Evidence for IRF-1-dependent gene expression deficiency in interferon unresponsive HepG2 cells.

Induction of the antiproliferative and antiviral state by IFNs (type I and II) is dramatically impaired in HepG2 cells. We show here that RNase L, IDO, GBP-2 and iNOS genes normally expressed as a secondary response to IFN are no longer inducible in HepG2 cells, while induction of primary response genes (IRF-1, PKR, p48-ISGF3gamma, 2-5AS, 6-16 and p56-(trp)tRNA) are unaffected. On the basis of previous data implicating transcription factor IRF-1 in the induction of some IFN-induced genes, we tested the effects of transfecting an IRF-1 oligonucleotide antisense in HeLa cells and found specifically impaired IFN induction of secondary response genes (RNase L, IDO and GBP-2). This raised the possibility that IRF-1 was defective in HepG2 cells. However, some molecular and biochemical analyses reveal that IRF-1 is induced normally by IFNs and retains its normal size, cellular location, phosphorylation status and ability to bind the IDO promoter in vitro. Therefore, we conclude that although the primary response pathway is fully functional, some aspects of the secondary pathway involving IRF-1 (but not IRF-1 itself) are defective in HepG2 cells. It may be possible that the promoter region of these deficient HepG2-genes requires an unidentified transcription factor in addition to de novo IRF-1, which could be elicited by a cooperative activator.

Lack of 2',5'-oligoadenylate-dependent RNase expression in the human hepatoma cell line HepG2.

2',5'-adenylate oligonucleotide (2-5A)-dependent RNase and 2-5A-synthetase are two enzymes of the 2-5A system strongly implicated in the basal control of RNA decay of both interferon-treated and untreated cells. RNase is activated by a 2-5A produced by 2-5A-synthetase, both enzymes being overexpressed by type I-interferon (alpha/beta). We described here for the first time a cell line completely deficient in RNase and its mRNA, while p69 2-5A-synthetase was normally interferon alpha/beta-induced. The complete absence of this RNase in human hepatoma cells (HepG2) was shown using three different methods based on the binding of a [32P]-labeled 2-5A probe of high specific activity to its binding site. Negative Western blotting assay with a specific monoclonal antibody correlated the previous findings. RNase-specific mRNA was not detectable even after treatment of cells with 1000 units/ml of interferon alpha/beta. This is not due to a mutation of the gene because an intronless genomic DNA sequence encoding 2-5A-binding site was cloned and expressed. It is likely that the expression of 2-5A-dependent RNase was impaired at the transcriptional level while having the known IFN alpha/beta-transcriptional regulatory factors as revealed by induction of p69 2-5A-synthetase gene. This may account for a differential activation of 2-5A-dependent RNase and 2-5A-synthetase genes by type I-interferon, and suggests that other members of regulatory transcription factors, different from IRF-1 and STAT proteins, may participate in two different interferon alpha/beta signaling pathways.

2',5'-Oligoadenylate-dependent RNAse located in nuclei: biochemical characterization and subcellular distribution of the nuclease in human and murine cells.

A cellular fractionation procedure allowed the rapid preparation of membraneless nuclei which contained a 2',5'-oligoadenylate (2-5A)-binding activity which was not due to cytoplasmic contaminants. Purified nuclei prepared from human lymphocytic leukaemia cells and mouse fibroblasts were found to contain 20-22% of the total cellular enzyme. In contrast with the cytoplasmic enzyme which was only present in a 2-5A-free form, 75% of the 2-5A-binding activity was found in the nuclei after a denaturing-renaturing procedure as the 2-5A-binding site was masked. Although the purification of nuclei from mouse fibroblasts was less effective, it appeared that, in confluent and growing cells, 50% and 75% respectively of the 2-5A-binding site was masked. Additional findings obtained by partial proteolysis and two-dimensional gel analysis provided definitive data on the nuclear location of this enzyme. Study of the nuclear 2-5A-dependent RNAase with a 2-5A-masked site could lead to an understanding of the molecular pathway involved in single-stranded RNA stability.