Marked genetic differences between stage pTa and stage pT1 papillary bladder cancer detected by comparative genomic hybridization.

Little is known about the genetic changes underlying invasive tumor growth in bladder cancer. Because alterations that are linked to invasive tumor growth may be detectable in minimally invasive (stage pT1) but not in noninvasive (stage pTa) tumors, we searched for genetic differences between 28 pTa and 28 papillary pT1 bladder tumors by comparative genomic hybridization. Losses of 9q (54%), 9p (39%), and Y (28%) and gains of 1q (14%) were most prevalent in pTa tumors. These changes may play a role in the initiation of noninvasive papillary bladder cancer. The total number of aberrations was higher in pT1 tumors (6.5 +/- 5.4) than in pTa tumors (2.3 +/- 2.1; P = 0.0003), suggesting an increased genetic instability at stage pT1. Specific alterations, which were significantly more frequent in pT1 than in pTa tumors (P < or = 0.05), included deletions at 2q (36% of pT1 tumors), 8p (32%), and 11p (21%) and gains at 1q (54%), 8q (32%), 3p, 3q, 5p, 6p, and 10p (18% each). These loci are candidates for carrying genes involved in invasive tumor growth in bladder cancer. High-level amplifications at 1q22-24, 3p24-25, 6p22, 8p12, 8q21-22, 10p12.1-14, 11q13, 12q15-21, 13q31-33, Xp11-13, and Xq21-22.2 may pinpoint the location of oncogenes with relevance for bladder cancer.

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.

Genetic differences in endocrine pancreatic tumor subtypes detected by comparative genomic hybridization.

The molecular pathogenesis as well as histogenesis of endocrine pancreatic tumors (EPTs) is not well understood, and the clinical behavior of EPTs is difficult to predict using current morphological criteria. Thus, more accurate markers of risk and better understanding of tumor initiation and progression are needed to allow a precise classification of EPTs. We have studied 44 benign and malignant EPTs by comparative genomic hybridization to correlate the overall number of genetic alterations with clinical and histopathological parameters and to identify chromosomal regions which might harbor genes involved in EPT pathogenesis and progression. Aberrations were found in 36 EPTs, and chromosomal losses (mean, 5.3) were slightly more frequent than gains (mean, 4. 6). The most frequent losses involved Y (45% of male EPTs), 6q (39%), 11q (36%), 3p, 3q, 11p (each 30%), 6p (27%), and 10q and Xq (each 25%), whereas most common gains included 7q (43%), 17q (41%), 5q and 14q (each 32%), 7p, 9q, 17p, 20q (each 27%), and 12q and Xp (each 25%). A correlation was found between the total number of genetic changes per tumor and both tumor size and disease stage. In particular, losses of 3p and 6 and gains of 14q and Xq were found to be associated with metastatic disease. Furthermore, characteristic patterns of genetic changes were found in the various EPT subtypes, eg, 6q loss in malignant insulinomas, indicating that these groups might evolve along genetically different pathways. The highlighted genetic aberrations, including the newly found involvement of 6q losses and sex chromosome alterations, should stimulate the further analysis of these chromosomal regions, which may lead to the discovery of novel genes important in the tumorigenesis and evolution of EPTs.