Overexpression of chicken interferon regulatory factor-1 (Ch-IRF-1) induces constitutive expression of MHC class I antigens but does not confer virus resistance to a permanent chicken fibroblast cell line.

The chicken fibroblast cell line C32 has been transfected with the chicken homolog (Ch-IRF-1) of the mammalian transcription factor IRF-1. Stable transfectants were generated, constitutively overexpressing Ch-IRF-1 mRNA and protein. Cells overexpressing Ch-IRF-1 showed enhanced constitutive expression of MHC class I (B-F, beta-microglobulin) antigens. With increasing number of passages cells with normal B-F IV surface antigen expression accumulated. In the revertants, the amount of Ch-IRF-1 mRNA was reduced. Overexpression of Ch-IRF-1 had no effect on the constitutive expression and the induction by chicken interferon type-I and type-II (Ch-IFN) of guanylate-binding protein (GBP). Susceptibility to vesicular stomatitis virus, sindbis virus, Newcastle disease virus and vaccinia virus was not altered by overexpression of Ch-IRF-1. An antiviral state could be induced against all viruses tested by similar amounts of Ch-IFN type I in clone 20-18 expressing Ch-IRF-1 and cells transfected with empty vector.

The genomic structure of the chicken ICSBP gene and its transcriptional regulation by chicken interferon.

The chicken interferon consensus sequence binding protein (ChICSBP) gene spans over 9 kb of DNA and consists, as its murine homolog, of nine exons. The first untranslated exon was identified by 5'-RACE technology. The second exon contains the translation initiation codon. Canonical consensus splice sites are found on every exon/intron junction. The introns are generally smaller than their mammalian counterparts. The ChICSBP and ChIRF-1 genes have been mapped by fluorescence in situ hybridization to different microchromosomes. The transcription start site has been mapped by primer extension. Inspection of the DNA sequence of a genomic clone containing the first exon and the region 1700-bp upstream revealed several potential cisregulatory elements of transcription. The ChICSBP mRNA is induced by recombinant ChIFN type I and ChIFN-gamma. A palindromic IFN regulatory element (pIRE) with high sequence homology to gamma activation site (GAS) sequences was functionally required in transient transfection assays for the induction of transcription by ChIFN-gamma.

Interferon-stimulated response element (ISRE)-binding protein complex DRAF1 is activated in Sindbis virus (HR)-infected cells.

To elucidate the host cell defense mechanisms in response to Sindbis viral infection, we have started to characterize interferon (IFN)-stimulated response element (ISRE)-binding proteins activated in infected cells that are involved in the transcriptional induction of IFN type I-inducible genes. Using electromobility shift assays (EMSA), we detected several protein complexes with a human IFN-stimulated gene 15 (ISG15) ISRE in extracts from virus-infected L929 cells that were absent in extracts from uninfected cells. Comigration with Newcastle disease virus-activated ISRE-binding complexes, ISRE-binding specificity, supershift experiments, and conditions of formation indicate that the complexes activated by Sindbis viral infection in L929 cells correspond to DRAF1 and ISG factor 3 (ISGF3). Transfection of L929 cells with poly rI:rC induced only ISGF3. DRAF1 could be detected in Sindbis virus-infected mouse embryo fibroblasts derived from IFNR type I and type II KO mice. Viral RNA synthesis is required for activation of DRAF1.

Interferon sensitivity of expression of histone H5/H1(0)-vaccinia thymidine kinase fusion genes expressed by recombinant vaccinia viruses is enhanced by shortening the histone sequence.

To elucidate the structural basis responsible for the reduced IFN sensitivity of expression of the histone H1(0) and H5 gene, integrated into the vaccinia virus genome, vaccinia virus thymidine kinase (VV-TK)-histone H1(0)/H5 fusion genes were constructed and translocated into the TK locus of the VV genome. The chimeric genes, consisting of parts of either of the two histone genes and the 5' or 3' half of the TK gene, respectively, were expressed as histone-TK fusion proteins under the control of either the VV-TK promoter or the early sequences of the VV 7.5K promoter. IFN sensitivity of the expression of histone-TK fusion genes was shown to be influenced by the relative length of the histone sequence. Expression of fusion genes containing more than 45% cellular sequence either from the 5' or the 3' part of one of the two histone genes showed clearly reduced IFN sensitivity compared to the expression of VV-TK. On the other hand, by further reducing the relative amount of histone H5 or H1(0) sequence to 32%, the IFN sensitivity of expression of the corresponding fusion gene was drastically enhanced to levels indistinguishable from those of VV-TK.

Regulation of histone H5 and H1 zero gene expression under the control of vaccinia virus-specific sequences in interferon-treated chick embryo fibroblasts.

The duck histone H5 and human H1 zero were inserted into the thymidine kinase (TK) gene of vaccinia virus and the interferon sensitivity of their expression under the control of the viral TK and P7.5 promoters in chick embryo fibroblasts (CEF) was compared to the interferon sensitivity of vaccinia virus WR specific TK induction. Expression and transport of these histones to the nucleus in CEF infected with the appropriate vaccinia virus recombinants could be detected with antisera raised against chick histone H5. In CEF cultivated for 3 days, interferon treatment that completely inhibited TK synthesis had no or only a marginal inhibitory effect on the expression of the histone genes. Inhibition of the expression of the histones could be detected under conditions of increased interferon sensitivity in aged CEF. The magnitude of inhibition was, however, less pronounced than the inhibition of viral TK synthesis. These data indicate that flanking vaccinia virus DNA regions confer interferon sensitivity to the expression of these histone genes, but that they contain structural information that partially exempts their expression from the inhibitory activity of the interferon-induced regulatory system.