Telomerase is up-regulated in the vast majority of human cancers and serves to halt the progressive telomere shortening that ultimately blocks would-be cancer cells from achieving a full malignant phenotype. In contrast to humans, the laboratory mouse possesses long telomeres and, even in early generation telomerase-deficient mice, the level of telomere reserve is sufficient to avert telomere-based checkpoint responses and to permit full malignant progression. These features in the mouse provide an opportunity to determine whether enforced high-level telomerase activity can serve functions that extend beyond its ability to sustain telomere length and function. Here, we report the generation and characterization of transgenic mice that express the catalytic subunit of telomerase (mTERT) at high levels in a broad variety of tissues. Expression of mTERT conferred increased telomerase enzymatic activity in several tissues, including mammary gland, splenocytes, and cultured mouse embryonic fibroblasts. In mouse embryonic fibroblasts, mTERT overexpression extended telomere lengths but did not prevent culture-induced replicative arrest, thus reinforcing the view that this phenomenon is not related to occult telomere shortening. Robust telomerase activity, however, was associated with the spontaneous development of mammary intraepithelial neoplasia and invasive mammary carcinomas in a significant proportion of aged females. These data indicate that enforced mTERT expression can promote the development of spontaneous cancers even in the setting of ample telomere reserve.
NFB is an essential survival factor in several physiological conditions such as embryonal liver development and liver regeneration. However, NFB is also a main mediator of the cellular response to a variety of extracellular stress stimuli, and it has been shown that some viral-induced host cell apoptosis appears to be dependent on NFB activation. The activation of NFB upon viral infection may be a rapid way of initiating an innate immune response against the viral particles.
Our study shows that liver cirrhosis is the prime risk factor for hepatocarcinogenesis in Germany. However, the very high proportion of hepatitis virus related HCC, in particular the high proportion of HBV infections, contradicts the common view that alcohol is by far the most important etiological factor for hepatocarcinogenesis in low hepatitis virus endemic areas such as Germany.
The transcription factor nuclear factor kappaB (NFkappaB) is an essential antagonist of apoptosis during liver regeneration and embryonal development of hepatocytes. Several reports have indicated that NFkappaB may also inhibit the programmed cell death induced by cytokines, ionizing radiation, or cytotoxic drugs in some cancer cell lines. Because hepatocellular carcinomas (HCCs) are one of the most resistant tumors to systemic chemotherapy, we investigated the activation of NFkappaB and the consequence of its inhibition by an IkappaBalpha-super repressor during tumor necrosis factor alpha (TNFalpha)- and chemotherapy-induced apoptosis in HCC cell lines. We demonstrate that both TNFalpha and adriamycin activate NFkappaB in hepatoma cells. Activation of NFkappaB could be blocked through an adenoviral vector expressing the IkappaBalpha super repressor, regardless of the activating agent. Inhibition of NFkappaB enhanced the apoptosis induced by TNFalpha, whereas IkappaBalpha had an anti-apoptotic effect on chemotherapy-induced programmed cell death. A strong inhibition of chemotherapy- and TNFalpha-induced apoptosis by dominant-negative Fas-associated death domain indicated an essential contribution of death receptor-mediated apoptosis. To elucidate the different role of NFkappaB in chemotherapy-induced apoptosis, we investigated the expression of Fas (CD95) and Fas ligand (CD95 ligand), which have been described as important mediators of chemotherapy-induced cell death and as target genes of NFkappaB. However, our investigations demonstrated that in hepatoma cells, the chemotherapy-induced up-regulation of Fas (CD95) and Fas ligand (CD95 ligand) is not transcriptionally mediated through NFkappaB. Thus, other molecular mechanisms must account for the anti-apoptotic effect of IkappaBalpha in adriamycin-induced death of hepatoma cells. In summary, our investigations indicate that the activation of NFkappaB in response to cytotoxic drugs, in contrast to TNFalpha, exerts a pro-apoptotic stimulus rather than an anti-apoptotic function, which has implications for therapy of HCCs.
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