基因组DNA拷贝数增减。     

Genetic heterogeneity of neuroblastoma studied by comparative genomic hybridization

Comparative genomic hybridization (CGH) analysis was performed on 36 neuroblastomas of both low and high stage of disease. This study significantly increases the number of neuroblastoma tumors studied by CGH. Analysis of larger series of tumors is particularly important in view of the different clinical subgroups that are recognized for this tumor. The present data and a comparison with all published CGH data on neuroblastoma provide further insights into the genetic heterogeneity of neuroblastoma. Stage 1, 2, and 4S tumors showed predominantly whole chromosome gains and losses. A similar pattern of whole chromosome imbalances, although less frequent, was observed in stage 3 and 4 tumors, in addition to partial chromosome gains and losses. An increase in chromosome 17 or 17q copy number was observed in 81% of tumors. The most frequent losses, either through partial or whole chromosome underrepresentation, were observed for 1p (25%), 3p (25%), 4p (14%), 9p (19%), 11q (28%), and 14q (31%). The presence of 3p, 11q or 14q deletions defines a genetic subset of neuroblastomas and contributes to the further genetic characterization of stage 3 and 4 tumors without MYCN amplification (MNA) and 1p deletion. The present study also provides additional evidence for a possible role of genes at 11q13 in neuroblastoma. In a few cases, 1p deletion or MNA detected by FISH or Southern blotting was not found by CGH, indicating that the use of a second, independent technique for evaluation of these genetic parameters is recommended. Genes Chromosomes Cancer 23:141–152, 1998. © 1998 Wiley-Liss, Inc.     

Genetic imbalances in precursor lesions of endometrial cancer detected by comparative genomic hybridization

Endometrial hyperplasia is regarded as a precursor lesion of endometrioid adenocarcinomas of the endometrium. The genetic events involved in the multistep process from normal endometrial glandular tissue to invasive endometrial carcinomas are primarily unknown. We chose endometrial hyperplasia as a model for identifying chromosomal aberrations occurring during carcinogenesis. Comparative genomic hybridization (CGH) was performed on 47 formalin-fixed, paraffin-embedded specimens of endometrial hyperplasia using the microdissection technique to increase the number of tumor cells in the samples and reduce contamination from normal cells. CGH analysis revealed that 24 out of 47 (51%) samples had detectable chromosomal imbalances, whereas 23 (49%) were in a genetically balanced state. The incidence of aberrant CGH profiles tended to parallel dysplasia grade, ranging from 22% aberrant profiles in simple hyperplasia to 67% in complex hyperplasia with atypia. The most frequent imbalances were 1p, 16p, and 20q underrepresentations and 4q overrepresentations. Copy number changes in 1p were more frequent in atypical complex hyperplasia than in complex lesions without atypical cells or simple lesions (42% versus 20% and 0%). Our results show that endometrial hyperplasia reveals recurrent chromosomal imbalances which tend to increase with the presence of atypical cells. The most frequent aberrations in endometrial cancer, 1q and 8q overrepresentations, are not present or are rare in its precursor lesions. This analysis provides evidence that tumorigenesis proceeds through the accumulation of a series of genetic alterations and suggests a stepwise mode of tumorigenesis.     

Analysis of colorectal tumor progression by microdissection and comparative genomic hybridization

This investigation aimed to identify patterns of copy number change in colorectal tumor progression from adenoma to liver metastasis. Fifty-three microdissected sub-regions from 17 cases of colorectal cancer were assigned to one of six histopathologically defined categories: coexisting adenoma, tumor above the muscularis layer, tumor within the muscularis layer, tumor extending through the bowel wall to serosal fat, lymph node metastasis, and liver metastasis. Microdissected samples were treated by a microwave processing step and then used as templates for universal PCR amplification. PCR products were fluorophore labeled and subjected to comparative genomic hybridization. Copy number changes were found in all samples, and every chromosome arm (excluding acrocentric short arms) was affected. More losses than gains were detected, but there were no significant differences between the numbers of changes seen in each category. Each individual sample revealed unique changes, additional to those shared within each case. The most frequently observed gains were of X and 12q. The most common losses were of 8p, 16p, 9p, 15q, 18q, and 10q. Nominally significant associations were observed between metastatic tumor and loss of 12q24.1 or 10p13-14, non-metastatic tumor and loss of 8q24.1, tumor extending to serosal fat and loss of 6q24-25 or gain of 4q11-13, tumor extending to serosal fat and metastatic lesions and loss of 4q32-34 or 22q11-12, and adenoma and loss of 15q24. Loss of 4q32-34 remained highly significant after correction for multiple testing. Adenoma was the only category not to show loss of 17p. These data reveal a genetically heterogeneous picture of tumor progression, with a small number of changes associated with advanced disease.     

Genetic alterations of gastric cancer: comparative genomic hybridization and fluorescence In situ hybridization studies

Genetic changes leading to the development of gastric cancers are still in dispute. In the following study, we used comparative genomic hybridization (CGH) to screen for DNA copy number changes along all chromosomes in 37 gastric carcinomas, and fluorescence in situ hybridization (FISH) with the C-MYC and TP53 probes in 14 cases for comparison. The aim of this study was to identify those chromosome regions that contain genes important for the development of gastric carcinomas and to identify genetic markers associated with tumor progression. The most often involved gains were 2q, 7pq, 8pq, 13q, 17q, 18q, and 20pq. The most commonly deleted regions were 17p. The pattern of genetic changes was different depending on the existence of nodal metastasis and histologic types. Gains in 8q and losses in 17p were the most common features of the CGH changes. However, only 3 among the available 10 cases (30%) showed an amplification of the C-MYC gene by FISH. Allelic loss of TP53 was found in 2 of 4 cases (50%). This difference might be due to another rearrangement of these 2 genes which cannot be detected by FISH, or other possible genes in that area may be involved in the tumorigenesis and nodal metastasis of gastric carcinomas.     

Chromosome arm 20q gains and other genomic alterations in colorectal cancer metastatic to liver, as analyzed by comparative genomic hybridization and fluorescence in situ hybridization.

Comprehensive information about the molecular cytogenetic changes in metastases of colorectal cancer is not yet available. To define such changes in metastases, we measured relative DNA sequence copy numbers by comparative genomic hybridization (CGH). Samples from 27 liver metastases and 6 synchronous primary tumors were analyzed. An average of 9.9 aberrations per tumor was found in the metastases. Gains of chromosome arms 20q (85%), 13q (48%), 7p (44%), and 8q (44%) and losses of chromosome arms 18q (89%), 8p (59%), 1p (56%), and 18p (48%) were detected most frequently. Chromosomes 14 and 15 were lost in 26% and 30% of the metastases, respectively. No consistent differences were observed between primary tumors and synchronous metastases. Fluorescence in situ hybridization (FISH) was used for further characterization of gains of chromosome arm 20q. Touch preparations of 13 tumors that had demonstrated 20q gain with CGH were examined with FISH by use of a set of probes mapping to different parts of 20q. A probe for 20p was used as a reference. FISH showed relative gain of at least one 20q locus in 12 of the tumors. High-level gains were detected in 38% of the tumors, preferentially for probes mapping to band 20q13. Our CGH data indicate that colorectal metastases show chromosomal changes similar to those that have been reported for primary tumors. Chromosomal losses were seen at higher frequency, particularly for chromosomes 14 and 15. By FISH, we identified subregions on chromosome arm 20q that are frequently involved in DNA amplifications in colorectal cancer and that may harbor candidate proto-oncogenes.     

Genetic changes at specific stages of breast cancer progression detected by comparative genomic hybridization

Although a simple linear progression model for breast cancer has already been proposed, its validity still remains controversial. Especially, the genetic and molecular features of breast cancer at different stages during the development and progression, as well as their relationship, have rarely been studied under the same experimental conditions simultaneously. According to these limitations in this research area, the current study applied comparative genomic hybridization technique to investigate genomic changes in 15 cases of breast atypical ductal hyperplasia (ADH), 15 cases of ductal carcinomas in situ (DCIS), and 15 cases of invasive ductal carcinomas (IDC) and the relationship among the genetic changes. Thirty commonly altered regions that were identified included known (gains of 1q,8q, 17q,20q,Xq and losses of 8p,13q,16q,17p,22q) and several uncharacterized (gains of 2q,5p, 10p,12q,16p,18q, etc. and losses of 11p13-pter,11q,14q,Xp, etc). The overall frequency of copy number losses was higher in IDC than that in DCIS (P = 0.013). ADH showed more frequent gain of 17q than that in IDC (P = 0.007), and IDC exhibited a higher frequency for the loss of 22q than that in ADH (P = 0.018). On one hand, several common genomic changes shared by ADH, DCIS, and IDC make a linear relationship for these three lesions possible. On the other hand, the heterogeneity has also showed clonal diversification and different pathways of breast cancer progression. The regions of chromosomal copy number alterations may bring new insights into the strategy for tumor progression blocking and the discovery of new potential targets for breast cancer treatment. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorised users.     

Genetic changes in localized prostate cancer of Japanese patients shown by comparative genomic hybridization

To search for additional amplification and deletion sites that may serve as a starting point for the discovery of new oncogenes or tumor suppressor genes, 30 Japanese localized prostate cancers were analyzed by comparative genomic hybridization (CGH) in this study. CGH was used to search for changes in DNA sequence copy-number in a series of 30 primary prostate adenocarcinomas, consisting of 22 cases of pT2N0 (organ confined; without capsular invasion) and 8 cases of pT3N0 (with capsular invasion), removed by radical prostatectomy. CGH revealed that the shortest regions of overlap (SRO) of gains in pT2N0 were at 8q22.2 approximately q24.2, 11q13.1 approximately q14.1, and 12q23 approximately q24.2, whereas the SRO of losses were seen at 8p23.3 approximately p22, 13q21.2 approximately p22, and 18q21 approximately q22. The SRO of gains in pT3N0 were noted at 5q32 approximately q34, 8q22.3 approximately q24.1, 11q14.1 approximately q22.3, and 12q22 approximately q24.2, whereas the SRO of losses were seen at 18q21.2 approximately q23. These results suggest that gains or losses of DNA in these regions are important for prostate cancer progression. The detection of the SRO may serve as a starting point to discover novel oncogenes and tumor suppressor genes involved in prostate cancer progression.     

Association between genomic alterations and metastatic behavior of colorectal cancer identified by array‐based comparative genomic hybridization

Colorectal cancers (CRCs) exhibit multiple genetic alterations, including allelic imbalances (copy number alterations, CNAs) at various chromosomal loci. In addition to genetic aberrations, DNA methylation also plays important roles in the development of CRC. To better understand the clinical relevance of these genetic and epigenetic abnormalities in CRC, we performed an integrative analysis of copy number changes on a genome‐wide scale and assessed mutations of TP53, KRAS, BRAF, and PIK3CA and DNA methylation of six marker genes in single glands isolated from 39 primary tumors. Array‐based comparative genomic hybridization (array‐CGH) analysis revealed that genomic losses commonly occurred at 3q26.1, 4q13.2, 6q21.32, 7q34, 8p12‐23.3, 15qcen and 18, while gains were commonly found at 1q21.3‐23.1, 7p22.3‐q34, 13q12.11‐14.11, and 20. The total numbers and lengths of the CNAs were significantly associated with the aberrant DNA methylation and Dukes' stages. Moreover, hierarchical clustering analysis of the array‐CGH data suggested that tumors could be categorized into four subgroups. Tumors with frequent DNA methylation were most strongly enriched in subgroups with infrequent CNAs. Importantly, Dukes' D tumors were enriched in the subgroup showing the greatest genomic losses, whereas Dukes' C tumors were enriched in the subgroup with the greatest genomic gains. Our data suggest an inverse relationship between chromosomal instability and aberrant methylation and a positive association between genomic losses and distant metastasis and between genomic gains and lymph node metastasis in CRC. Therefore, DNA copy number profiles may be predictive of the metastatic behavior of CRCs. © 2012 Wiley Periodicals, Inc.     

Expression profiling and interferon-beta regulation of liver metastases in colorectal cancer cells

Liver metastasis is the major cause of death among colorectal cancer patients. Many gene products have been associated with the colon cancer cells' ability to metastasize to the liver, including carcinoembryonic antigen (CEA) and mucins. In this study we examined changes in expression of 384 genes in a model of human colorectal cancer metastasis in nude mice. Using DNA microarrays, we compared expression between MIP-101 cells, a poorly metastatic human colon cancer cell line, with an interferon-beta (IFN-β) resistant subline of MIP-101 (β-MIP) that is metastatic to the liver. Treatment of β-MIP cells with increasing concentrations of IFN-β caused a reversion to the non-metastatic phenotype. The array data showed down-regulation of genes involved in apoptosis in β-MIP cells and their return to the MIP-101 pattern upon IFN-β treatment. Cluster analysis also showed involvement of genes belonging to cell cycle, angiogenesis and invasion pathways. Selected genes were chosen to validate the microarray data by semi-quantitative RT-PCR. Association between gene expression pattern and metastatic phenotype was verified by intra-splenic injection in nude mice. The number of genes examined in this study was small, but carefully selected. Significant changes associated with cell growth and survival were observed, which gave the metastatic cells an advantage to grow in the liver. This information may help identifying new markers for colorectal cancer prognosis as well as aid the development of new therapeutic approaches. This revised version was published online in July 2006 with corrections to the Cover Date.     

Genetic heterogeneity by comparative genomic hybridization in BRCAx breast cancers

The chromosomal changes in eight familial BRCAx breast cancers (i.e., negative for BRCA1 or BRCA2) were analyzed by comparative genomic hybridization (CGH) to investigate intratumor heterogeneity. This was the first step in a study of most frequent chromosomal aberrations in BRCAx familial breast cancers. Laser microdissection analysis of paraffin tissue samples was followed by whole-genome amplification. CGH was performed on DNA isolated from two to three different cell groups per case to detect any cytogenetic aberrations in important clones that might have been missed when analyzing DNA extracted from large numbers of cells. The results were compared, to evaluate the influence of tumor heterogeneity on CGH, and the heterogeneity was confirmed comparing CGH with fluorescence in situ hybridization results. Different chromosomal aberrations were detected between adjacent clones within the same section, which highlights the utility of microdissection in addressing the problem of heterogeneity in whole-genome studies. Some chromosomal regions were more frequently altered in the eight BRCAx tumors; loss of 2q, 3p, 3q, 8p, 9p, and 15q and gains of 1p, 4p, 4q, 5p, 6q, 12q, and 19p were the most common. Further studies focusing on specific genes and sequences with more sensitive approaches, such as array-CGH, are warranted to confirm these findings.     

Genetic aberrations detected by comparative genomic hybridization predict outcome in node-negative breast cancer.

Breast cancer progression is determined by a complex pattern of multiple genetic aberrations the association of which with patient prognosis is unknown. In this study, we have undertaken a genome-wide screening to detect genetic changes associated with clinical outcome in node-negative breast cancer. Comparative genomic hybridization was used to screen for DNA sequence gains and losses across all human chromosomes in 23 tumors from node-negative breast cancer patients with no disease recurrence after at least 5 years of follow-up and in 25 node-negative patients with recurrence during the first 5 years of follow-up. The total number of genetic aberrations (copy number gains and losses) per tumor was significantly greater in the recurrence group (P = 0.019) and in the subgroup of these patients who died as a result of breast cancer (P = 0.0022). When copy number losses and gains were analyzed separately, only losses were significant (P = 0.013 for recurrence and P = 0.002 for overall survival). Of the individual loci involved, a high level gain of the long arm of chromosome 8 was significantly associated with recurrence (P = 0.01, Fisher's exact test). Furthermore, amplification of DNA sequences at chromosome 20q12-13 was found in 7 cases (15%), 6 of which had early recurrence within 32 months of diagnosis. This genome-wide overview by comparative genomic hybridization suggests that genetically advanced node-negative breast cancers having a high overall number of genetic aberrations may have a poor prognosis and that increased copy number of two specific regions, 8q and 20q13, may confer a more aggressive phenotype. Results of this pilot study suggest that determination of the total number of DNA sequence copy number aberrations may help therapeutic decision making. Specific probes should be developed to test the prognostic value of 8q and 20q12-13 amplifications in large numbers of patients.     

G-显带技术、荧光原位杂交和比较基因组杂交技术在产前诊断中的应用

目的 探讨G显带、荧光原位杂交(fluorescencein situ hybridization,FISH)和比较基因组杂交(comparative genomic hybridization,CGH)技术在产前诊断中应用的程序及意义.方法 采集102例妊娠16周～24周胎儿的羊水,采用G显带、G显带/FISH和G显带/FISH/CGH三阶梯的核型诊断程序,并分析其在产前诊断中的意义.结果 102例胎儿中,经第1阶梯诊断核型98例,诊断困难2例,失败2例;第2阶梯诊断核型2例,诊断困难1例,失败1例;第3阶梯诊断核型2例.经3阶梯诊断程序核型的诊断率达100%(102/102例),异常核型7例(7/102例,6.68 0A),其中第1、第2和第3阶梯分别诊断异常核型4例(4/7例,57.1 oA)、1例(1/7例,14.3%)和2例(2/7例,28.5%).结论 在产前诊断中实施3阶梯诊断程序有助于提高核型的确诊率,规范染色体诊断流程.     

Genetic alterations in epithelial ovarian tumors analyzed by comparative genomic hybridization

The genetic changes involved in the pathogenesis of ovarian carcinoma are not completely understood. To investigate this matter, we studied paraffin-embedded, microdissected tissue of 47 ovarian epithelial tumors (9 adenomas, 11 tumors of low malignant potential [LMP], 14 serous carcinomas, and 13 nonserous carcinomas) using comparative genomic hybridization (CGH). (The primary data used in this study are available at our CGH online tumor database at http://amba.charite.de/cgh.) Chromosomal imbalances were found in 1 serous adenoma and in 7 LMP tumors. In the latter the alterations appeared randomly and showed no overlap with alterations found in invasive carcinomas. Although the mean aberration number of low-grade serous carcinomas was comparable to LMP tumors, the imbalances of the former occurred with high incidence (>50%) and were found at different localizations. High-grade serous carcinomas had more than twice as much chromosomal imbalances as low-grade serous carcinomas and also had pronounced alterations. In serous carcinomas, gains were found on 3q, 6p, 7, 8q, and 20, and losses were found on 4q, 6q, 12q, 13q, and 16q. Comparing serous and nonserous carcinomas, the mean aberration number was comparable, but the number of high incidence changes was lower, and the most frequent imbalances were losses on 13q and gains on 20p. Overlapping alterations occurring in serous and nonserous carcinomas were gains on 3q and 6p, as well as losses on 4q. Chromosomal imbalances associated with poor prognosis of ovarian carcinomas were gains on 6p, 7q, and 13q and losses on 15q, 17p, 18q, and 21q. Our data indicate that serous LMP tumors and invasive carcinomas have different genetic aberrations, indicating that invasive carcinomas do not arise from preexisting serous LMP tumors. On the other hand, there are common genetic abnormalities in serous and nonserous carcinomas, suggesting that they have very early lesions in common but take different paths of further development.