Genomic alterations and phenotype of large compared to small high-grade ductal carcinoma in situ

A clinically distinct subgroup of pure ductal carcinoma in situ presents as an extensive, high-grade lesion, which nevertheless lacks invasion. We sought to evaluate differences between those ductal carcinomas in situ presenting as large versus small lesions while controlling for high-grade, to determine whether there exist phenotypic and genetic differences between the 2 groups. Fifty-two cases of pure high-grade ductal carcinomas in situ were collected retrospectively, consisting of 27 large (>40 mm) and 25 small (<15 mm) cases. The 2 groups were compared based on genomic copy number assessed by array-based comparative genomic hybridization and by phenotype determined by immunohistochemistry for estrogen receptor, progesterone receptor, Ki-67, p53, cyclin D1, p16, cyclooxygenase 2, human epidermal growth factor receptor 2, and CD68. Large lesions presented at a younger age, with lower incidence of comedonecrosis and periductal macrophage response. Larger lesions also had significantly lower estrogen receptor expression, lower cyclin D1 expression, and lower Ki-67 index. The subset of 9 large palpable tumors had significantly lower p16/cyclooxygenase 2 expression and lower Ki-67 index compared to nonpalpable tumors. Genomically, larger lesions had fewer break points, fewer amplifications, and decreased copy number gains involving chromosome 8q and chromosome 20q when compared to the small lesions. Among pure high-grade tumors, small and large groups show specific genomic and phenotypic differences. Interestingly, larger tumors showed some molecular features associated with better prognosis. A more thorough evaluation of these differences could help identify the likelihood of recurrence or progression for in situ lesions.     

Quantitative multigene FISH on breast carcinomas identifies der(1;16)(q10;p10) as an early event in luminal A tumors

In situ detection of genomic alterations in cancer provides information at the single cell level, making it possible to investigate genomic changes in cells in a tissue context. Such topological information is important when studying intratumor heterogeneity as well as alterations related to different steps in tumor progression. We developed a quantitative multigene fluorescence in situ hybridization (QM FISH) method to detect multiple genomic regions in single cells in complex tissues. As a “proof of principle” we applied the method to breast cancer samples to identify partners in whole arm (WA) translocations. WA gain of chromosome arm 1q and loss of chromosome arm 16q are among the most frequent genomic events in breast cancer. By designing five specific FISH probes based on breakpoint information from comparative genomic hybridization array (aCGH) profiles, we visualized chromosomal translocations in clinical samples at the single cell level. By analyzing aCGH data from 295 patients with breast carcinoma with known molecular subtype, we found concurrent WA gain of 1q and loss of 16q to be more frequent in luminal A tumors compared to other molecular subtypes. QM FISH applied to a subset of samples (n = 26) identified a derivative chromosome der(1;16)(q10;p10), a result of a centromere‐close translocation between chromosome arms 1q and 16p. In addition, we observed that the distribution of cells with the translocation varied from sample to sample, some had a homogenous cell population while others displayed intratumor heterogeneity with cell‐to‐cell variation. Finally, for one tumor with both preinvasive and invasive components, the fraction of cells with translocation was lower and more heterogeneous in the preinvasive tumor cells compared to the cells in the invasive component. © 2014 The Authors Genes, Chromosomes & Cancer Published by Wiley Periodicals, Inc.     

Comparative genomic hybridization reveals recurrent enhancements on chromosome 20 and in one case combined amplification sites on 15q24q26 and 20p11p12 in glioblastomas

We examined homogenized tissue samples of biopsies from 19 astrocytomas of different grades for genetic imbalances using comparative genomic hybridization (CGH): three astrocytomas grade II, and 16 astrocytomas grade IV (glioblastoma multiforme), one of the glioblastomas representing the recurrence of a benign oligoastrocytoma. In two of three cases of astrocytoma grade II, a gain of chromosome 7 was found. The alterations in the glioblastomas were complex, and most frequently showed the characteristic gain of chromosome 7 and loss of chromosome 10. The single analyzed case of recurrence of an oligoastrocytoma was characterized by a unique CGH pattern. This tumor showed two distinct alterations: apart from an amplification on 15q24q26, we found a distinct amplification of a small region on 20p11.2p12, which has not been previously described in brain tumors. Partial or complete gains of chromosome 20 arose in six other tumors; we conclude that chromosome 20 in particular 20p11. 2p12, may harbor relevant genes for glioma progression.     

Comparative genomic hybridization identifies loss of 18q22-qter as an early and specific event in tumorigenesis of midgut carcinoids

Carcinoid tumors are rare neuroendocrine tumors occurring in the lung or in the digestive tract where they are further subclassified as foregut, midgut, or hindgut carcinoids. To gain a better understanding of the genetic basis of the different types of carcinoid tumors, we have characterized numerical imbalances in a series of midgut carcinoids, and compared the results to previous findings in carcinoids from the lung. Numerical imbalances were revealed in 16 of the 18 tumors, and the most commonly detected aberrations were losses of 18q22-qter (67%), 11q22-q23 (33%), and 16q21-qter (22%), and gain of 4p14-qter (22%). The total number of alterations found in the metastases was significantly higher than in the primary tumors, indicating the accumulation of acquired genetic changes in the tumor progression. Losses of 18q and 11q were present both in primary tumors and metastases, whereas loss of 16q and gain of 4 were only detected in metastases. Furthermore, the pattern of comparative genomic hybridization alterations varied depending on the total number of detected alterations. Taken together, the findings would suggest a progression of numerical imbalances, in which loss of 18q and 11q represent early events, and loss of 16q and gain of 4p are late events in the tumor progression of midgut carcinoids. When compared to previously published comparative genomic hybridization abnormalities in lung carcinoids, loss of 11q was found to occur in both tumor types, whereas loss of 18q and 16q and gain of 4 were not revealed in lung carcinoids. The results indicate that inactivation of a putative tumor suppressor gene in 18q22-qter represents a frequent and early event that is specific for the development of midgut carcinoids.     

Common chromosomal abnormalities in mycosis fungoides transformation

To identify cytogenetic features of large cell transformation in mycosis fungoides (T-MF), we selected in 11 patients, 16 samples either from skin tumors (13), lymph node (1), or peripheral blood cells (2) collected at the time of the transformation. Comparative genomic hybridization (CGH), G-banding, fluorescence in situ hybridisation (FISH), multicolour FISH (mFISH), and DNA content analysis were used. Fifteen samples displayed unbalanced CGH profiles, with gains more frequently observed than losses. Recurrent chromosomal alterations were observed for chromosomes 1, 2, 7, 9, 17, and 19. The most common imbalances were gain of chromosome regions 1p36, 7, 9q34, 17q24-qter, 19, and loss of 2q36-qter, 9p21, and 17p. In six samples 1p36-pter gain was associated with 9q34-qter gain and whole chromosome 19 gain. In five of these samples whole or partial gain of chromosome 17 was also observed. No specific pattern was seen with regard to the expression of the CD30 antigen by tumor cells. Cytogenetics and/or DNA content analysis of skin tumor cells revealed an abnormal chromosome number in all tested cases (n = 7) with DNA ploidy ranging from hyperdiploid (2.78) to hypotetraploid (3.69) (mean 3.14+/-0.38). Thus, T-MF displayed frequent chromosomal imbalances associated with hypotetraploidy.     

Highly recurrent der(1;16)(q10;p10) and other 16q arm alterations in lobular breast cancer

Cytogenetic data on infiltrating lobular carcinomas (ILCs) of the breast are described. In addition to 9 tumors, including 2 bilateral ones, with apparently normal chromosomes, recurrent chromosome alterations were found among 18 tumors. A der(1;16)(q10;p10), resulting in 1q gain and 16q loss, was observed in 11 tumors. Chromosome arm 16q was lost by other rearrangements in 3 other tumors. Thus, the deletion of 16q appears to be highly recurrent in ILCs. Compared to infiltrating ductal carcinomas (IDCs), ILCs have fairly simple karyotypes that remain pseudo- or near-diploid in most cases. This finding is confirmed by DNA ploidy studied by flow cytometry, which shows that about half of the tumors are diploid. This makes the der(1;16)(q10;p10) and other alterations of the 16q arm an early alteration of tumor progression, possibly related to the loss of expression of E-cadherin, whose gene is mapped on the 16q arm. Genes Chromosomes Cancer 23:300–306, 1998. © 1998 Wiley-Liss, Inc.     

Novel candidate tumour suppressor gene loci on chromosomes 11q23-24 and 22q13 involved in human insulinoma tumourigenesis

Insulinomas represent the predominant syndromic subtype of endocrine pancreatic tumours. Previous molecular studies have shown that gain of chromosome 9q rather than MEN1 gene mutation is an important early event in tumour development and that chromosomal instability is associated with metastatic disease. In order to identify new gene loci and to define further the critical genetic events in insulinoma tumourigenesis, 27 insulinomas were investigated by array-based comparative genomic hybridization (array CGH) on 3.7 k genomic BAC arrays (resolution < or =1 Mb). Fluorescence in situ hybridization was used to validate alterations in a subset of tumours. Array CGH most frequently detected loss of chromosomes 11q and 22q and gains of chromosome 9q. The chromosomal regions of interest (CRI) included 11q24.1 (56%), 22q13.1 (67%), 22q13.31 (56%), and 9q32 (63%). Evaluation of the simultaneous occurrence of these aberrations in the individual tumours revealed that gain of 9q32 and loss of 22q13.1 are early genetic events in insulinomas, occurring independently of the other alterations. In tumours with increased genomic complexity, these alterations were often detected simultaneously, occurring in the same tumour cells. Losses of 11q24.1 and 22q13.31 were also associated with these more advanced tumour cases. The CRIs identified most likely harbour crucial candidate genes important in insulinoma tumourigenesis.     

Phyllodes tumors of the breast analyzed by comparative genomic hybridization and association of increased 1q copy number with stromal overgrowth and recurrence

Phyllodes tumors are rare neoplasms of the breast. Although they contain both epithelial and stromal components they are considered to be stromally derived lesions. The chromosomal copy number changes were determined in 19 well characterized samples from 18 patients using comparative genomic hybridization. Most chromosomes were involved and generally the gains and losses were similar to those found in breast cancer with the exception that the phyllodes tumors showed no evidence of genomic amplification. The one recurrent sample analyzed had the same imbalances as the original tumor. Frequent changes were gain of 1q (7/18) and loss of 3p (6/18), followed by gain of 7q (4/18) and loss of 6q (4/18) and 3q (3/18). Gain of 1q material was significantly associated with histologically defined stromal overgrowth (P = 0.011). In addition, all the cases with gain of 1q material, without 1p gain, had a clinical history of recurrence. Only one case without 1q gain had a recurrence and this had loss of the X chromosome as the sole abnormality. Increased copy number of 1q material in the phyllodes tumors studied, in one case restricted to 1q24–32, was associated with recurrence (P = 0.00365) and might therefore be considered as an indicator of local aggressiveness requiring more radical treatment. Genes Chromosomes Cancer 20:275–281, 1997. © 1997 Wiley-Liss, Inc.     

Gain of 1q and loss of 9q21.3-q32 are associated with a less favorable prognosis in papillary thyroid carcinoma

In order to approach the genetic mechanisms behind initiation and progression of papillary thyroid carcinoma (PTC) tumorigenesis, we characterized numerical chromosomal imbalances in a panel of 25 PTCs with varying histopathological and clinical features using comparative genomic hybridization (CGH). The most frequently detected imbalance was gain of 9q33-qter, which was seen in close to 30% of the cases. The commonly occurring regions of loss were assigned to 22q (12%) and 9q21.3-q32 (12%), while gains preferentially involved the entire X chromosome (20%), 1q (16%), 17q (16%), and 22q (12%). The distribution of CGH alterations supports the idea of a progression of genetic events in the development of PTC, where gain of 9q33-qter would represent a relatively early event that is followed by loss of 22q and gain of X, 1q, 17q, and 22q. When the detected CGH alterations were compared with the clinical outcome and the histopathological features of the 25 PTC cases, several statistically significant correlations were revealed. The total number of genetic alterations was higher in tumors from patients with aggressive disease as compared to those without signs of aggressiveness. Gain of 1q and loss of 9q21.3-q32 were exclusively seen in tumors from patients with aggressive disease, and the presence of distant metastases was associated with gain of 1q. A sex-dependent distribution was also evident for one of the common alterations, with gain of X exclusively seen in male cases. Taken together, the findings identify several candidate locations for tumor suppressor genes and oncogenes that are potentially involved in the establishment and progression of papillary thyroid carcinogenesis.     

Cytogenetic and comparative genomic hybridization findings in four cases of breast cancer after neoadjuvant chemotherapy

To assess a potential common pattern of genetic alterations in chemotherapy-resistant tumors we analyzed four tumors from breast cancer patients (patients 1-4) after neoadjuvant chemotherapy, by comparative genome hybridization (CGH) and conventional chromosome banding analysis. All patients showed structural aberrations involving chromosomes 1, 5, 11, 16, and 17. In CGH analysis, the patients showed typical imbalances for ductal breast cancer: gains of 1q (3 patients), 5q (2 patients), 8q (3 patients), and X (4 patients) and losses of 1p33 approximately p36 (3 patients), 16q (3 patients), 17p (3 patients), 19 (4 patients), and 22q (4 patients). Other recurrent imbalances of atypical pattern for ductal breast cancer were gain of 4q21 approximately q32 (2 patients), 20q21 approximately q22 (2 patients), and 21 (2 patients) and loss of 20p (3 patients). Three patients showed involvement of several regions bearing genes of drug resistance (MDR1 [HUGO symbol: ABCB1], BCRP [HUGO symbol: ABCG2], MRP1 [HUGO symbol: ABCC1], RFC1); the fourth patient displayed an amplification in the region of MYC (alias c-myc), thus providing--at the level of the light microscope--an explanatory background for the ability of their tumors to survive anthracycline-, taxane- and cyclophosphamide-based chemotherapy. Conventional cytogenetic analysis and CGH displayed highly coincidental findings in the tumors of four patients after neoadjuvant chemotherapy for breast cancer.     

Differential expression of the calcium sensing receptor and combined loss of chromosomes 1q and 11q in parathyroid carcinoma

Malignant transformation of parathyroid tumours is rare. Nevertheless, this small subset of malignant tumours often creates diagnostic and therapeutic problems. In this work, the morphological characteristics of 26 primary parathyroid carcinomas and seven metastases have been studied. Furthermore, immunohistochemical expression profiles for the calcium sensing receptor (CASR), cyclin D1 (CCND1), and Ki-67 were determined for parathyroid carcinomas and compared with adenomas and hyperplasias using a tissue microarray. Loss of heterozygosity (LOH) of the chromosome 1q region containing the HRPT2 gene and chromosome 11q (MEN1) was determined in the carcinomas. In contrast to the adenomas and hyperplasias, 31% of carcinomas demonstrated down-regulation of CASR. A significant correlation was found between CASR expression and the Ki-67 proliferation index. Chromosome 1q and chromosome 11q LOH were found in 12 of 22 (55%) and 11 of 22 (50%) carcinomas tested, respectively. Combined 1q and 11q LOH was seen in 8 of 22 (36%) carcinomas, in contrast to the low percentage of LOH reported in both regions in adenomas. In conclusion, this study demonstrates that combined 1q and 11q LOH in parathyroid tumours is suggestive of malignant behaviour. Strong down-regulation of the CASR protein is seen in a proportion of parathyroid carcinomas with a high proliferation index.     

Molecular analysis of chromosome arm 17q gain in neuroblastoma

Complete or partial gain of the long arm of chromosome 17 (17q) has been shown recently by molecular cytogenetic techniques to be the most frequent chromosomal change in neuroblastoma and to be associated with adverse prognosis. Few reports, however, have focused on the precise mapping of the commonly overrepresented region. We have investigated 17q gain by the analysis of allelic imbalances at microsatellite loci dispersed along chromosome 17 in a series of 69 neuroblastomas. Allelic imbalances for at least two consecutive loci were observed in 39/59 informative cases, that is in agreement with previously reported frequencies of 17q gain. In a subset of the cases, comparative genomic hybridization analysis established the relationship between these allelic imbalances and the gain of 17q material. A partial 17q gain was observed in 9 cases, delineating a common region of 17q gain between the marker D17S787 (75 cM, 360 cR) and the telomere. In most cases, molecular results were suggestive of partial tri- or tetrasomy, whereas in 4 cases a higher copy number was documented. Our results also confirm that the presence of additional 17q material is closely associated with 1p36 deletion, MYCN amplification, and diploid or tetraploid chromosomal content. Genes Chromosomes Cancer 28:276-284, 2000.     

Early loss of heterozygosity on chromosome arm 16q in flat epithelial atypia of the breast. Detection by microsatellite analyses

With the improvement of breast carcinoma screening, pre-malignant cell lesions such as flat epithelial atypia (FEA) are detected more frequently. Several studies have demonstrated that FEA show features of a ductal neoplasia, but is it really a precursor lesion? We have started a comparative genetic analysis of a panel of nine microsatellite markers on six different chromosomal regions to investigate whether FEAs show the same characteristic genetic alterations as ductal carcinomas in situ (DCISs) and invasive carcinoma of the breast. FEAs, DCISs and invasive carcinomas of the same patients were microdissected using PALM micro laser technology. DNA was isolated using the QIAamp DNA Micro Kit (QIAGEN). We have investigated a set of the polymorphic microsatellite markers D7S522, D8S522, NEFL, D10S541 (PTEN), D13S153 (RB1), D16S400, D16S402, D16S422 and D17S855 (BRCA1) using multiplex PCR for the detection of allelic imbalances. Most of the investigated FEAs showed a lower frequency of loss of heterozygosity than associated DCISs or invasive carcinomas. However, we were able to detect the same alterations in FEAs as in DCISs or invasive carcinomas in a number of cases. Notably, the microsatellite marker on 16q showed more prevalent allelic imbalances in FEAs than the other investigated markers. One of the hallmarks in the pathogenesis of a large subgroup of invasive breast carcinomas is the early loss of chromosome arm 16q. In this study, we were able to detect frequent genetic alterations on chromosome 16q in FEAs, associated DCISs and invasive carcinomas. This suggests that FEA is a precursor lesion in the low-grade pathway.     

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.     

Human hepatocellular carcinoma is characterized by a highly consistent pattern of genomic imbalances, including frequent loss of 16q23.1-24.1

Comparative genomic hybridization (CGH) analysis was used to identify chromosomal imbalances in 52 human primary hepatocellular carcinomas (HCCs). The most prominent changes were gains of part or all of chromosome arms 8q (83% of cases) and 1q (73%) and loss of 16q (63%). Other commonly overrepresented sites were 5p, 7q, and Xq. Recurrent sites of DNA sequence amplification included 8q23--24 (five cases) and 11q13--14 (four cases). Other frequently underrepresented sites were 4q, 8p, 16p, and 17p. Taken collectively, these findings and data from other CGH studies of HCCs define a subset of chromosome segments that are consistently over- or underrepresented and highlight sites of putative oncogenes and tumor suppressor genes, respectively, involved in hepatocellular oncogenesis. Loss of heterozygosity analysis with a panel of polymorphic microsatellite markers distributed along 16q defined a minimal region of chromosomal loss at 16q23.1--24.1, suggesting that this region harbors a tumor suppressor gene whose loss/inactivation may contribute to the pathogenesis of many HCCs.     

Highly frequent allelic loss of chromosome 6q16-23 in osteosarcoma: involvement of cyclin C in osteosarcoma

The molecular pathogenesis of osteosarcoma is very complicated and associated with chaotic abnormalities on many chromosomal arms. We analyzed 12 cases of osteosarcomas with comparative genomic hybridization (CGH) to identify chromosomal imbalances, and detected highly frequent chromosomal alterations in chromosome 6q, 8p, 10p and 10q. To define the narrow rearranged region on chromosome 6 with higher resolution, loss of heterozygosity (LOH) analysis was performed with 21 microsatellite markers. Out of 31 cases, 23 cases (74%) showed allelic loss at least with one marker on chromosome 6q. We identified two distinct commonly deleted regions on chromosome 6 using markers D6S1565 located at 6q16 and 6q23MS1 at 6q23. The expression analysis of genes located at the deleted region was performed, and the decreased mRNA expression of the CCNC gene, one of the regulators of cell cycle, was detected. Growth of osteosarcoma cell line was significantly suppressed after the CCNC cDNA transfection. Fine mapping of the deleted region containing a possible tumor suppressor gene and the transfection assay suggest that the CCNC is a candidate tumor suppressor gene.     

Identification of novel deletion regions on chromosome arms 2q and 6p in breast carcinomas by amplotype analysis

DNA fingerprinting by arbitrarily primed PCR (AP-PCR) was employed to identify molecular genetic alterations in 37 primary breast carcinomas. AP-PCR is a PCR-based technique that uses only one primer of arbitrary sequence that generates a molecular karyotype (amplotype) of tumors. The breast cancer amplotype generated with two arbitrary primers (MCG1 and Blue) showed a relatively high frequency (more than 20% of the tumors) of gains at chromosomes 1, 4, and 8, and of losses at chromosomes 2, 4, 6, 9, 10, 11, 13, and the X chromosome. We further analyzed the regions most commonly gained at chromosome 8 (47%) and lost at chromosomes 2 (38%) and 6 (49%) by determining the subchromosomal localization of the fingerprint bands from these chromosomes. The region of gain at chromosome 8 was mapped at 8q24.1, close to MYC. Band MCG1-A1 was assigned to chromosome band 2q22, and band Blue-J was assigned to 6p21. Common losses of these chromosomal regions have not been described for breast cancer. To map these deletion regions more precisely, we performed loss of heterozygosity (LOH) analysis by microallelotyping on 20 of the 37 cancers previously analyzed by AP-PCR and another additional 52 breast carcinomas. The results suggest that the regions at 2q21-24 and 6p21-23 may harbor novel tumor suppressor genes for breast cancer. LOH at 2q21-24 (D2S2304) was more frequent in high-grade tumors (59%) than in low-grade tumors (29%) (P = 0.03). This suggests that this genetic alteration may be associated with tumor progression and shows the power of the amplotype approach in detecting novel genetic alterations that are useful as clinical parameters of breast cancer.     

TP53 mutations are associated with a particular pattern of genomic imbalances in breast carcinomas

TP53 mutations play an important role in the development of several cancers and are present in 20-40% of all breast carcinomas, contributing to increased genomic instability. In order to address the relationship of mutated TP53 to genomic complexity, the present study analysed 61 breast carcinomas for TP53 mutations and compared mutation status with the pattern of genomic imbalances as assessed by comparative genomic hybridization (CGH). Twenty per cent of the present series of breast carcinomas harboured TP53 mutations. An increasing number of abnormalities, as identified by CGH (higher genomic complexity), correlated significantly with mutant TP53. Among the chromosome arms most commonly altered (in more than 20% of the tumours), loss of 8p and gain of 8q were associated with TP53 mutations, whereas loss of 16q was associated with wild-type TP53. By performing supervised hierarchical clustering analysis of the CGH data, a cluster of chromosome imbalances was observed that showed differences between wild-type and mutant TP53 cases. Among these, loss of chromosome arm 5q revealed the strongest correlation with altered TP53. To investigate further the most commonly deleted region of 5q, gene expression patterns from two publicly available microarray data sets of breast carcinomas were evaluated statistically. The expression data sets identified potential target genes, including genes involved in ubiquitination and the known TP53 target CSPG2. The genomic complexity of breast carcinomas as assessed by CGH is associated with TP53 mutation status; breast cancers with TP53 mutations display more complex genomes than do those with wild-type TP53. The pattern of genomic imbalances associated with mutant TP53 is non-random, with loss of chromosome arm 5q being particularly closely associated with TP53 mutations.     

Analysis of genetic alterations in primary nasopharyngeal carcinoma by comparative genomic hybridization

To identify genetic alterations associated with the development and progression of human nasopharyngeal carcinoma (NPC), 57 tumors were analyzed by comparative genomic hybridization (CGH). In 47 cases, chromosomal imbalances were found. Several recurrent chromosomal abnormalities were identified in the present study. The most frequently detected chromosomal gains involved chromosome arms 12q (24 cases, 51%), 4q (17 cases, 36%), 3q (16 cases, 34%), 1q (15 cases, 32%), and 18q (15 cases, 32%). Common regions of gain involved 12q13--q15, 4q12--q21, and 3q21--q26. High-copy-number increases of chromosomal materials were detected in four chromosomal regions, 3q21--q26.2, 4p12--q21, 8p, and 12q14--q15. The most frequently detected loss of chromosomal materials involved chromosome arms 16q (26 cases, 55%), 14q (21 cases, 45%), 1p (20 cases, 43%), 3p (20 cases, 43%), 16p (19 cases, 40%), 11q (17 cases, 36%), and 19p (16 cases, 34%). The most common regions of loss involved 14q24--qter, 1pter--p36.1, 3p22--p21.3, 11q21--qter, and the distal region of 19p. Genomic alterations detected by CGH were compared and found to be largely consistent with those identified in banding analysis and loss of heterozygosity studies. However, several previously unrecognized recurrent alterations were also identified in the present study, including gain of 4q and 18q, and loss of 16q, 14q, and 19p. In addition, gain of 1q, 8q, 18q, and loss of 9q showed a statistically significant association with advanced clinical stages (P < 0.05). Identification of recurrent sites of chromosomal gain and loss identify regions of the genome that may contain oncogenes or tumor suppressor genes, respectively, which may be involved in the tumorigenesis of NPC. Published 2000 Wiley-Liss, Inc.     

髓母细胞瘤比较基因组杂交分析及ERBB-2异常表达的意义

目的研究髓母细胞瘤全基因组的遗传学异常,探讨癌基因的异常表达在髓母细胞瘤发病机制中的作用以及与预后的关系。方法应用比较基因组杂交（comparative genomic hybridization,CGH）技术检测14例髓母细胞瘤全基因组的遗传学改变;同时,在扩大系列的29例髓母细胞瘤中,应用荧光原位杂交（fluorescence in situ hybridization,FISH）和免疫组化染色分别检测ERBB-2在基因水平和蛋白水平的表达。结果（1）CGH结果显示,在所有14例髓母细胞瘤标本中,每一条染色体臂上都检测到了染色体的失衡（获得或丢失）,最常见的染色体异常为17q（85．7％）和7q（35．7％）的获得,以及8p（50％）、16q（28．6％）和17p（35．7％）的丢失;（2）FISH检测中,44．5％（13／29例）的肿瘤细胞有ERBB-2基因的异常表达;（3）免疫组化结果显示,37．9％（11／29例）的病例有抗体c-erbB-2的阳性表达;（4）在预后较差的16例患者中,56％（9／16例）的病例有ERBB-2的过度表达。结论CGH研究发现了髓母细胞瘤全基因组的染色体失衡。在染色体17q特异性位点上ERBB-2基因的异常改变很可能在髓母细胞瘤的发病机制中起着重要的作用,其过度表达与患者的预后密切相关。