Increased copy number at 17q22-q24 by CGH in breast cancer is due to high-level amplification of two separate regions

Studies by comparative genomic hybridization (CGH) have defined a chromosomal site at 17q22-q24 that is often overrepresented in breast cancer, neuroblastoma, and several other tumor types. Due to the limited resolution and dynamic range of CGH, it remains unclear whether this gain reflects high-level amplification of small subregion(s) or low-level gain of most of the distal 17q. We used 32 physically mapped 17q probes to construct more accurate copy number profiles for 14 breast cancer cell lines by interphase fluorescence in situ hybridization (FISH). Six cell lines (43%) showed an increased copy number of the 17q22-q24 region by CGH, and seven (50%) by FISH. FISH copy number profiles had a substantially higher dynamic range than did CGH profiles. FISH revealed two independent, highly amplified regions (A and B) at 17q23, separated by about 5 Mb of non-amplified DNA. These regions were distinctly telomeric from the ERBB2 gene locus. However, region A was often co-amplified with ERBB2, whereas B was amplified in cell lines that showed no ERBB2 amplification. We conclude that distal 17q gains recently discovered in breast cancer by CGH are due to high-level amplifications of two different regions at 17q23. This chromosomal region has previously been reported to undergo allelic loss and therefore was thought to harbor a tumor suppressor gene. The present FISH data provide support for the presence, and a starting point for the positional isolation, of 17q23 genes whose upregulation by amplification may play a role in the progression of breast cancer and many other tumor types. Genes Chromosomes Cancer 20:372–376, 1997. © 1997 Wiley-Liss, Inc.     

Loss of the chromosomal region 5q11-q31 in the myeloid cell line HL-60: Characterization by comparative genomic hybridization and fluorescence in situ hybridization

Comparative genomic hybridization was used to identify the regions of genomic gain and loss in the myeloid cell line HL-60. These included amplification at 8q24 corresponding to previous reports of overrepresentation of the MYC gene; loss of material from the short arms of chromosomes 9 (9p21-p23), 10, and 17; loss of the chromosome regions 9q32-qter and 14q11-q24; and an extra copy of chromosome 18. Additionally, deletion of the 5q11-q31 region was noted and was associated with translocation of chromosome 5 material to chromosomes 16 and a dic(5;17)(q11;p11) chromosome (previously described as mar3). Loss of chromosome 5 material in myeloid malignancies, including the M2 subtype from which HL-60 was derived, is usually associated with interstitial deletions of the long arm, including the critical 5q31 region, resulting in a 5q-chromosome. The HL-60 cell line may be a useful model to investigate the role of potential tumour suppressor genes associated with loss of 5q material in myeloid leukaemias. Genes Chromosom Cancer 15:182–186 (1996). © 1996 Wiley-Liss, Inc.     

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.     

Loss of chromosome 13 is the most frequent genomic imbalance in malignant fibrous histiocytomas. A comparative genomic hybridization analysis of a series of 30 cases.

Regional chromosome localizations of DNA copy number imbalances were studied by comparative genomic hybridization in 30 malignant fibrous histiocytomas: 13 primary tumors (2 myxoid, 9 storiform pleomorphic, and 2 with more undifferentiated phenotype) and 17 local recurrences (2 myxoid, 11 storiform pleomorphic, and 4 with more undifferentiated phenotype). Abnormal comparative genomic hybridization (CGH) profiles were observed in 25 tumors (83%). The most frequent gains (ratio > 1.2) corresponded, by order of frequency, to entire Xp, and bands 1q21, 19q13.1, 19p13, 5p13-p14, 1p31, 17p, 18p, 20q, 1p35, 17q23, and 22q12. High levels of gains (ratio > 1.5) were recurrently detected for Xp (10 cases), and in bands 1q21-q22 (8 cases), 3q27 (4 cases), 5p13-p14 (3 cases), 13q32-q34 (3 cases), 15q22-q26 (3 cases), and 17p11-p12 (3 cases). Losses of 13q12-q14 or 13q21 were observed in a large proportion of tumors (17 cases), suggesting that a gene localized in this region could act as a tumor suppressor gene. Losses of 11q23, 2q32, 11p13, 10p, 1q4, 9p2, 16q12, 4q3, 10q25, 3p23, 2p24, and 12p were also recurrently observed. Taken together, these results provide an overview of chromosome imbalances present in MFH, which could be of use for diagnostic purposes. They point to various chromosome regions which may harbor genes important for malignant fibrous histiocytomas (MFH) oncogenesis and progression.     

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.     

Amplification of <Emphasis Type="Italic">NOTCH1</Emphasis> and <Emphasis Type="Italic">ABL1</Emphasis> gene loci is a frequent aberration in enteropathy-type T-cell lymphoma

We have shown previously that amplification of chromosomal region 9q34 is the most frequent aberration in enteropathy-type T-cell lymphoma (ETL). To determine the minimum amplified 9q34 region and identify possible candidate gene(s), we performed a detailed microsatellite screening and quantitative real-time PCR (QPCR) on 26 ETL cases. Microsatellite analysis revealed allelic imbalance in both ABL1 and NOTCH1 gene loci (microsatellites D9S290–D9S1847 and D9S158 flanking the former and latter genes, respectively) localized in the band 9q34. The results were confirmed by TaqMan-based QPCR showing amplification of ABL1 and NOTCH1 exons in 50% and 65% of cases, respectively. Amplifications of the NOTCH1 gene were more frequent than of the ABL1 gene; moreover, the analyzed NOTCH1 exon consistently displayed higher levels of amplification than ABL1 coding sequences. From 9q34 known genes, NOTCH1 could thus be the primary target of genomic DNA amplification in ETL.     

Concomitant gastrin and ERBB2 gene amplifications at 17q12–q21 in the intestinal type of gastric cancer

Our recent studies using comparative genomic hybridization showed that gain or amplification at the 17q12–q21 region is very common in the intestinal type of gastric cancer. Here, we describe a fluorescence in situ hybridization study with gastrin (GAS)‐specific and ERBB2‐specific probes on ten specimens of gastric carcinoma that, by using comparative genomic hybridization, showed 1) DNA copy number gain or amplification at 17q12–q21, a region known to harbor the GAS and ERBB2 genes (four cases); 2) gain of the entire chromosome 17 (three cases); or 3) normal copy number of chromosome 17 (three cases). GAS and ERBB2 protein expression was studied by Western immunoblotting from gastric cancer cell lines with or without gain at 17q12–q21 as well as a breast cancer cell line with ERBB2 amplification. Our results showed that simultaneous amplification of both GAS and ERBB2 was four‐ to ninefold in the tumors with the 17q12–q21 amplification. Both genes were amplified in the same nuclei, and the hybridization signals were localized to the same region of the nucleus. Overexpression of GAS and ERBB2 was observed by Western immunoblotting only in the gastric cancer cell line with gain at 17q12–q21. The ERBB2 amplification is also a recurrent change in breast cancer. To investigate whether the GAS amplification is unique in gastric cancer, fluorescence in situ hybridization analysis was performed on 40 breast cancer cell lines. The ERBB2 amplification was observed in 11 cell lines, but none of the lines showed the GAS amplification. This indicates that the formation of an amplicon, in which both the GAS and the ERBB2 genes are amplified, might be unique in gastric cancer, especially in its intestinal type, and that simultaneous amplification of both genes is important to the tumorigenesis of intestinal gastric cancer. We demonstrate here for the first time that a gene of a physiological hormone is amplified in tumors that originate from cells that normally secrete the hormone. Genes Chromosomes Cancer 24:24–29, 1999. © 1999 Wiley‐Liss, Inc.     

Recurrent cytogenetic abnormalities in squamous cell carcinomas of the head and neck region

We characterized the breakpoints, gains, and losses of chromosome material in squamous cell carcinomas of the head and neck region from 29 patients. Cell lines were karyotyped in 1/3 of cases, direct preparations or early in vitro harvests in 1/3, and both in 1/3 of cases. GTG-banding was employed in all cases, as were C-banding and RBG- and AgNOR-staining in most. Some tumors were near-diploid and others near-tetraploid, but many had mixed populations, with diploid, tetraploid, and octoploid subclones representing essentially the same karyotypic pattern. The most frequent changes were deletions. Losses affecting 3p13-p24, 5q12-q23, 8p22-p23, 9p21 -p24, and 18q22-q23 ranged in frequency from 40% to 60% of tumors. Loss of the short arm of the inactive X occurred in 70% of tumors from female patients, and loss or rearrangement of the Y occurred in 74% of tumors from male patients. Loss of 18q appeared to be associated with short survival, as did the presence of multiple deletions. There was gain (2-5 extra copies) of 3q21 -qter, 5p, 7p, 8q, and 11q 13-q23 in 28-38% of tumors. Three tumors had an hsr involving 11q13-q21. Gain of material at 11q13 is postulated to be associated with amplification of the PRADI/CCND gene at that locus. A translocation between proximal 1 p and either an acrocentric short arm or proximal 8p or 9p was observed in squamous cell carcinomas of the head and neck region but not in female genital tract tumors. No other abnormalities appeared to be site specific, suggesting a pattern of genetic evolution in squamous cell carcinoma that is independent of anatomic site. Genes Chrom Cancer 9:192-206 (1994). © 1994 Wiley-Liss, Inc.     

Molecular cytogenetic characterization and physical mapping of 12q13–15 amplification in human cancers

Amplification of sequences derived from 12q13-15 is frequent in human sarcomas and brain tumors. Detailed mapping studies of the amplified region are necessary for definition of the impact of these amplification events on the tumor cell phenotype. By using the genes in this region and genomic fragments isolated by chromosome microdissection, we have established a series of ordered probes from 12q13-15 for fluorescence in situ hybridization (FISH) and Southern blot analysis. These probes have been used for physical mapping of two portions of the interval from GLI to D12S8. The centromeric region extends 1.8 Mb from GLI to microclone M79 and contains at least five genes, including the cyclin-dependent kinase gene CDK4. The more telomeric region includes the p53 regulator MDM2 and covers 1.1 Mb. We used the same group of probes to determine the pattern of amplification in three cell lines and three tumor specimens carrying amplified sequences from 12q13-15. In addition, we used a yeast artificial chromosome (YAC) contig of several megabases covering the entire region from SAS to D12S8 for FISH to determine the pattern of amplification in the neuroblastoma cell line NGP-127. The results suggest that the MDM2 and CDK4 regions may be either coamplified or amplified independently, and they illustrate how the map positions of genes and their functions may interact to determine the pattern of DNA amplification in human malignancies. Genes Chromosom Cancer 17:205–214 (1996). © 1996 Wiley-Liss, Inc.

1 This article is a US Government work and, as such, is in the public domain in the United States of America.

     

Localization,structure and polymorphism of two paralogous <Emphasis Type="Italic">Xenopus laevis</Emphasis> mitochondrial malate dehydrogenase genes

Two paralogous mitochondrial malate dehydrogenase 2 (Mdh2) genes of Xenopus laevis have been cloned and sequenced, revealing 95% identity. Fluorescence in-situ hybridization (FISH) combined with tyramide amplification discriminates both genes; Mdh2a was localized into chromosome q3 and Mdh2b into chromosome q8. One kb cDNA probes detect both genes with 85% accuracy. The remaining signals were on the paralogous counterpart. Introns interrupt coding sequences at the same nucleotide as defined for mouse. Restriction polymorphism has been detected in the first intron of Mdh2a, while the individual variability in intron 6 of Mdh2b gene is represented by an insertion of incomplete retrotransposon L1Xl. Rates of nucleotide substitutions indicate that both genes are under similar evolutionary constraints. X. laevis Mdh2 genes can be used as markers for physical mapping and linkage analysis.     

High-resolution genomic profiling of adenomas and carcinomas of the salivary glands reveals amplification, rearrangement, and fusion of HMGA2

Carcinoma ex pleomorphic adenoma (Ca-ex-PA) is an epithelial malignancy developing within a benign salivary gland pleomorphic adenoma (PA). Here we have used genome-wide, high-resolution array-CGH, and fluorescence in situ hybridization to identify genes amplified in double min chromosomes and homogeneously staining regions in PA and Ca-ex-PA and to identify additional genomic imbalances characteristic of these tumor types. Ten of the 16 tumors analyzed showed amplification/gain of a 30-kb minimal common region, consisting of the 5'-part of HMGA2 (encoding the three DNA-binding domains). Coamplification of MDM2 was found in nine tumors. Five tumors had cryptic HMGA2-WIF1 gene fusions with amplification of the fusion oncogene in four tumors. Expression analysis of eight amplified candidate genes in 12q revealed that tumors with amplification/rearrangement of HMGA2 and MDM2 had significantly higher expression levels when compared with tumors without amplification. Analysis of individual HMGA2 exons showed that the expression of exons 3-5 were substantially reduced when compared with exons 1-2 in 9 of 10 tumors with HMGA2 activation, indicating that gene fusions and rearrangements of HMGA2 are common in tumors with amplification. In addition, recurrent amplifications/gains of 1q11-q32.1, 2p16.1-p12, 8q12.1, 8q22-24.1, and 20, and losses of 1p21.3-p21.1, 5q23.2-q31.2, 8p, 10q21.3, and 15q11.2 were identified. Collectively, our results identify HMGA2 and MDM2 as amplification targets in PA and Ca-ex-PA and suggest that amplification of 12q genes (in particular MDM2), deletions of 5q23.2-q31.2, gains of 8q12.1 (PLAG1) and 8q22.1-q24.1 (MYC), and amplification of ERBB2 may be of importance for malignant transformation of benign PA.     

Molecular cytogenetic analysis of non-small cell lung carcinoma by spectral karyotyping and comparative genomic hybridization

The overall pattern of chromosomal changes detected by spectral karyotype (SKY) analysis of two cell lines of each major histological subtype of NSCLC, namely squamous cell carcinoma (SQCC) and adenocarcinoma (ADC), indicated a greater degree of chromosomal rearrangement, than was present or predicted by either comparative genomic hybridization (CGH) or G-banding analysis alone. To investigate these observations, CGH was used to screen DNA derived from 8 primary tumors and 15 cell lines. The results indicated that the most frequently gained chromosome arms were 5p (70%), 8q (65%), 15q (52%), 20q (48%), 1q (43%), 19q (39%), 3q (35%), and 11q (35%). Chromosomal losses were less frequently observed, and included 18q (39%), 9 (35%), 6q (30%), 13q (21%), 5q12-q32 (17%), and 19p (17%). Amplifications were found on 2p23-p24, 3q24-q27, 5p, 6cen-p21.1, 6q26, 7p21, 7q31, 8q, 11q13-qter, 20q12-q13.2. Comparison between CGH findings of the two major histological subtypes showed that gains at 1q22-q32.2, 15q, 20q, and losses at 6q, 13q, and 18q was common in ADCs, whereas SQCCs exhibited gains/amplifications at 3q. Distal 8q was gained by CGH in 65% of tumors of both subtypes. Low level MYCC amplification was confirmed by direct fluorescence in situ hybridization (FISH) analysis. The pattern of overall chromosomal changes detected using combinations of molecular cytogenetic analytical methods suggests that it will be easier to detect recurrent subtype-dependent aberrations in NSCLC.     

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.     

Positional gene expression analysis identifies 12q overexpression and amplification in a subset of neuroblastomas

Neuroblastoma is a heterogeneous disease with variable clinical behaviors. Unique molecular features are associated with clinically relevant subgroups. We performed a comprehensive microarray gene expression analysis of 95 neuroblastomas in an effort to define clinically important molecular subtypes. A subset of tumors overexpressed several contiguous genes located at 12q13 approximately q15 and were studied further. By microarray, 5 of 95 neuroblastomas had overexpression of genes mapped to 12q13.1 approximately q15, suggesting an amplification event in this region. Positional expression mapping identified the narrowest region of overlap containing 21 genes, with 11 genes overexpressed in all five cases. Fluorescence in situ hybridization demonstrated 3 neuroblastomas with more than a 10-fold increase in 12q gene copies and 9 with 3- to 5-fold increases. Amplification and overexpression of genes at 12q13 approximately q15 were observed in a small subset of neuroblastomas. Although amplification of 12q has been previously reported in neuroblastoma cell lines, this is the first demonstration in tumor samples, and it defines a distinct subset that has not been described previously. The expressed genes mapped closely to the complex amplicon reported in sarcomas, and they identify critical genes and pathways affected by 12q gene amplification.     

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.     

Chromosomal gains and losses are uncommon in hairy cell leukemia: a study based on comparative genomic hybridization and interphase fluorescence in situ hybridization.

In contrast to other subtypes of lymphoproliferative malignancies, the genetic mechanisms underlying the pathogenesis of hairy cell leukemia (HCL) are unknown. We studied densely infiltrated splenic tissue of 14 cases of HCL for the presence of chromosomal gains and losses by comparative genomic hybridization (CGH). Chromosomal imbalances were detected in only four of the 14 cases. Chromosomal gains involved the regions 5q13-q31 (two cases) and 1p32-p36.2 (one case). A loss of the region 11q14-q22 was found in one additional patient. The imbalances affecting the regions 5q and 11q were confirmed by interphase fluorescence in situ hybridization (FISH) using PAC clone 144G9 (5q31) and YAC clones 755B11 (11q22.3-q23.1) and 801E11 (11q22.3-q23.1 spanning the ATM gene) and occurred in 61% to 75% of analyzed nuclei. The latter DNA probes and probes hybridizing to chromosomal regions, which are frequently deleted in other subtypes of non-Hodgkin lymphomas (NHL), namely 9p21/ P16(INK4A), 13q14/D13S25, and 17p13/P53 were subsequently applied to all 14 cases of HCL, but no additional abnormalities were found. We conclude that overrepresentation of chromosome 5 represents a recurrent aberration in HCL and that the commonly overrepresented region resides in 5q13-q31. Chromosomal imbalances including deletions of the tumor suppressor gene loci 9p21/P16(INK4A), 13q14/D13S25, and 17p13/P53 rarely occur in HCL in contrast to some other subtypes of B-cell NHL. The pathogenetic role of 11q/ATM alterations in HCL remains to be determined.