Nonviral oligonucleotides at the 5' terminus of cytoplasmic influenza viral mRNA deduced from cloned complete genomic sequences

Natural History of Influenza B Virus-Current Knowledge on Treatment, Resistance and Therapeutic Options

Influenza B virus (IBV) significantly impacts the health and the economy of the global population. WHO global health estimates project 1 billion flu cases annually, with 3 to 5 million resulting in severe disease and 0.3 to 0.5 million influenza-related deaths worldwide. Influenza B virus epidemics result in significant economic losses due to healthcare expenses, reduced workforce productivity, and strain on healthcare systems. Influenza B virus epidemics, such as the 1987-1988 Yamagata lineage outbreak and the 2001-2002 Victoria lineage outbreak, had a significant global impact. IBV's fast mutation and replication rates facilitate rapid adaptation to the environment, enabling the evasion of existing immunity and the development of resistance to virus-targeting treatments. This leads to annual outbreaks and necessitates the development of new vaccination formulations. This review aims to elucidate IBV's evolutionary genomic organization and life cycle and provide an overview of anti-IBV drugs, resistance, treatment options, and prospects for IBV biology, emphasizing challenges in preventing and treating IBV infection.

Role of RNA Polymerase II Promoter-Proximal Pausing in Viral Transcription

The promoter-proximal pause induced by the binding of the DRB sensitivity-inducing factor (DSIF) and the negative elongation factor (NELF) to RNAP II is a key step in the regulation of metazoan gene expression. It helps maintain a permissive chromatin landscape and ensures a quick transcriptional response from stimulus-responsive pathways such as the innate immune response. It is also involved in the biology of several RNA viruses such as the human immunodeficiency virus (HIV), the influenza A virus (IAV) and the hepatitis delta virus (HDV). HIV uses the pause as one of its mechanisms to enter and maintain latency, leading to the creation of viral reservoirs resistant to antiretrovirals. IAV, on the other hand, uses the pause to acquire the capped primers necessary to initiate viral transcription through cap-snatching. Finally, the HDV RNA genome is transcribed directly by RNAP II and requires the small hepatitis delta antigen to displace NELF from the polymerase and overcome the transcriptional block caused by RNAP II promoter-proximal pausing. In this review, we will discuss the RNAP II promoter-proximal pause and the roles it plays in the life cycle of RNA viruses such as HIV, IAV and HDV.

Small RNA Plays Important Roles in Virus-Host Interactions

Non-coding small RNAs play important roles in virus-host interactions. For hosts, small RNAs can serve as sensors in antiviral pathways including RNAi and CRISPR; for viruses, small RNAs can be involved in viral transcription and replication. This paper covers several recent discoveries on small RNA mediated virus-host interactions, and focuses on influenza virus cap-snatching and a few important virus sensors including PIR-1, RIG-I like protein DRH-1 and piRNAs. The paper also discusses recent advances in mammalian antiviral RNAi.

Influenza A virus utilizes noncanonical cap-snatching to diversify its mRNA/ncRNA

Influenza A virus (IAV) utilizes cap-snatching to obtain host capped small RNAs for priming viral mRNA synthesis, generating capped hybrid mRNAs for translation. Previous studies have been focusing on canonical cap-snatching, which occurs at the very 5' end of viral mRNAs. Here we discovered noncanonical cap-snatching, which generates capped hybrid mRNAs/noncoding RNAs mapped to the region ∼300 nucleotides (nt) upstream of each mRNA 3' end, and to the 5' region, primarily starting at the second nt, of each virion RNAs (vRNA). Like canonical cap-snatching, noncanonical cap-snatching utilizes a base-pairing between the last nt G of host capped RNAs and a nt C of template RNAs to prime RNA synthesis. However, the nt upstream of this template C is usually A/U rather than just U; prime-realignment occurs less frequently. We also demonstrate that IAV can snatch capped IAV RNAs in addition to host RNAs. Noncanonical cap-snatching likely generates novel mRNAs with start AUG encoded in viral or host RNAs. These findings expand our understanding of cap-snatching mechanisms and suggest that IAV may utilize noncanonical cap-snatching to diversify its mRNAs/ncRNAs.

Toscana virus cap-snatching and initiation of transcription

Toscana virus (TOSV) is an arthropod-borne phlebovirus within the family Phenuiviridae in the order Bunyavirales. It seems to be an important agent of human meningoencephalitis in the warm season in the Mediterranean area. Because the polymerase of Bunyavirales lacks a capping activity, it cleaves short-capped RNA leaders derived from the host cell, and uses them to initiate viral mRNA synthesis. To determine the size and nucleotide composition of the host-derived RNA leaders, and to elucidate the first steps of TOSV transcription initiation, we performed a high-throughput sequencing of the 5' end of TOSV mRNAs in infected cells at different times post-infection. Our results indicated that the viral polymerase cleaved the host-capped RNA leaders within a window of 11-16 nucleotides. A single population of cellular mRNAs could be cleaved at different sites to prime the synthesis of several viral mRNA species. The majority of the mRNA resulted from direct priming, but we observed mRNAs resulting from several rounds of prime-and-realign events. Our data suggest that the different rounds of the prime-and-realign mechanism result from the blocking of the template strand in a static position in the active site, leading to the slippage of the nascent strand by two nucleotides when the growing duplex is sorted out from the active site. To minimize this rate-limiting step, TOSV polymerase cleaves preferentially capped RNA leaders after GC, so as to greatly reduce the number of cycles of priming and realignment, and facilitate the separation of the growing duplex.

Influenza A virus cap-snatches host RNAs based on their abundance early after infection

The influenza A virus RNA polymerase cleaves the 5' ends of host RNAs and uses these RNA fragments as primers for viral mRNA synthesis. We performed deep sequencing of the 5' host-derived ends of the eight viral mRNAs of influenza A/Puerto Rico/8/1934 (H1N1) virus in infected A549 cells, and compared the population to those of A/Hong Kong/1/1968 (H3N2) and A/WSN/1933 (H1N1). In the three strains, the viral RNAs target different populations of host RNAs. Host RNAs are cap-snatched based on their abundance, and we found that RNAs encoding proteins involved in metabolism are overrepresented in the cap-snatched populations. Because this overrepresentation could be a reflection of the host response early after infection, and thus of the increased availability of these transcripts, our results suggest that host RNAs are cap-snatched mainly based on their abundance without preferential targeting.

Bunyaviridae RdRps: structure, motifs, and RNA synthesis machinery

Bunyaviridae family is the largest and most diverse family of RNA viruses. It has more than 350 members divided into five genera: Orthobunyavirus, Phlebovirus, Nairovirus, Hantavirus, and Tospovirus. They are present in the five continents, causing recurrent epidemics, epizootics, and considerable agricultural loss. The genome of bunyaviruses is divided into three segments of negative single-stranded RNA according to their relative size: L (Large), M (Medium) and S (Small) segment. Bunyaviridae RNA-dependent RNA polymerase (RdRp) is encoded by the L segment, and is in charge of the replication and transcription of the viral RNA in the cytoplasm of the infected cell. Viral RdRps share a characteristic right hand-like structure with three subdomains: finger, palm, and thumb subdomains that define the formation of the catalytic cavity. In addition to the N-terminal endonuclease domain, eight conserved motifs (A-H) have been identified in the RdRp of Bunyaviridae. In this review, we have summarized the recent insights from the structural and functional studies of RdRp to understand the roles of different motifs shared by RdRps, the mechanism of viral RNA replication, genome segment packaging by the nucleoprotein, cap-snatching, mRNA transcription, and other RNA mechanisms of bunyaviruses.

Inherent properties not conserved in other tenuiviruses increase priming and realignment cycles during transcription of Rice stripe virus

Two tenuiviruses Rice stripe virus (RSV) and Rice grassy stunt virus (RGSV) were found to co-infect rice with the same reovirus Rice ragged stunt virus (RRSV). During the co-infection, both tenuiviruses recruited 10-21 nucleotides sized capped-RNA leaders from the RRSV. A total of 245 and 102 RRSV-RGSV and RRSV-RSV chimeric mRNA clones, respectively, were sequenced. An analysis of the sequences suggested a scenario consistent with previously reported data on related viruses, in which capped leader RNAs having a 3' end complementary to the viral template are preferred and upon base pairing the leaders prime processive transcription directly or after one to several cycles of priming and realignment (repetitive prime-and-realign). Interestingly, RSV appeared to have a higher tendency to use repetitive prime-and-realign than RGSV even with the same leader derived from the same RRSV RNA. Combining with relevant data reported previously, this points towards an intrinsic feature of RSV.

Influenza A virus preferentially snatches noncoding RNA caps

Influenza A virus (IAV) lacks the enzyme for adding 5' caps to its RNAs and snatches the 5' ends of host capped RNAs to prime transcription. Neither the preference of the host RNA sequences snatched nor the effect of cap-snatching on host processes is completely defined. Previous studies of influenza cap-snatching used poly(A)-selected RNAs from infected cells or relied on annotated host genes to define the snatched host RNAs, and thus lack details on many noncoding host RNAs including snRNAs, snoRNAs, and promoter-associated capped small (cs)RNAs, which are made by "paused" Pol II during transcription initiation. In this study, we used a nonbiased technique, CapSeq, to identify host and viral-capped RNAs including nonpolyadenylated RNAs in the same samples, and investigated the substrate-product correlation between the host RNAs and the viral RNAs. We demonstrated that noncoding host RNAs, particularly U1 and U2, are the preferred cap-snatching source over mRNAs or pre-mRNAs. We also found that csRNAs are highly snatched by IAV. Because the functions of csRNAs remain mostly unknown, especially in somatic cells, our finding reveals that csRNAs at least play roles in the process of IAV infection. Our findings support a model where nascent RNAs including csRNAs are the preferred targets for cap-snatching by IAV and raise questions about how IAV might use snatching preferences to modulate host-mRNA splicing and transcription.

Deep sequencing reveals the eight facets of the influenza A/HongKong/1/1968 (H3N2) virus cap-snatching process

The influenza A virus RNA polymerase cleaves the 5′ end of host pre-mRNAs and uses the capped RNA fragments as primers for viral mRNA synthesis. We performed deep sequencing of the 5′ ends of viral mRNAs from all genome segments transcribed in both human (A549) and mouse (M-1) cells infected with the influenza A/HongKong/1/1968 (H3N2) virus. In addition to information on RNA motifs present, our results indicate that the host primers are divergent between the viral transcripts. We observed differences in length distributions, nucleotide motifs and the identity of the host primers between the viral mRNAs. Mapping the reads to known transcription start sites indicates that the virus targets the most abundant host mRNAs, which is likely caused by the higher expression of these genes. Our findings suggest negligible competition amongst RdRp:vRNA complexes for individual host mRNA templates during cap-snatching and provide a better understanding of the molecular mechanism governing the first step of transcription of this influenza strain.

Interaction between hantavirus nucleocapsid protein (N) and RNA-dependent RNA polymerase (RdRp) mutants reveals the requirement of an N-RdRp interaction for viral RNA synthesis

Viral ribonucleocapsids harboring the viral genomic RNA are used as the template for viral mRNA synthesis and replication of the viral genome by viral RNA-dependent RNA polymerase (RdRp). Here we show that hantavirus nucleocapsid protein (N protein) interacts with RdRp in virus-infected cells. We mapped the RdRp binding domain at the N terminus of N protein. Similarly, the N protein binding pocket is located at the C terminus of RdRp. We demonstrate that an N protein-RdRp interaction is required for RdRp function during the course of virus infection in the host cell.

Signatures of host mRNA 5' terminus for efficient hantavirus cap snatching

Hantaviruses, similarly to other negative-strand segmented RNA viruses, initiate the synthesis of translation-competent capped mRNAs by a unique cap-snatching mechanism. Hantavirus nucleocapsid protein (N) binds to host mRNA caps and requires four nucleotides adjacent to the 5' cap for high-affinity binding. N protects the 5' caps of cellular transcripts from degradation by the cellular decapping machinery. The rescued 5' capped mRNA fragments are stored in cellular P bodies by N, which are later efficiently used as primers by the hantaviral RNA-dependent RNA polymerase (RdRp) for transcription initiation. We showed that N also protects the host mRNA caps in P-body-deficient cells. However, the rescued caps were not effectively used by the hantavirus RdRp during transcription initiation, suggesting that caps stored in cellular P bodies by N are preferred for cap snatching. We examined the characteristics of the 5' terminus of a capped test mRNA to delineate the minimum requirements for a capped transcript to serve as an efficient cap donor during hantavirus cap snatching. We showed that hantavirus RdRp preferentially snatches caps from the nonsense mRNAs compared to mRNAs engaged in translation. Hantavirus RdRp preferentially cleaves the cap donor mRNA at a G residue located 14 nucleotides downstream of the 5' cap. The sequence complementarity between the 3' terminus of viral genomic RNA and the nucleotides located in the vicinity of the cleavage site of the cap donor mRNA favors cap snatching. Our results show that hantavirus RdRp snatches caps from viral mRNAs. However, the negligible cap-donating efficiency of wild-type mRNAs in comparison to nonsense mRNAs suggests that viral mRNAs will not be efficiently used for cap snatching during viral infection due to their continuous engagement in protein synthesis. Our results suggest that efficiency of an mRNA to donate caps for viral mRNA synthesis is primarily regulated at the translational level.

Fig mosaic virus mRNAs show generation by cap-snatching

Fig mosaic virus (FMV), a member of the newly described genus Emaravirus, has four negative-sense single-stranded genomic RNAs, and each codes for a single protein in the viral complementary RNA (vcRNA). In this study we show that FMV mRNAs for genome segments 2 and 3 contain short (12-18 nucleotides) heterogeneous nucleotide leader sequences at their 5' termini. Furthermore, by using the high affinity cap binding protein eIF4E(K119A), we also determined that a 5' cap is present on a population of the FMV positive-sense RNAs, presumably as a result of cap-snatching. Northern hybridization results showed that the 5' capped RNA3 segments are slightly smaller than the homologous vcRNA3 and are not polyadenylated. These data suggest that FMV generates 5' capped mRNAs via cap-snatching, similar to strategies used by other negative-sense multipartite ssRNA viruses.

Repetitive prime-and-realign mechanism converts short capped RNA leaders into longer ones that may be more suitable for elongation during rice stripe virus transcription initiation

Cucumber mosaic virus (CMV) RNAs were found to serve as cap donors for rice stripe virus (RSV) transcription initiation during their co-infection of Nicotiana benthamiana. The 5' end of CMV RNAs was cleaved preferentially at residues that had multiple-base complementarity to the 3' end of the RSV template. The length requirement for CMV capped primers to be suitable for elongation varied between 12 and 20 nt, and those of 12-16 nt were optimal for elongation and generated more CMV-RSV chimeric mRNA transcripts. The original cap donors that were cleaved from CMV RNAs were predominantly short (10-13 nt). However, the CMV capped RNA leaders that underwent long-distance elongation were found to contain up to five repetitions of additional AC dinucleotides. Sequence analysis revealed that these AC dinucleotides were used to increase the size of short cap donors in multiple prime-and-realign cycles. Each prime-and-realign cycle added an AC dinucleotide onto the capped RNA leaders; thus, the original cap donors were gradually converted to longer capped RNA leaders (of 12-20 nt). Interestingly, the original 10 nt (or 11 nt) cap donor cleaved from CMV RNA1/2 did not undergo direct extension; only capped RNA leaders that had been increased to ≥12 nt were used for direct elongation. These findings suggest that this repetitive priming and realignment may serve to convert short capped CMV RNA leaders into longer, more suitable sizes to render a more stabilized transcription complex for elongation during RSV transcription initiation.

Characterization of the Interaction between hantavirus nucleocapsid protein (N) and ribosomal protein S19 (RPS19)

Hantaviruses, members of the Bunyaviridae family, are negative-stranded emerging RNA viruses and category A pathogens that cause serious illness when transmitted to humans through aerosolized excreta of infected rodent hosts. Hantaviruses have evolved a novel translation initiation mechanism, operated by nucleocapsid protein (N), which preferentially facilitates the translation of viral mRNAs. N binds to the ribosomal protein S19 (RPS19), a structural component of the 40 S ribosomal subunit. In addition, N also binds to both the viral mRNA 5' cap and a highly conserved triplet repeat sequence of the viral mRNA 5' UTR. The simultaneous binding of N at both the terminal cap and the 5' UTR favors ribosome loading on viral transcripts during translation initiation. We characterized the binding between N and RPS19 and demonstrate the role of the N-RPS19 interaction in N-mediated translation initiation mechanism. We show that N specifically binds to RPS19 with high affinity and a binding stoichiometry of 1:1. The N-RPS19 interaction is an enthalpy-driven process. RPS19 undergoes a conformational change after binding to N. Using T7 RNA polymerase, we synthesized the hantavirus S segment mRNA, which matches the transcript generated by the viral RNA-dependent RNA polymerase in cells. We show that the N-RPS19 interaction plays a critical role in the translation of this mRNA both in cells and rabbit reticulocyte lysates. Our results demonstrate that the N-mediated translation initiation mechanism, which lures the host translation machinery for the preferential translation of viral transcripts, primarily depends on the N-RPS19 interaction. We suggest that the N-RPS19 interaction is a novel target to shut down the N-mediated translation strategy and hence virus replication in cells.

Base-pairing promotes leader selection to prime in vitro influenza genome transcription

The requirements for alignment of capped leader sequences along the viral genome during influenza transcription initiation (cap-snatching) have long been an enigma. In this study, competition experiments using an in vitro transcription assay revealed that influenza virus transcriptase prefers leader sequences with base complementarity to the 3'-ultimate residues of the viral template, 10 or 11 nt from the 5' cap. Internal priming at the 3'-penultimate residue, as well as prime-and-realign was observed. The nucleotide identity immediately 5' of the base-pairing residues also affected cap donor usage. Application to the in vitro system of RNA molecules with increased base complementarity to the viral RNA template showed stronger reduction of globin RNA leader initiated influenza transcription compared to those with a single base-pairing possibility. Altogether the results indicated an optimal cap donor consensus sequence of (7m)G-(N)(7-8)-(A/U/G)-(A/U)-AGC-3'.

Preferential use of RNA leader sequences during influenza A transcription initiation in vivo

In vitro transcription initiation studies revealed a preference of influenza A virus for capped RNA leader sequences with base complementarity to the viral RNA template. Here, these results were verified during an influenza infection in MDCK cells. Alfalfa mosaic virus RNA3 leader sequences mutated in their base complementarity to the viral template, or the nucleotides 5' of potential base-pairing residues, were tested for their use either singly or in competition. These analyses revealed that influenza transcriptase is able to use leaders from an exogenous mRNA source with a preference for leaders harboring base complementarity to the 3'-ultimate residues of the viral template, as previously observed during in vitro studies. Internal priming at the 3'-penultimate residue, as well as "prime-and-realign" was observed. The finding that multiple base-pairing promotes cap donor selection in vivo, and the earlier observed competitiveness of such molecules in vitro, offers new possibilities for antiviral drug design.

Hantavirus nucleocapsid protein has distinct m7G cap- and RNA-binding sites

Hantaviruses, members of the Bunyaviridae family, are emerging category A pathogens that carry three negative stranded RNA molecules as their genome. Hantavirus nucleocapsid protein (N) is encoded by the smallest S segment genomic RNA (viral RNA). N specifically binds mRNA caps and requires four nucleotides adjacent to the cap for high affinity binding. We show that the N peptide has distinct cap- and RNA-binding sites that independently interact with mRNA cap and viral genomic RNA, respectively. In addition, N can simultaneously bind with both mRNA cap and vRNA. N undergoes distinct conformational changes after binding with either mRNA cap or vRNA or both mRNA cap and vRNA simultaneously. Hantavirus RNA-dependent RNA polymerase (RdRp) uses a capped RNA primer for transcription initiation. The capped RNA primer is generated from host cell mRNA by the cap-snatching mechanism and is supposed to anneal with the 3' terminus of vRNA template during transcription initiation by single G-C base pairing. We show that the capped RNA primer binds at the cap-binding site and induces a conformational change in N. The conformationally altered N with a capped primer loaded at the cap-binding site specifically binds the conserved 3' nine nucleotides of vRNA and assists the bound primer to anneal at the 3' terminus. We suggest that the cap-binding site of N, in conjunction with RdRp, plays a key role during the transcription and replication initiation of vRNA genome.

Influenza A virus and the cell nucleus

It is over 20 years since the publication of experiments that showed that influenza A virus RNA synthesis takes place in the cell nucleus and that here, the virus subverts the cellular transcription machinery to express and replicate its own single-strand RNA genome. In the years since, our understanding of the organisation of the nucleus has increased enormously, particularly with regards to the functional integration of the RNA polymerase II transcriptosome. This review summarises recent progress in defining the intimate association between the viral and cellular transcriptional machinery.

Functional association between viral and cellular transcription during influenza virus infection

Influenza viruses replicate and transcribe their segmented negative-sense single-stranded RNA genome in the nucleus of the infected host cell. All RNA synthesising activities associated with influenza virus are performed by the virally encoded RNA-dependent RNA polymerase (RdRp) that consists of three subunits, PA, PB1 and PB2. However, viral transcription is critically dependent on on-going cellular transcription, in particular, on activities associated with the cellular DNA-dependent RNA polymerase II (Pol II). Thus, the viral RdRp uses short 5' capped RNA fragments, derived from cellular Pol II transcripts, as primers for viral mRNA synthesis. These capped RNA primers are generated by cleavage of host Pol II transcripts by an endonuclease activity associated with the viral RdRp. Moreover, some viral transcripts require splicing and since influenza virus does not encode splicing machinery, it is dependent on host splicing, an activity also related to Pol II transcription. Despite these functional links between viral and host Pol II transcription, there has been no evidence that a physical association existed between the two transcriptional machineries. However, recently it was reported that there is a physical interaction between the trimeric viral RdRp and cellular Pol II. The viral RdRp was found to interact with the C-terminal domain (CTD) of initiating Pol II, at a stage in the transcription cycle when capping takes place. It was therefore proposed that this interaction may be required for the viral RNA (vRNA) polymerase to gain access to capped RNA substrates for endonucleolytic cleavage. The virus not only relies on cellular factors to support its own RNA synthesis, but also subverts cellular pathways in order to generate an environment optimised for viral multiplication. In this respect, the interaction of the viral NS1 protein with factors involved in cellular pre-mRNA processing is of particular relevance. The virus also alters the distribution of Pol II on cellular genes, leading to a reduction in elongating Pol II thereby contributing to the phenomenon known as host shut-off.

Influenza virus endoribonuclease

The influenza virus polymerase complex contains two associated enzymatic activities, an endoribonuclease and a RNA-dependent RNA polymerase activity. Both activities have so far been observed only with the complete polymerase complex consisting of three subunits, PB1, PB2, and PA. This chapter describes a robust and optimized procedure for the purification of active influenza virus polymerase in complex with genomic RNA and the single-stranded RNA-binding protein nucleoprotein from influenza virus particles. It also explains the synthesis of capped RNA molecules as substrates of the influenza virus endonuclease. The enzymatic properties of influenza virus-derived endoribonuclease activity have been characterized with a model RNA substrate of 20-nucleotide length, termed G20 RNA. The rate of RNA cleavage under steady state conditions appears to be limited by product dissociation. Therefore conditions have been optimized to study the chemical step of RNA cleavage under single turnover conditions. The enzyme requires divalent metal ions for activity and can use Mn(II), Co(II), and Fe(II) efficiently at pH 7, Mg(II) with intermediate efficiency, and Ni(II) and Zn(II) with lower efficiency. The reaction progress curves show slow binding of Zn(II) and Ni(II) to the protein, suggesting a conformational change of the active site as a prerequisite for endonuclease activity in the presence of these two metal ions. Low concentrations of the detergent DOC inhibit the activity and also disrupt the trimeric polymerase complex, whereas other detergents do not have a significant effect on the activity.

In vivo analysis of the TSWV cap-snatching mechanism: single base complementarity and primer length requirements

Requirements for capped leader sequences for use during transcription initiation by tomato spotted wilt virus (TSWV) were tested using mutant alfalfa mosaic virus (AMV) RNAs as specific cap donors in transgenic Nicotiana tabacum plants expressing the AMV replicase proteins. Using a series of AMV RNA3 mutants modified in either the 5'-non-translated region or in the subgenomic RNA4 leader, sequence analysis revealed that cleaved leader lengths could vary between 13 and 18 nucleotides. Cleavage occurred preferentially at an A residue, suggesting a requirement for a single base complementarity with the TSWV RNA template, which could be confirmed by analyses of host mRNAs used in vivo as cap donors.

Mutagenic analysis of the 5' arm of the influenza A virus virion RNA promoter defines the sequence requirements for endonuclease activity

Short synthetic influenza virus-like RNAs derived from influenza virus promoter sequences were examined for their ability to stimulate the endonuclease activity of recombinant influenza virus polymerase complexes in vitro, an activity that is required for the cap-snatching activity of primers from host pre-mRNA. An extensive set of point mutants of the 5' arm of the influenza A virus viral RNA (vRNA) was constructed to determine the cis-acting elements which influenced endonuclease activity. Activity was found to be dependent on three features of the conserved vRNA termini: (i) the presence of the 5' hairpin loop structure, (ii) the identity of residues at positions 5 and 10 bases from the 5' terminus, and (iii) the presence of base pair interactions between the 5' and 3' segment ends. Further experiments discounted a role for the vRNA U track in endonuclease activation. This study represents the first mutagenic analysis of the influenza virus promoter with regard to endonuclease activity.

RNA and DNA hydrolysis are catalyzed by the influenza virus endonuclease

The influenza virus polymerase complex contains a metal ion-dependent endonuclease activity, which generates short capped RNA primer molecules from capped RNA precursors. Previous studies have provided evidence for a two-metal ion mechanism of RNA cleavage, and the data are consistent with a direct interaction of a divalent metal ion with the catalytic water molecule. To refine the model of this active site, we have generated a series of DNA, RNA, and DNA-RNA chimeric molecules to study the role of the 2'-hydroxy groups on nucleic acid substrates of the endonuclease. We could observe specific cleavage of nucleic acid substrates devoid of any 2'-hydroxy groups if they contained a cap structure (m7GpppG) at the 5'-end. The capped DNA endonuclease products were functional as primers for transcription initiation by the influenza virus polymerase. The apparent cleavage rates were about 5 times lower with capped DNA substrates as compared with capped RNA substrates. Cleavage rates with DNA substrates could be increased to RNA levels by substituting the deoxyribosyl moieties immediately 5' and 3' of the cleavage site with ribosyl moieties. Similarly, cleavage rates of RNA substrates could be lowered to DNA levels by exchanging the same two ribosyl groups with deoxyribosyl groups at the cleavage site. These results demonstrate that the 2'-hydroxy groups are not essential for binding and cleavage of nucleic acids by the influenza virus endonuclease, but small differences of the nucleic acid conformation in the endonuclease active site can influence the overall rate of hydrolysis. The observed relative cleavage rates with DNA and RNA substrates argue against a direct interaction of a catalytic metal ion with a 2'-hydroxy group in the endonuclease active site.

An endonuclease switching mechanism in the virion RNA and cRNA promoters of Thogoto orthomyxovirus

An in vitro assay was developed to investigate endonuclease activity of Thogoto virus, a tick-borne orthomyxovirus. Endonuclease activity relied on an interaction between the 3' and 5' termini of virion RNA (vRNA) and not those of cRNA. Evidence was obtained that cap structures are cleaved directly from cap donors and that cleavage does not occur after pyrimidines. A 5' hook structure, present in the vRNA promoter but not the cRNA promoter, was introduced into cRNA promoter mutants. These mutants stimulated endonuclease activity, although at levels slightly lower than that of vRNA. The ability of the cRNA promoter to stimulate endonuclease activity when mutated to contain a 5' hook structure indicates that this structure constitutes a switching mechanism for endonuclease activity between the vRNA and cRNA promoters.

The 5' ends of Thogoto virus (Orthomyxoviridae) mRNAs are homogeneous in both length and sequence

Thogoto (THO) virus is a tick-borne member of the Orthomyxoviridae whose genome consists of six segments of linear, negative sense, single-stranded RNA. To gain insight into the mechanism by which viral mRNA transcripts are initiated, poly(A)+ RNA isolated from THO virus-infected cells was characterized by (i) primer extension experiments, (ii) immunoprecipitation studies with an anticap monoclonal antibody, (iii) direct sequencing analysis of the isolated RNA, and (iv) cloning and sequencing of individual mRNA molecules. The results indicated that THO virus mRNAs are capped and homogeneous in both length and sequence at their 5' end. These findings contrast with the situation found in all other segmented, negative sense or ambisense, single-stranded RNA viruses so far analyzed in which the 5' ends of viral mRNAs are heterogeneous in length and sequence. These results are discussed in terms of the mechanism used by THO virus to initiate mRNA synthesis.

Nucleoprotein viral RNA and mRNA of Thogoto virus: a novel "cap-stealing" mechanism in tick-borne orthomyxoviruses?

Tick-borne Thogoto virus (THOV) represents the prototype virus of a new genus in the Orthomyxoviridae family. Its genome consists of six segments of negative-sense, single-stranded RNA. We have cloned and sequenced the fifth genomic segment, which codes for the viral nucleoprotein (NP). The deduced amino acid sequence shows 43% similarity to the NP of Dhori virus, a related tick-transmitted orthomyxovirus, and about 14% sequence similarity to those of the influenza viruses. To reveal the mechanism by which THOV initiates mRNA synthesis, we characterized the 5' ends of the NP mRNAs. Transcripts were recognized by a cap-specific monoclonal antibody, indicating that THOV mRNAs are capped. Surprisingly, no large heterogeneous extensions were found at the 5' end, as would have been expected if THOV were using a classical "cap-stealing" mechanism. We therefore propose that THOV is stealing only the cap structure with one or two additional nucleotides from cellular mRNAs to generate appropriate primers for initiation of viral mRNA transcription.

Characterization of the RNA-fork model of virion RNA in the initiation of transcription in influenza A virus

It has been shown that both 3' and 5' conserved termini of influenza A virus virion RNA are involved in the initiation of transcription. An RNA-fork model has been proposed, according to which there is a crucial double-stranded region formed by complementary bases at positions 10 to 12 of the 3' terminus and bases at positions 11' to 13' of the 5' terminus, which are extended by 2 or 3 segment-specific base pairs. The two termini at positions 1 to 9 and 1' to 10' in the 3' and 5' termini, respectively, are in a single-stranded conformation. Here we further characterize this model, focusing on the individual roles of the proposed duplex region and the proposed two single-stranded ends. Residues within the conserved 5' terminus that are involved in the initiation of transcription were determined. Single, double, and triple mutations in the proposed duplex region provided further evidence that, for the initiation of transcription in vitro, the duplex RNA is more important than the actual sequence of these residues, although some restrictions in sequence were apparent. On the other hand, there was evidence that base pairing is not required at residues 1 to 7. We propose that the 5' terminus of virion RNA should be treated as an integral part of the virion RNA promoter and discuss a possible mechanism for the recognition of the virion RNA promoter by the influenza A virus RNA polymerase complex.

The influenza virus panhandle is involved in the initiation of transcription

The role of the influenza A virus panhandle structure formed from the 3'- and 5'-terminal nucleotides of virion RNA segments was studied in both an RNA polymerase binding assay and an in vitro transcription assay. Despite recent indications that promoter activity is simply a function of the 3'-terminal sequence of virion RNA, our results show that both 3'- and 5'-terminal sequences are involved in the initiation of transcription. We propose a new model for the initiation of transcription which has implications for the mechanisms by which influenza virus transcription, replication, and polyadenylation may be regulated in the infected cell.

Recombinant influenza virus polymerase: requirement of both 5' and 3' viral ends for endonuclease activity

Influenza virus polymerase complexes that were expressed in the absence of genomic viral RNA and nucleoprotein were examined for endonuclease activity and transcriptase ability in vitro. Nuclear extracts of cells that express influenza virus polymerase through recombinant vaccinia virus infection did not display specific endonuclease activity in vitro. This polymerase presumably represents an early form of enzyme present in infected cells prior to ribonucleoprotein assembly. Upon addition of a virus-like model RNA template, containing the partially complementary sequence found at the ends of viral RNA, endonuclease activity is stimulated in a concentration-dependent and sequence-specific manner. Once stimulated, the polymerase is able to elongate from the added viral template. Thus, addition of viral template is required for polymerase activity, while the presence of nucleoprotein is not required for limited transcription. Also, full activation of this recombinant viral polymerase is dependent on the presence of both the 3' and 5' ends of the viral genome, as model RNA containing either end alone could not effectively trigger the endonuclease.

Viral RNA polymerases

Recent progress in molecular biological techniques revealed that genomes of animal viruses are complex in structure, for example, with respect to the chemical nature (DNA or RNA), strandedness (double or single), genetic sense (positive or negative), circularity (circle or linear), and so on. In agreement with this complexity in the genome structure, the modes of transcription and replication are various among virus families. The purpose of this article is to review and bring up to date the literature on viral RNA polymerases involved in transcription of animal DNA viruses and in both transcription and replication of RNA viruses. This review shows that the viral RNA polymerases are complex in both structure and function, being composed of multiple subunits and carrying multiple functions. The functions exposed seem to be controlled through structural interconversion.

Direct characterization of influenza viral NS1 mRNA and related sequences from infected HeLa cells and a cell-free transcription system

The NS1 mRNA of the influenza A virus WSN (H0N1) strain was isolated from a cell-free transcription system, and from the cytoplasm of virus-infected HeLa cells. The 32P-labeled NS1 mRNA derived from the infected cell cytoplasm was characterized by the secondary enzymatic analysis of sixteen of its large or distinct RNAase T1-resistant oligonucleotides. Several WSN strain-specific nucleotide differences from the previously-determined sequence of NS1 mRNA from the PR8 (H0N1) strain of influenza A virus, were located within these sequences. The RNAase T1-resistant oligonucleotides were placed within the primary sequence of NS1 mRNA, using the PR8 strain sequence data. The resulting linear map was then used to identify NS2 mRNA isolated from the infected cell cytoplasm, and an NS-related RNA species generated from NS1 mRNA incubated in a HeLa cell-free extract.

Messenger RNA of the M segment RNA of Rift Valley fever virus

The putative messenger RNA (mRNA) of the M segment RNA of the phlebovirus Rift Valley fever virus (RVFV) has been characterized using S1 nuclease mapping and oligonucleotide primer extension procedures. These experiments revealed that the 3' end of the mRNA lacks approximately 112 nucleotides of the M genomic RNA sequences, and that the 5' end of the mRNA possesses all of the sequences present at the 3' end of the M RNA but is further extended beyond the end of the genome by some 12-14 nucleotides of unknown origin. The implications of these data are discussed in relation to the replication and expression strategy of this virus.

A specific sub-set of host-cell mRNAs prime influenza virus mRNA synthesis

The host-cell derived RNA primer sequences at the 5' termini of mRNAs of influenza A and B viruses, obtained from sequences of 29 cDNA clones, have been compared. This has been done for clones of five different genome segments from four strains of influenza A and B virus. The results indicate that host RNA primers containing a 3'-terminal Py-G-C-A sequence before the presumed endonuclease cleavage site are preferred for use as primers in influenza virus mRNA synthesis. Primer-extension analyses of the 5'-terminal heterogeneous sequences of in vivo synthesized mRNAs confirm the preference for G-C-A-terminated primer fragments, with some differences noted between the transcripts of types A and B influenza virus genome segments.

Combined action of mouse alpha and beta interferons in influenza virus-infected macrophages carrying the resistance gene Mx

In mice, the combined action of alpha and beta interferons (IFNs) against influenza viruses is modulated by the host gene Mx. High concentrations of IFN fail to prevent efficiently the replication of influenza A virus in cultured macrophages lacking the gene Mx, whereas cultured macrophages carrying Mx develop strong antiviral activity even at low concentrations of IFN. Several steps in the replication cycle of influenza virus were compared in Mx/Mx and +/+ mouse macrophages treated with IFN-alpha + beta. Uncoating was not affected. A twofold reduction in the accumulation of primary transcripts was observed in IFN-treated macrophages at the highest concentration of IFN regardless of the genetic constitution of the host cell. No evidence was obtained for inhibition of influenza virus translation in macrophages which lacked Mx when treated with IFN-alpha + beta. In contrast, a marked shut-off of influenza virus polypeptide synthesis occurred in Mx-bearing macrophages treated with these IFNs, although the primary transcripts were active in directing the synthesis of viral polypeptides in a cell-free system. We concluded that a specific inhibitory mechanism for influenza virus translation was induced by IFN-alpha + beta in macrophages bearing the resistance gene Mx.

Identification of the influenza virus transcriptase by affinity-labeling with pyridoxal 5'-phosphate

Pyridoxal 5'-phosphate (PLP), a reversible inhibitor of in vitro transcription by fowl plaque virus, has been used to identify the transcriptase. Kinetic analyses showed that PLP competitively inhibits the addition of each nucleoside triphosphate in ApG-primed reactions, suggesting that both initiation and elongation are affected. The irreversible inhibition by PLP following reduction with borohydride was prevented by preincubation with the first substrate: GTP in unprimed reactions or CTP in the presence of ApG. On reaction of FPV proteins with PLP and [3H]borohydride the core protein PB1 was preferentially labeled and the labeling was selectively blocked by GTP or ApG + CTP. These data suggest that PB1 has the nucleotide-binding site of the transcriptase, is responsible for both initiation and elongation, and is apparently associated with the 3' ends of template RNAs in virions.

Nonviral heterogeneous sequences are present at the 5' ends of one species of snowshoe hare bunyavirus S complementary RNA

Analyses of the 5' ends of snowshoe hare bunyavirus plus sense S RNA species (including mRNA) recovered from infected cells have revealed two types of termini. These include ends that are essentially exact copies of the 3' end of the viral S RNA and others that are similar, but additionally have 13-14 nucleotide extensions that are heterogeneous in sequence. The former probably represent replicative plus sense RNA species, the latter mRNA species that have host cell derived primer sequences.

RNA polymerase of influenza virus. IV. Catalytic properties of the capped RNA endonuclease associated with the RNA polymerase

Catalytic properties of the capped RNA-specific endonuclease associated with the influenza virus RNA polymerase were analyzed with use of synthetic hetero- and homopolymers containing 32P-labeled CAP structures at their 5' termini. The endonuclease displays its intrinsic activity provided that substrate RNA contains both the CAP-1 structure (m7GpppGm) and either A or U residues at 9 to 11 nucleotides distant from the CAP structure. Independent recognition of multiple RNA signals by the endonuclease was further supported by the findings that dinucleotide ApG, free CAP structures and RNA without the CAP structure inhibited the endonuclease activity to different extents. In the presence of four species of ribonucleoside 5'-triphosphates, the endonucleolytically cleaved fragments with the CAP-1 structure were incorporated into polynucleotides, supporting the concept that they are used as the primers for the transcription. The initial nucleotide linked to the primers was a G residue, the nucleotide complementary to the second base of the 3' termini of the vRNA segments.

The sequence of RNA segment 1 of influenza virus A/NT/60/68 and its comparison with the corresponding segment of strains A/PR/8/34 and A/WSN/33

The complete nucleotide sequence of RNA segment 1 of influenza virus A/NT/60/68, corresponding to the PB2 protein, has been determined. It is 2341 nucleotides long, encoding a predicted product of 759 amino acids with a net charge of +27 1/2 at neutral pH. The predicted amino acid sequence has been compared to the equivalent sequences in influenza viruses A/PR/8/34 and A/WSN/33. Evolutionary divergence, assuming a direct lineage from A/PR/8/34 and allowing for "laboratory drift", is 0.08% per year. The alignment of RNA segment 10 of A/NT/60/68 with segments 1 and 3 is completed, confirming that it is a mosaic of regions from these two segments.

Sequence analysis of the polymerase 1 gene and the secondary structure prediction of polymerase 1 protein of human influenza virus A/WSN/33

The nucleotide sequence of polymerase 1 (P1) gene of a human influenza virus (A/WSN/33) has been determined by using cDNA clones, except for the last 83 nucleotides, which were obtained by primer extension. The WSN P1 gene contains 2,341 nucleotides and codes for a protein of 757 amino acids (Mr = 86,500). P1 gene possesses a striking tandem repeat of 12 nucleotides (nucleotide position 2,188 to 2,199, 2,200 to 2,211) and a corresponding tandem repeat of tetrapeptide in the P1 protein. The deduced sequence of P1 protein is enriched in basic amino acids, particularly arginine. In addition, it also contains clusters of basic amino acids which may provide sites for the interaction with the template virion RNA capped primer as well as with other proteins involved in viral replication and transcription. A secondary structure prediction, using Chou and Fasman analyses (Annu. Rev. Biochem. 47:251-276, 1978), shows that the P1 protein possesses some unique features, viz., one "four-helical supersecondary structure" and four "polypeptide double helices" (antiparallel beta-pleated sheets) which are considered important in RNA binding.

Influenza B virus genome: sequences and structural organization of RNA segment 8 and the mRNAs coding for the NS1 and NS2 proteins

Double-stranded DNA derived from influenza B virus genome RNA segment 8, which codes for the NS1 and NS2 proteins, was constructed by hybridization of full-length cDNA copies of RNA segment 8 and of the NS1 mRNA. This DNA was cloned in plasmid pBR322 and sequenced. The NS1 mRNA (approximately 1,080 viral nucleotides) contains nonviral nucleotides at its 5' end and is capable of coding for a protein of 281 amino acids. Sequencing of the NS2 mRNA has shown that it contains an interrupted sequence of 655 nucleotides and is most likely synthesized by a splicing mechanism. The first approximately 75 virus-specific nucleotides at the 5' end of the NS2 mRNA are the same as are found at the 5' -end of the NS1 mRNA. This region contains the initiation codon for protein synthesis and coding information for 10 amino acids common to the two proteins. The approximately 350-nucleotide body region of the NS2 mRNA can be translated in the +1 reading frame, and the sequence indicates that the NS1 and NS2 protein-coding regions overlap by 52 amino acids translated from different reading frames. Thus, between the influenza A and B viruses, the organization of the NS1 and NS2 mRNAs and the sizes of the NS2 mRNA and protein are conserved despite the larger size of the influenza B virus RNA segment, NS1 mRNA, and NS1 protein.