Novel regions of chromosomal loss in familial neuroblastoma by comparative genomic hybridization

Childhood neuroblastoma, an embryonal neoplasm of sympathetic nervous system progenitors, occurs in a familial form with an autosomal dominant mode of inheritance. Genetic susceptibility to this disorder is thought to arise via a germline mutation affecting a tumor suppressor gene, in accord with the two-hit model established for familial and sporadic retinoblastoma. Surprisingly, the familial neuroblastoma predisposition locus does not map to chromosome band 1p36, a genomic region likely to contain one or more neuroblastoma suppressor genes. We reasoned that inherited point mutations affecting one allele would be unmasked in many cases by somatically acquired deletions of the second allele that included the target gene in the tumor cells from these patients. Thus, to identify chromosomal regions that might contain suppressor genes important in hereditary neuroblastoma, we analyzed six familial tumors by comparative genomic hybridization. Recurrent losses of genetic material were detected on chromosome arms 3p (consensus region, 3p24-pter), 10p (consensus, 10p12-p13), 10q (consensus, 10q25-qter), 16q (consensus, 16q12-q22), and 20q (consensus, 20q13.3-qter), in addition to the regions commonly deleted in sporadic neuroblastomas (1p36 and 11q). These chromosomal sites may harbor novel tumor suppressor genes that could aid in our understanding of the predisposition to and pathogenesis of familial neuroblastoma and potentially sporadic tumors as well. Genes Chromosom. Cancer 19:176–184, 1997. © 1997 Wiley-Liss Inc.     

Molecular evidence for putative tumour suppressor genes on chromosome 13q specific to BRCA1 related ovarian and fallopian tube cancer.

BACKGROUND/AIMS: Loss of heterozygosity (LOH) on chromosome 13q has been reported to occur frequently in human ovarian cancer, and indications have been found that chromosome 13 may also play a specific role in the inherited form of ovarian cancer. The aim of this study was to define regions on chromosome 13 that may harbour additional tumour suppressor genes involved in the tumorigenesis of BRCA1 related ovarian and fallopian tube cancer. MATERIALS/METHODS: DNA extracted from paraffin wax blocks of 36 BRCA1 associated ovarian and fallopian tube carcinomas was analysed by LOH polymerase chain reaction using seven highly polymorphic microsatellite markers spanning chromosome 13q. RESULTS: High LOH frequencies were found on loci 13q11, 13q14, 13q21, 13q22-31, 13q32, and 13q32-4, suggesting the presence of putative tumour suppressor genes on the long arm of chromosome 13 that may play a role in the pathogenesis of BRCA1 related ovarian and fallopian tube cancer. LOH patterns appeared to be independent of the type of BRCA1 mutation, stage, and grade. Although in some cases there were indications for loss of larger parts of chromosome 13, in most cases losses were fairly randomly distributed over chromosome 13 with retained parts in between lost parts. Microsatellite instability was found in six cases. CONCLUSION: Several loci on chromosome 13q show high frequencies of LOH in BRCA1 related ovarian and fallopian tube cancer, and may therefore harbour putative tumour suppressor genes involved in the carcinogenesis of this particular type of hereditary cancer.     

Clinical implications of chromosomal abnormalities in gastric adenocarcinomas

Gastric carcinoma (GC) is one of the most common malignancies worldwide and has a very poor prognosis. Genetic imbalances in 62 primary gastric adenocarcinomas of various histopathologic types and pathologic stages and six gastric cancer-derived cell lines were analyzed by comparative genomic hybridization, and the relationship of genomic abnormalities to clinical features in primary GC was evaluated at a genome-wide level. Eighty-four percent of the tumors and all six cell lines showed DNA copy number changes. The recurrent chromosomal abnormalities including gains at 15 regions and losses at 8 regions were identified. Statistical analyses revealed that gains at 17q24-qter (53%), 20q13-qter (48%), 1p32-p36 (42%), 22q12-qter (27%), 17p13-pter (24%), 16p13-pter (21%), 6p21-pter (19%), 20p12-pter (19%), 7p21-pter (18%), 3q28-qter (8%), and 13q13-q14 (8%), and losses at 18q12-qter (11%), 3p12 (8%), 3p25-pter (8%), 5q14-q23 (8%), and 9p21-p23 (5%), are associated with unique patient or tumor-related features. GCs of differing histopathologic features were shown to be associated with distinct patterns of genetic alterations, supporting the notion that they evolve through distinct genetic pathways. Metastatic tumors were also associated with specific genetic changes. These regions may harbor candidate genes involved in the pathogenesis of this malignancy.     

Comparative genomic hybridization detects frequent overrepresentation of chromosomal material from 3q26, 8q24, and 20q13 in human ovarian carcinomas

We used comparative genomic hybridization (CGH) to identify recurrent chromosomal imbalances in tumor DNA from 25 malignant ovarian carcinomas and two ovarian tumors of low malignant potential (LMP). Many of the carcinoma specimens displayed numerous imbalances. The most common sites of copy number increases, in order of frequency, were 8q24.1, 20q13.2-qter, 3q26.3-qter, 1q32, 20p, 9p21-pter, and 12p. DNA amplification was identified in 12 carcinomas (48%). The most frequent sites of amplification were 8q24.1-24.2, 3q26.3, and 20q13.2-qter. Other recurrent sites of amplification included 7q36, 17q25, and 19q13.1-13.2. The most frequent sites of copy number decreases were 5q21, 9q, 17p, 17q12-21, 4q26-31, 16q, and 22q. Underrepresentation of 17p was observed in six of 16 stage III/IV tumors, but in none of seven stage I/II tumors, suggesting that this change may be a late event associated with the transition of ovarian carcinomas to a more metastatic disease. Overrepresentation of 3q26.3-qter, 5p14-pter, 8q24.1, 9p21-pter, 20p, and 20q13.2-qter and underrepresentation of 4q26-31 and 17q12-21 also tended to be more common in advanced-stage tumors. All ten grade 3 tumors had copy number increases involving 8q24.1, compared to only three of nine grade 2 tumors. Overrepresentation of 3q26.3-qter and 20q13.2-qter was also observed at a higher frequency in high-grade tumors. One of the two LMP tumors displayed chromosomal alterations, which consisted of overrepresentation of 5p and 9p only. Taken collectively, these findings and data from other CGH studies of ovarian cancers define a set of small chromosome segments that are consistently over- or underrepresented and, thus, highlight sites of putative oncogenes and tumor suppressor genes that contribute to the pathogenesis of these highly malignant neoplasms. Genes Chromosomes Cancer 20:320–328, 1997. © 1997 Wiley-Liss, Inc.     

DNA copy number amplifications in human neoplasms: review of comparative genomic hybridization studies.

This review summarizes reports of recurrent DNA sequence copy number amplifications in human neoplasms detected by comparative genomic hybridization. Some of the chromosomal areas with recurrent DNA copy number amplifications (amplicons) of 1p22-p31, 1p32-p36, 1q, 2p13-p16, 2p23-p25, 2q31-q33, 3q, 5p, 6p12-pter, 7p12-p13, 7q11.2, 7q21-q22, 8p11-p12, 8q, 11q13-q14, 12p, 12q13-q21, 13q14, 13q22-qter, 14q13-q21, 15q24-qter, 17p11.2-p12, 17q12-q21, 17q22-qter, 18q, 19p13.2-pter, 19cen-q13.3, 20p11.2-p12, 20q, Xp11.2-p21, and Xp11-q13 and genes therein are presented in more detail. The paper with more than 150 references and two tables can be accessed from our web site http://www.helsinki.fi/lglvwww/CMG.html. The data will be updated biannually until the year 2001.     

Cytogenetic aberrations and their prognostic impact in chondrosarcoma.

Chondrosarcoma is the second most common primary malignancy of bone. Cytogenetic data are available from close to 100 cases, including all subtypes of chondrosarcoma. Specific chromosomal rearrangements have been identified only in extraskeletal myxoid chondrosarcoma (EMC). Strong prognostic factors are largely missing, although size and, in particular, histologic tumor grade have been implicated. In the present study, we investigated the genomic aberrations in 59 chondrosarcomas (six grade 1, 24 grade 2, and 29 grade 3, including dedifferentiated tumors), excluding EMC, by chromosome banding analysis and DNA flow cytometry and correlated the findings with clinical outcome. Hyperhaploid to near-diploid karyotypes were found in half of the cases, and there was a good correlation between cytogenetics and flow cytometry data; discrepancies were seen primarily in cases with normal karyotypes and in those with -Y as the sole anomaly. Abnormal karyotypes, excluding those with -Y as the only change, were found in 36 cases. No recurrent structural aberration was found, but a nonrandom pattern of aberrations was seen. Total or partial gains and losses were the dominant karyotypic features. Genomic imbalances found in at least 10 cases included -1p36, -1p13-p22, -4, -5q13-q31, -6q22-qter, +7p13-pter, -9p22-pter, -10p, -10q24-qter, -11p13-pter, -11q25, +12q15-qter, -13q21-qter, -14q24-qter, -18p, -18q22-qter, +19, +20pter-q11, +21q, and -22q13. At the latest follow-up, 19 patients had experienced distant metastases, and the 5-year metastasis-free survival rate was 0.69. By univariate analysis, malignancy grade and loss of material from 6q, 10p, 11p or 11q, 13q, and 22q were associated with impaired metastasis-free survival. Only -13q was an independent prognostic factor for metastasis, regardless of tumor grade or size.     

Cytogenetic analysis of esophageal squamous cell carcinoma cell lines by comparative genomic hybridization: relationship of cytogenetic aberrations to in vitro cell growth

Cancer is characterized by autonomous growth of cells, and it is widely accepted that cell proliferation is primarily influenced by individual cell genetics. To elucidate the mechanisms of cancer cell proliferation, we studied differences in genetic aberrations for different type of tumors with different proliferation characteristics. We employed comparative genomic hybridization (CGH) to detect genetic aberrations in six cell lines of esophageal squamous cell carcinoma (ESCC). Three cell lines (YES-1, -2, and -3) grow in culture without fetal calf serum (group A), while others require serum to be maintained in vitro (group B). Both groups showed very similar cytogenetic aberrations: over-representations of 11q13 (6/6), 8q23-qter (5/6), Xq25-qter (5/6), 3q26-qter (4/6), 5p (4/6), 7p15-pter (4/6), 8q21.3-q22 (4/6), 17p (4/6), and 20q13 (4/6), and under-representations of 18q21-qter (6/6), 4q28-q33 (4/6), and 9p21 (4/6). Six amplification loci were mapped to chromosomal regions of 6q23 (1 case), 7p12 (2 cases), 9p21 (1 case), 11p11.2-12 (3 cases), 11q13 (2 cases), and 17p12 (2 cases). However, some differences were detected. DNA copy number increases at 7p12-p13, 11q14-q22, and 11q22-qter and under-representations of 4p, 8p, and 11p14-pter. In contrast, gains at 12p and 20p, and losses at 3p and 5q were detected only in group-B cell lines. These observations suggest that cytogenetic differences between the two groups may be linked to differences in cell growth characteristics in vitro, and that the genes in these chromosomal regions may play important roles in cell proliferation.     

Overrepresentation of 3q and 8q material and loss of 18q material are recurrent findings in advanced human ovarian cancer

In order to define the ability of comparative genomic hybridization (CGH) to detect and map genetic imbalances, we investigated 47 malignant ovarian tumors and 2 ovarian tumors of low malignant potential. The most common genetic changes in order of frequency included DNA gains of chromosome arms 8q (53%), 3q (51%), 20q (43%), 1p (32%), 19q (30%), 1q (28%), 12p (28%), 6p (21%), and 2q (19%). The smallest regions of overrepresentation could be defined in 3q26-qter, 8q23-qter, 1p35-pter, 12p12, and 6p21-22, respectively. Losses were detected on 18q (23%), chromosome 4 (23%), 13q (17%), and 16q (17%) with the smallest underrepresented regions on 18q22-qter, 13q21, and 16q23-qter. Also, losses of the X chromosome (19%) were detected, correlating with higher ages of the patients. Therefore, some of these X chromosome losses might be due to a well-known aging phenomenon and in these cases will be more preferably lost during cell division and tumor progression. Our findings show that ovarian carcinomas reveal consistent chromosomal abnormalities. Further detailed studies of these regions with specific molecular genetic techniques may lead to the identification of oncogenes and/or tumor suppressor genes playing an important role in the tumorigenesis of ovarian carcinomas. Genes Chromosom Cancer 16:46–54 (1996). © 1996 Wiley-Liss, Inc.     

Genomic imbalances in Korean hepatocellular carcinoma

Hepatocellular carcinoma (HCC) is one of the most prevalent gastrointestinal malignant tumors in Southeast Asia. Thirty-one cirrhotic HCC, 14 noncirrhotic HCC, and 13 metastastic HCC in the Korean population were investigated on microdissected tissues for chromosomal aberrations by degenerate oligonucleotide-primed polymerase chain reaction (PCR) comparative genomic hybridization. A number of prominent sites of genomic imbalances were observed. The gains of 1q, 6p, 7, 8q, 12q, 13q3-q32, 16p, 17q, and 20q and the losses of 1p, 4q, 6q, 8p, 9p, and 13q regions were observed with a similar high frequency in all types. Various chromosomal aberrations were observed preferentially to specific types. Gains of 4p15-pter, 10q24-qter, 18p11-pter, and 19p10-pter and a loss of 11q14-q22 were observed in the cirrhotic HCC, whereas losses of 14q21-q23 and 10q22-q23 were observed in noncirrhotic HCC. In metastatic HCC, gains of 3q25-qter and Xp21-pter and losses of 21q11-qter and Y were observed. The recurrent gains and losses of chromosomal regions identified in this study are consistent with several previous observations and provide possible candidate regions for the involvement of tumorigenesis and progressions of HCC.     

Comparative genomic hybridization analysis reveals 3q gain resulting in genetic alteration in 3q in advanced oral squamous cell carcinoma.

We analyzed DNA sequence copy number aberrations (DSCNAs) in 17 primary oral squamous cell carcinomas (OSCCs) by comparative genomic hybridization. DSCNAs were detected frequently at 3q25-qter (7/17), Xp21 (5/17), and Xq12-q23 and 8q23-q24 (4/17), and losses were detected frequently at 13q21-q22 (5/17), 3p21-pter, 4p15-pter and 17p13 (4/17), and 8p22-pter and 9p21-pter (3/17). Four tumors showed amplifications of seven loci: 3q11-qter, 3q13, 3q26, 7q21-q22, 8q23-qter, 9p22-pter, and 12p11. The total number of DSCNAs was significantly greater in stage III and stage IV tumors than in stage I and stage II tumors (P=.008). Furthermore, 3q gain was detected preferentially in stage III and stage IV tumors (6/8) rather than in stage I and stage II tumors (1/9, P=.013). In our study, all tumors with gain of 3q also contained one or more loss(es) in common regions. On the other hand, all tumors with gain of 9p did not contain 3q gains. These observations indicate that gain of 3q and accumulation of DSCNAs are strongly associated with tumor progression in OSCC. Furthermore, 3q gain and loss of one or more additional loci in common aberration regions appears to be a group of DSCNs associated with dominant genetic pathways of leading to advanced OSCCs.     

Analysis of BRCA1, TP53, and TSG101 germline mutations in German breast and/or ovarian cancer families

The establishment of esophageal cancer cell lines can facilitate the search for molecular mechanisms underlying its pathogenesis. Two novel human esophageal squamous cell carcinoma (ESCC) cell lines, HKESC-2 and HKESC-3, were established from a moderately differentiated ESCC of a 46-year-old Chinese woman and a well-differentiated ESCC of a 74-year-old Chinese man, both from Hong Kong. The pathological characteristics (morphological, immunohistochemical, and electron microscopic studies), tumorigenicity in nude mice, cytogenetic features, and DNA ploidy of the two cell lines were investigated. The two cell lines have been maintained in vitro for more than 17 months and passaged over 85 times for HKESC-2 and 58 times for HKESC-3. Both grew as monolayers, with a doubling time of 24 hours for HKESC-2 and 48 h for HKESC-3. Their squamous epithelial nature was authenticated by their strong immunopositivity with the anti-cytokeratin antibodies and the ultrastructural demonstration of tonofilaments and desmosomes. They are tumorigenic in nude mice and had DNA aneuploidy. G-banding cytogenetic analysis showed hyperdiploidy in HKESC-2 and near-tetraploidy in HKESC-3. Frequent breakpoints were noted at 1p22, 1p32, and 9q34 in HKESC-2 and at 1p31, 3p25, 3p14, 6q16, 6q21, 8p21, 9q34, 13q32, and 17q25 in HKESC-3. Comparative genomic hybridization analysis found that chromosomal gains were at 3q24-qter, 5q21-qter, 8q11-qter, 13q21-q31, 17q11-qter, 19, 22q22 for HKESC-2 and at 3q13-qter, 5p, 6p, 9q21-qter, 10q21-q22, 12q15-pter, 14q24-qter, 16, 17q24-qter, 20 for HKESC-3. Chromosomal losses were at 3p13-pter, 18q12-qter for HKESC-3. These two newly established cell lines will be useful tools in the study of the molecular pathogenesis and biological behavior of ESCC cells and for testing new therapeutic reagents for ESCC in the future.     

Methylation profiles of hereditary and sporadic ovarian cancer

Bol G M, Suijkerbuijk K P M, Bart J, Vooijs M, van der Wall E & van Diest P J
(2010) Histopathology 57, 363–370
Methylation profiles of hereditary and sporadic ovarian cancer Aims: Tumour suppressor gene silencing through promoter hypermethylation plays an important role in oncogenesis. Carcinogenesis of hereditary cancers usually differs from that of their sporadic counterparts, but methylation has hardly been studied in hereditary ovarian cancer. The aim of this study was to investigate promoter methylation of a set of common tumour suppressor genes in BRCA1‐related ovarian cancer in comparison with sporadic ovarian cancer. Methods and results: Methylation‐specific multiplex ligation‐dependent probe amplification was used to assess the extent of promoter methylation of 24 different tumour suppressor genes in BRCA1‐associated (n = 25) and matched sporadic ovarian tumours (n = 50). A cumulative methylation index (CMI) was calculated and differences between individual genes were analysed. There was no significant difference in cumulative methylation between BRCA1‐associated and sporadic ovarian carcinomas (median CMI 108; CMI 110; P = 0.86). Also, methylation patterns of individual genes did not show distinct differences after correction for multiple comparisons. CDH13, GSTP1 and RASSF1 were frequently methylated in both sporadic and hereditary ovarian cancers. BRCA1 methylation occurred in 14% of sporadic tumours, but was not detected in BRCA1‐associated tumours. Conclusions: CDH13, GSTP1 and RASSF1 are frequently methylated in both sporadic and BRCA1‐associated ovarian cancers. Interestingly, methylation of BRCA1, while frequent in sporadic ovarian cancer, never occurred in the hereditary group. BRCA1‐associated ovarian cancers mimic their sporadic counterparts in extent and pattern of promoter methylation of several common tumour suppressor genes. This finding could have implications for future chemotherapy regimens based on epigenetic changes.     

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.     

Genomic profiling of peripheral T-cell lymphoma, unspecified, and anaplastic large T-cell lymphoma delineates novel recurrent chromosomal alterations

To characterize genetic alterations in peripheral T-cell lymphoma, not otherwise specified (PTCL NOS), and anaplastic large T-cell lymphoma (ALCL), 42 PTCL NOS and 37 ALCL [17 anaplastic large cell kinase (ALK)-negative ALCL, 9 ALK-positive ALCL, 11 cutaneous ALCL] were analyzed by comparative genomic hybridization. Among 36 de novo PTCL NOS, recurrent chromosomal losses were found on chromosomes 13q (minimally overlapping region 13q21, 36% of cases), 6q and 9p (6q21 and 9p21-pter, in 31% of cases each), 10q and 12q (10q23-24 and 12q21-q22, in 28% of cases each), and 5q (5q21, 25% of cases). Recurrent gains were found on chromosome 7q22-qter (31% of cases). In 11 PTCL NOS, high-level amplifications were observed, among them 3 cases with amplification of 12p13 that was restricted to cytotoxic PTCL NOS. Whereas cutaneous ALCL and ALK-positive ALCL showed few recurrent chromosomal imbalances, ALK-negative ALCL displayed recurrent chromosomal gains of 1q (1q41-qter, 46%), and losses of 6q (6q21, 31%) and 13q (13q21-q22, 23%). Losses of chromosomes 5q, 10q, and 12q characterized a group of noncytotoxic nodal CD5+ peripheral T-cell lymphomas. The genetics of PTCL NOS and ALK-negative ALCL differ from other T-NHLs characterized genetically so far, among them enteropathy-type T-cell lymphoma, T-cell prolymphocytic leukemia, and adult T-cell lymphoma/leukemia.     

Genetic alterations in intrahepatic cholangiocarcinoma as revealed by degenerate oligonucleotide primed PCR-comparative genomic hybridization

Intrahepatic cholangiocarcinoma (ICC), a malignant neoplasm of the biliary epithelium,is usually fatal because of difficulty in early diagnosis and lack of availability of effective therapy. The genetic mechanisms involved in the development of ICC are not well understood and only a few cytogenetic studies of ICC have been published. Recently, technique of degenerate oligonucleotide primed (DOP)-PCR comparative genomic hybridization (CGH) permits genetic imbalances screening of the entire genome using only small amounts of tumor DNA. In this study chromosomal aberrations in 33 Korean ICC were investigated by DOP-PCR CGH. The common sites of copy number increases were 20q (67%), 17 (61%), 11q11-q13 (42%), 8p12- qter (39%), 18p (39%), 15q22-qter (36%), 16p (36%), 6p21 (30%), 3q25-qter (27%), 1q41-qter (24%), and 5p14-q11.2 (24%). DNA amplification was identified in 16 carcinomas (48%). The frequent sites of amplification were 20q, 17p, 17q23-qter, and 7p. The most frequent sites of copy number decreases were 1p32-pter (21%) and 4q (21%). The recurrent chromosomal aberrations identified in this study provide candidate regions involved in the tumorigenesis and progression of ICC.     

Genomic imbalances of 7p and 17q in malignant peripheral nerve sheath tumors are clinically relevant.

We investigated 31 malignant peripheral nerve sheath tumors (MPNSTs) from 23 patients by means of comparative genomic hybridization (CGH) in order to study quantitative genomic aberrations of these tumors. Twenty-one of the 23 patients revealed changes, with a mean value of 11 aberrations per sample (range 2-29). The minimal common regions of the most frequent gains were 8q23-q24.1 (12 cases), 5p14 (11 cases), and 6p22-pter, 7p15-p21, 7q32-q35, 8q21.1-q22, 8q24.2-qter, and 17q22-qter (10 cases each). Seventeen high-level amplifications were detected in eight of the 21 samples. In three cases, the high-level amplifications involved 8q24.1-qter, and in two cases each the high-level amplifications involved regions 5p14, 7p14-pter, 8q21.1-q23, and 13q32-q33. The minimal common region of frequent losses was 14q24.3-qter (five cases). The gain of 8q as a single common change in the primary tumor, the recurrence, and the metastasis from the same patient suggests that this aberration is an early change in the tumorigenesis of MPNSTs. Comparable aberrations were observed in separate tumors of the same patients affected by Recklinghausen's disease, indicating a limited number of accidental secondary changes. In sporadic MPNSTs, the most frequent gains were narrowed down predominantly to 5p, 6, 8q, and 20q, whereas in MPNSTs from patients with Recklinghausen's disease, there was most often a gain in 7q, 8q, 15q, and 17q. The occurrence of gain of both 7p15-p21 and 17q22-qter was associated with a statistically significant poor overall survival rate (P = 0.0096).     

DNA copy number changes and evaluation of MYC, IGF1R, and FES amplification in xenografts of pancreatic adenocarcinoma

We analyzed eight samples of xenografted human pancreatic tumors and two metastases developed in mice by comparative genomic hybridization (CGH). The most recurrent changes were: gains on chromosomes 8 (8q24-qter; 7/8 cases), 15 (15q25-q26; 6/8 cases), 16 (16p in 6/8 cases; 16q in 5/8 cases), 20 (20q; 6/8 cases), and 19 (19q; 5/8 cases); and losses on chromosomes 18 (18q21; 6/8 cases), 6 (6q16-q21 and 6q24-qter; 5/8 cases each), and 9 (9p23-pter; 5/8 cases). The two metastases maintained the aberrations of the original pancreatic tumor plus gain of 11q12-q13 and 22q. Loss of heterozygosity analysis was carried out for 10p14-pter, a region that was lost in 3/8 samples. All of them presented allelic imbalance for all the informative loci. Fluorescence in situ hybridization and Southern analysis were performed to test some candidate oncogenes in 8q24 (MYC) and 15q25-qter (IGF1R and FES). Two of seven tumors showed high-level amplification of MYC relative to the centromere (> 3-fold), another two tumors had low-level amplification (1.5- to 3.0-fold), and one displayed 5.5 MYC signals/cell. In relation to the FES gene, low-level amplification was found in three tumors. Southern analysis showed five cases with a low-level amplification of IGF1R. Our data suggest that either few extra gene copies may be enough for cancer progression or other genes located in these regions are responsible for the amplifications found by CGH.     

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.     

High frequency of allelic imbalance at regions of chromosome arm 8p in ovarian carcinoma

Progressive genetic changes such as the inactivation of tumor suppressor genes (TSG) are thought to play an important role in the initiation and progression of ovarian cancer. Frequent nonrandom allelic imbalance (AI) at 8p11-p21 and 8p22-pter suggests the existence of TSGs that may be involved in the carcinogenesis of several human malignancies. We investigated 70 ovarian tumors with 11 highly polymorphic markers spanning 8p12-p21 and 8p22-pter to produce an AI map of 8p in epithelial ovarian cancer. Allelic imbalance was demonstrated in 54 tumors (77%), most frequently occurring at D8S136 (54%) and at D8S1992 (55%). Poorly differentiated and advanced stage cancers were more often affected by AI (G1+G2 vs. G3; 20% vs. 66%; stage I+II vs. III+IV, 36% vs. 54%, P<.001; Kruskal-Wallis test) than well differentiated and early stage tumors. There was no relationship between histological subtype and AI. Smallest regions of overlap (SRO) were delineated by analyzing 38 tumors with partial AI. This study provides compelling evidence for the involvement of TSGs on the short arm of chromosome 8, at 8p12-p21 and at 8p23 in the development and progression of epithelial ovarian cancer.     

声门上喉癌的染色体异常和重要相关基因的研究

目的筛查声门上喉癌发生、发展及转移相关的异常染色体和重要基因。方法应用比较基因组杂交（comparative genomic hybridization，CGH）分析喉声门上鳞状细胞癌（laryngeal squamous cell cancer，LSCC）癌组织和癌旁组织DNA拷贝数的差异。应用cDNA芯片结合聚类分析研究喉声门上癌癌旁组织、癌组织和转移淋巴组织中差异表达的基因。结果CGH结果表明每例喉癌平均涉及12．9个染色体的异常，其中出现高频率扩增的染色体区集中在3q15-21（14／18）、5p12-13（11／18）、8q22-24（6／18）、11q12-13（8／18）、15q21-23（7／18）and 18p11（8／18），而高频率缺失的染色体区集中在1p13-21（8／18）、3p21-23（14／18）、5q21-22（14／18）、9p12-pter（11／18）and 13q21—31（8／18）。聚类分析将表达差异的基因分为3组。表达差异在5倍以上的基因12个，在由癌旁至癌阶段、癌至转移阶段均存在表达异常的基因3个。这15个重要基因是喉癌新的相关基因，其中4个基因cytoehrome C oxidase Va，PPBP，EPHX2 and PONI与喉癌相关性的研究未见报道，而且，SH3GL2位于高频率缺失的染色体区9p12-pter。结论我们发现的特异染色体区和重要基因将为喉癌发生、发展和转移的研究提供重要线索。