Definition of a high-affinity Gag recognition structure mediating packaging of a retroviral RNA genome

All retroviral genomic RNAs contain a cis-acting packaging signal by which dimeric genomes are selectively packaged into nascent virions. However, it is not understood how Gag (the viral structural protein) interacts with these signals to package the genome with high selectivity. We probed the structure of murine leukemia virus RNA inside virus particles using SHAPE, a high-throughput RNA structure analysis technology. These experiments showed that NC (the nucleic acid binding domain derived from Gag) binds within the virus to the sequence UCUG-UR-UCUG. Recombinant Gag and NC proteins bound to this same RNA sequence in dimeric RNA in vitro; in all cases, interactions were strongest with the first U and final G in each UCUG element. The RNA structural context is critical: High-affinity binding requires base-paired regions flanking this motif, and two UCUG-UR-UCUG motifs are specifically exposed in the viral RNA dimer. Mutating the guanosine residues in these two motifs--only four nucleotides per genomic RNA--reduced packaging 100-fold, comparable to the level of nonspecific packaging. These results thus explain the selective packaging of dimeric RNA. This paradigm has implications for RNA recognition in general, illustrating how local context and RNA structure can create information-rich recognition signals from simple single-stranded sequence elements in large RNAs.     

Mechanism of tripartite RNA genome packaging in Rift Valley fever virus

The Bunyaviridae family includes pathogens of medical and veterinary importance. Rift Valley fever virus (RVFV), a member in the Phlebovirus genus of the family Bunyaviridae, is endemic to sub-Saharan Africa and causes a mosquito-borne disease in ruminants and humans. Viruses in the family Bunyaviridae carry a tripartite, single-stranded, negative-sense RNA genome composed of L, M, and S RNAs. Little is known about how the three genomic RNA segments are copackaged to generate infectious bunyaviruses. We explored the mechanism that governs the copackaging of the three genomic RNAs into RVFV particles. The expression of viral structural proteins along with replicating S and M RNAs resulted in the copackaging of both RNAs into RVFV-like particles, while replacing M RNA with M1 RNA, lacking a part of the M RNA 5' UTR, abrogated the RNA copackaging. L RNA was efficiently packaged into virus particles released from cells supporting the replication of L, M, and S RNAs, and replacing M RNA with M1 RNA abolished the packaging of L RNA. Detailed analyses using various combinations of replicating viral RNAs suggest that M RNA alone or a coordinated function of M and S RNAs exerted efficient L RNA packaging either directly or indirectly. Collectively, these data are consistent with the possibility that specific intermolecular interactions among the three viral RNAs drive the copackaging of these RNAs to produce infectious RVFV.     

Human Retrovirus Genomic RNA Packaging

Two non-covalently linked copies of the retrovirus genome are specifically recruited to the site of virus particle assembly and packaged into released particles. Retroviral RNA packaging requires RNA export of the unspliced genomic RNA from the nucleus, translocation of the genome to virus assembly sites, and specific interaction with Gag, the main viral structural protein. While some aspects of the RNA packaging process are understood, many others remain poorly understood. In this review, we provide an update on recent advancements in understanding the mechanism of RNA packaging for retroviruses that cause disease in humans, i.e., HIV-1, HIV-2, and HTLV-1, as well as advances in the understanding of the details of genomic RNA nuclear export, genome translocation to virus assembly sites, and genomic RNA dimerization.     

Functional RNA elements in the dengue virus genome

Dengue virus (DENV) genome amplification is a process that involves the viral RNA, cellular and viral proteins, and a complex architecture of cellular membranes. The viral RNA is not a passive template during this process; it plays an active role providing RNA signals that act as promoters, enhancers and/or silencers of the replication process. RNA elements that modulate RNA replication were found at the 5' and 3' UTRs and within the viral coding sequence. The promoter for DENV RNA synthesis is a large stem loop structure located at the 5' end of the genome. This structure specifically interacts with the viral polymerase NS5 and promotes RNA synthesis at the 3' end of a circularized genome. The circular conformation of the viral genome is mediated by long range RNA-RNA interactions that span thousands of nucleotides. Recent studies have provided new information about the requirement of alternative, mutually exclusive, structures in the viral RNA, highlighting the idea that the viral genome is flexible and exists in different conformations. In this article, we describe elements in the promoter SLA and other RNA signals involved in NS5 polymerase binding and activity, and provide new ideas of how dynamic secondary and tertiary structures of the viral RNA participate in the viral life cycle.     

Rewiring the RNAs of influenza virus to prevent reassortment

Influenza viruses contain segmented, negative-strand RNA genomes. Genome segmentation facilitates reassortment between different influenza virus strains infecting the same cell. This phenomenon results in the rapid exchange of RNA segments. In this study, we have developed a method to prevent the free reassortment of influenza A virus RNAs by rewiring their packaging signals. Specific packaging signals for individual influenza virus RNA segments are located in the 5′ and 3′ noncoding regions as well as in the terminal regions of the ORF of an RNA segment. By putting the nonstructural protein (NS)-specific packaging sequences onto the ORF of the hemagglutinin (HA) gene and mutating the packaging regions in the ORF of the HA, we created a chimeric HA segment with the packaging identity of an NS gene. By the same strategy, we made an NS gene with the packaging identity of an HA segment. This rewired virus had the packaging signals for all eight influenza virus RNAs, but it lost the ability to independently reassort its HA or NS gene. A similar approach can be applied to the other influenza A virus segments to diminish their ability to form reassortant viruses.     

Translation of Pr55(gag) augments packaging of human immunodeficiency virus type 1 RNA in a cis-acting manner

The full-length RNA of human immunodeficiency virus type 1 (HIV-1) serves both as a messenger (mRNA) to direct the translation of Pr55(gag) proteins and as genomic or viral particle RNA (vpRNA) to be packaged into virions. In this study, we have assessed a putative cis-acting effect of Pr55(gag) translation on HIV-1 RNA packaging. To pursue this subject, we have measured the relative competence of two distinct types of HIV-1 RNA for being packaged by virus particles under conditions in which only one of them is permissive for production of Pr55(gag). Not surprisingly, wild-type BH10 RNA was packaged at far higher efficiency than that associated with mutant viral RNA that was deleted of RNA packaging signals and incapable of Pr55(gag) production. However, when production of Pr55(gag) was eliminated from the wild-type BH10 viral RNA by insertion of stop codons either in matrix (MA) or in capsid (CA) sequences, regardless of retention of wild-type RNA packaging signals, these Pr55(gag)-deficient viral RNAs were packaged at low levels similar to those observed with viral RNA species that lack RNA packaging signals and are capable of Pr55(gag) generation. Moreover, loss of Pr55(gag) production did not affect stability of the relevant viral RNA; this observation rules out the possibility that lowered packaging efficiency associated with Pr55(gag)-deficient HIV-1 RNA is a result of reduced RNA stability. Taken together, our data demonstrate that cis translation of Pr55(gag) is needed for efficient packaging of HIV-1 RNA.     

The Role of the Stem-Loop A RNA Promoter in Flavivirus Replication

An essential challenge in the lifecycle of RNA viruses is identifying and replicating the viral genome amongst all the RNAs present in the host cell cytoplasm. Yet, how the viral polymerase selectively recognizes and copies the viral RNA genome is poorly understood. In flaviviruses, the 5′-end of the viral RNA genome contains a 70 nucleotide-long stem-loop, called stem-loop A (SLA), which functions as a promoter for genome replication. During replication, flaviviral polymerase NS5 specifically recognizes SLA to both initiate viral RNA synthesis and to methylate the 5′ guanine cap of the nascent RNA. While the sequences of this region vary between different flaviviruses, the three-way junction arrangement of secondary structures is conserved in SLA, suggesting that viruses recognize a common structural feature to replicate the viral genome rather than a particular sequence. To better understand the molecular basis of genome recognition by flaviviruses, we recently determined the crystal structures of flavivirus SLAs from dengue virus (DENV) and Zika virus (ZIKV). In this review, I will provide an overview of (1) flaviviral genome replication; (2) structures of viral SLA promoters and NS5 polymerases; and (3) and describe our current model of how NS5 polymerases specifically recognize the SLA at the 5′ terminus of the viral genome to initiate RNA synthesis at the 3′ terminus.     

HIV-1 RNA genome dimerizes on the plasma membrane in the presence of Gag protein

Retroviruses package a dimeric genome comprising two copies of the viral RNA. Each RNA contains all of the genetic information for viral replication. Packaging a dimeric genome allows the recovery of genetic information from damaged RNA genomes during DNA synthesis and promotes frequent recombination to increase diversity in the viral population. Therefore, the strategy of packaging dimeric RNA affects viral replication and viral evolution. Although its biological importance is appreciated, very little is known about the genome dimerization process. HIV-1 RNA genomes dimerize before packaging into virions, and RNA interacts with the viral structural protein Gag in the cytoplasm. Thus, it is often hypothesized that RNAs dimerize in the cytoplasm and the RNA–Gag complex is transported to the plasma membrane for virus assembly. In this report, we tagged HIV-1 RNAs with fluorescent proteins, via interactions of RNA-binding proteins and motifs in the RNA genomes, and studied their behavior at the plasma membrane by using total internal reflection fluorescence microscopy. We showed that HIV-1 RNAs dimerize not in the cytoplasm but on the plasma membrane. Dynamic interactions occur among HIV-1 RNAs, and stabilization of the RNA dimer requires Gag protein. Dimerization often occurs at an early stage of the virus assembly process. Furthermore, the dimerization process is probably mediated by the interactions of two RNA–Gag complexes, rather than two RNAs. These findings advance the current understanding of HIV-1 assembly and reveal important insights into viral replication mechanisms.All viruses must encapsidate their genomes into virions to ensure that their genetic information is transferred to the new target cells. In most, if not all, retroviruses, the virion RNA genomes are dimeric, although each RNA encodes all of the genetic information required for replication. Most HIV-1 particles contain two copies of genomes (1), indicating that RNA encapsidation is a highly regulated process. This regulation is achieved by recognizing a dimeric RNA, and not by packaging a certain mass of viral genome (2).Our previous studies showed that HIV-1 RNA dimerization is a critical step in viral RNA genome packaging and virus assembly and that the two copies of copackaged RNA genomes are dimerized before encapsidation (1, 3, 4). The dimerization initiation signal (DIS), a 6-nt palindromic sequence located at the 5′ UTR of the HIV-1 RNA genome (5), most likely initiates the interaction between two HIV-1 RNA genomes (3, 4). When two HIV-1 RNAs contain similar sequences including the same DIS, they are copackaged efficiently at a rate similar to that predicted from random distribution (1, 2). In contrast, when two HIV-1 RNAs contain discordant palindromic sequences that cannot form perfect base pairing, they are not copackaged efficiently into the same viral particle (1, 2). The ability of RNA genomes from different HIV-1 variants to dimerize has important biological consequences. For example, inefficient copackaging is known to be a major barrier for intersubtype HIV-1 recombination (4). Although DIS plays a key role in RNA dimerization, virion RNAs isolated from mutants with DIS deletions remained dimeric, suggesting that other cis-acting element(s) are also involved in the dimerization (6).Despite the importance of RNA dimerization for HIV-1 replication, many aspects of this process are unknown, including the location at which dimerization occurs. Previously, we showed that RNA dimerization leading to HIV-1 genome packaging occurs after viral RNA is exported from the nucleus (7). The viral protein Gag is known to have chaperone activity (8). Additionally, biochemical experiments showed that HIV-1 Gag can interact with viral RNAs in the cytoplasm (9, 10). Thus, it is often hypothesized that two copies of HIV-1 RNAs dimerize in the cytoplasm and that this dimeric RNA is complexed with Gag and travels to the plasma membrane (7, 11–15), the major assembly site for virus assembly. The assembly of HIV-1 RNA and Gag was demonstrated in an elegant study using total internal reflection fluorescence (TIRF) microscopy (14), which illuminates a shallow volume near the glass/cell interface and is ideal for studying events near the plasma membrane (16). However, it was difficult to address the monomeric/dimeric state of the viral RNA in this previous study because the RNA was labeled with a single type of fluorescent protein.In the present study, we sought to delineate the location at which HIV-1 RNA dimerization occurs, which leads to genome encapsidation, and whether Gag is required for RNA dimerization. We used a previously described method to label HIV-1 RNA with fluorescent proteins through interactions of sequence-specific RNA-binding proteins. We engineered HIV-1 genomes to contain RNA stem-loops that are recognized by the Escherichia coli BglG protein or the bacteriophage MS2 coat protein; because these sequences are located in the pol gene, they are present only in full-length unspliced HIV-1 RNAs. When introduced into human cells, these constructs express full-length RNAs that can serve as templates for the translation of Gag proteins and as genomes in the viral particles. Most (>90%) of the particles contain RNA genomes, indicating that the full-length viral RNAs derived from these constructs are efficiently packaged. Furthermore, RNAs derived from different constructs can dimerize and copackage at a rate close to random distribution (1), consistent with the genetic analyses from recombination studies (4, 17, 18). By using this method, we were able to detect HIV-1 RNA with single-RNA-molecule sensitivity (1) and tracked HIV-1 RNA movement in the cytoplasm by using live-cell imaging (19). In this report, we tagged two HIV-1 RNAs and Gag, each with a different fluorescent protein, and studied the RNA:RNA and RNA:Gag interactions on the plasma membrane. We found that HIV-1 RNA dimerizes on the plasma membrane and that Gag protein is required for stabilization of the dimer.     

Imaging the interaction of HIV-1 genomes and Gag during assembly of individual viral particles

The incorporation of viral genomes into particles has never previously been imaged in live infected cells. Thus, for many viruses it is unknown how the recruitment and packaging of genomes into virions is temporally and spatially related to particle assembly. Here, we devised approaches to simultaneously image HIV-1 genomes, as well as the major HIV-1 structural protein, Gag, to reveal their dynamics and functional interactions during the assembly of individual viral particles. In the absence of Gag, HIV-1 RNA was highly dynamic, moving in and out of the proximity of the plasma membrane. Conversely, in the presence of Gag, RNA molecules docked at the membrane where their lateral movement slowed and then ceased as Gag assembled around them and they became irreversibly anchored. Viral genomes were not retained at the membrane when their packaging signals were mutated, nor when expressed with a Gag mutant that was not myristoylated. In the presence of a Gag mutant that retained membrane- and RNA-binding activities but could not assemble into particles, the viral RNA docked at the membrane but continued to drift laterally and then often dissociated from the membrane. These results, which provide visualization of the recruitment and packaging of genomes into individual virus particles, demonstrate that a small number of Gag molecules recruit viral genomes to the plasma membrane where they nucleate the assembly of complete virions.     

Conserved Structural Motifs of Two Distant IAV Subtypes in Genomic Segment 5 RNA

The functionality of RNA is fully dependent on its structure. For the influenza A virus (IAV), there are confirmed structural motifs mediating processes which are important for the viral replication cycle, including genome assembly and viral packaging. Although the RNA of strains originating from distant IAV subtypes might fold differently, some structural motifs are conserved, and thus, are functionally important. Nowadays, NGS-based structure modeling is a source of new in vivo data helping to understand RNA biology. However, for accurate modeling of in vivo RNA structures, these high-throughput methods should be supported with other analyses facilitating data interpretation. In vitro RNA structural models complement such approaches and offer RNA structures based on experimental data obtained in a simplified environment, which are needed for proper optimization and analysis. Herein, we present the secondary structure of the influenza A virus segment 5 vRNA of A/California/04/2009 (H1N1) strain, based on experimental data from DMS chemical mapping and SHAPE using NMIA, supported by base-pairing probability calculations and bioinformatic analyses. A comparison of the available vRNA5 structures among distant IAV strains revealed that a number of motifs present in the A/California/04/2009 (H1N1) vRNA5 model are highly conserved despite sequence differences, located within previously identified packaging signals, and the formation of which in in virio conditions has been confirmed. These results support functional roles of the RNA secondary structure motifs, which may serve as candidates for universal RNA-targeting inhibitory methods.     

Evidence that viral RNAs have evolved for efficient, two-stage packaging

Genome packaging is an essential step in virus replication and a potential drug target. Single-stranded RNA viruses have been thought to encapsidate their genomes by gradual co-assembly with capsid subunits. In contrast, using a single molecule fluorescence assay to monitor RNA conformation and virus assembly in real time, with two viruses from differing structural families, we have discovered that packaging is a two-stage process. Initially, the genomic RNAs undergo rapid and dramatic (approximately 20–30%) collapse of their solution conformations upon addition of cognate coat proteins. The collapse occurs with a substoichiometric ratio of coat protein subunits and is followed by a gradual increase in particle size, consistent with the recruitment of additional subunits to complete a growing capsid. Equivalently sized nonviral RNAs, including high copy potential in vivo competitor mRNAs, do not collapse. They do support particle assembly, however, but yield many aberrant structures in contrast to viral RNAs that make only capsids of the correct size. The collapse is specific to viral RNA fragments, implying that it depends on a series of specific RNA–protein interactions. For bacteriophage MS2, we have shown that collapse is driven by subsequent protein–protein interactions, consistent with the RNA–protein contacts occurring in defined spatial locations. Conformational collapse appears to be a distinct feature of viral RNA that has evolved to facilitate assembly. Aspects of this process mimic those seen in ribosome assembly.     

RNAi-mediated immunity provides strong protection against the negative-strand RNA vesicular stomatitis virus in Drosophila

Activation of innate antiviral responses in multicellular organisms relies on the recognition of structural differences between viral and cellular RNAs. Double-stranded (ds)RNA, produced during viral replication, is a well-known activator of antiviral defenses and triggers interferon production in vertebrates and RNAi in invertebrates and plants. Previous work in mammalian cells indicates that negative-strand RNA viruses do not appear to generate dsRNA, and that activation of innate immunity is triggered by the recognition of the uncapped 5' ends of viral RNA. This finding raises the question whether antiviral RNAi, which is triggered by the presence of dsRNA in insects, represents an effective host-defense mechanism against negative-strand RNA viruses. Here, we show that the negative-strand RNA virus vesicular stomatitis virus (VSV) does not produce easily detectable amounts of dsRNA in Drosophila cells. Nevertheless, RNAi represents a potent response to VSV infection, as illustrated by the high susceptibility of RNAi-defective mutant flies to this virus. VSV-derived small RNAs produced in infected cells or flies uniformly cover the viral genome, and equally map the genome and antigenome RNAs, indicating that they derive from dsRNA. Our findings reveal that RNAi is not restricted to the defense against positive-strand or dsRNA viruses but can also be highly efficient against a negative-strand RNA virus. This result is of particular interest in view of the frequent transmission of medically relevant negative-strand RNA viruses to humans by insect vectors.     

New Structure Sheds Light on Selective HIV-1 Genomic RNA Packaging

Two copies of unspliced human immunodeficiency virus (HIV)-1 genomic RNA (gRNA) are preferentially selected for packaging by the group-specific antigen (Gag) polyprotein into progeny virions as a dimer during the late stages of the viral lifecycle. Elucidating the RNA features responsible for selective recognition of the full-length gRNA in the presence of an abundance of other cellular RNAs and spliced viral RNAs remains an area of intense research. The recent nuclear magnetic resonance (NMR) structure by Keane et al. [1] expands upon previous efforts to determine the conformation of the HIV-1 RNA packaging signal. The data support a secondary structure wherein sequences that constitute the major splice donor site are sequestered through base pairing, and a tertiary structure that adopts a tandem 3-way junction motif that exposes the dimerization initiation site and unpaired guanosines for specific recognition by Gag. While it remains to be established whether this structure is conserved in the context of larger RNA constructs or in the dimer, this study serves as the basis for characterizing large RNA structures using novel NMR techniques, and as a major advance toward understanding how the HIV-1 gRNA is selectively packaged.     

One influenza virus particle packages eight unique viral RNAs as shown by FISH analysis

Influenza A virus possesses a segmented genome of eight negative-sense, single-stranded RNAs. The eight segments have been shown to be represented in approximately equal molar ratios in a virus population; however, the exact copy number of each viral RNA segment per individual virus particles has not been determined. We have established an experimental approach based on multicolor single-molecule fluorescent in situ hybridization (FISH) to study the composition of viral RNAs at single-virus particle resolution. Colocalization analysis showed that a high percentage of virus particles package all eight different segments of viral RNAs. To determine the copy number of each RNA segment within individual virus particles, we measured the photobleaching steps of individual virus particles hybridized with fluorescent probes targeting a specific viral RNA. By comparing the photobleaching profiles of probes against the HA RNA segment for the wild-type influenza A/Puerto Rico/8/34 (PR8) and a recombinant PR8 virus carrying two copies of the HA segment, we concluded that only one copy of HA segment is packaged into a wild type virus particle. Our results showed similar photobleaching behaviors for other RNA segments, suggesting that for the majority of the virus particles, only one copy of each RNA segment is packaged into one virus particle. Together, our results support that the packaging of influenza viral genome is a selective process.     

HIV-1 Packaging Visualised by In-Gel SHAPE

HIV-1 packages two copies of its gRNA into virions via an interaction with the viral structural protein Gag. Both copies and their native RNA structure are essential for virion infectivity. The precise stepwise nature of the packaging process has not been resolved. This is largely due to a prior lack of structural techniques that follow RNA structural changes within an RNA–protein complex. Here, we apply the in-gel SHAPE (selective 2’OH acylation analysed by primer extension) technique to study the initiation of HIV-1 packaging, examining the interaction between the packaging signal RNA and the Gag polyprotein, and compare it with that of the NC domain of Gag alone. Our results imply interactions between Gag and monomeric packaging signal RNA in switching the RNA conformation into a dimerisation-competent structure, and show that the Gag–dimer complex then continues to stabilise. These data provide a novel insight into how HIV-1 regulates the translation and packaging of its genome.     

RNAi-mediated viral immunity requires amplification of virus-derived siRNAs in Arabidopsis thaliana

In diverse eukaryotic organisms, Dicer-processed, virus-derived small interfering RNAs direct antiviral immunity by RNA silencing or RNA interference. Here we show that in addition to core dicing and slicing components of RNAi, the RNAi-mediated viral immunity in Arabidopsis thaliana requires host RNA-directed RNA polymerase (RDR) 1 or RDR6 to produce viral secondary siRNAs following viral RNA replication-triggered biogenesis of primary siRNAs. We found that the two antiviral RDRs exhibited specificity in targeting the tripartite positive-strand RNA genome of cucumber mosaic virus (CMV). RDR1 preferentially amplified the 5′-terminal siRNAs of each of the three viral genomic RNAs, whereas an increased production of siRNAs targeting the 3′ half of RNA3 detected in rdr1 mutant plants appeared to be RDR6-dependent. However, siRNAs derived from a single-stranded 336-nucleotide satellite RNA of CMV were not amplified by either antiviral RDR, suggesting avoidance of the potent RDR-dependent silencing as a strategy for the molecular parasite of CMV to achieve preferential replication. Our work thus identifies a distinct mechanism for the amplification of immunity effectors, which together with the requirement for the biogenesis of endogenous siRNAs, may play a role in the emergence and expansion of eukaryotic RDRs.