Messenger RNA for the coat protein of southern bean mosaic virus

Ryegrass mottle virus complete genome determination and development of infectious cDNA by combining two methods- 3' RACE and RNA-Seq

Ryegrass mottle virus (RGMoV; genus: Sobemovirus) is a single-stranded positive RNA virus with a 30 nm viral particle size. It exhibits T = 3 symmetry with 180 coat protein (CP) subunits forming a viral structure. The RGMoV genome comprises five open reading frames that encode P1, Px, a membrane-anchored 3C-like serine protease, a viral genome-linked protein, P16, an RNA-dependent RNA polymerase, and CP. The RGMoV genome size varies, ranging from 4175 nt (MW411579.1) to 4253 nt (MW411579.1) in the deposited sequences. An earlier deposited RGMoV complete genome sequence of 4212 nt length (EF091714.1) was used to develop an infectious complementary DNA (icDNA) construct for in vitro gRNA transcription from the T7 promoter. However, viral infection was not induced when the transcribed gRNA was introduced into oat plants, indicating the potential absence of certain sequences in either the 5' or 3' untranslated regions (UTR) or both. The complete sequence of the 3' UTR was determined through 3' end RACE, while the 5' UTR was identified using high-throughput sequencing (HTS)-RNA-Seq to resolve the potential absences. Only the icDNA vector containing the newly identified UTR sequences proved infectious, resulting in typical viral infection symptoms and subsequent propagation of progeny viruses, exhibiting the ability to cause repeated infections in oat plants after at least one passage. The successful generation of icDNA highlighted the synergistic potential of utilizing both methods when a single approach failed. Furthermore, this study demonstrated the reliability of HTS as a method for determining the complete genome sequence of viral genomes.

Reversible swelling of SBMV is associated with reversible disordering

The structures of the compact and swollen southern bean mosaic virus (SBMV) particles have been compared by X-ray diffraction and proton magnetic resonance (PMR). Small-angle X-ray scattering showed that removal of divalent cations at alkaline pH causes the particle diameter to increase from 289 Å in the native SBMV by 12% in solution and by 9% in microcrystals. The swelling is fully reversible upon re-addition of Ca²⁺ and Mg²⁺ ions, as shown by the X-ray patterns at 6 Å resolution and by the 270 MHz PMR spectra. Beyond 30 Å resolution, X-ray patterns from the compact SBMV in solution and in microcrystals show fine fringes of ∼1/225 Å⁻¹ width extending to 6 Å resolution, whereas patterns from the swollen SBMV in solution and in microcrystals show only broader fringes of ∼1/90 Å⁻¹ width, Model calculations demonstrate that the fine fringes from compact SBMV arise from regular packing of the protein subunits on the icosahedral surface lattice; the smearing of fine fringes in the swollen virus pattern can be simulated by uncorrelated displacements of pentamers and hexamers of protein subunits, with a standard deviation of 6 Å from their mean locations. The PMR spectrum of compact SBMV is poorly resolved, whereas PMR spectrum of swollen SBMV shows sharp resonances in the methyl proton region. The line-narrowing for a fraction of the aliphatic protons upon swelling cannot be accounted for by rotational relaxation of the particle of 6 × 10⁶ MW, but must be attributed to internal motion in small regions of the protein subunits.

Overview on Sobemoviruses and a Proposal for the Creation of the Family Sobemoviridae

The genus Sobemovirus, unassigned to any family, consists of viruses with single-stranded plus-oriented single-component RNA genomes and small icosahedral particles. Currently, 14 species within the genus have been recognized by the International Committee on Taxonomy of Viruses (ICTV) but several new species are to be recognized in the near future. Sobemovirus genomes are compact with a conserved structure of open reading frames and with short untranslated regions. Several sobemoviruses are important pathogens. Moreover, over the last decade sobemoviruses have become important model systems to study plant virus evolution. In the current review we give an overview of the structure and expression of sobemovirus genomes, processing and functions of individual proteins, particle structure, pathology and phylogenesis of sobemoviruses as well as of satellite RNAs present together with these viruses. Based on a phylogenetic analysis we propose that a new family Sobemoviridae should be recognized including the genera Sobemovirus and Polemovirus. Finally, we outline the future perspectives and needs for the research focusing on sobemoviruses.

An essential fifth coding ORF in the sobemoviruses

The sobemoviruses have one of the smallest of all known RNA virus genomes. ORF1 encodes P1 which plays a role in suppression of silencing and virus movement, ORFs 2a and 2b encode the replicational polyproteins P2a and P2ab, and ORF3 encodes the coat protein. Translation of ORF2a from the genomic RNA is dependent on a leaky scanning mechanism. We report the presence of an additional ORF (ORFx), conserved in all sobemoviruses. ORFx overlaps the 5′ end of ORF2a in the +2 reading frame and also extends some distance upstream of ORF2a. ORFx lacks an AUG initiation codon and its expression is predicted to depend on low level initiation at near-cognate non-AUG codons, such as CUG, by a proportion of the ribosomes that are scanning the region between the ORF1 and ORF2a initiation codons. Mutations that disrupt translation of ORFx in turnip rosette virus prevent the establishment of infection.

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The plant-infecting sobemoviruses have a 4–4.5 kb genome with four know coding ORFs.

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We report an additional ORF (ORFx) that is conserved in all sobemoviruses.

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Translation of ORFx is predicted to depend on leaky scanning and non-AUG initiation.

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Mutations that disrupt translation of ORFx prevent the establishment of infection.

Lucerne transient streak virus RNA and its translation in rabbit reticulocyte lysate and wheat germ extract

Two abundant, encapsidated RNAs of lucerne transient streak virus (LTSV) are the 1.5 x 10(6) molecular weight (Mr) linear RNA-1 and both circular (RNA-2) and linear (RNA-3) forms of a 0.15 x 10(6) Mr viroid-like RNA. Two additional discrete minor RNAs, Mr 0.35 x 10(6) and 0.07 x 10(6), and a heterogeneous mixture of RNAs in the Mr range 0.05 to 1.0 x 10(6) are reported. Principal polypeptides translated from unfractionated LTSV RNA in rabbit reticulocyte lysate were of Mr 105,000 (p105), 78,000 (p78), and 33,000 (p33), the last not easily detected after translation in wheat germ extracts. All apparently are encoded in RNA-1. However, p33, which was precipitated by antibody of LTSV particles and presumably is the major capsid protein, was more readily translated from a smaller, most likely the Mr 0.35 x 10(6), RNA. Partial proteolysis and other tests indicate that p105 has a carboxyl terminal extension of p78 amino acid sequences and that neither shares sequences with p33. No translation products were attributed to RNA-2, RNA-3 or the Mr 0.07 x 10(6) RNA.

Identification of a satellite RNA associated with turnip crinkle virus

Turnip plants infected with turnip crinkle virus (TCV) contain four major RNA species which are not found in uninfected plants (A = 1.3 x 10(6) MW, B = 0.28 x 10(6) MW, C = 0.17 x 10(6) MW, and D = 0.13 x 10(6) MW). At least two of these RNAs, RNA A and RNA C, are packaged in the mature virion, but only the large RNA A is required for infection. Plants infected with RNA A alone produce neither the small virion RNA C nor the small nonvirion RNAs B and D. The small virion RNA C is not infective by itself, but requires coinfection with RNA A to replicate in plants. RNA C increases the severity of symptoms in plants infected with RNA A and restores the production of the nonvirion RNAs B and D. T1 RNase oligonucleotide mapping and copy DNA hybridization analysis indicate that the virion RNAs A and C do not have extensive homology. These data suggest that the large virion RNA A contains the full TCV genome and that the smaller virion RNA C is a dispensible satellite, designated S-TCV.

Propriedades moleculares de um isolado brasileiro do Southern bean mosaic virus

Um isolado do Southern bean mosaic virus (SBMV), gênero Sobemovirus, encontrado em feijoeiro (Phaseolus vulgaris) no Estado de São Paulo, foi purificado e algumas de suas propriedades moleculares determinadas. As partículas virais apresentam diâmetro de 28-30 nm e proteína capsidial com massa molecular estimada em 30 kDa. Das partículas virais foi extraído RNA de vários tamanhos (4,2 Kb, 3,1 Kb, 2,65 Kb, 2,15 Kb, 1,64 Kb, 1,36 Kb e 1,0 Kb) sendo aquele de 4,2 Kb o RNA genômico e o de 1,0 Kb supostamente um subgenômico que codifica para a proteína capsidial. Ácidos ribonucleicos de mesmo tamanho foram também detectados in vivo, indicando estar associados à replicação viral. Na análise do RNA de fita dupla (dsRNA), somente duas espécies foram detectadas (4,2 Kpb e 1,0 Kpb) correspondendo às formas replicativas do RNA genômico e do subgenômico para proteína capsidial. Os resultados indicam que somente estes dois RNA são replicados por meio de formas replicativas (RFs), enquanto os demais devem ser formados talvez por iniciação interna da fita negativa do RNA genômico. O SBMV-B SP apresentou propriedades moleculares análogas àquelas do SBMV descrito na América do Norte.

Identification of viral genes required for cell-to-cell movement of southern bean mosaic virus

Inoculation of Vigna unguiculata (cowpea) with transcripts synthesized in vitro from a genome-length cDNA clone of the cowpea strain of southern bean mosaic virus (SBMV-C) resulted in a systemic SBMV-C infection of this host. Capped RNA was about five times more infectious than uncapped RNA as determined by a local lesion assay. The SBMV-C cDNA clone was also used for mutagenesis of the four SBMV-C open reading frames (ORFs). ORF1, ORF3, and coat protein (CP) mutants were not infectious in cowpea. Electroporation of cowpea protoplasts with mutant transcripts demonstrated that the ORF1, ORF3, and CP gene products were not required for SBMV-C RNA synthesis, and the ORF1 and ORF3 gene products were not required for SBMV-C assembly. From these results, it was concluded that the ORF1 and ORF3 proteins and the CP are required for SBMV-C cell-to-cell movement. One of the ORF3 mutants pSBMV2-UAA1833 contained a nonsense codon between the predicted -1 ribosomal frameshift site (SBMV-C nucleotides 1796-1802) and a potential ORF3 translation initiation codon at SBMV-C nucleotide 1895. The lack of infectivity of this mutant suggested that ORF3 was expressed by a -1 ribosomal frameshift in ORF2 rather than by initiation of translation at nucleotide 1895.

The 105-kDa polyprotein of southern bean mosaic virus is translated by scanning ribosomes

The cowpea strain of southern bean mosaic virus (SBMV-C) is a positive-sense RNA virus. Three open reading frames (ORF-1, ORF2, and ORF3) are expressed from the genomic RNA. The ORF1 and ORF2 initiation codons are located at nucleotide (nt) positions 49 and 570, respectively. ORF1 is expressed by a 5' end-dependent scanning mechanism, but it is not known how ribosomes gain access to the ORF2 initiation codon. In experiments described here, it was demonstrated that the translation of ORF2 was sensitive to cap analog in a cell-free extract. In vitro and in vivo studies showed that the addition of one or more AUG codons between the 5' end of the SBMV-C RNA and the ORF2 initiation codon reduced ORF2 expression and that elimination of the ORF1 initiation codon increased ORF2 expression. Altering the sequence context of the ORF1 initiation codon to one more favorable for translation initiation also reduced ORF2 expression in vivo. Nucleotide deletions and insertions between SBMV-C nt 218-520 did not abolish ORF2 expression. In most cases, these mutations resulted in reduced expression of both ORF1 and ORF2. These results are consistent with translation of ORF2 by leaky scanning.

Expression of the rice yellow mottle virus P1 protein in vitro and in vivo and its involvement in virus spread

Rice yellow mottle sobemovirus (RYMV) is responsible for the yellow mottle disease on rice in Africa. The expression and function of the protein P1 (17.8 kDa) encoded by the first open reading frame (ORF) of RYMV was investigated. Using an antibody raised against purified P1, two proteins with apparent molecular masses of 18 and 19 kDa were identified in in vitro translation reactions of transcripts of the full-length cDNA of RYMV. Likewise, gene products with similar molecular mass were detected in inoculated and systemically infected rice leaves and in infected rice protoplasts. A mutant from which ORF1 nucleotides 88 to 547 were deleted and a frameshift mutant that resulted in truncation of 83 amino acids from the C terminus of P1 were incapable of replicating in protoplasts. In contrast, a mutant that does not express P1 due to a mutation at the initiation codon replicated efficiently in protoplasts but at a reduced level (about 0.5- to 2-fold less) compared to replication of wild-type RNA. None of these mutants caused systemic infection in rice plants. Transgenic rice plants that express P1 complemented the initiation codon mutant, but not the deletion mutants, and produced systemic infection. These experiments demonstrate that P1 of RYMV is dispensible for virus replication, although nucleotide deletions or additions in ORF1 are apparently lethal for virus replication. Furthermore, P1 of RYMV is required for the infection of plants and is important for virus spread.

Mapping and expression of southern bean mosaic virus genomic and subgenomic RNAs

The coat protein of the cowpea strain of southern bean mosaic sobemovirus (SBMV-C) is translated from a subgenomic RNA (sgRNA) that is synthesized in the virus-infected cell. Like the SBMV-C genomic RNA, the sgRNA has a viral protein (VPg) covalently bound to its 5' end. The mechanism(s) by which ribosomes initiate translation on the SBMV-C RNAs is not known. To begin to characterize the translation of the sgRNA it was first necessary to precisely map its 5' end. Primer extension was used to identify SBMV-C nucleotide (nt) 3241 as the transcription start site. As a control, the 5' end of the genomic RNA was also mapped. Surprisingly, the 5' terminal nt of this RNA was identified as SBMV-C nt 2. The primary structure of the 5' ends of these two RNAs is therefore expected to be VPg-ACAAAA. Precise mapping of the 5' end of the sgRNA of the bean strain of SBMV (SBMV-B) demonstrated that it has these same elements. Translation of coat protein from the SBMV-C sgRNA and p21 from the SBMV-C genomic RNA was compared using a cell-free system. The results of these experiments were consistent with translation of these proteins by a 5' end-dependent scanning mechanism rather than by internal ribosome binding.

Nucleotide sequence of the bean strain of southern bean mosaic virus

The genome of the bean strain of southern bean mosaic virus (SBMV-B) comprises 4109 nucleotides and thus is slightly shorter than those of the two other sequenced sobemoviruses (southern bean mosaic virus, cowpea strain (SBMV-C) and rice yellow mottle virus (RYMV)). SBMV-B has an overall sequence similarity with SBMV-C of 55% and with RYMV of 45%. Three potential open reading frames (ORFs) were recognized in SBMV-B which were in similar positions in the genomes of SBMV-C and RYMV. However, there was no analog of SBMV-C and RYMV ORF 3. From a comparison of the predicted sequences of the ORFs of these three sobemoviruses and of the noncoding regions, it is suggested that the two SBMV strains differ from one another as much as they do from RYMV and that they should be considered as different viruses.

Detection of genomic-length soybean mosaic virus RNA on polyribosomes of infected soybean leaves

Soybean mosaic virus (SMV)-related RNAs were examined in both polyribosomal and nonpolyribosomal fractions of systemically infected soybean leaves. Viral RNAs were detected by Northern blot hybridization analysis using two cloned SMV-cDNAs representing different regions of the viral genome as hybridization probes. Genomic length SMV-RNA (Mr of 3.3 X 10(6] was found in specific association with EDTA-sensitive polyribosomes of infected leaves, indicating that it functions as a messenger RNA in these cells. A smaller SMV-related RNA (Mr of 1.6 X 10(6] was sometimes detected in the polyribosomal fraction; however, reconstruction experiments indicate that this RNA is a breakdown product of the genomic-length RNA, generated during cell fractionation or RNA extraction. Two other SMV-related RNAs with Mr of 2.0 and 0.78 X 10(6) were sometimes detected in infected cells and were not generated from genomic SMV-RNA or intact virus particles in reconstruction experiments. However, these RNAs were exclusively associated with the EDTA-resistant, nonpolyribosomal fraction of infected cells. These data suggest that genomic-length SMV-RNA is the only viral RNA which is translated in these infected plants.