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High-level Amplification (high-level + amplification)

Distribution by Scientific Domains
Medical Sciences100%
Distribution within Medical Sciences
Oncology & Radiotherapy71%
Pathology28%

Selected Abstracts

High-throughput tissue microarray analysis of 11q13 gene amplification (CCND1, FGF3, FGF4, EMS1) in urinary bladder cancer

THE JOURNAL OF PATHOLOGY, Issue 4 2003
Boriana M Zaharieva
Abstract Gene amplification is a common mechanism for oncogene overexpression. High-level amplifications at 11q13 have been repeatedly found in bladder cancer by comparative genomic hybridization (CGH) and other techniques. Putitative candidate oncogenes located in this region are CCND1 (PRAD1, bcl-1), EMS1, FGF3 (Int-2), and FGF4 (hst1, hstf1). To evaluate the involvement of these genes in bladder cancer, a tissue microarray (TMA) containing 2317 samples was screened by fluorescence in situ hybridization (FISH). The frequency of gains and amplifications of all genes increased significantly from stage pTa to pT1,4 and from low to high grade. In addition, amplification was associated with patient survival and progression of pT1 tumours. Among 123 tumours with amplifications, 68.3% showed amplification of all four genes; 19.5% amplification of CCND1, FGF4, and FGF3; and 0.8% co-amplification of FGF4, FGF3, and EMS1. Amplification of CCND1 alone was found in 9% of the tumours, while EMS1 alone was amplified in 1.6% and FGF4 in 0.8%. Overall, the amplification frequency decreased with increasing genomic distance from CCND1, suggesting that, among the genes examined, CCND1 is the major target gene in the 11q13 amplicon in bladder cancer. Copyright © 2003 John Wiley & Sons, Ltd. [source]

Profiling genomic copy number changes in retinoblastoma beyond loss of RB1

GENES, CHROMOSOMES AND CANCER, Issue 2 2007
Ella Bowles
Loss of both RB1 alleles is rate limiting for development of retinoblastoma (RB), but genomic copy number gain or loss may impact oncogene(s) and tumor suppressor genes, facilitating tumor progression. We used quantitative multiplex polymerase chain reaction to profile "hot spot" genomic copy number changes for gain at 1q32.1, 6p22, and MYCN, and loss at 16q22 in 87 primary RB and 7 cell lines. Loss at 16q22 (48%) negatively associated with MYCN gain (18%) (Fisher's exact P = 0.031), gain at 1q32.1 (62%) positively associated with 6p "hot spot" gain (43%) (P = 0.033), and there was a trend for positive association between 1q and MYCN gain (P = 0.095). Cell lines had a higher frequency of MYCN amplification than primary tumors (29% versus 3%; P= 0.043). Novel high-level amplification of 1q32.1 in one primary tumor, confirmed by fluorescence in situ hybridization, strongly supports the presence of oncogene(s) in this region, possibly the mitotic kinesin, KIF14. Gene-specific quantitative multiplex polymerase chain reaction of candidate oncogenes at 1q32.1 (KIF14), 6p22 (E2F3 and DEK), and tumor suppressor genes at 16q22 (CDH11) and 17q21 (NGFR) showed the most common gene gains in RB to be KIF14 in cell lines (80%) and E2F3 in primary tumors (70%). The patterns of gain/loss were qualitatively different in 25 RB compared with 12 primary hepatocellular carcinoma and 12 breast cancer cell lines. Gene specific analysis of one bone marrow metastasis of RB, prechemotherapy and postchemotherapy, showed the typical genomic changes of RB pretreatment, which normalized after chemotherapy. © 2006 Wiley-Liss, Inc. [source]

The gene for polycomb group protein enhancer of zeste homolog 2 (EZH2) is amplified in late-stage prostate cancer

GENES, CHROMOSOMES AND CANCER, Issue 7 2006
Outi R. Saramäki
Overexpression of the polycomb group protein enhancer of zeste homologue 2 (EZH2) has been found in several malignancies, including prostate cancer, with an aggressive phenotype. Amplification of the gene has previously been demonstrated in several malignancies, but not in prostate cancer. Our goal was to evaluate the gene copy number and expression alterations of EZH2 in prostate cancer. The copy number of EZH2 in cell lines (LNCaP, DU145, PC-3, 22Rv1), xenografts (n = 10), and clinical tumors (n = 191) was studied with fluorescence in situ hybridization. All cell lines had a gain of EZH2. Eight of the ten xenografts showed an increased copy number of the gene, including one case of high-level amplification (,5 copies of the gene and EZH2/centromere ratio ,2). 34/125 (27%) of untreated prostate carcinomas showed increased copy number, but only one case of low-level amplification (,5 copies of the gene and EZH2/centromere ratio <2), whereas half (25/46) of the hormone-refractory carcinomas showed increased copy number, including seven cases of low-level amplification and three cases of high-level amplification (P < 0.0001). Expression of EZH2 was significantly (P = 0.0009) higher in hormone-refractory prostate cancer compared with that in benign prostatic hyperplasia or untreated cancer, according to quantitative real-time RT-PCR assay. Also, the expression of EZH2 protein was found to be higher in hormone-refractory tumors than in hormone-naïve tumors by immunohistochemistry. The EZH2 gene amplification was significantly (P < 0.05) associated with increased EZH2 protein expression. The data show that amplification of the EZH2 gene is rare in early prostate cancer, whereas a fraction of late-stage tumors contains the gene amplification leading to the overexpression of the gene, thus indicating the importance of EZH2 in the progression of prostate cancer. © 2006 Wiley-Liss, Inc. [source]

Genome profiles of familial/bilateral and sporadic testicular germ cell tumors

GENES, CHROMOSOMES AND CANCER, Issue 2 2002
Sigrid Marie Kraggerud
In order to investigate the genetics of testicular germ cell tumors (TGCTs), we examined 33 TGCTs, including 15 familial/bilateral and 18 sporadic tumors, using comparative genomic hybridization. The frequencies of the histological subtypes were comparable between the two groups. Gains of the whole or parts of chromosome 12 were found in 30 tumors (91%). Furthermore, increased copy number of the whole or parts of chromosomes 7, 8, 17, and X, and decreased copy number of the whole or parts of chromosomes 4, 11, 13, and 18 were observed in ,50% of the tumors. Sixteen smallest regions of overlapping changes were delineated on 12 different chromosomes. The chromosomal copy numbers of familial/bilateral and sporadic TGCTs were comparable, suggesting similar genetic pathways to disease in both groups. However, significant differences were observed between the two main histological subgroups. Gains from 15q and 22q were associated with seminomas (P = 0.005 and P = 0.02, respectively), whereas gain of the proximal 17q (17q11.2,21) and high-level amplification from chromosome arm 12p, and losses from 10q were associated with nonseminomas (P < 0.001, P = 0.04, and P = 0.03, respectively). © 2002 Wiley-Liss, Inc. [source]

Allelic Gain and Amplification on the Long Arm of Chromosome 17 in Anaplastic Meningiomas

BRAIN PATHOLOGY, Issue 2 2002
Rainer Büschges
Using comparative genomic hybridization (CGH) we have previously identified amplification at 17q21-qter as a common aberration in anaplastic meningiomas but not in atypical or benign meningiomas (19). To define the amplified genomic region, we analyzed 44 meningeal tumors, including 7 benign meningiomas of World Health Organization (WHO) grade I, 19 atypical meningiomas (WHO grade II) and 18 anaplastic meningiomas (WHO grade III) at 46 chromosome 17 loci (including 42 17q loci). In line with the CGH data we found evidence of increased numbers of alleles on 17q. The incidence rose with malignancy grade, culminating at 61% (11 of 18 cases) in the anaplastic meningioma group. The majority of cases showing increased allele numbers had, on average, low-level allelic gains (relative increase in allele dosage of 2- to 5-fold). Amplification of alleles (defined here as an average relative increase in allele dosage of more than 5 times) was detected in 2 anaplastic meningiomas. The amplification patterns in these tumors defined a number of common regions of amplification/increased allele copy number, the best defined include one between D17S790 and D17S1607 and one between D17S1160 and PS6K. Real-time PCR analysis of the PS6K candidate gene revealed no high-level amplification despite this affecting adjacent loci. Our findings are fundamental for the identification of the gene(s) in 17q22-q23 that is (are) the target(s) for increased copy number in anaplastic meningiomas and possibly other tumor types. [source]

ITCH is a putative target for a novel 20q11.22 amplification detected in anaplastic thyroid carcinoma cells by array-based comparative genomic hybridization

CANCER SCIENCE, Issue 10 2008
Takaya Ishihara
Anaplastic thyroid carcinoma (ATC) is one of the most virulent of all human malignancies, with a mean survival time among patients of less than 1 year after diagnosis. To date, however, cytogenetic information on this disease has been very limited. During the course of a program to screen a panel of ATC cell lines for genomic copy-number aberrations using array-based comparative genomic hybridization, we identified a high-level amplification of the ITCH gene, which is mapped to 20q11.22 and belongs to the homologous to the E6-associated protein carboxylterminus ubiquitin ligase family. The expression of ITCH was increased in 4 of 14 ATC cell lines (28.6%), including 8305C in which there was a copy-number amplification of this gene, and six of seven primary cases (85.7%). Among the primary thyroid tumors, a considerable number of ITCH high expressers was found in ATC (40/45, 88.9%), papillary thyroid carcinoma (25/25, 100%), and papillary microcarcinoma (25/25, 100%). Furthermore, knockdown of ITCH by specific small interfering RNA significantly inhibited the growth of ITCH-overexpressing cells, whereas ectopic overexpression of ITCH promoted growth of ATC cell lines with relatively weak expression. These observations indicate ITCH to be the most likely target for 20q11.22 amplification and to play a crucial role in the progression of thyroid carcinoma. (Cancer Sci 2008; 99: 1940,1949) [source]

Selective elimination of amplified CDK4 sequences correlates with spontaneous adipocytic differentiation in liposarcoma

GENES, CHROMOSOMES AND CANCER, Issue 11 2009
Zofia Hélias-Rodzewicz
Well-differentiated and undifferentiated liposarcomas are characterized by high-level amplifications of chromosome 12 regions including the CDK4 and MDM2 genes. These amplicons are either localized, in well-differentiated liposarcoma (WDLPS), on extrachromosomal structures (ring or rod chromosomes), or integrated into chromosome arms in undifferentiated tumors. Our results reveal that extrachromosomal amplicons are unstable, and frequently lost by micronucleation. This loss correlates with hypermethylation of eliminated sequences and changes of their replication time. Treatment of cells with demethylating agents during early S-phase significantly decreases the rate of micronuclei positive for CDK4. We also demonstrate that, in our model, micronuclei are generated during anaphase as a consequence of anaphase abnormalities (chromosome lagging and anaphase bridges). Finally, a dramatic increase of adipocytic differentiation was noted in cells that have eliminated copies of CDK4 gene in micronuclei. These findings provide evidence that, in WDLPS, adipocytic differentiation could be the consequence of CDK4 loss, an event occurring rarely in undifferentiated tumors in which the amplified sequences are integrated into chromosome arms. © 2009 Wiley-Liss, Inc. [source]