Complete genome sequence of a new quadrivirus infecting a member of the genus Thelonectria

A novel dsRNA virus named “Thelonectria quadrivirus 1” (TQV1) was found in a member of the genus Thelonectria (Ascomycota), isolated from a root associated with stem collar necrosis of Fraxinus excelsior L. The complete genome of TQV1 is composed of four segments, each containing a single ORF on the positive sense RNA. The sequence of the 5´ (5´-(C/T)ACGAAAAA-3´) and 3´termini (5´AT(T/G)AGCAATG(T/C)GC(G/A)CG-3’) of dsRNA 1 (4876 bp), dsRNA 2 (4312 bp), dsRNA 3 (4158 bp), and dsRNA 4 (3933 bp) are conserved. Based on its genome organization and phylogenetic position, TQV1 is suggested to be a new member of the family Quadriviridae. This is the first report of a mycovirus infecting a member of the genus Thelonectria.

Genome Features of a New Double-Stranded RNA Helper Virus (LBCbarr) from Wine Torulaspora delbrueckii Killer Strains

The killer phenotype of Torulaspora delbrueckii (Td) and Saccharomyces cerevisiae (Sc) is encoded in the genome of medium-size dsRNA viruses (V-M). Killer strains also contain a helper large size (4.6 kb) dsRNA virus (V-LA) which is required for maintenance and replication of V-M. Another large-size (4.6 kb) dsRNA virus (V-LBC), without known helper activity to date, may join V-LA and V-M in the same yeast. T. delbrueckii Kbarr1 killer strain contains the killer virus Mbarr1 in addition to two L viruses, TdV-LAbarr1 and TdV-LBCbarr1. In contrast, the T. delbrueckii Kbarr2 killer strain contains two M killer viruses (Mbarr1 and M1) and a LBC virus (TdV-LBCbarr2), which has helper capability to maintain both M viruses. The genomes of TdV-LBCbarr1 and TdV-LBCbarr2 were characterized by high-throughput sequencing (HTS). Both RNA genomes share sequence identity and similar organization with their ScV-LBC counterparts. They contain all conserved motifs required for translation, packaging, and replication of viral RNA. Their Gag-Pol amino-acid sequences also contain the features required for cap-snatching and RNA polymerase activity. However, some of these motifs and features are similar to those of LA viruses, which may explain that at least TdV-LBCbarr2 has a helper ability to maintain M killer viruses. Newly sequenced ScV-LBC genomes contained the same motifs and features previously found in LBC viruses, with the same genome location and secondary structure. Sequence comparison showed that LBC viruses belong to two clusters related to each species of yeast. No evidence for associated co-evolution of specific LBC with specific M virus was found. The presence of the same M1 virus in S. cerevisiae and T. delbrueckii raises the possibility of cross-species transmission of M viruses.

A full-length infectious cDNA clone of a dsRNA totivirus-like virus

Totivirus-like viruses are icosahedral non-enveloped double-stranded (ds)RNA viruses belonging to a group recently discovered and provisionally assigned in the Totiviridae family. Unlike fungal and protozoan Totiviridae viruses, these totivirus-like viruses infect a diverse spectrum of metazoan hosts and currently have enormous impacts on fisheries and agriculture. We developed the first totivirus-like virus Omono River virus (OmRV) infectious full-length DNA clone and produce the infectious particles using an RNA-transcript-based method. Unlike the parent wild-type particles from nature, the reverse-genetically-generated OmRV particles had an indistinguishable cytopathic effect, infectivity, and morphology. The established system is one of the few systems that have been reported for generating a non-segmented dsRNA virus DNA clone.

Proof-of-concept for the yadokari nature: a capsidless replicase-encoding but replication-dependent (+)ssRNA virus hosted by an unrelated dsRNA virus

We have previously proposed a new virus lifestyle or yadokari/yadonushi nature exhibited by a positive-sense ssRNA virus, yadokari virus 1 (YkV1), and an unrelated dsRNA virus, yadonushi virus 1 (YnV1) in a phytopathogenic ascomycete, Rosellinia necatrix . We have proposed that YkV1 diverts the YnV1 capsid to trans-encapsidate YkV1 RNA and RNA-dependent RNA polymerase (RdRp) and replicate in the heterocapsid. However, it remains uncertain whether YkV1 replicates using its own RdRp, and whether YnV1 capsid co-packages both YkV1 and YnV1 components. To address these questions, we first took advantage of the reverse genetics tools available for YkV1. Mutations in the GDD RdRp motif, one of the two identifiable functional motifs on the YkV1 polyprotein, abolished its replication competency. Mutations were also introduced in the conserved 2A-like peptide motif, hypothesized to cleave the YkV1 polyprotein co-translationally. Interestingly, the replication proficiency of YkV1 mutants in the host fungus agreed with the cleavage activity of the 2A-like peptide tested using a baculovirus expression system. Cesium chloride equilibrium density gradient centrifugation allowed for the separation of particles, with a subset of YnV1 capsid solely packaging YkV1 dsRNA and RdRp. These results provide proof-of-concept that a capsidless (+)ssRNA virus is hosted by an unrelated dsRNA virus. Importance Viruses typically encode their own capsids that encase their genomes. However, a capsidless (+)ssRNA virus, YkV1, depends on an unrelated dsRNA virus, YnV1, for encapsidation and replication. We have previously shown that YkV1 highjacks the capsid of YnV1 for trans-encapsidation of its own RNA and RdRp. YkV1 was hypothesized to divert the hetero-capsid as the replication site, as is commonly observed for dsRNA viruses. Herein, mutational analyses showed that the RdRp and 2A-like domains on the YkV1 polyprotein are important for its replication. The active RdRp must be cleaved by a 2A-like peptide from the C-proximal protein. Cesium chloride equilibrium density gradient centrifugation allowed for the separation of particles, with YnV1 capsid solely packaging YkV1 dsRNA and RdRp. This study provides proof-of-concept of a virus neo-lifestyle where a (+)ssRNA virus snatches capsids from an unrelated dsRNA virus to replicate with its own RdRp, thereby mimicking the typical dsRNA virus lifestyle.

Molecular characterization of a novel mycovirus isolated from Rhizoctonia solani AG-1 IA 9-11

The complete genome of the dsRNA virus isolated from Rhizoctonia solani AG-1 IA 9–11 (designated as Rhizoctonia solani dsRNA virus 11, RsRV11 ) were determined. The RsRV11 genome was 9,555 bp in length, contained three conserved domains, SMC, PRK and RT-like super family, and encoded two non-overlapping open reading frames (ORFs). ORF1 potentially coded for a 204.12 kDa predicted protein, which shared low but significant amino acid sequence identities with the putative protein encoded by Rhizoctonia solani RNA virus HN008 (RsRV-HN008) ORF1. ORF2 potentially coded for a 132.41 kDa protein which contained the conserved motifs of the RNA-dependent RNA polymerase (RdRp). Phylogenetic analysis indicated that RsRV11 was clustered with RsRV-HN008 in a separate clade independent of other virus families. It implies that RsRV11, along with RsRV-HN008 possibly a new fungal virus taxa closed to the family Megabirnaviridae, and RsRV11 is a new member of mycoviruses.

Cryo-EM reveals a previously unrecognized structural protein of a dsRNA virus implicated in its extracellular transmission

Mosquito viruses cause unpredictable outbreaks of disease. Recently, several unassigned viruses isolated from mosquitoes, including the Omono River virus (OmRV), were identified as totivirus-like viruses, with features similar to those of the Totiviridae family. Most reported members of this family infect fungi or protozoans and lack an extracellular life cycle stage. Here, we identified a new strain of OmRV and determined high-resolution structures for this virus using single-particle cryo-electron microscopy. The structures feature an unexpected protrusion at the five-fold vertex of the capsid. Disassociation of the protrusion could result in several conformational changes in the major capsid. All these structures, together with some biological results, suggest the protrusions’ associations with the extracellular transmission of OmRV.

Discrete Virus Factories Form in the Cytoplasm of Cells Coinfected with Two Replication-Competent Tagged Reporter Birnaviruses That Subsequently Coalesce over Time

ABSTRACT The Birnaviridae family, responsible for major economic losses to poultry and aquaculture, is composed of nonenveloped viruses with a segmented double-stranded RNA (dsRNA) genome that replicate in discrete cytoplasmic virus factories (VFs). Reassortment is common; however, the underlying mechanism remains unknown given that VFs may act as a barrier to genome mixing. In order to provide new information on VF trafficking during dsRNA virus coinfection, we rescued two recombinant infectious bursal disease viruses (IBDVs) of strain PBG98 containing either a split GFP11 or a tetracysteine (TC) tag fused to the VP1 polymerase (PBG98-VP1-GFP11 and PBG98-VP1-TC). DF-1 cells transfected with GFP1-10 prior to PBG98-VP1-GFP11 infection or stained with a biarsenical derivative of the red fluorophore resorufin (ReAsH) following PBG98-VP1-TC infection, had green or red foci in the cytoplasm, respectively, that colocalized with VP3 and dsRNA, consistent with VFs. The average number of VFs decreased from a mean of 60 to 5 per cell between 10 and 24 h postinfection (hpi) (P < 0.0001), while the average area increased from 1.24 to 45.01 μm2 (P < 0.0001), and live cell imaging revealed that the VFs were highly dynamic structures that coalesced in the cytoplasm. Small VFs moved faster than large (average 0.57 μm/s at 16 hpi compared to 0.22 μm/s at 22 hpi), and VF coalescence was dependent on an intact microtubule network and actin cytoskeleton. During coinfection with PBG98-VP1-GFP11 and PBG98-VP1-TC viruses, discrete VFs initially formed from each input virus that subsequently coalesced 10 to 16 hpi, and we speculate that Birnaviridae reassortment requires VF coalescence. IMPORTANCE Reassortment is common in viruses with segmented double-stranded RNA (dsRNA) genomes. However, these viruses typically replicate within discrete cytoplasmic virus factories (VFs) that may represent a barrier to genome mixing. We generated the first replication competent tagged reporter birnaviruses, infectious bursal disease viruses (IBDVs) containing a split GFP11 or tetracysteine (TC) tag and used the viruses to track the location and movement of IBDV VFs, in order to better understand the intracellular dynamics of VFs during a coinfection. Discrete VFs initially formed from each virus that subsequently coalesced from 10 h postinfection. We hypothesize that VF coalescence is required for the reassortment of the Birnaviridae. This study provides new information that adds to our understanding of dsRNA virus VF trafficking.