West Nile virus NS2A protein facilitates virus-induced apoptosis independently of interferon response.

The flavivirus NS2A protein is a small, multifunctional protein, involved in replication, virion formation and regulation of the innate immune response. Using the Kunjin strain of West Nile virus (WNV(KUN)) we previously demonstrated that a single amino acid change from alanine to proline at position 30 of the NS2A protein (A30P) reduced viral cytopathicity in cells and virulence in mice. To further investigate functions of the NS2A protein we have substituted alanine at position 30 with different amino acids (A30 mutants) in a WNV(KUN) infectious clone. The virulence of mutant viruses in wild-type (WT) and IRF3/IRF7 double-knockout mice was influenced by the amino acid change and ranged from high to low in the order of WT>A30L>A30E>A30P/A30G. Moreover, infection of beta interferon (IFN-ß)-deficient Vero cells with A30P virus showed less pronounced chromosomal DNA degradation and lower percentage of cells with positive TUNEL labelling than in WT virus infection, indicating a role for the WT NS2A protein in IFN-independent apoptotic cell death.

NS1' of flaviviruses in the Japanese encephalitis virus serogroup is a product of ribosomal frameshifting and plays a role in viral neuroinvasiveness.

Flavivirus NS1 is a nonstructural protein involved in virus replication and regulation of the innate immune response. Interestingly, a larger NS1-related protein, NS1', is often detected during infection with the members of the Japanese encephalitis virus serogroup of flaviviruses. However, how NS1' is made and what role it performs in the viral life cycle have not been determined. Here we provide experimental evidence that NS1' is the product of a -1 ribosomal frameshift event that occurs at a conserved slippery heptanucleotide motif located near the beginning of the NS2A gene and is stimulated by a downstream RNA pseudoknot structure. Using site-directed mutagenesis of these sequence elements in an infectious clone of the Kunjin subtype of West Nile virus, we demonstrate that NS1' plays a role in viral neuroinvasiveness.

Selection for gene junction sequences important for VSV transcription.

The heptauridine tract at each gene end and intergenic region (IGR) at the gene junctions of vesicular stomatitis virus (VSV) have effects on synthesis of the downstream mRNA, independent of their respective roles in termination of the upstream mRNA. To investigate the role of the U tract and the IGR in downstream gene transcription, we altered the N/P gene junction of infectious VSV such that transcription levels would be affected and result in altered molar ratios of the N and P proteins, which are critical for optimal viral RNA replication. The changes included extended IGRs between the N and P genes and shortening the length of the heptauridine tract upstream of the P gene start. Viruses having various combinations of these changes were recovered from cDNA and selective pressure for efficient viral replication was applied by sequential passage in cell culture. The replicative ability and sequence at the altered intergenic junctions were monitored throughout the passages to compare the effects of the changes at the IGR and U tract. VSV variants with wild-type U tracts upstream of the P gene replicated to levels similar to wt VSV. Variants with shortened U tracts were reduced in their ability to replicate. With passage, populations emerged that replicated to higher levels. Sequence analysis revealed that mutations had been selected for in these populations that increased the length of the U tract. This correlated with an increase in abundance of P mRNA and protein to provide improved N:P protein molar ratios. Extended IGRs resulted in decreased downstream transcription but the effect was not as extensive as that caused by shortened U tracts. Extended IGRs were not selected against in 5 passages. Our results indicate that the size of the upstream gene end U tract is an important determinant of efficient downstream gene transcription in infectious virus.

The VSV polymerase can initiate at mRNA start sites located either up or downstream of a transcription termination signal but size of the intervening intergenic region affects efficiency of initiation.

Transcription by the vesicular stomatitis virus (VSV) polymerase has been characterized as obligatorily sequential with transcription of each downstream gene dependent on termination of the gene immediately upstream. In studies described here we investigated the ability of the VSV RNA-dependent RNA polymerase (RdRp) to access mRNA initiation sites located at increasing distances either downstream or upstream of a transcription termination signal. Bi-cistronic subgenomic replicons were constructed containing progressively extended intergenic regions preceding the initiation site of a downstream gene. The ability of the RdRp to access the downstream sites was progressively reduced as the length of the intergenic region increased. Alternatively, bi-cistronic replicons were constructed containing an mRNA start signal located at increasing distances upstream of a termination site. Analysis of transcription of these "overlapped" genes showed that for an upstream mRNA start site to be recognized it had to contain not only the canonical 3'-UUGUCnnUAG-5' gene start signal, but that signal needed also to be preceded by a U7 tract. Access of these upstream mRNA initiation sites by the VSV RdRp was proportionately reduced with increasing distance between the termination site and the overlapped initiation signal. Possible mechanisms for how the RdRp accesses these upstream start sites are discussed.

Identification of an upstream sequence element required for vesicular stomatitis virus mRNA transcription.

Vesicular stomatitis virus (VSV), the prototypic rhabdovirus, has a nonsegmented negative-sense RNA genome with five genes flanked by 3' leader and 5' trailer sequences. Transcription of VSV mRNAs is obligatorily sequential, starting from a single 3' polymerase entry site, and termination of an upstream mRNA is essential for transcription of a downstream gene. cis-acting signals for transcription of VSV mRNAs are present within the leader region, at the leader-N junction, and at the internal gene junctions. The gene junctions of VSV consist of a conserved 23-nucleotide region that includes the gene end sequence of the upstream gene, 3'-AUACU7-5', a nontranscribed intergenic dinucleotide, 3'-G/CA-5', and the gene start sequence, 3'-UUGUCNNUAG-5', at the beginning of the gene immediately downstream. Previous work has shown that the gene end sequence and intergenic region are sufficient to signal polyadenylation and termination of VSV transcripts. Mutagenesis of the gene start sequence has determined the importance of this region in the processes of initiation and 5'-end modification of mRNAs. However, because the gene end sequence is positioned directly upstream of the gene start sequence in the gene junction, and because of the requirement for termination of the upstream gene prior to transcription of the downstream gene, it has not been possible to investigate whether the gene end sequence contributes to transcription of the downstream gene. In this study, we inserted an additional gene end sequence upstream of the gene junction in a subgenomic replicon of VSV, which extended the intergenic region from 2 to 88 nucleotides. This duplication of termination signals allowed us to separate the signals required for termination from those required for initiation. We investigated the effect that the upstream gene end sequences had on downstream mRNA transcription. Our data show that the U7 tract of the upstream gene end sequence is necessary for optimal transcription of the downstream gene, independent of its role in termination of the upstream gene. Altering the sequence or changing the length of the U tract directly upstream of the gene start sequence significantly decreased transcription of the downstream gene. These results show that the U tract is a multifunctional region that is required not only for polyadenylation and termination of the upstream mRNA but also for efficient transcription of the downstream gene.