Increased early RNA replication by chimeric West Nile virus W956IC leads to IPS-1-mediated activation of NF-κB and insufficient virus-mediated counteraction of the resulting canonical type I interferon signaling.

Although infections with "natural" West Nile virus (WNV) and the chimeric W956IC WNV infectious clone virus produce comparable peak virus yields in type I interferon (IFN) response-deficient BHK cells, W956IC infection produces higher levels of "unprotected" viral RNA at early times after infection. Analysis of infections with these two viruses in IFN-competent cells showed that W956IC activated NF-κB, induced higher levels of IFN-ß, and produced lower virus yields than WNV strain Eg101. IPS-1 was required for both increased induction of IFN-ß and decreased yields of W956IC. In Eg101-infected cells, phospho-STAT1/STAT2 nuclear translocation was blocked at all times analyzed, while some phospho-STAT1/STAT2 nuclear translocation was still detected at 8 h after infection in W956IC-infected mouse embryonic fibroblasts (MEFs), and early viral protein levels were lower in these cells. A set of additional chimeras was made by replacing various W956IC gene regions with the Eg101 equivalents. As reported previously, for three of these chimeras, the low early RNA phenotype of Eg101 was restored in BHK cells. Analysis of infections with two of these chimeric viruses in MEFs detected lower early viral RNA levels, higher early viral protein levels, lower early IFN-ß levels, and higher virus yields similar to those seen after Eg101 infection. The data suggest that replicase protein interactions directly or indirectly regulate genome switching between replication and translation at early times in favor of translation to minimize NF-κB activation and IFN induction by decreasing the amount of unprotected viral RNA, to produce sufficient viral protein to block canonical type I IFN signaling, and to efficiently remodel cell membranes for exponential genome amplification.

Identification of novel host cell binding partners of Oas1b, the protein conferring resistance to flavivirus-induced disease in mice.

Oas1b was previously identified as the product of the Flv(r) allele that confers flavivirus-specific resistance to virus-induced disease in mice by an uncharacterized, RNase L-independent mechanism. To gain insights about the mechanism by which Oas1b specifically reduces the efficiency of flavivirus replication, cellular protein interaction partners were identified and their involvement in the Oas1b-mediated flavivirus resistance mechanism was analyzed. Initial difficulties in getting the two-hybrid assay to work with full-length Oas1b led to the discovery that this Oas protein uniquely has a C-terminal transmembrane domain that targets it to the endoplasmic reticulum (ER). Two peptides matching to oxysterol binding protein-related protein 1L (ORP1L) and ATP binding cassette protein 3, subfamily F (ABCF3), were identified as Oas1b interaction partners in yeast two-hybrid assays, and both in vitro-transcribed/translated peptides and full-length proteins in mammalian cell lysates coimmunoprecipitated with Oas1b. Knockdown of a partner involved in Oas1b-mediated antiflavivirus activity would be expected to increase flavivirus replication but not that of other types of viruses. However, RNA interference (RNAi) knockdown of ORP1L decreased the replication of the flavivirus West Nile virus (WNV) as well as that of other types of RNA viruses. This virus-nonspecific effect may be due to the recently reported dysregulation of late endosome movement by ORP1L knockdown. Knockdown of ABCF3 protein levels increased the replication of WNV but not that of other types of RNA viruses, and this effect on WNV replication was observed only in Oas1b-expressing cells. The results suggest that Oas1b is part of a complex located in the ER and that ABCF3 is a component of the Flv(r)-mediated resistance mechanism.

West nile virus infections suppress early viral RNA synthesis and avoid inducing the cell stress granule response.

West Nile virus (WNV) recently became endemic in the United States and is a significant cause of human morbidity and mortality. Natural WNV strain infections do not induce stress granules (SGs), while W956IC (a lineage 2/1 chimeric WNV infectious clone) virus infections produce high levels of early viral RNA and efficiently induce SGs through protein kinase R (PKR) activation. Additional WNV chimeric viruses made by replacing one or more W956IC genes with the lineage 1 Eg101 equivalent in the W956IC backbone were analyzed. The Eg-NS4b+5, Eg-NS1+3+4a, and Eg-NS1+4b+5 chimeras produced low levels of viral RNA at early times of infection and inefficiently induced SGs, suggesting the possibility that interactions between viral nonstructural proteins and/or between viral nonstructural proteins and cell proteins are involved in suppressing early viral RNA synthesis and membrane remodeling during natural WNV strain infections. Detection of exposed viral double-stranded RNA (dsRNA) in W956IC-infected cells suggested that the enhanced early viral RNA synthesis surpassed the available virus-induced membrane protection and allowed viral dsRNA to activate PKR.

West Nile virus infection does not induce PKR activation in rodent cells.

dsRNA-activated protein kinase (PKR) is activated by viral dsRNAs and phosphorylates eIF2a reducing translation of host and viral mRNA. Although infection with a chimeric West Nile virus (WNV) efficiently induced PKR and eIF2a phosphorylation, infections with natural lineage 1 or 2 strains did not. Investigation of the mechanism of suppression showed that among the cellular PKR inhibitor proteins tested, only Nck, known to interact with inactive PKR, colocalized and co-immunoprecipitated with PKR in WNV-infected cells and PKR phosphorylation did not increase in infected Nck1,2-/- cells. Several WNV stem-loop RNAs efficiently activated PKR in vitro but not in infected cells. WNV infection did not interfere with intracellular PKR activation by poly(I:C) and similar virus yields were produced by control and PKR-/- cells. The results indicate that PKR phosphorylation is not actively suppressed in WNV-infected cells but that PKR is not activated by the viral dsRNA in infected cells.

The Flvr-encoded murine oligoadenylate synthetase 1b (Oas1b) suppresses 2-5A synthesis in intact cells.

Resistance to flavivirus-induced disease in mice is conferred by the autosomal gene Flv, identified as 2'-5' oligoadenylate synthetase 1b (Oas1b). Resistant mice express a full-length Oas1b protein while susceptible mice express the truncated Oas1btr. In this study, Oas1b was shown to be an inactive synthetase. Although the Oas/RNase L pathway was previously shown to have an antiviral role during flavivirus infections, Oas1b protein inhibited Oas1a in vitro synthetase activity in a dose-dependent manner and reduced 2-5A production in vivo in response to poly(I:C). These findings suggest that negative regulation of 2-5A by inactive Oas1 proteins may fine tune the RNase L response that if not tightly controlled could cause significant damage in cells. The results also indicate that flavivirus resistance conferred by Oas1b is not mediated by 2-5A. Instead, Oas1b inhibits flavivirus replication by an alternative mechanism that overrides the proviral effect of reducing 2-5A accumulation and RNase L activation.

Insect globin gene polymorphisms: intronic minisatellites and a retroposon interrupting exon 1 of homologous globin genes in Chironomus (Diptera).

Exon 1 of globin gene ct-13RT in clone lambdagb2-1 from Chironomus thummi contains a 444nt SINE (CTRT1). Based on in situ hybridization to polytene salivary gland chromosomes, C. thummi (ct), C. piger (cp) and C. tentans (ctn) contain copies of CTRT1 at multiple chromosomal loci. Genomic PCR amplifications reveal interrupted (ct-13RT) and uninterrupted (ct-13) alleles of the globin gene in the German population of C. thummi maintained in our laboratory, and only uninterrupted alleles or their homologs in different populations of C. thummi, C. piger and C. tentans. PCR amplification did generate different length fragments from cp-13 gene homologs in natural and laboratory C. piger populations that were due to variation in the length of minisatellite expansions of the central introns of the genes rather than a CTRT1-like SINE. Within minisatellite arrays, aligned homologs were more similar than paralogs in a single population, indicating that a tandem cluster of these repeats predated separation of the C. piger populations. The ct-13 genes of several C. thummi populations lack the minisatellites, suggesting their origin in C. piger only after the thummi/piger split. CTRT1 transposition into a ct-13 allele is even more recent, occurring after separation of German and other European C. thummi populations. The nearly intact ct-13RT and comparison with its intact ct-13 allele support a very recent transposition of the CTRT1 SINE into one of at least two already diverged ct-13 globin gene alleles. PCR analysis of DNA from individual adults in C. thummi shows a 1:2:1 distribution of ct-13/ct-13:ct-13/ct-13RT:ct-13RT/ct-13RT genotypes, consistent with a neutral spread of the ct-13RT allele since transposition, and indicating that the hemoglobin encoded by ct-13 is not necessary for survival, at least in a laboratory population of C. thummi.

Interspersed DNA element restricted to a specific group of telomeres in the dipteran Chironomus pallidivittatus.

Telomeres in the dipteran Chironomus pallidivittatus terminate with 340bp tandem DNA repeats belonging to different subfamilies with characteristic intertelomeric distribution. We have now found, interspersed between such repeats, a composite element of approx. 1400bp present in two similar size variants, with several components of nontelomeric origin. There were about 50 copies of the element, predominantly or exclusively present in a previously defined group of telomeres, characterized by a unique set of telomeric tandem repeat subfamilies. Elements were integrated at irregular distances from each other, and intervening telomeric tandem repeat DNA was variable in composition. Nevertheless, the flanks immediately surrounding the elements were identical for different elements; in other words, there was a site-specific insertion. We suggest that this selective invasion of a small part of the genome by an interspersed, probably rapidly evolving element is best explained by repeated gene conversions.

The Chironomus (Camptochironomus) tentans genome contains two non-LTR retrotransposons.

A cDNA library from salivary gland cells of Chironomus tentans was screened with a probe containing the NLRCth1 non-LTR (long terminal repeat) retrotransposon from Chironomus thummi. Several positive clones were obtained and one of them, p62, was characterized by in situ hybridization and sequencing. The sequencing analysis showed that this clone contained a 4607 bp nucleotide sequence of a new transposable element that hybridized in situ to more than 100 sites over all four C. tentans chromosomes. The detailed analysis of this sequence revealed the presence of the 3'-end of open reading frame 1 (ORF1), a complete ORF2, and a 1.3-kb 3'-end untranslated region (UTR). The new element has been designated NLRCt2 (non-LTR retrotransposon 2 from C. tentans). A comparison of the nucleotide sequences of NLRCth1 and NLRCt2 showed 30% similarity in the region of ORF1 and 70% similarity in the region of ORF2. Based on the results of Southern blot analysis, two transposable elements have been found in the C. tentans genome, one of which is identical to NLRCth1 from C. thummi. This may be explained by horizontal transmission. The second element, NLRCt2, has been found in two different forms in the C. tentans genome. These can be distinguished by the presence of the 1.3-kb 3'-end UTR in one of the forms. Since the cDNA clone investigated was isolated from a tissue-specific cDNA library, the data showed that NRLCt2 is expressed in somatic cells.

A tissue-specific puff (Balbiani ring a) in Chironomus thummi may contain a gene encoding a 67-kDa protein which exhibits non-tissue-specific expression.

A 2.3-kb genomic clone has been isolated from the region where the tissue-specific puff, Balbiani ring a (BRa), is found on chromosome IV of the special lobe of Chironomus thummi salivary gland cells. The clone was characterized by nucleotide sequence analysis. Two clusters of direct tandem repeats were identified, as well as large and small open reading frames (ORFs). The large ORF was fused to an Escherichia coli lacZ gene. Antibodies against the beta-galactosidase/ORF fusion protein reacted selectively on Western blots with a 67-kDa protein. Western-blot analysis and immunoelectron microscopy showed that this protein was distributed in the cells of all larval tissues examined. We concluded that BRa, a tissue-specific puff, whose activity correlates with the synthesis of 160-kDa secretory protein [Kolesnikov et al., Chromosoma 83 (1981) 661-677], may also contain a gene which is not expressed in a tissue-specific manner.