Telomerase deletion limits progression of p53-mutant hepatocellular carcinoma with short telomeres in chronic liver disease.

BACKGROUND & AIMS: During early stages of carcinogenesis most human epithelial cancers including hepatocellular carcinoma (HCC) have been observed to transit through a "crisis" stage characterized by telomere shortening, loss of p53 checkpoint function, and a sharp increase in aneuploidy. The function of telomerase during in vivo hepatocarcinogenesis has not been studied in this genetic context. METHODS: Here we generated a mouse model in which HCC was induced by chronic organ damage (HBs-AG transgene) in the presence of telomere shortening and p53 deletion. Tumor development was analyzed in late-generation telomerase knockout mice (mTERC(-/-)) and littermates, genetically rescued for telomerase gene expression (mTERC(+/-)). RESULTS: The formation of HCCs was strongly suppressed in mTERC(-/-) mice compared to mTERC(+/-) siblings correlating with reduced rates of tumor cell proliferation and elevated rates of tumor cell apoptosis. Although the prevalence of short telomeres was similar in chronically damaged liver of both cohorts, mTERC(-/-) HCC developed increased levels of DNA damage and aneuploidy compared to mTERC(+/-) HCC. CONCLUSIONS: This study provides direct evidence that telomerase is a critical component for in vivo progression of p53 mutant HCC with short telomeres in the chronically damaged liver. In this molecular context, telomerase limits the accumulation of telomere dysfunction, the evolution of excessive aneuploidy, and the activation of p53-independent checkpoints suppressing hepatocarcinogenesis.

Specific ablation of the transcription factor CREB in sympathetic neurons surprisingly protects against developmentally regulated apoptosis.

The cyclic-AMP response element-binding (CREB) protein family of transcription factors plays a crucial role in supporting the survival of neurons. However, a cell-autonomous role has not been addressed in vivo. To investigate the cell-specific role of CREB, we used as a model developing sympathetic neurons, whose survival in vitro is dependent on CREB activity. We generated mice lacking CREB in noradrenergic (NA) and adrenergic neurons and compared them with the phenotype of the germline CREB mutant. Whereas the germline CREB mutant revealed increased apoptosis of NA neurons and misplacement of sympathetic precursors, the NA neuron-specific mutation unexpectedly led to reduced levels of caspase-3-dependent apoptosis in sympathetic ganglia during the period of naturally occurring neuronal death. A reduced level of p75 neurotrophin receptor expression in the absence of CREB was shown to be responsible. Thus, our analysis indicates that the activity of cell-autonomous pro-survival signalling is operative in developing sympathetic neurons in the absence of CREB.