BACKGROUND & AIMS: To gain more information about the molecular mechanisms leading to dedifferentiation of hepatocellular adenoma (HCA) and hepatocellular carcinoma (HCC), high-resolution array-based comparative genomic hybridization (array-CGH) was performed on 24 cases of HCC and 10 cases of HCA. METHODS: DNA chips containing 6251 individual bacterial artificial chromosome/plasmid artificial chromosome clones were used. They allowed for a genome-wide resolution of 1 Mb and an even higher resolution of up to 100 kb for chromosome regions recurrently involved in human tumors and for regions containing known tumor-suppressor genes and oncogenes. RESULTS: Copy number changes on the genomic scale were found by array-based comparative genomic hybridization in all cases. In HCC, gains of chromosomal regions 1q (91.6%), and 8q (58.3%), and losses of 8p (54%) were found most frequently. Hierarchic cluster analysis branched all HCA from HCC. However, in 2 adenomas with a known history of glycogenosis type I and adenomatosis hepatis gains of 1q were found, too. The critically gained region was narrowed down to bands 1q22-23. Although no significant differences in the mean number of chromosomal aberrations were seen between adenomas and well-differentiated carcinomas (2.7 vs 4.6), a significant increase accompanied the dedifferentiation of HCC (14.1 in HCC-G2 and 16.3 in HCC-G2/3; P < .02). Dedifferentiation of HCC also was correlated closely to losses of 4q and 13q (P <.001 and <.005, respectively). CONCLUSIONS: The increased chromosomal instability during dedifferentiation of HCC leads to an accumulation of structural chromosomal aberrations and losses and gains of defined chromosome regions.
BACKGROUND & AIMS: To gain more information about the molecular mechanisms leading to dedifferentiation of hepatocellular adenoma (HCA) and hepatocellular carcinoma (HCC), high-resolution array-based comparative genomic hybridization (array-CGH) was performed on 24 cases of HCC and 10 cases of HCA. METHODS: DNA chips containing 6251 individual bacterial artificial chromosome/plasmid artificial chromosome clones were used. They allowed for a genome-wide resolution of 1 Mb and an even higher resolution of up to 100 kb for chromosome regions recurrently involved in humantumors and for regions containing known tumor-suppressor genes and oncogenes. RESULTS: Copy number changes on the genomic scale were found by array-based comparative genomic hybridization in all cases. In HCC, gains of chromosomal regions 1q (91.6%), and 8q (58.3%), and losses of 8p (54%) were found most frequently. Hierarchic cluster analysis branched all HCA from HCC. However, in 2 adenomas with a known history of glycogenosis type I and adenomatosis hepatis gains of 1q were found, too. The critically gained region was narrowed down to bands 1q22-23. Although no significant differences in the mean number of chromosomal aberrations were seen between adenomas and well-differentiated carcinomas (2.7 vs 4.6), a significant increase accompanied the dedifferentiation of HCC (14.1 in HCC-G2 and 16.3 in HCC-G2/3; P < .02). Dedifferentiation of HCC also was correlated closely to losses of 4q and 13q (P <.001 and <.005, respectively). CONCLUSIONS: The increased chromosomal instability during dedifferentiation of HCC leads to an accumulation of structural chromosomal aberrations and losses and gains of defined chromosome regions.