Evolution of complementary nucleotides in 5' and 3' untranslated regions of influenza A virus genomic segments

Effective Inhibition of Newly Emerged A/H7N9 Virus with Oligonucleotides Targeted to Conserved Regions of the Virus Genome

Newly emerged highly pathogenic A/H7N9 viruses with pandemic potential are effectively transmitted from birds to humans and require the development of novel antiviral drugs. For the first time, we studied the in vitro and in vivo antiviral activity against A/H7N9 of oligodeoxyribonucleotides (ODNs), which were delivered into the cells in the proposed TiO₂-based nanocomposites (TiO₂∼ODN). The highest inhibition of A/H7N9 in vitro (∼400-fold) and efficient, sequence-specific, and dose-dependent protection (up to 100%) of A/H7N9-infected mice was revealed when ODN was targeted to the conserved terminal 3'-noncoding region of viral (-)RNA. After the treatment with ODN, the virus titer values in the lungs of mice decreased by several orders of magnitude. The TiO₂∼ODN nanocomposite did not show toxicity in mice under the treatment conditions. The proposed approach for effective inhibition of the A/H7N9 can be tested against other viruses, for example, new emerging influenza viruses and coronaviruses with pandemic potential.

Packaging signal of influenza A virus

Influenza A virus (IAV) contains a genome with eight single-stranded, negative-sense RNA segments that encode 17 proteins. During its assembly, all eight separate viral RNA (vRNA) segments are incorporated into virions in a selective manner. Evidence suggested that the highly selective genome packaging mechanism relies on RNA-RNA or protein-RNA interactions. The specific structures of each vRNA that contribute to mediating the packaging of the vRNA into virions have been described and identified as packaging signals. Abundant research indicated that sequences required for genome incorporation are not series and are varied among virus genotypes. The packaging signals play important roles in determining the virus replication, genome incorporation and genetic reassortment of influenza A virus. In this review, we discuss recent studies on influenza A virus packaging signals to provide an overview of their characteristics and functions.

Family Level Phylogenies Reveal Relationships of Plant Viruses within the Order Bunyavirales

Bunyavirales are negative-sense segmented RNA viruses infecting arthropods, protozoans, plants, and animals. This study examines the phylogenetic relationships of plant viruses within this order, many of which are recently classified species. Comprehensive phylogenetic analyses of the viral RNA dependent RNA polymerase (RdRp), precursor glycoprotein (preGP), the nucleocapsid (N) proteins point toward common progenitor viruses. The RdRp of Fimoviridae and Tospoviridae show a close evolutional relationship while the preGP of Fimoviridae and Phenuiviridae show a closed relationship. The N proteins of Fimoviridae were closer to the Phasmaviridae, the Tospoviridae were close to some Phenuiviridae members and the Peribunyaviridae. The plant viral movement proteins of species within the Tospoviridae and Phenuiviridae were more closely related to each other than to members of the Fimoviridae. Interestingly, distal ends of 3′ and 5′ untranslated regions of species within the Fimoviridae shared similarity to arthropod and vertebrate infecting members of the Cruliviridae and Peribunyaviridae compared to other plant virus families. Co-phylogeny analysis of the plant infecting viruses indicates that duplication and host switching were more common than co-divergence with a host species.

A Short Chemically Modified dsRNA-Binding PNA (dbPNA) Inhibits Influenza Viral Replication by Targeting Viral RNA Panhandle Structure

RNAs play critical roles in diverse catalytic and regulatory biological processes and are emerging as important disease biomarkers and therapeutic targets. Thus, developing chemical compounds for targeting any desired RNA structures has great potential in biomedical applications. The viral and cellular RNA sequence and structure databases lay the groundwork for developing RNA-binding chemical ligands through the recognition of both RNA sequence and RNA structure. Influenza A virion consists of eight segments of negative-strand viral RNA (vRNA), all of which contain a highly conserved panhandle duplex structure formed between the first 13 nucleotides at the 5' end and the last 12 nucleotides at the 3' end. Here, we report our binding and cell culture anti-influenza assays of a short 10-mer chemically modified double-stranded RNA (dsRNA)-binding peptide nucleic acid (PNA) designed to bind to the panhandle duplex structure through novel major-groove PNA·RNA₂ triplex formation. We demonstrated that incorporation of chemically modified PNA residues thio-pseudoisocytosine (L) and guanidine-modified 5-methyl cytosine (Q) previously developed by us facilitates the sequence-specific recognition of Watson-Crick G-C and C-G pairs, respectively, at physiologically relevant conditions. Significantly, the chemically modified dsRNA-binding PNA (dbPNA) shows selective binding to the dsRNA region in panhandle structure over a single-stranded RNA (ssRNA) and a dsDNA containing the same sequence. The panhandle structure is not accessible to traditional antisense DNA or RNA with a similar length. Conjugation of the dbPNA with an aminosugar neamine enhances the cellular uptake. We observed that 2-5 μM dbPNA-neamine conjugate results in a significant reduction of viral replication. In addition, the 10-mer dbPNA inhibits innate immune receptor RIG-I binding to panhandle structure and thus RIG-I ATPase activity. These findings would provide the foundation for developing novel dbPNAs for the detection of influenza viral RNAs and therapeutics with optimal antiviral and immunomodulatory activities.

Dual Roles of the Hemagglutinin Segment-Specific Noncoding Nucleotides in the Extended Duplex Region of the Influenza A Virus RNA Promoter

We recently reported that the segment-specific noncoding regions (NCRs) of the hemagglutinin (HA) and neuraminidase (NA) segments are subtype specific, varying significantly in sequence and length at both the 3' and 5' ends. Interestingly, we found that nucleotides CC at positions 13 and 14 at the 3' end and GUG at positions 14 to 16 at the 5' end (termed 14' and 16' to distinguish them from 3' positions) are absolutely conserved among all HA subtype-specific NCRs. These HA segment-specific NCR nucleotides are located in the extended duplex region of the viral RNA promoter. In order to understand the significance of these highly conserved HA segment-specific NCR nucleotides in the virus life cycle, we performed extensive mutagenesis on the HA segment-specific NCR nucleotides and studied their functional significance in regulating influenza A virus replication in the context of the HA segment with both RNP reconstitution and virus infection systems. We found that the base pairing of the 3'-end 13 position with the 5'-end 14' position (^3'13-^5'14') position is critical for RNA promoter activity while the identity of the base pair is critical in determining HA segment packaging. Moreover, the identity of the residue at the 3'-end 14 position is functionally more important in regulating virus genome packaging than in regulating viral RNA synthesis. Taken together, these results demonstrated that the HA segment-specific NCR nucleotides in the extended duplex region of the promoter not only form part of the promoter but also play a key role in controlling virus selective genome packaging.

IMPORTANCE

The segment-specific complementary nucleotides (13 to 15 in the 3' end and 14' to 16' in the 5' end) in the extended duplex region of the influenza virus RNA promoter vary significantly among different segments and have rarely been studied. Here, we performed mutagenesis analysis of the highly conserved HA segment-specific nucleotides in the extended duplex region and examined their effects on virus replication in the context of the influenza A/WSN/33 (WSN) virus infection. We found that these HA segment-specific nucleotides not only act as a part of the RNA promoter but also play a critical role in HA segment packaging. Therefore, we showed experimentally, for the first time, the requirement of the nucleotides in the extended duplex region for the RNA promoter and also identified specific noncoding residues in regulating HA segment packaging. This work has implications for the development of attenuated vaccine strains and for elucidation the mechanisms of the virus genome packaging.

Self-Folding of Naked Segment 8 Genomic RNA of Influenza A Virus

Influenza A is a negative sense RNA virus that kills hundreds of thousands of humans each year. Base pairing in RNA is very favorable, but possibilities for RNA secondary structure of the influenza genomic RNA have not been investigated. This work presents the first experimentally-derived exploration of potential secondary structure in an influenza A naked (protein-free) genomic segment. Favorable folding regions are revealed by in vitro chemical structure mapping, thermodynamics, bioinformatics, and binding to isoenergetic microarrays of an entire natural sequence of the 875 nt segment 8 vRNA and of a smaller fragment. Segment 8 has thermodynamically stable and evolutionarily conserved RNA structure and encodes essential viral proteins NEP and NS1. This suggests that vRNA self-folding may generate helixes and loops that are important at one or more stages of the influenza life cycle.

A possible packaging signal in the rotavirus genome

Group A rotavirus (RVA), an etiological agent of gastroenteritis in young mammals and birds, possesses a genome of 11 double-stranded RNA segments. Although it is believed that the RVA virion contains one copy of each genomic segment and that the positive-strand RNA (+RNA) is incorporated into the core shell, the packaging mechanisms of RVA are not well understood. Here, packaging signals of RVA were searched for by analyzing genomic sequences of mammalian and avian RVA, which are considered to have evolved independently without reassortment. Assuming that packaging is mediated by direct interaction between +RNA segments via base-pairing, co-evolving complementary nucleotide sites were identified within and between genomic segments. There were two pairs of co-evolving complementary sites within the segment encoding VP7 (the VP7 segment) and one pair between the NSP2 and NSP3 segments. In the VP7 segment, the co-evolving complementary sites appeared to form stem structures in both mammalian and avian RVA, supporting their functionality. In contrast, co-evolving complementary sites between the NSP2 and NSP3 segments tended to be free from base-pairings and constituted loop structures, at least in avian RVA, suggesting that they are involved in a specific interaction between these segments as a packaging signal.

Virtual screening of gene expression regulatory sites in non-coding regions of the infectious salmon anemia virus

BACKGROUND

Members of the Orthomyxoviridae family, which contains an important fish pathogen called the infectious salmon anemia virus (ISAV), have a genome consisting of eight segments of single-stranded RNA that encode different viral proteins. Each of these segments is flanked by non-coding regions (NCRs). In other Orthomyxoviruses, sequences have been shown within these NCRs that regulate gene expression and virulence; however, only the sequences of these regions are known in ISAV, and a biological role has not yet been attributed to these regions. This study aims to determine possible functions of the NCRs of ISAV.

RESULTS

The results suggested an association between the molecular architecture of NCR regions and their role in the viral life cycle. The available NCR sequences from ISAV isolates were compiled, alignments were performed to obtain a consensus sequence, and conserved regions were identified in this consensus sequence. To determine the molecular structure adopted by these NCRs, various bioinformatics tools, including RNAfold, RNAstructure, Sfold, and Mfold, were used. This hypothetical structure, together with a comparison with influenza, yielded reliable secondary structure models that lead to the identification of conserved nucleotide positions on an intergenus level. These models determined which nucleotide positions are involved in the recognition of the vRNA/cRNA by RNA-dependent RNA polymerase (RdRp) or mRNA by the ribosome.

CONCLUSIONS

The information obtained in this work allowed the proposal of previously unknown sites that are involved in the regulation of different stages of the viral cycle, leading to the identification of new viral targets that may assist future antiviral strategies.

Impact of the segment-specific region of the 3'-untranslated region of the influenza A virus PB1 segment on protein expression

The 12 and 13 terminal nucleotides in the 3'- and 5'-untranslated regions (UTRs) of the influenza A virus genome, respectively, are important for the transcription of the viral RNA and the translation of mRNA. However, the functions of the segment-specific regions of the UTRs are not well known. We utilized an enhanced green fluorescent protein (eGFP) flanked at both ends by different UTRs (from the eight segments of H1N1 PR8/34) as a reporter gene to evaluate the effects of these UTRs on protein expression in vitro. The results showed that the protein expression levels of NP-eGFP, NS-eGFP, and HA-eGFP were higher than those of the other reporters and that the protein level of PB1-eGFP remained at a relatively low amount 48-h post-transfection. The results revealed that the UTRs of all segments differently affected the protein expression levels and that the effect of the UTRs of PB1 segment on protein expression was significant. The deletion of "UAAA" and "UAAACU" motifs in the PB1-3'-UTR significantly increased the protein expression level by 49.8 and 142.6%, respectively. This finding suggests that the "UAAACU" motif in the PB1-3'-UTR is at least partly responsible for the low protein expression level. By introducing the "UAAACU" motif into other 3'-UTRs (PA, NS, NP, and HA) at similar locations, the eGFP expression was reduced as expected by 56, 61, 22, and 22%, respectively. This result further confirmed that the "UAAACU" motif of the PB1-3'-UTR can inhibit protein expression. Our findings suggest that the segment-specific regions in the UTRs and not just the conserved regions of the UTRs play an important role in the viral protein expression. Additionally, the reported findings may also shed light on novel regulatory mechanism for the influenza A virus genome.

Adaptation of avian influenza A virus polymerase in mammals to overcome the host species barrier

Avian influenza A viruses, such as the highly pathogenic avian H5N1 viruses, sporadically enter the human population but often do not transmit between individuals. In rare cases, however, they establish a new lineage in humans. In addition to well-characterized barriers to cell entry, one major hurdle which avian viruses must overcome is their poor polymerase activity in human cells. There is compelling evidence that these viruses overcome this obstacle by acquiring adaptive mutations in the polymerase subunits PB1, PB2, and PA and the nucleoprotein (NP) as well as in the novel polymerase cofactor nuclear export protein (NEP). Recent findings suggest that synthesis of the viral genome may represent the major defect of avian polymerases in human cells. While the precise mechanisms remain to be unveiled, it appears that a broad spectrum of polymerase adaptive mutations can act collectively to overcome this defect. Thus, identification and monitoring of emerging adaptive mutations that further increase polymerase activity in human cells are critical to estimate the pandemic potential of avian viruses.