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.     

Segment-specific inverted repeats found adjacent to conserved terminal sequences in wound tumor virus genome and defective interfering RNAs.

Defective interfering (DI) RNAs are often associated with transmission-defective isolates of wound tumor virus (WTV), a plant virus member of the Reoviridae. We report here the cloning and characterization of WTV genome segment S5 [2613 base pairs (bp)] and three related DI RNAs (587-776 bp). Each DI RNA was generated by a simple internal deletion event that resulted in no sequence rearrangement at the deletion boundaries. Remarkably, although several DI RNAs have been in continuous passage for more than 20 years, their nucleotide sequences are identical to that of corresponding portions of segment S5 present in infrequently passaged, standard, transmission-competent virus. The positions of the deletion breakpoints indicate that the minimal sequence information required for replication and packaging of segment S5 resides within 319 bp from the 5' end of the (+)-strand and 205 bp from the 3' end of the (+)-strand. The terminal portions of segment S5 were found to contain a 9-bp inverted repeat immediately adjacent to the conserved terminal 5'-hexanucleotide and 3'-tetranucleotide sequences shared by all 12 WTV genome segments. The presence of a 6- to 9-nucleotide segment-specific inverted repeat immediately adjacent to the conserved terminal sequences was found to be a feature common to all WTV genome segments. These results reveal several basic principles that govern the replication and packaging of a segmented double-stranded RNA genome.     

An Association Between Globin Messenger RNA and 60S RNA Derived from Friend Leukemia Virus

The association between certain cellular RNAs and purified RNA tumor viruses prompted us to examine the possibility that specific host messenger RNAs might also be incorporated into RNA tumor viruses. Using a mouse cell line infected with Friend leukemia virus, T-3-Cl-2, which can be induced to accumulate mouse-globin messenger RNA, we show that mouse-globin messenger RNA sequences are present in viral particles purified from the culture medium of globin-producing cells. These globin messenger RNA sequences are absent from viral particles derived from T-3-Cl-2 cells that are not producing globin messenger RNA. Virus-associated globin messenger RNA sequences sediment in association with the 60S viral RNA complex as well as in free, 9S form. However, under mild denaturing conditions which result in the conversion of viral 60S RNA to 30S and smaller forms, all the globin sequences sediment as 9S RNA. Appropriate control experiments indicate that the virus-associated globin messenger RNA is resistant to degradation by exogenous ribonuclease; that exogenously added globin messenger RNA does not become associated with the 60S viral RNA complex; and that globin messenger RNA can be detected in virions derived from cells both induced for and constitutively synthesizing globin messenger RNA.     

A -1 ribosomal frameshift in a double-stranded RNA virus of yeast forms a gag-pol fusion protein.

The L-A double-stranded RNA (dsRNA) virus of Saccharomyces cerevisiae has two open reading frames (ORFs). ORF1 encodes the 80-kDa major coat protein (gag). ORF2, which is expressed only as a 180-kDa fusion protein with ORF1, encodes a single-stranded RNA-binding domain and has the consensus sequence for RNA-dependent RNA polymerases of (+)-strand and double-stranded RNA viruses (pol). We show that the 180-kDa protein is formed by -1 ribosomal frame-shifting by a mechanism indistinguishable from that of retro-viruses. Analysis of the "slippery site" suggests that a low probability of unpairing of the aminoacyl-tRNA from the 0-frame codon at the ribosomal A site reduces the efficiency of frameshifting more than the reluctance of a given tRNA to have its wobble base mispaired. Frameshifting of L-A requires a pseudoknot structure just downstream of the shift site. The efficiency of the L-A frameshift site is 1.8%, similar to the observed molar ratio in viral particles of the 180-kDa fusion protein to the major coat protein.     

Cellular proteins specifically bind single- and double-stranded DNA and RNA from the initiation site of a transcript that crosses the origin of DNA replication of herpes simplex virus 1

The small-component origins of herpes simplex virus 1 DNA synthesis are transcribed late in infection by an RNA with heterogeneous initiation sites approximately 290-360 base pairs from the origins. We report that cellular proteins react with a labeled RNA probe representing the 5' terminus of a subset of this RNA but not with the complementary strand of this RNA. The proteins form two complexes. Complex 2 was formed by all nuclear extracts tested, whereas complex 1 was invariably formed by proteins present only in nuclear extracts of mock-infected cells. Complex 1 protects a contiguous stretch of 40 nucleotides of the labeled RNA probe from nuclease degradation. Formation of complex 1 was competitively inhibited in a sequence-specific fashion by single-stranded RNA and DNA and by double-stranded RNA and DNA. The protein(s) forming complex 1 is, thus, quite distinct from known nucleic acid-binding proteins in that they recognize a specific nucleotide sequence, irrespective of the nature (single- and double-stranded RNA and DNA) of the nucleic acid. We conclude the following: (i) the proteins forming complex 1 and 2 are probably different, (ii) complex 1 is neither required throughout infection for viral replication nor able to hinder viral replication in cells in culture, and (iii) cells susceptible to infection encode one or more proteins that recognize specific sequences in single-stranded nucleic acids; either these proteins impart a compatible conformation on single-stranded nucleic acids with the conformation of the same strand in the double-stranded nucleic acid, or these proteins confer a specific, distinct conformation to both single-stranded and double-stranded nucleic acids.     

Activation of the Antiviral Kinase PKR and Viral Countermeasures

The interferon-induced double-stranded (ds)RNA-dependent protein kinase (PKR) limits viral replication by an eIF2α-mediated block of translation. Although many negative-strand RNA viruses activate PKR, the responsible RNAs have long remained elusive, as dsRNA, the canonical activator of PKR, has not been detected in cells infected with such viruses. In this review we focus on the activating RNA molecules of different virus families, in particular the negative-strand RNA viruses. We discuss the recently identified non-canonical activators 5'-triphosphate RNA and the vRNP of influenza virus and give an update on strategies of selected RNA and DNA viruses to prevent activation of PKR.     

Polyoma virus giant RNAs contain tandem repeats of the nucleotide sequence of the entire viral genome.

The bulk of late virus-specific RNA synthesized in polyoma virus-infected mouse cells is larger than a single strand of poloma DNA. The arrangement of viral nucleotide sequences in these giant polyoma RNAs was studied by electron microscopy of hybrids between purified high molecular weight viral RNA and the HindII-1 fragment of polyoma DNA, which contains 91% of the viral genome. Hybrid molecules containing a short single-stranded gap (corresponding to the 9% of viral sequences not present in HindII-1), flanked by double-stranded regions, were photographed and measured. The majority of hybrid molecules contained no single-stranded loops or branches, showing that all viral sequences are transcribed contiguously and that no nonviral sequences are present in the RNA. Hybrid molecules, containing RNA up to 3.5 times the genome length, had a repeating structure of single-stranded gaps 8% of genome length interspersed with double-stranded regions 89% of genome length, showing that giant polyoma RNAs contain tandem repeats of the nucleotide sequence of the entire viral DNA. A small proportion of hybrid molecules contained single-stranded branches or deletion loops in characteristic positions, indicating that RNA "splicing" may occur on high molecular weight nuclear polyoma RNA.     

Regulation of ribonuclease III processing by double-helical sequence antideterminants

The double helix is a ubiquitous feature of RNA molecules and provides a target for nucleases involved in RNA maturation and decay. Escherichia coli ribonuclease III participates in maturation and decay pathways by site-specifically cleaving double-helical structures in cellular and viral RNAs. The site of cleavage can determine RNA functional activity and half-life and is specified in part by local tertiary structure elements such as internal loops. The involvement of base pair sequence in determining cleavage sites is unclear, because RNase III can efficiently degrade polymeric double-stranded RNAs of low sequence complexity. An alignment of RNase III substrates revealed an exclusion of specific Watson–Crick bp sequences at defined positions relative to the cleavage site. Inclusion of these “disfavored” sequences in a model substrate strongly inhibited cleavage in vitro by interfering with RNase III binding. Substrate cleavage also was inhibited by a 3-bp sequence from the selenocysteine-accepting tRNA^Sec, which acts as an antideterminant of EF-Tu binding to tRNA^Sec. The inhibitory bp sequences, together with local tertiary structure, can confer site specificity to cleavage of cellular and viral substrates without constraining the degradative action of RNase III on polymeric double-stranded RNA. Base pair antideterminants also may protect double-helical elements in other RNA molecules with essential functions.     

Intermediates in the biosynthesis of double-stranded ribonucleic acids of bacteriophage phi 6.

Pseudomonas phaseolicola infected with bacteriophage phi 6 synthesized all three viral double-stranded RNA segments, three single-stranded RNAs, and three replicative intermediate-like RNAs in the presence of rifampin. The single-stranded RNA intermediates sedimented and electrophoresed along with melted viral double-stranded RNA, annealed with melted viral double-stranded RNA, and were transient in nature. The relative amounts of the single-stranded RNA intermediates varied during the infection cycle and were altered in the presence of chloramphenicol. The replicative intermediate-like RNAs sedimented faster than double-stranded RNA, failed to enter 2.5% polyacrylamide gels, eluted with double-stranded RNA from a CF-11 cellulose column, were precipitated with single-stranded RNA in 2 M LiC1, and yielded three genome-size pieces of double-stranded RNA upon digestion with RNase. These results are consistent with the hypothesis that complementary strands of the phi 6 double-stranded RNAs are synthesized asynchronously during the infection cycle.     

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.     

Autonomously replicating RNA in mitochondria of maize plants with S-type cytoplasm

Mitochondria isolated from maize plants with S-type male-sterile cytoplasms are capable of synthesizing four species of RNA at concentrations of actinomycin D that eliminate all DNA-directed RNA synthesis. No RNA synthesis occurs under the same conditions with mitochondria from plants possessing normal (N) cytoplasm or with other subcellular fractions from plants with S cytoplasm. The actinomycin D-resistant RNA synthesis occurs within the mitochondria since the labeling of these species is unaffected by inclusion of RNase in the incubation medium and since they become completely sensitive to RNase upon lysis of the mitochondria with low concentrations of Triton X-100. Two of the actinomycin D-resistant products are double stranded. These are 2850 and 900 base pairs in length, whereas the remaining two are 2150 and 850 bases. The synthesis of all four RNAs occurs in at least five different accessions of S cytoplasm, suggesting it is a general feature of S mitochondria. The double-stranded RNAs show homology to single-stranded S mitochondrial RNA but not to N mitochondrial RNA. Our observations indicate that the replication of these RNAs occurs independently of mtDNA and that they thus represent a novel type of inheritable element in organelles, an RNA plasmid.     

Molecular Mechanism of Arenavirus Assembly and Budding

Arenaviruses have a bisegmented negative-strand RNA genome, which encodes four viral proteins: GP and NP by the S segment and L and Z by the L segment. These four viral proteins possess multiple functions in infection, replication and release of progeny viruses from infected cells. The small RING finger protein, Z protein is a matrix protein that plays a central role in viral assembly and budding. Although all arenaviruses encode Z protein, amino acid sequence alignment showed a huge variety among the species, especially at the C-terminus where the L-domain is located. Recent publications have demonstrated the interactions between viral protein and viral protein, and viral protein and host cellular protein, which facilitate transportation and assembly of viral components to sites of virus egress. This review presents a summary of current knowledge regarding arenavirus assembly and budding, in comparison with other enveloped viruses. We also refer to the restriction of arenavirus production by the antiviral cellular factor, Tetherin/BST-2.     

Discovery and Genomic Function of a Novel Rice Dwarf-Associated Bunya-like Virus

Bunyaviruses cause diseases in vertebrates, arthropods, and plants. Here, we used high-throughput RNA-seq to identify a bunya-like virus in rice plants showing the dwarfing symptom, which was tentatively named rice dwarf-associated bunya-like virus (RDaBV). The RDaBV genome consists of L, M, and S segments. The L segment has 6562 nt, and encodes an RdRp with a conserved Bunya_RdRp super family domain. The M segment has 1667 nt and encodes a nonstructural protein (NS). The complementary strand of the 1120 nt S segment encodes a nucleocapsid protein (N), while its viral strand encodes a small nonstructural protein (NSs). The amino acid (aa) sequence identities of RdRp, NS, and N between RDaBV and viruses from the family Discoviridae were the highest. Surprisingly, the RDaBV NSs protein did not match any viral proteins. Phylogenetic analysis based on RdRp indicated that RDaBV is evolutionarily close to viruses in the family Discoviridae. The PVX-expressed system indicated that RDaBV N and NS may be symptom determinants of RDaBV. Our movement complementation and callose staining experiment results confirmed that RDaBV NSs is a viral movement protein in plants, while an agro-infiltration experiment found that RDaBV NS is an RNA silencing suppressor. Thus, we determined that RDaBV is a novel rice-infecting bunya-like virus.     

Molecular cloning and characterization of an isolate of hepatitis delta virus from Taiwan

The genomic RNA of an Asian isolate of hepatitis delta virus was cloned from a Chinese patient from Taiwan, using the polymerase chain reaction to amplify cDNA for cloning and sequencing. The sequence of this hepatitis delta virus isolate shares an 86% to 88% similarity with the three published hepatitis delta virus RNA sequences, suggesting heterogeneity of hepatitis delta viruses from different geographical areas. Four highly conserved, long stretches of sequence were found. These four regions corresponded to the sequences required for the autocatalytic cleavage activities of the genomic and antigenomic RNAs and the middle and the carboxyl terminal parts of the open reading frame for the delta antigen on the antigenomic strand. The conservation of nucleotide sequence in these four regions was further confirmed by sequencing additional hepatitis delta virus RNAs obtained from three patients with chronic delta hepatitis who lived in Los Angeles. These findings suggest that the conserved sequences are critical for viral replication. These conserved regions offer ideal sites for primer selection to carry out polymerase chain reactions to detect hepatitis delta virus RNA in patients with hepatitis delta virus infection.