AKT activation was not essential for hepatocellular carcinoma cell survival under glucose deprivation.

Hepatocellular carcinoma (HCC) is the second leading cause of cancer-related death worldwide, with a dismal 5-year survival rate less than 15%. The present study aimed to investigate whether AKT inhibition and glucose deprivation could synergistically kill HCC cells and the molecular mechanisms involved. HCC cells were starved in glucose deprivation, and then the resultant cell death was determined by flow cytometry and mitochondrial oxygen consumption rates using a Seahorse XF-24 Extracellular Flux Analyzer. Glucose deprivation reduced mitochondrial oxygen consumption rates for ATP production, enhanced mitochondrial proton leaks, reduced Mcl-1 expression, and subsequently caused significant cell death in the sensitive HepG2 and HCC-M cells. In the resistant Hep3B and Huh7 cells that survived, glucose starvation induced time-dependent AKT activation. However, blockage of AKT activation using chemical inhibitors (ZSTK474 and LY290042) or specific AKT1-targeting siRNAs could not markedly sensitize glucose deprivation-induced cell death. In contrast, AKT inhibitors or AKT1-targeting siRNAs significantly protected the sensitive HepG2 cells from glucose deprivation-induced cell death. More importantly, AKT inhibition mechanically suppressed mTOR activity and induced the prosurvival autophagy pathway in the sensitive HCC cells. Taken together, these data demonstrated that AKT activity was not essential for HCC cell survival during glucose deprivation. The reduction of mTOR activity and induction of the autophagy pathway may hinder the potential application of AKT inhibitors in the cancer therapy of solid tumors such as HCC.

C/EBPα negatively regulates SIRT7 expression via recruiting HDAC3 to the upstream-promoter of hepatocellular carcinoma cells.

Mammalian Sirtuin proteins (SIRTs) are homologs of yeast Sir2, and characterized as class III histone deacetylases of NAD(+) dependence. Unlike their lower counterparts that are directly involved in the extending of lifespan, mammalian SIRTs mainly function in metabolism and cellular homeostasis, among them, SIRT7 is the least understood. SIRT7 is localized in the nucleus and rich in nucleoli associated with RNA polymerase I, and correlated with cell proliferation. In contrast, SIRT7 has recently been demonstrated to specifically deacetylate H3K18ac in the chromatin, and in most cases represses proliferation. Although MicroRNA as miR-125b has been reported to down-regulate SIRT7 by binding to its 3'UTR, however, how SIRT7 gene is regulated remains unclear. Here, we identified the transcription initiation site of human SIRT7 gene at the upstream 23rd A nucleotide respective to the translational codon, and the SIRT7 is a TATA-less and initiator-less gene. The sequences in the upstream region between -256 and -129 bp are identical with important functions in the three species detected. A C/EBPα responding element is found that binds both C/EBPα and C/EBPß in vitro. We showed TSA induced SIRT7 gene transcription and only the HDAC3, but not its catalytic domain depleted mutant, interacted with C/EBPα to occupy the C/EBPα element and repressed SIRT7 gene in the hepatocellular carcinoma cells. To our knowledge, this is the first report on the regulation mechanism of SIRT7 gene, in which, HDAC3 collaborated with C/EBPα to occupy its responding element in the upstream region of SIRT7 gene and repressed its expression in human cells.