The satellite RNA of barley yellow dwarf virus-RPV is supported by beet western yellows virus in dicotyledonous protoplasts and plants

Yellow Dwarf Viruses of Cereals: Taxonomy and Molecular Mechanisms

Yellow dwarf viruses are the most economically important and widespread viruses of cereal crops. Although they share common biological properties such as phloem limitation and obligate aphid transmission, the replication machinery and associated cis-acting signals of these viruses fall into two unrelated taxa represented by Barley yellow dwarf virus and Cereal yellow dwarf virus. Here, we explain the reclassification of these viruses based on their very different genomes. We also provide an overview of viral protein functions and their interactions with the host and vector, replication mechanisms of viral and satellite RNAs, and the complex gene expression strategies. Throughout, we point out key unanswered questions in virus evolution, structural biology, and genome function and replication that, when answered, may ultimately provide new tools for virus management.

Identification of two novel putative satellite RNAs with hammerhead structures in the virome of French and Spanish carrot samples

Carrot virome analysis using high-throughput sequencing revealed the presence of two RNA molecules with properties of satellite RNAs that are homologous to the satellite RNA of cereal yellow dwarf virus-RPV (CYDV-RPV). Satellite 1 is 298 nt long, while satellite 2 is 368 nt long. Their positive and negative genome strands contain hammerhead ribozymes similar to those found in other self-cleaving satellite RNAs. While both satellites were detected in Spanish carrot populations, only satellite 2 was found in French carrot populations. The most likely helper virus for these two satellites is carrot red leaf virus (CtRLV), which, like CYDV-RPV, is a polerovirus.

Proof of Concept of the Yadokari Nature: a Capsidless Replicase-Encoding but Replication-Dependent Positive-Sense Single-Stranded RNA Virus Hosted by an Unrelated Double-Stranded RNA Virus

We previously proposed a new virus lifestyle or yadokari/yadonushi nature exhibited by a positive-sense single-stranded RNA (ssRNA) virus, yadokari virus 1 (YkV1), and an unrelated double-stranded RNA (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 copackages 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 in the YkV1 polyprotein, abolished its replication competency. Mutations were also introduced in the conserved 2A-like peptide motif, hypothesized to cleave the YkV1 polyprotein cotranslationally. 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 capsids solely packaging YkV1 dsRNA and RdRp. These results provide proof of concept that a capsidless positive-sense ssRNA [(+)ssRNA] virus is hosted by an unrelated dsRNA virus. IMPORTANCE Viruses typically encode their own capsids that encase their genomes. However, a capsidless positive-sense single-stranded RNA [(+)ssRNA] virus, YkV1, depends on an unrelated double-stranded RNA (dsRNA) virus, YnV1, for encapsidation and replication. We previously showed that YkV1 highjacks the capsid of YnV1 for trans-encapsidation of its own RNA and RdRp. YkV1 was hypothesized to divert the heterocapsid as the replication site, as is commonly observed for dsRNA viruses. Herein, mutational analyses showed that the RdRp and 2A-like domains of 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 capsids 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.

Two distinct sites are essential for virulent infection and support of variant satellite RNA replication in spontaneous beet black scorch virus variants

Spontaneous point mutations of virus genomes are important in RNA virus evolution and often result in modifications of their biological properties. Spontaneous variants of beet black scorch virus (BBSV) and its satellite (sat) RNA were generated from cDNA clones by serial propagation in Chenopodium amaranticolor and Nicotiana benthamiana. Inoculation with recombinant RNAs synthesized in vitro revealed BBSV variants with divergent infectious phenotypes that affected either symptom expression or replication of satRNA variants. Sequence alignments showed a correlation between the phenotypes and distinct BBSV genomic loci in the 3'UTR or in the domain encoding the viral replicase. Comparative analysis between a virulent variant, BBSV-m294, and the wild-type (wt) BBSV by site-directed mutagenesis indicated that a single-nucleotide substitution of a uridine to a guanine at nt 3477 in the 3'UTR was responsible for significant increases in viral pathogenicity. Gain-of-function analyses demonstrated that the ability of the BBSV variants to support replication of variant satRNAs was mainly determined by aa 516 in the P82 replicase. In this case, an arginine substitution for a glutamine residue was essential for high levels of replication, and alterations of other residues surrounding position 516 in the wtBBSV isolate led to only minor phenotypic effects. These results provide evidence that divergence of virus functions affecting pathogenicity and supporting parasitic replication can be determined by a single genetic site, either a nucleotide or an amino acid. The results suggest that complex interactions occur between virus and associated satRNAs during virus evolution.

Baculovirus-expressed virus-like particles of Pea enation mosaic virus vary in size and encapsidate baculovirus mRNAs

Pea enation mosaic virus (PEMV: family Luteoviridae) is transmitted in a persistent, circulative manner by aphids. We inserted cDNAs encoding the structural proteins of PEMV, the coat protein (CP) and coat protein-read through domain (CPRT) into the genome of the baculovirus Autographa californica multiple nucleopolyhedrovirus with and without a histidine tag or an upstream Kozak consensus sequence. The Sf21 cell line provided the highest level of CP expression of the cell lines tested and resulted in production of virus-like particles (VLPs). The CPRT was not detected in recombinant baculovirus-infected cells by Western blot. Addition of a Kozak sequence increased the yield of baculovirus produced VLPs. Baculovirus-expressed VLPs purified on a nickel NTA column were of variable size (13-30 nm) and contained CP mRNA. The purified VLPs were also shown by RT-PCR to contain 70% of 154 baculovirus mRNAs, indicative of non-specific RNA encapsidation in the absence of viral RNA replication. When fed to the pea aphid, Acyrthosiphon pisum (Harris), the VLPs entered the aphid hemocoel, demonstrating that CPRT is not required for uptake of PEMV from the aphid gut. Baculovirus expression of PEMV VLPs provides a useful tool for future analysis of RNA encapsidation requirements and molecular aphid-virus interactions.

Infectious genomic RNA of Rhopalosiphum padi virus transcribed in vitro from a full-length cDNA clone

Availability of a cloned genome from which infectious RNA can be transcribed is essential for investigating RNA virus molecular mechanisms. To date, no such clones have been reported for the Dicistroviridae, an emerging family of invertebrate viruses. Previously we demonstrated baculovirus-driven expression of a cloned Rhopalosiphum padi virus (RhPV; Dicistroviridae) genome that was infectious to aphids, and we identified a cell line (GWSS-Z10) from the glassy-winged sharpshooter, that supports RhPV replication. Here we report that RNA transcribed from a full-length cDNA clone is infectious. Transfection of GWSS-Z10 cells with the RhPV transcript resulted in cytopathic effects, ultrastructural changes, and accumulation of progeny virions, consistent with virus infection. Virions from transcript-infected cells were infectious in aphids. This infectious transcript of a cloned RhPV genome provides a valuable tool, and a more tractable system without interference from baculovirus infection, for investigating replication and pathogenesis of dicistroviruses.

Putative Replication Intermediates in Endornavirus, a Novel Genus of Plant dsRNA Viruses

Oryza sativa endornavirus (OSV) belongs to a new genus (Endornavirus) and family (Endoviridae) with members containing large double-stranded RNA (dsRNA) replicons with plasmid-like properties. Analysis of products obtained from in vitro reaction of the OSV RNA-dependent RNA polymerase revealed a rapid increase of a population of the non-coding strand RNA molecules with a head-to-tail composition. Northern hybridization of total RNA from OSV-carrier cells with riboprobes specific for the coding strand RNA, revealed two types of RNA molecules (i) with a site specific nick and (ii) full-length unnicked molecules. Quantitative analyses of these RNAs showed about 50-fold higher amounts of full-length unnicked molecules in cultured cells in which the OSV copy number increases compared with those found in the seedling cells. Both the head-to-tail linked non-coding strand and the full-length coding strand molecules were also found in wild rice and broad beans infected with other endornaviruses indicating that the presence of these unique types of RNA molecules should be considered as a characteristic feature of Endoviridae .

Cis and trans requirements for rolling circle replication of a satellite RNA

Satellite RNAs usurp the replication machinery of their helper viruses, even though they bear little or no sequence similarity to the helper virus RNA. In Cereal yellow dwarf polerovirus serotype RPV (CYDV-RPV), the 322-nucleotide satellite RNA (satRPV RNA) accumulates to high levels in the presence of the CYDV-RPV helper virus. Rolling circle replication generates multimeric satRPV RNAs that self-cleave via a double-hammerhead ribozyme structure. Alternative folding inhibits formation of a hammerhead in monomeric satRPV RNA. Here we determine helper virus requirements and the effects of mutations and deletions in satRPV RNA on its replication in oat cells. Using in vivo selection of a satRPV RNA pool randomized at specific bases, we found that disruption of the base pairing necessary to form the non-self-cleaving conformation reduced satRPV RNA accumulation. Unlike other satellite RNAs, both the plus and minus strands proved to be equally infectious. Accordingly, very similar essential replication structures were identified in each strand. A different region is required only for encapsidation. The CYDV-RPV RNA-dependent RNA polymerase (open reading frames 1 and 2), when expressed from the nonhelper Barley yellow dwarf luteovirus, was capable of replicating satRPV RNA. Thus, the helper virus's polymerase is the sole determinant of the ability of a virus to replicate a rolling circle satellite RNA. We present a framework for functional domains in satRPV RNA with three types of function: (i) conformational control elements comprising an RNA switch, (ii) self-functional elements (hammerhead ribozymes), and (iii) cis-acting elements that interact with viral proteins.

Biolistic-mediated inoculation of immature wheat embryos with Barley yellow dwarf virus-PAV

Successful mechanical inoculation of plant with viruses requires an efficient method to introduce the viral pathogen into the appropriate cells of the plant. Barley yellow dwarf virus-PAV (BYDV-PAV, Luteovirus), transmitted naturally by aphids, must be inoculated into the phloem tissue to infect systemically inoculated hosts. The particle bombardment method used widely for nucleic acid transfer into plant tissues was adapted to inoculate immature embryos of winter and spring wheat cultivars with either BYDV-PAV particles or viral full-length RNAs. DAS-ELISA and RT-PCR were carried out on extracts of developed leaves at 7 weeks post-bombardment and revealed that up to 14% of bombarded embryos produced BYDV-infected wheat plants. This is the first report of an aphid-free inoculation method for BYDV.

Satellite cereal yellow dwarf virus-RPV (satRPV) RNA requires a douXble hammerhead for self-cleavage and an alternative structure for replication

The 110 nt hammerhead ribozyme in the satellite RNA of cereal yellow dwarf virus-RPV (satRPV RNA) folds into an alternative conformation that inhibits self-cleavage. This alternative structure comprises a pseudoknot with base-pairing between loop (L1) and a single-stranded bulge (L2a), which are located in hammerhead stems I and II, respectively. Mutations that disrupt this base-pairing, or otherwise cause the ribozyme to more closely resemble a canonical hammerhead, greatly increase self-cleavage. In a more natural multimeric sequence context containing the full-length satRPV RNA and two copies of the hammerhead, wild-type RNA cleaves much more efficiently than in the 110 nt context. Mutations in the upstream hammerhead, including a knock-out in the catalytic core, affect cleavage at the downstream cleavage site, indicating that multimers of satRPV RNA cleave via a double hammerhead. The double hammerhead includes base-pairing between two copies of the L1 sequence which extends stem I. Disruption of L1-L1 base-pairing slows cleavage of the multimer. L1-L2a base-pairing is required for efficient replication of satRPV RNA in oat protoplasts. Mutations that affect self-cleavage of the multimer do not correlate with replication efficiency, indicating that the ability to self-cleave is not a primary determinant of replication. We present a replication model in which multimeric satRPV RNA folds into alternative conformations that cannot form in the monomer. One potential metastable intermediate conformation involves L1-L2a base-pairing that may facilitate formation of the double hammerhead. However, we conclude that L1-L2a also performs some other essential function in the satRPV RNA replication cycle, because the L1-L2a base-pairing is more important than efficient self-cleavage for replication.

A Small RNA Resembling the Beet Western Yellows Luteovirus ST9-Associated RNA Is a Component of the California Carrot Motley Dwarf Complex

ABSTRACT Virions were purified from Anthriscus cerefolium or Coriandrum sativum plants infected with the viruses that cause California carrot motley dwarf. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of virion preparations yielded a single prominent protein species of approximately 28,000 molecular weight; however, denaturing agarose gel electrophoresis showed that virions contained three prominent single-stranded RNAs of approximately 5.6, 4.2, and 2.8 kb. Northern hybridization analyses, using transcripts generated from cloned cDNAs that corresponded to each of the virion RNAs, showed that the 5.6- and 4.2-kb RNAs were the genomic RNAs of the carrot red leaf luteovirus (CRLV) and the carrot mottle umbravirus (CMoV), respectively. Virions also contained an approximately 1.3-kb RNA related to the CMoV genomic RNA. The 2.8-kb RNA did not hybridize with CRLV or CMoV cRNA probes. Analysis of naturally infected carrot (Daucus carota) plants showed that CRLV, CMoV, and the 2.8-kb RNA were always present in carrot motley dwarf-affected plants. Greenhouse aphid- and mechanical-transmission experiments showed that the 2.8-kb RNA was consistently present in plants also infected by both CRLV and CMoV, but never in plants infected by only CMoV. Near full-length cloned cDNAs corresponding to the 2.8-kb RNA were prepared, and the complete nucleotide sequence was determined to be 2,835 nucleotides. Two large open reading frames (ORFs), 1a and 1b, were present within the sequence and were separated by an amber (UAG) stop codon. A third ORF (ORF 2), capable of encoding a protein of 4,289 molecular weight, was located near the 3' terminus. BLASTP results showed that the 2.8-kb RNA was most closely related to the beet western yellows luteovirus (BWYV) ST9-associated RNA. Based on its biological and molecular characteristics, we have named the 2.8-kb RNA the CRLV-associated RNA (CRLVaRNA).

Barley yellow dwarf viruses

Barley yellow dwarf viruses represent one of the most economically important and ubiquitous groups of plant viruses. This review focuses primarily on four research areas in which progress has been most rapid. These include (a) evidence supporting reclassification of BYDVs into two genera; (b) elucidation of gene function and novel mechanisms controlling gene expression; (c) initial forays into understanding the complex interactions between BYDV virions and their aphid vectors; and (d) replication of a BYDV satellite RNA. Economic losses, symptomatology, and means of control of BYD are also discussed.