These findings suggest that inactivation of pRB and/or p16 is a major event in human hepatocarcinogenesis, while cyclin D1 overexpression may confer additional growth advantages to the tumor in addition to pRB and/or p16 inactivation in HCC.
In conclusion, gankyrin expression induced in liver fibrosis accelerated the degradation of pRB during liver cirrhosis, and inactivation of p16 exon 1 by DNA hypermethylation occurred during the progression of tumor cells to poorly differentiated HCC.
DNA hypermethylation on CpG islands of the p16 (8% and 66%) and hMLH1 (0% and 0%) genes and methylated in tumor (MINT) 1 (6% and 34%), 2 (24% and 58%), 12 (21% and 33%), 25 (0% and 5%), and 31 (0% and 23%) clones, and DNA hypomethylation on satellites 2 and 3 (18% and 67%), were detected in noncancerous liver tissues and HCCs, respectively.
The INK4a-ARF-/p53-pathway was disrupted in 86% of HCC, either by p53 mutations or by INK4a-ARF inactivation, and may have co-operative effects in hepatocarcinogenesis.
An optimal correlation was found between p15 and p16 gene methylation and complete protein loss in HCC detected by immunocytochemistry, whereas a partial loss of the same proteins was a feature of methylated cirrhoses.
Inactivation of p14(ARF) was always associated with the concomitant inactivation of p16(INK4a) and occurred more frequently in hepatitis C virus (HCV)-associated HCC (p=0.042).
Inactivation of p14(ARF) was always associated with the concomitant inactivation of p16(INK4a) and occurred more frequently in hepatitis C virus (HCV)-associated HCC (p=0.042).
In conclusion, our results demonstrate that RASSF1A and p16(INK4a) inactivation by methylation are frequent events in hepatocellular carcinoma, but not in HCA, which is in contrast to HCC without cirrhosis, viral hepatitis, storage diseases, or genetic background.
We previously reported that aberrant p16 RNA transcripts are expressed in hepatocellular carcinoma (HCC) cell lines having hypermethylated p16 promoters.
As p16INK4a protein is inactivated in hepatocellular carcinoma (HCC), we aimed to investigate the role of Id-1 in regulating p16INK4a expression during the development of HCC in HCC patients and direct ectopic Id-1 introduction into the PLC/PRF/5 HCC cell line.
HCC samples showing low Id-1 protein expression had a lower Id-1 mRNA level (340.2 versus 1467%, P = 0.039) and higher p16INK4a expression (195 versus -78.6%, P = 0.039) than samples with high Id-1 protein expression.
In our study, we screened HCCs resulting from HCV infection (51 cases), HBV infection (26 cases) or excess alcohol intake (23 cases) for alterations in genes involved in the RB1 pathway (p16(INK4a), p15(INK4b), RB1, CDK4 and cyclin D1), the p53 pathway (p53, p14(ARF) and MDM2) and the Wnt pathway (beta-catenin, APC).
No significant difference was seen in the detectability and concentrations of methylated p16INK4a sequences (range: 10-4046 genome-equivalents/ml) between preoperative plasma and serum samples from HCC patients.
The status of p14 was evaluated in 117 HCC tumoral nodules and 110 corresponding non-tumor tissues by loss of heterozygosity at the 9p21-22 region, homozygous deletions, single strand conformation polymorphism-polymerase chain reaction mutational analysis and methylation-specific polymerase chain reaction.