Numerical abnormalities of chromosomes 1, 11, 17, and X are associated with stromal invasion in serous and mucinous epithelial ovarian tumours

The clinical behaviour of ovarian tumours of low malignant potential (LMP) is unpredictable and it has been suggested that the majority of these lesions have no invasive potential. This study has analysed 92 epithelial ovarian tumours [11 mucinous cystadenomas, 18 mucinous LMP tumours, 15 mucinous carcinomas (9 FIGO stage I), 16 serous cystadenomas, 15 serous LMP tumours, and 17 serous carcinomas (11 FIGO stage I)] for numerical abnormalities of chromosomes 1, 11, 17, and X by interphase cytogenetics. Overall, numerical aberrations were identified in none of the cystadenomas, 15 per cent of serous LMP tumours, 17 per cent of mucinous LMP tumours, 67 per cent of mucinous carcinomas, and 82 per cent of invasive serous carcinomas. In mucinous LMP tumours, chromosome gains were associated with spindled nuclear morphology. Chromosome abnormalities were significantly more frequent in invasive mucinous (overall p< 0·01; stage I p< 0·05) and serous (overall p< 0·001; stage I p< 0·01) carcinomas than in the corresponding LMP tumours. No significant relationship between either stromal invasion or tumour type and the pattern of chromosome loss or gain was identified, although monosomy X was identified almost exclusively in invasive serous carcinomas. These observations are consistent with the concept that LMP tumours are unlikely to be precursors of ovarian carcinoma, but suggest that chromosome instability is important in the development of the invasive phenotype. Copyright © 1999 John Wiley & Sons, Ltd.     

Cyclin D1 overexpression lacks prognostic significance in superficial urinary bladder cancer

The biological behaviour of urinary bladder neoplasms cannot be adequately predicted by histological criteria alone. Cyclin D1 is a cell-cycle regulating protein known to be overexpressed in a proportion of bladder carcinomas. To evaluate the prognostic significance of cyclin D1 expression and its relationship with tumour phenotype, 392 bladder carcinomas were analysed by immunohistochemistry. Clinical follow-up information was available in 337 patients with superficial bladder tumours (stages pTa/pT1). Cyclin D1 positivity was seen in 176 of 392 carcinomas. Cyclin D1 overexpression was strongly linked to papillary tumour growth, low stage, and low histological grade (p<0·005 each). Multivariate analysis showed that papillary tumour growth was the only parameter which was independently linked to cyclin D1 positivity. There was no significant difference in proliferative activity (Ki67 labelling index) between cyclin D1-negative and -positive tumours. Cyclin D1 positivity was not linked to the risk of recurrence or tumour progression, either in pTa or in pT1 carcinomas. It is concluded that cyclin D1 positivity distinguishes a large subgroup of papillary bladder tumours, but there is no evidence of prognostic significance for increased cyclin D1 expression. Copyright © 1999 John Wiley & Sons, Ltd.     

Identification of chromosome 9 alterations and p53 accumulation in isolated carcinoma in situ of the urinary bladder versus carcinoma in situ associated with carcinoma

Carcinoma in situ (CIS) of the urinary bladder is a flat, aggressive lesion and may be the most common precursor of invasive bladder cancer. Although chromosome 9 alterations are among the earliest and most prevalent genetic alterations in bladder cancer, discrepancy exists about the frequency of chromosome 9 losses in CIS. We analyzed 22 patients with CIS of the bladder (15 patients with isolated CIS, 7 patients combined with synchronous pTa or pT1 carcinomas) for gains and losses of chromosome (peri)centromere loci 1q12, 7p11-q11, 9p11-q12, and 9p21 harboring the INK4A/ARF locus (p16(INK4A)/p14(ARF)) and INK4B (p15(INK4B)) by multiple-target fluorescence in situ hybridization, and for p53 protein accumulation by immunohistochemistry. In 15 of 20 (75%) CIS lesions analyzed p53 overexpression was detected, whereas aneusomy for chromosomes 1 and 7 was identified in 20 of 22 (91%) CIS. In 13 of 22 (60%) CIS cases analyzed, 12 of which were not associated with a synchronous pTa or pT1 carcinoma, no numerical losses for chromosome 9 (p11-q12 and 9p21) were detected as compared with chromosomes 1 and 7. Furthermore 6 of 12 (50%) patients showed a metachronous invasive carcinoma within 2 years. In the remaining nine biopsies CIS lesions (40%) were recognized that showed losses of chromosome 9p11-q12 and 9p21, six of these were associated with a synchronous pTa or pT1 carcinoma. Three of these carcinomas were pTa and exhibited loss of 9q12 as well as a homozygous deletion of 9p21. The others were invasive carcinomas in which CIS lesions were also recognized that showed no numerical loss of chromosome 9, but did show an accumulation of p53. In conclusion our data demonstrate that predominantly isolated CIS lesions contained cells with no specific loss of chromosome 9, as opposed to CIS lesions with synchronous carcinomas that showed evidence of chromosome 9 loss. Furthermore our data strengthen the proposition that p53 mutations (p53 overexpression) precede loss of chromosomes 9 and 9p21 in CIS as precursor for invasive bladder cancer, as opposed to noninvasive carcinomas where chromosome 9 (9p11-q12) losses are early and frequently combined with homozygous deletions of 9p21.     

Investigation of genetic alterations associated with the grade of astrocytic tumor by comparative genomic hybridization

Comparative genomic hybridization (CGH) is a technique that allows the detection of losses and gains in DNA copy number across the entire genome. We used CGH to study the genetic alterations that occur in primary astrocytomas, including 14 glioblastomas (GBM), 12 anaplastic astrocytomas (AA), and 7 low-grade astrocytomas (LGA). The average numbers of total aberrations in GBM, AA, and LGA were 9.7, 5.4, and 4.0, respectively. The average number of DNA sequence losses in GBM was significantly higher than that in AA or LGA (P < 0.01). Frequently altered regions (> eight cases) observed in all grades of astrocytoma were 7p13-p12 (gain), 7q31 (gain), 8q24.1-q24.2 (gain), 9p21 (loss), 10p12-p11 (loss), 10q22-qter (loss), 13q21-q22 (loss), and 20q13.1-q13.2 (gain). Loss of 9p, 10p, or 10q, and the gain or amplification of 7p, were observed frequently in GBM (64%, 57%, 64%, and 50% of cases, respectively). Frequent alterations found in AA were losses of 9p, 10q, and 13q, and gains of 1q, chromosome 7, 11q, and Xq. Whereas 7p13-p11 amplification occurred exclusively in cases with the loss of all or part of chromosome 10, this change never occurred in cases having an increase in copy number of 8q, which was the most frequent change observed in LGA (four of seven cases). These results may indicate that an increase in copy number of 8q is an important event in GBM, with a genetic pathway, which is distinct from that in GBM with 7p amplification. Genes Chromosomes Cancer 21:340–346, 1998. © 1998 Wiley-Liss, Inc.     

p53 but not erbB-2 expression is associated with rapid tumor proliferation in urinary bladder cancer

Tumor proliferation in bladder cancer is associated with tumor behavior. To assess the association between Ki-67 labeling index (LI), p53, and c-erbB-2 overexpression, formalin-fixed tissue samples of 160 patients with transitional cell carcinoma (TCC) of the urinary bladder were studied by immunohistochemistry. Ki-67 LI was strongly associated with tumor stage (P < .0001), tumor grade (P < .0001), and p53 status (P = .0014) but not with erbB-2 overexpression (P > .2). Ki-67 LI was higher in p53-positive tumors (19%) than in p53-negative tumors (14%) when all stages were compared. Ki-67 LI was independent of p53 expression in pTa tumors (p53-positive, 9%; p53-negative, 11%), showing that p53 overexpression alone is not sufficient to induce rapid tumor cell proliferation in pTa tumors. Ki-67 LI also was independent of p53 expression in pT2 to pT4 tumors (p53-positive, 20%; p53-negative, 23%), indicating that p53 expression is not necessary for rapid tumor cell proliferation in advanced stages. However, there was a striking difference in Ki-67 LI between p53-positive pT1 tumors (22.0% ± 8.8 standard deviation [SD]; n = 20) and p53-negative pT1 tumors (9.7 ± 8.3 SD; n = 22; P = .0001). These results suggest that increased proliferation in p53-positive pT1 tumors is caused by additional alterations that occur during tumor progression.     

EXPRESSION OF CATHEPSIN D IN TRANSITIONAL CELL BLADDER TUMOURS

Biopsy specimens from 177 bladder tumours were analysed by immunohistochemical methods for the expression of cathepsin D. Strong expression of cathepsin D was detected in transitional carcinoma cells in 40 per cent of cases. Umbrella cells were positive in 29 per cent of cases and a cathepsin D-positive cell zone composed of tissue macrophages was detected at the invasion front in 34 per cent of tumours. Strong expression of cathepsin D was related to muscle invasive growth phase (T⩾2) ( P =0·019), grade 2–3 histology ( P =0·008), S-phase fraction over 10 per cent ( P =0·032), and overexpression of epidermal growth factor receptor (EGFR) ( P <0·001). Umbrella cells were positive in low-grade ( P =0·03) papillary tumours ( P =0·02) with an S-phase fraction ⩽10 per cent ( P =0·02). Cathepsin D was expressed in macrophage-like cells in the invasion front in tumours which were densely infiltrated by inflammatory cells ( P =0·017) and in tumours overexpressing EGFR ( P =0·017) or p53 protein ( P =0·007). Progression in N- ( P =0·04) and M-categories ( P =0·01) was related to strong expression of cathepsin D in cancer cells and in univariate survival analysis; this was weakly related to poor outcome ( P =0·09). In multivariate analysis, papillary status ( P =0·055) and S-phase fraction ( P =0·079) predicted prognosis in Ta-1 tumours. In T2–4 tumours, T-category ( P <0·001), papillary status ( P <0·001), S-phase fraction ( P =0·028), and the presence of cathepsin D-positive tissue macrophages ( P =0·017) were independent prognostic factors.     

Karyotypic characterization of colorectal adenocarcinomas

Cytogenetic analysis of short-term cultures from 52 primary colorectal adenocarcinomas revealed clonal chromosome aberrations in 45 tumors, whereas the remaining 7 had a normal karyotype. More than 1 abnormal clone was detected in 26 tumors; in 18 of them, the clones were cytogenetically unrelated. The modal chromosome number was near-diploid in 32 tumors and near-triploid to near-tetraploid in 13. Only numerical aberrations were identified in 13 carcinomas, only structural aberrations in 3, and 29 had both numerical and structural changes. The most common numerical abnormalities were, in order of decreasing frequency, gains of chromosomes 7, 13, 20, and Y and losses of chromosomes 18, Y, 14, and 15. The structural changes most often affected chromosomes 1, 17, 8, 7, and 13. The most frequently rearranged chromosome bands were, in order of decreasing frequency, 13q10, 17p10, 1p22, 8q10, 17p11, 7q11, 1p33, 7p22, 7q32, 12q24, 16p13, and 19p13. Frequently recurring aberrations affecting these bands were del(1)(p22), i(8)(q10), i(13)(q10), and add(17)(p11–13). The most common partial gains were from chromosome arms 8q, 13q, and 17q and the most common partial losses from chromosome arms 1p, 8p, 13p, and 17p. A correlation analysis between the karyotype and the clinicopathologic features in our total material, which consists of altogether 153 colorectal carcinomas, including 116 with an abnormal karyotype, showed a statistically significant association (P < 0.05) between the karyotype and tumor grade and site. Carcinomas with structural chromosome rearrangements were often poorly differentiated; well and moderately differentiated tumors often had only numerical aberrations or normal karyotypes. Abnormal karyotypes were more common in rectal carcinomas than in carcinomas situated higher up. Near-triploid to near-tetraploid karyotypes were more than twice as frequent in tumors of the distal colon as in those of the proximal colon and rectum. The cytogenetic data indicate that carcinomas located in the proximal colon and rectum, which often are near-diploid with simple numerical changes and cytogenetically unrelated clones, probably arise through different mechanisms than do tumors located in the distal colon, which more often have complex near-triploid to near-tetraploid karyotypes.     

Chromosome 8p deletions are associated with invasive tumor growth in urinary bladder cancer.

Alterations of chromosome 8, including deletions of 8p, occur frequently in many tumors. In this study, fluorescence in situ hybridization was used to study the relationship between 8p deletions, 8q gains, and phenotype in bladder cancer. Cells from 87 tumors were examined by dual-labeling fluorescence in situ hybridization with a centromere 8 probe (pJM12) and P1 probes for 8p22, 8p12, 8q12, and 8q24. Both 8p22 deletions and 8q24 gains were strongly associated with tumor phenotype. There was a marked difference in 8p22 deletions between noninvasive (pTa) tumors (3/33) and minimally invasive (pT1) tumors (8/19; P = 0.005) whereas there was no significant difference between pT1 and muscle-invasive (pT2-4) tumors (19/35; P = 0.3926). Six tumors with 8p22 deletion were examined at 8p12. Three of these tumors showed no 8p12 deletion, narrowing down the site of a putative tumor suppressor gene distal to 8p12. In one other case, there was a marked increase in 8p12 copy number (> 40 per cell; amplification), suggesting the presence of an oncogene involved in bladder cancer at 8p12. The marked difference in 8p22 deletions between noninvasive (pTa) and minimally invasive (pT1) tumors is consistent with a role of a putative tumor suppressor gene on 8p for development of invasive tumor phenotype.     

p53 OVEREXPRESSION AND HUMAN PAPILLOMAVIRUS INFECTION IN TRANSITIONAL CELL CARCINOMA OF THE URINARY BLADDER: CORRELATION WITH HISTOLOGICAL PARAMETERS

Seventy-nine transitional cell carcinomas (TCCs) of the urinary bladder (25 grade 1, 22 grade 2, and 32 grade 3 tumours) were examined for p53 overexpression by immunohistochemistry with a monoclonal antibody and for human papillomavirus (HPV) infection by the polymerase chain reaction (PCR). Positive immunostaining for p53 was detected in 40·5 per cent of the cases; the percentage of positive cases was significantly lower in low-grade (G1 and G2) TCCs than in high-grade (G3) tumours (10·6 per cent vs. 84·4 per cent; P <0·0001). The overall rate of HPV infection was 32·9 per cent; 20·3 per cent of the cases were positive for HPV 16, 3·8 per cent for HPV 18, and 8·9 per cent for both. Consensus primers as well as type-specific primers for HPV types 6, 11, and 33 failed to detect any additional case with HPV infection. The prevalence of HPV 16 and/or HPV 18 infection was significantly higher in low-grade than in high-grade tumours (44·7 per cent vs. 15·6 per cent; P =0·0061). p53-positive cases were more common among papillary, deeply infiltrating tumours, and HPV-positive cases among papillary, non-infiltrating lesions. According to these data, p53 overexpression and HPV 16/18 infection are common findings in bladder TCC and there appears to be an inverse correlation of p53 overexpression and of HPV infection with tumour aggressiveness. The possibility of different molecular pathways in superficial low-grade and in invasive high-grade tumours is suggested.     

Aberrations of chromosomes 5 and 8 as recurrent cytogenetic events in anaplastic carcinoma of the thyroid as detected by fluorescence in situ hybridisation and comparative genomic hybridisation

Comparative genomic hybridisation (CGH) is a technique which identifies gains and losses of DNA sequence copy number in tumours. We used CGH to search for genetic changes in one of the most aggressive malignancies--anaplastic thyroid carcinoma (ATC). For this purpose, we analysed tumour specimens of nine ATCs and DNA of two ATC cell lines. CGH detected aberrations in 10 of 11 samples, with a mean number of gains or losses per carcinoma of 4.8 (range 0-13). Total or partial changes of chromosome 8 (n=6), including gains or losses of 8p (n=6) or 8q (n=5) were those detected most frequently. Chromosome 5p was amplified in five cases. Gains in two of three samples were found for 3q, 7p, 11q and 20q. Gains in a fewer number were seen for 1p (1 case), 1q (1), 7q (2), 9q (2), 11p (2), 12q (1), 14 (1), 15 (1), 17q (2), 18p (2), 18q (1), 20p (1), 21 (2), Xp (2) and Xq (2). Losses were less frequent than gains and observed for 1p (2 cases), 1q (1), 2p (1), 2q (2), 3p (2), 3q (1), 4q (2), 6q (1), 9p (2), 9q (1), 18p (1), 18q (1) and Y (2). Examples of analysis of tumour sections and cell lines performed by fluorescence in situ hybridisation (FISH) confirmed the gains and losses found by CGH and detected additional signals for 8q21 in tumour cells in a sample with no gains or losses normally in CGH. The results suggest that aberrations of 5p, 8p and 8q, which are rarely found in differentiated thyroid carcinoma, may play an important role in the development of ATC. Therefore, these chromosomes could harbour gene loci potentially involved in the aggressiveness of neoplastic tumours, as shown in tumours such as in this study for ATC.     

Helicobacter pylori-related and -non-related gastric cancers do not differ with respect to chromosomal aberrations

Gastric carcinogenesis is strongly associated with Helicobacter pylori infection, but the underlying genetic mechanisms are largely unknown. The aim of this study was to correlate chromosomal aberrations in gastric cancer to H. pylori status and its different strains, as well as to histological type and other clinico-pathological variables. DNA from 46 gastric cancers (male/female 35/11, age 27-85 years) was extracted from formaldehyde-fixed, paraffin-embedded material and tested for chromosomal gains and losses by comparative genomic hybridization (CGH). Chromosomal aberrations with frequencies of 20% or higher were considered to be non-random changes associated with gastric cancer. The mean number of chromosomal events per tumour was 9.7 (range 0-27), with a mean of 3.2 gains (range 0-16) and 6.5 losses (range 0-15). Gains were most frequently found at chromosomes 8q and 13q (24% and 26%, respectively). Losses were predominantly found on chromosome arms 2q, 9p, 12q, 14q, 15q, 16p, 16q, 17p, 17q, 19p, 19q, and 22q (22%, 30%, 43%, 22%, 33%, 50%, 28%, 50%, 39%, 33%, 39%, and 37%, respectively). Common regions of overlap narrowed down to 2q11-14, 8q23, 9p21, 12q24, 13q21-22, 14q24 and 15q11-15. The mean number of gains was higher in tumours with metastases than in localized tumours (4.1 vs. 1.9, p=0.04). Tumours with a loss at 17p showed a higher number of losses than tumours without a 17p loss (9. 5 vs. 4.7 on average, p<0.001). Neither H. pylori status (+, n=25; -, n=21) nor H. pylori strain was correlated to the total number of events or to any specific chromosomal aberration, nor were there differences between intestinal (n=30) and diffuse (n=15) cancers or any other clinico-pathological variable tested. In conclusion, a complex of chromosomal aberrations is involved in gastric cancer, but their pattern does not depend on H. pylori status or strain, nor on the histological type of the tumour. The exact biological meaning of these aberrations in carcinogenesis needs further clarification.     

LOSS OF CHROMOSOME 9 IN TISSUE SECTIONS OF TRANSITIONAL CELL CARCINOMAS AS DETECTED BY INTERPHASE CYTOGENETICS. A COMPARISON WITH RFLP ANALYSIS

Interphase cytogenetics by in situ hybridization (ISH) using a panel of centromere-associated DNA probes for chromosomes 1, 7, 9, 10, 11, 16, 17, and 18 was performed on 5 μm thick frozen tissue sections of transitional cell carcinomas (TCCs) of the urinary bladder. By this approach, chromosome ploidy, numerical chromosome aberrations, imbalance between chromosomes, and heterogeneity of aberrations within individual tumours were determined. In 15 of 24 TCCs, loss or underrepresentation of chromosome 9, compared with the ISH copy numbers of at least five other chromosomes, was demonstrated. Independently, RFLP analysis were performed on the same cases to detect loss of heterozygosity (LOH) of chromosome loci 9q34, 11p15, 16q22–24, 17p13, and 18q21. LOH was found in 9 of 19 informative cases for chromosome locus 9q34. Comparison of the ISH and RFLP results showed no correlation between numerical aberration and LOH for the loci on chromosomes 11, 16, 17, and 18. However, numerical loss of chromosome 9 was found in 89 per cent (eight of nine cases) with LOH for 9q34. Conversely, LOH at 9q34 was observed in only 67 per cent (eight of 12 cases) with underrepresentation of chromosome 9. Moreover, in 60 per cent of the non-informative cases (three of five cases), underrepresentation for chromosome 9 was observed. These results indicate that the heterochromatin probe for chromosome 9 can be reliably used in TCC tissue sections for the detection of chromosomal loss. In aneuploid TCCs, this DNA probe can be used for the detection of chromosomal underrepresentation only in combination with other centromere-associated DNA probes.     

Numerical abnormalities of chromosome 7 in human prostate cancer detected by fluorescence in situ hybridization (FISH) on paraffin-embedded tissue sections with centromere-specific dna probes

Fluorescence in situ hybridization (FISH) using chromosome-specific α-satellite DNA probes for chromosomes 7, 8, and 12 was performed on paraffin-embedded tissue sections and touch imprint preparations of 53 cases of human prostate cancer. Subsequent haematoxylin and eosin (H & E) staining of the hybridized tissue sections allowed unambiguous assignment of hybridization signals either to tumour or to non-tumorous parenchyma. Fifty-three cases of human prostate cancer were evaluated for numerical aberrations of chromosome 7. Scoring 200 cells of tumour and non-tumorous parenchyma in each case revealed abnormalities exclusively in tumour parenchyma in 41 cases (77 per cent). Ten of 41 cases (24 per cent) showed trisomy 7, and 15 cases (37 per cent) monosomy 7 or trisomy 7 in combination with monosomy 7, respectively. Sixteen cases (39 per cent) exhibited polysemy 7 in cells of the tumour parenchyma. In the tumour tissue in one case, different polyploid clones (triploid, tetraploid) and polysomy 7 could be identified by double hybridization with chromosome-specific DNA probes for chromosome 7, plus 8 or 12. The indicated numerical aberrations of chromosome 7 were correlated with 78 per cent of advanced pathological stages or poorly differentiated tumours (pT3/4 or G3) of prostate carcinomas. A statistical analysis of the data revealed significant relationships of particular numerical abnormalities of chromosome 7 to different pathological categories (pT, G, pN) of tumour classification. For the T-classification, the frequency of cells carrying polysomy 7 and polysomy 7/+7 increases significantly from pT1 to pT3/4 (P = 0·022). A significant increase from G1 to G3 also became apparent for the total frequencies of numerical abnormal cells (P = 0·05).     

CKS1B amplification is a frequent event in cutaneous squamous cell carcinoma with aggressive clinical behaviour

Genetic mechanisms giving rise to the development of cutaneous squamous cell carcinoma (cSCC) are poorly understood and development of genomic high resolution techniques has led to a better knowledge of the genetic basis of several human cancers. In this study, 16 cSCC were analyzed using array comparative genomic hybridization (arrayCGH). The most common aberrations found were gains of 3q11q13, 1q21.3q25, 13q34, and 19p13, and losses of 1p36p31, 3p24p21, 10p15q22, and 13q11q21. We detected gains (3/16) and amplification (1/16) of the 1q21.1q21.3 region. A potential candidate gene in this region, CKS1B (1q21.2), was selected for validation in an independent cohort and correlations with clinicopathological features were carried out. CKS1B gene and protein status were analyzed using fluorescence in situ hybridization (FISH) and immunohistochemistry (IHC) in a series of 53 cSCC, 22 actinic keratoses (AK), and 10 normal skin samples. cSCC presented a higher frequency of chromosome 1 polysomy than AK (70% vs. 46%, P = 0.047). Association between CKS1B protein overexpression and both polysomy and amplification was demonstrated in cSCC (P < 0.001). Regarding amplifications, 11 cSCC patients (21%) presented CKS1B gene amplification. Interestingly, 8/11 (73%) patients who showed a CKS1B amplification had presented metastatic spread (mcSCC). Differences between the presence of CKS1B amplification and the presence or absence of mcSCC were observed (mcSCC [8/14] vs. cSCC [3/39]) (P < 0.001). Several drugs targeting CKS1B have been reported and may be useful for treating patients with cSCC and CKS1B amplifications. © 2010 Wiley‐Liss, Inc.     

Chromosomal changes during progression of transitional cell carcinoma of the bladder and delineation of the amplified interval on chromosome arm 8q

The cascade of genetic alterations leading to malignant transformation has been described for adenocarcinoma of the colon but is not established for other common tumor entities. In the present study, different stages of transitional cell carcinoma (TCC) of the bladder are analyzed by comparative genomic hybridization. A dynamic pattern of the chromosomal changes during tumor progression is described. Deletion of chromosome arm 9q is the earliest genetic alteration in pTa tumors. In stage pT1 carcinomas, losses of 9q, 9p, and 11p and gain of 1q and 8q are the most common. In addition to the changes specific for earlier stages, gain of 5p and 20q becomes prominent in carcinomas stage ≥pT2. Association analysis reveals a remarkable cooccurrence of 9p deletion with gain of 5p and 20q in ≥pT2 tumors. In order to determine more precisely the size of the amplified segment and the degree of amplification on chromosome arm 8q in stage pT1 tumors, this region was analyzed by semiquantitative PCR using polymorphic microsatellite markers. These studies revealed an up to 13-fold amplification. The common region of amplification could be narrowed down to 8q22.3 and between GAAT1A4 and D8S1834 (about 7 cM). Genes Chromosomes Cancer 23:167–174, 1998. © 1998 Wiley-Liss, Inc.     

Detection of chromosomal aberrations in seminomatous germ cell tumours using comparative genomic hybridization

Comparative genomic hybridization (CGH) was used to evaluate tissue specimens from 16 seminomas in order to elucidate the pathogenesis of germ cell tumours in males. A characteristic pattern of losses and gains within the entire genomes was detected in 94% of the seminomas by comparing the ratio profiles of the tumours with a standard of cytogenetically normal genomic DNA. Losses represented 43% of the total number of alterations often affecting chromosomes and chromosome arms 4, 5, 11, 13q, and 18q. Gains amounted to 57% and were often observed on 1q, 7, 8, 12, 14q, 15q, 21q, and 22q. Aberrations of 12p and 21q appeared most consistently. Results from CGH analysis displayed no relationship to the clinical stages of the malignancy. Some rare aberrations appeared, however, only in clinical stage II and in tumours showing relapse in the contralateral testis following orchiectomy, although the alterations were not present in all of the tumours in question. Losses of 16q13-21 and gains of 9q22.1-22.2 were demonstrated in both groups, while loss of 16p12 and gains of 6p21 and 6q23.3-24 were detected in the latter group as well. In conclusion, a specific pattern of chromosomal alterations was demonstrated in the seminomas by improved detection criteria, which increased specificity and sensitivity. The rare aberrations, which appeared only in tumours in clinical stage II and relapsed tumours, may be linked to tumour progression, invasiveness, and bilateral disease. Genes Chromosomes Cancer 20:412–418, 1997. © 1997 Wiley-Liss, Inc.     

Cytogenetic patterns in ETV6/RUNX1-positive pediatric B-cell precursor acute lymphoblastic leukemia: A Nordic series of 245 cases and review of the literature

Between 1992 and 2004, 1,140 children (1 to<15 years) were diagnosed with B-cell precursor acute lymphoblastic leukemia (ALL) in the Nordic countries. Of these, 288 (25%) were positive for t(12;21)(p13;q22) [ETV6/RUNX1]. G-banding analyses were successful in 245 (85%); 43 (15%) were karyotypic failures. The modal chromosome numbers, incidence, types, and numbers of additional abnormalities, genomic imbalances, and chromosomal breakpoints in the 245 karyotypically informative cases, as well as in 152 previously reported cytogenetically characterized t(12;21)-positive ALLs in the same age group, were ascertained. The most common modal numbers among the 397 cases were 46 (67%), 47 (16%), 48 (6%), and 45 (5%). High-hyperdiploidy, triploidy, and tetraploidy were each found in approximately 1%; none had less than 40 chromosomes. Secondary chromosomal abnormalities were identified by chromosome banding in 248 (62%) of the 397 ALLs. Of these, 172 (69%) displayed only unbalanced changes, 14 (6%) only balanced aberrations, and 26 (10%) harbored both unbalanced and balanced abnormalities; 36 (15%) were uninformative because of incomplete karyotypes. The numbers of secondary changes varied between 1 and 19, with a median of 2 additional aberrations per cytogenetically abnormal case. The most frequent genomic imbalances were deletions of 6q21-27 (18%), 8p11-23 (6%), 9p13-24 (7%), 11q23-25 (6%), 12p11-13 (27%), 13q14-34 (7%), loss of the X chromosome (8%), and gains of 10 (9%), 16 (6%), and 21 (29%); no frequent partial gains were noted. The chromosome bands most often involved in structural rearrangements were 3p21 (2%), 5q13 (2%), 6q12 (2%), 6q14 (2%), 6q16 (2%), 6q21 (10%), 6q23 (6%), 6q25 (3%), 9p13 (2%), 11q13 (2%), 11q23 (2%), 12p11 (6%), 12p12 (7%), 12p13 (25%), 21q10 (6%), and 21q22 (6%). Considering that the t(12;21) is known to arise in utero and that the postnatal latency period is protracted, additional mutations are most likely necessary for overt ALL. The frequently rearranged chromosome regions may harbor genes of importance for the transformation and/or progression of an initial preleukemic t(12;21)-positive clone.     

High‐resolution genomic screening in mantle cell lymphoma—specific changes correlate with genomic complexity,the proliferation signature and survival

Mantle cell lymphoma (MCL) is characterized by the t(11;14)(q13;q32) and numerous copy number aberrations (CNAs). Recently, gene expression profiling defined a proliferation gene expression signature in MCL where high scores predict shorter survival. We investigated 31 MCL cases using high‐density single nucleotide polymorphism arrays and correlated CNA patterns with the proliferation signature and with clinical data. Many recurrent CNAs typical of MCL were detected, including losses at 1p (55%), 8p (29%), 9q (29%), 11q (55%), 13q (42%) and 17p (32%), and gains at 3q (39%), 8q (26%), 15q (23%) and 18q (23%). A novel deleted region at 20q (16%) contained only one candidate gene, ZFP64, a putative tumor suppressor. Unsupervised clustering identified subgroups with different patterns of CNAs, including a subset (19%) characterized by the presence of 11q loss in all cases and by the absence of 13q loss, and 3q and 7p gains. Losses at 1p, 8p, 13q and 17p were associated with increased genomic complexity. High proliferation signature scores correlated with increased number of large (>15 Mbp) CNAs (P = 0.03) as well as copy number gains at 7p (P = 0.02) and losses at 9q (P = 0.04). Furthermore, large/complex 13q losses were associated with improved survival (P < 0.05) as were losses/copy number neutral LOH at 19p13 (P = 0.01). In summary, this high‐resolution genomic analysis identified novel aberrations and revealed that several CNAs correlated with genomic complexity, the proliferation status and survival. © 2010 Wiley‐Liss,Inc.     

Submicroscopic genomic imbalances in burkitt lymphomas/leukemias: Association with age and further evidence that 8q24/MYC translocations are not sufficient for leukemogenesis

Chromosome banding analyses reveal secondary chromosome abnormalities in addition to the MYC translocations t(8;14)(q24;q32), t(8;22)(q24;q11), and t(2;8)(p11;q24) in 60%–80% of Burkitt lymphomas/leukemias (BL). The high incidence of such aberrations indicates that additional changes are important, perhaps necessary, for malignant transformation, i.e., the 8q24/MYC rearrangements may not be sufficient. To investigate this possibility, we performed single nucleotide polymorphism (SNP) array analysis on 20 cases of 8q24/MYC‐positive BL. Nineteen (95%) harbored genomic imbalances; the only case without such aberrations displayed secondary changes by chromosome banding analysis. Thus, all BL cases had abnormalities in addition to the 8q24 translocation. The adult cases harbored more changes (median 3; range 1–21) than did the childhood cases (median 1.5; range 0–5) (P = 0.034). Several recurrent aberrations were detected by SNP array analysis, in particular losses of 6q14.1‐q22.33, 9p21.3, and 13q14.2‐q14.3, gains of 1q23.3‐q31.3, chromosome 7, 13q31.3, and partial uniparental isodisomies for 6p12.2‐pter, 9p23‐pter, and 17p11.2‐pter. The molecular genetic consequences of these changes include deletions of the CDKN2A and TP53 genes, and gains/losses of several genes, such as MIR17HG and E2F2K, involved in the MYC pathway. Thus, deregulation of the MYC pathway, both directly through the 8q24/MYC translocation and indirectly through secondary genomic imbalances, may be essential not only for the initiation but also for the progression of BL. © 2012 Wiley Periodicals, Inc.     

Comparative genomic hybridization reveals frequent chromosome 13q and 4q losses in renal carcinomas with sarcomatoid transformation

Renal cell carcinomas (RCCs) with sarcomatoid transformation show the most malignant behaviour of all renal carcinoma types. In this study, comparative genomic hybridization was used to screen for losses and gains of DNA sequences along all chromosome arms in 12 sarcomatoid (S) RCCs. On average, there were 8·6 aberrations per tumour. DNA sequence losses (5·2±4·4) were slightly more frequent than gains (3·4±2·6). DNA gains most often involved chromosomes 17 (33 per cent), 7, and 8q (25 per cent each). High-level co-amplification involving 11q22–23 and 7p21–22 in one SRCC was not present in adjacent non-sarcomatous tumour areas, raising the possibility of oncogene involvement at these loci for sarcomatoid transformation. DNA losses were most prevalent at 13q (75 per cent) and 4q (50 per cent), suggesting that inactivation of tumour suppressor genes at chromosomes 13q and 4q may be linked to sarcomatoid growth of RCC. It is concluded that SRCCs are genetically highly complex. Chromosomes 13q, 4q, 7p21–22, and 11q22–23 may carry genes with relevance for sarcomatoid growth in RCC. © 1998 John Wiley & Sons, Ltd.