Nucleotide sequence of Hungarian grapevine chrome mosaic nepovirus RNA1

Re-examination of nepovirus polyprotein cleavage sites highlights the diverse specificities and evolutionary relationships of nepovirus 3C-like proteases

Plant-infecting viruses of the genus Nepovirus (subfamily Comovirinae, family Secoviridae, order Picornavirales) are bipartite positive-strand RNA viruses with each genomic RNA encoding a single large polyprotein. The RNA1-encoded 3C-like protease cleaves the RNA1 polyprotein at five sites and the RNA2 polyprotein at two or three sites, depending on the nepovirus. The specificity of nepovirus 3C-like proteases is notoriously diverse, making the prediction of cleavage sites difficult. In this study, the position of nepovirus cleavage sites was systematically re-evaluated using alignments of the RNA1 and RNA2 polyproteins, phylogenetic relationships of the proteases, and sequence logos to examine specific preferences for the P6 to P1' positions of the cleavage sites. Based on these analyses, the positions of previously elusive cleavage sites, notably the 2a-MP cleavage sites of subgroup B nepoviruses, are now proposed. Distinct nepovirus protease clades were identified, each with different cleavage site specificities, mostly determined by the nature of the amino acid at the P1 and P1' positions of the cleavage sites, as well as the P2 and P4 positions. The results will assist the prediction of cleavage sites for new nepoviruses and help refine the taxonomy of nepoviruses. An improved understanding of the specificity of nepovirus 3C-like proteases can also be used to investigate the cleavage of plant proteins by nepovirus proteases and to understand their adaptation to a broad range of hosts.

Complete sequence of RNA1 of grapevine Anatolian ringspot virus

The nucleotide sequence of RNA1 of grapevine Anatolian ringspot virus (GARSV), a nepovirus of subgroup B, was determined from cDNA clones. It is 7,288 nucleotides in length excluding the 3' terminal poly(A) tail and contains a large open reading frame (ORF), extending from nucleotides 272 to 7001, encoding a polypeptide of 2,243 amino acids with a predicted molecular mass of 250 kDa. The primary structure of the polyprotein, compared with that of other viral polyproteins, revealed the presence of all the characteristic domains of members of the order Picornavirales, i.e., the NTP-binding protein (1B(Hel)), the viral genome-linked protein (1C(VPg)), the proteinase (1D(Prot)), the RNA-dependent RNA polymerase (1E(Pol)), and of the protease cofactor (1A(Pro-cof)) shared by members of the subfamily Comovirinae within the family Secoviridae. The cleavage sites predicted within the polyprotein were found to be in agreement with those previously reported for nepoviruses of subgroup B, processing from 1A to 1E proteins of 67, 64, 3, 23 and 92 kDa, respectively. The RNA1-encoded polyprotein (p1) shared the highest amino acid sequence identity (66 %) with tomato black ring virus (TBRV) and beet ringspot virus (BRSV). The 5'- and 3'-noncoding regions (NCRs) of GARSV-RNA1 shared 89 % and 95 % nucleotide sequence identity respectively with the corresponding regions in RNA2. Phylogenetic analysis confirmed the close relationship of GARSV to members of subgroup B of the genus Nepovirus.

A novel member of the genus Nepovirus isolated from Cucumis melo in Japan

An unusual virus was isolated from a Japanese Cucumis melo cv. Prince melon plant showing mild mottling of the leaves. The virus had a broad experimental host range including at least 19 plant species in five families, with most infected plants showing no symptoms on inoculated and uninoculated systemically infected leaves. The virus particles were spherical, approximately 28 nm in diameter, and the coat protein (CP) had an apparent molecular mass of about 55 kDa. The virus possessed a bi-partite genome with two RNA species, of approximately 8,000 and 4,000 nucleotides. Both genome components for the new virus were sequenced. Amino acid sequence identities in CP between the new virus and previously characterized nepoviruses were found to be low (less than 27%); however, in phylogenetic reconstructions the closest relationship was revealed between the new virus and subgroup A nepoviruses. These results suggest that the new virus represents a novel member of the genus Nepovirus. A new name, Melon mild mottle virus, has been proposed for this new virus.

Characterization and partial genome sequence of stocky prune virus, a new member of the genus Cheravirus

Characterization of a seemingly new spherical virus isolated from severely affected plum trees in south-western France indicated that its divided genome is composed of two single-stranded, polyadenylated RNAs of approximately 7.4 and 3.7 kb. Its particles are composed of three coat protein subunits of approximately 23, 23.5, and 24.5 kDa. Partial sequencing of the genomic RNAs indicated that this new virus, tentatively named stocky prune virus (StPV), is distantly related to the two sequenced cheraviruses, cherry rasp leaf virus (CRLV) and apple latent spherical virus (ALSV). StPV should be regarded as a new member in the unassigned genus Cheravirus.

Sequence analysis of grapevine isolates of Raspberry ringspot nepovirus

The nucleotide sequences of RNAs 1 and 2 of a German isolate of Raspberry ringspot virus (RpRSV) infecting grapevine (RpRSV-Grapevine), as well as partial sequences of another grapevine isolate from Switzerland (RAC815) were determined. The sequences of the protease-polymerase region encoded by RNA1, and the movement protein and coat protein genes encoded by RNA 2, of these isolates were compared with those of other isolates available in databases. The coat proteins of the grapevine isolates formed a sister group to all those from other RpRSV isolates, but whether this resulted from divergence or recombination was uncertain.

Complete nucleotide sequence of an isolate of the nepovirus raspberry ringspot virus from grapevine

The complete nucleotide sequence of the RNAs 1 and 2 of the nepovirus Raspberry ringspot virus cherry isolate (RpRSV-ch) from grapevine was determined. The RNA 1 is 7935 nucleotides (nt) long excluding the poly(A) tail, and contains one long open reading frame (ORF) encoding a polypeptide of 2367 amino acids. This ORF is preceeded by a 136nt 5' non-coding region, and followed by a 695nt 3' non-coding region. Conserved amino acid motifs, characteristic of the viral protease cofactor, the NTP-binding protein, proteinase and polymerase, were found in the sequence of the RNA 1-encoded polyprotein. The RNA 2 is 3915nt long excluding the poly(A) tail, and contains one long ORF encoding a polypeptide of 1106 amino acids. This ORF is preceeded by a 203nt 5' non-coding region, and followed by a 390nt 3' non-coding region. When compared to the corresponding sequences of other nepoviruses, a maximum level of 34% identity was found between the RNA 1-encoded polypetides of RpRSV-ch and other nepoviruses. For the RNA 2-encoded polypeptide, 88% identity was found between RpRSV-ch and RpRSV-S, a Scottish isolate of RpRSV from raspberry, and a maximum 29% identity between RpRSV-ch and other nepoviruses.

Nucleotide sequence of black currant reversion associated nepovirus RNA1

The RNA1 of black currant reversion associated nepovirus (BRAV) is 7711 nucleotides (nt) long, excluding the poly-A tail, and contains one long open reading frame (ORF) which is translated into a polyprotein of 2094 amino acids. The 5' NTR of BRAV RNA1 is 66 nt long and 78% identical with RNA2 5' NTR only over the first 57 nucleotides. The 3' non-translated region (3'NTR) is 1360 nucleotides long, and after the first 24 nucleotides 95% identical with the 3'NTR of RNA2. RNA1 3'NTR contains several stretches, 694-24 nucleotides in length, which are 60-80% similar to corresponding areas of the other viruses of the subgroup c of nepoviruses (BLMV, CLRV, PRMV or TomRSV). The 2094 amino acids-long polypeptide encoded by BRAV RNA1 is 33% identical with that of PRMV between amino acids 9 and 2057, and has significant similarity also to those of other nepoviruses and comoviruses. Conserved amino acid motifs, characteristic for the viral protease co-factor, the NTP-binding protein, the cysteine protease and the RdRp core domains, known to occur in the polyproteins of different viruses of the picornavirus-like supergroup, are all detected in the amino acid sequences encoded by BRAV RNA1.

Complete nucleotide sequence and infectious cDNA clone of the RNA1 of a Chinese isolate of broad bean wilt virus 2

The nucleotide sequence of the RNA1 of broad bean wilt virus 2 (BBWV2) isolate B935 has been determined from overlapping cDNA clones. It contains 5956 nucleotides in length excluding the 3' terminal poly(A) tail and contains a single long open reading frame (ORF) of 5613 nucleotides extending from nucleotide 234 to 5846. A repeated motif has been found in the 5' non-coding region. The predicted polyprotein encoded by the long ORF is 1870 amino acid in length with a molecular weight of 210 K. Amino acid sequence comparisons between portions of the BBWV2 RNA1-encoded polyprotein and proteins encoded by several species in Comoviridae revealed the putative functions of BBWV2 RNA1-encoded proteins and the same general genetic organization as that of comoviruses and nepoviruses. Based on the determined sequence, full-length cDNA clone of RNA1 designated as pU1FL was constructed. Together with transcripts from full-length cDNA clone of RNA2 (pU2FL), transcripts from pU1FL infected Chenopodium quinoa successfully.

Proteolytic processing at a novel cleavage site in the N-terminal region of the tomato ringspot nepovirus RNA-1-encoded polyprotein in vitro

Tomato ringspot nepovirus RNA-1-encoded polyprotein (P1) contains the domains for the putative NTP-binding protein, VPg, 3C-like protease and a putative RNA-dependent RNA polymerase in its C-terminal region. The N-terminal region of P1, with a coding capacity for a protein (or a precursor) of 67 kDa, has not been characterized. Using partial cDNA clones, it is shown that the 3C-like protease can process the N-terminal region of P1 at a novel cleavage site in vitro, allowing the release of two proteins, X1 (located at the N terminus of P1) and X2 (located immediately upstream of the NTB domain). P1 precursors in which the protease was inactive or absent were not cleaved by exogenously added protease, suggesting that P1 processing was predominantly in cis. Results from site-directed mutagenesis of putative cleavage sites suggest that dipeptides Q(423)/G and Q(620)/G are the X1-X2 and X2-NTB cleavage sites, respectively. The putative X1 protein contains a previously identified alanine-rich sequence which is present in nepoviruses but not in the related comoviruses. The putative X2 protein contains a region with similarity to the comovirus 32 kDa protease co-factor (the only mature protein released from the N terminus of comovirus P1 polyproteins) and to the corresponding region of other nepovirus P1 polyproteins. These results raise the possibility that the presence of two distinct protein domains in the N-terminal part of the P1 polyprotein may be a common feature of nepoviruses.

Nucleotide sequence and genome organization of apple latent spherical virus: a new virus classified into the family Comoviridae

A virus with isometric virus particles (ca. 25 nm) was isolated from an apple tree and named Apple latent spherical virus (ALSV). Virus particles purified from infected Chenopodium quinoa formed two bands with densities of 1.41 and 1.43 g/cm(3) in CsCl equilibrium density-gradient centrifugation, indicating that the virus is composed of two components. The virus had two ssRNA species (RNA1 and RNA2) and three capsid proteins (Vp25, Vp24 and Vp20). The complete nucleotide sequences of RNA1 and RNA2 were determined to be 6815 nt and 3384 nt excluding the 3' poly(A) tail, respectively. RNA1 contains two partially overlapping ORFs encoding polypeptides of molecular mass 23 kDa ('23K'; ORF1) and 235 kDa ('235K'; ORF2); RNA2 has a single ORF encoding a polypeptide of 108 kDa ('108K'). The 235K protein has, in order, consensus motifs of the protease cofactor, the NTP-binding helicase, the cysteine protease and the RNA polymerase, in good agreement with the gene arrangement of viruses in the COMOVIRIDAE: The 108K protein contains an LPL movement protein (MP) motif near the N terminus. Direct sequencing of the N-terminal amino acids of the three capsid proteins showed that Vp25, Vp20 and Vp24 are located in this order in the C-terminal region of the 108K protein. The cleavage sites of the 108K polyprotein were Q/G (MP/Vp25 and Vp25/Vp20) and E/G (Vp20/Vp24). Phylogenetic analysis of the ALSV RNA polymerase domain showed that ALSV falls into a cluster different from the nepo-, como- and fabavirus lineages.

Cloning and sequencing of peach rosette mosaic virus RNA1

The complete nucleotide sequence of peach rosette mosaic nepovirus (PRMV) RNA1 has been determined. A grapevine isolate of PRMV from Michigan was propagated and purified and cDNA clones representing 99. 5% of the RNA1 were constructed. The cDNA and direct RNA sequence analysis revealed a RNA species of 8004 nucleotides, excluding a 3' polyadenylated tail. The 5'- and 3'-untranslated regions were 52 and 1474 nucleotides, respectively. Computer analysis of the PRMV RNA1 nucleotide sequence unveiled a single long open reading frame of 6477 nucleotides, which is capable of encoding a 240 kDa polyprotein. Analysis of the predicted amino acid sequence of RNA1 revealed amino acid motifs characteristic of a replicase, proteinase, NTP-binding protein and a proteinase cofactor. The order and identity of these putative proteins are consistent with other nepoviruses. Analysis of PRMV RNA1 further distinguishes the taxonomic subdivisions within the nepovirus group, confirms the subgroup three status of PRMV and lays the groundwork for a replicase-mediated resistance strategy.

Long, nearly identical untranslated sequences at the 3' terminal regions of the genomic RNAs of cherry leafroll virus (walnut strain)

Hybridization analyses of cDNA clones derived from the two genomic RNAs, RNA1 and RNA2, of the walnut strain of the nepovirus cherry leafroll nepovirus (wCLRV) demonstrated a long region of high homology between the two viral RNAs. Subsequent mapping and nucleotide sequencing revealed a long, noncoding, presumably untranslated, region (3' UTR) immediately 5' of the terminal polyadenylate, a region that is almost identical in the two RNAs. This 3' UTR is 1567 nucleotide residues long in RNA1. Homologies of about 80% were found with corresponding regions of genomic RNAs from other strains of CLRV, but not with the corresponding regions of other nepovirus genomic RNAs.

Sequence analysis of the 3' termini of RNA1 and RNA2 of blueberry leaf mottle virus

The 3' termini of RNA1 and RNA2 of blueberry leaf mottle virus (BBLMV) were cloned and the cDNA sequence of a portion of the putative polymerase gene, the complete coat protein (CP) gene, and the 3' non-coding regions was determined. The N terminus of the coat protein gene was precisely located by comparison with the amino acid sequence determined by the Edman degradation sequencing of the purified coat protein. The coat protein gene encoded a polypeptide of 521 amino acids with a predicted M(r) of 57,542. Homology to BBLMV coat protein was highest with tomato ringspot virus (TomRSV) and cherry leaf roll virus (CLRV); two other nepoviruses also belonging to a sub-group defined by the presence of large RNA2 components. The 3' terminal 1390 nt of RNA1 and RNA2 were nearly identical and apparently non-coding. No statistically significant sequence homology was found between the 3' non-coding region of this length is unusual, but has been reported for two other related viruses, TomRSV and CLRV. The biological function of the long 3' non-coding region and how the high level of sequence homology is maintained between RNA1 and RNA2, is unknown. Possible mechanisms for conservation of the 3' terminus are discussed.

Evolution and taxonomy of positive-strand RNA viruses: implications of comparative analysis of amino acid sequences

Despite the rapid mutational change that is typical of positive-strand RNA viruses, enzymes mediating the replication and expression of virus genomes contain arrays of conserved sequence motifs. Proteins with such motifs include RNA-dependent RNA polymerase, putative RNA helicase, chymotrypsin-like and papain-like proteases, and methyltransferases. The genes for these proteins form partially conserved modules in large subsets of viruses. A concept of the virus genome as a relatively evolutionarily stable "core" of housekeeping genes accompanied by a much more flexible "shell" consisting mostly of genes coding for virion components and various accessory proteins is discussed. Shuffling of the "shell" genes including genome reorganization and recombination between remote groups of viruses is considered to be one of the major factors of virus evolution. Multiple alignments for the conserved viral proteins were constructed and used to generate the respective phylogenetic trees. Based primarily on the tentative phylogeny for the RNA-dependent RNA polymerase, which is the only universally conserved protein of positive-strand RNA viruses, three large classes of viruses, each consisting of distinct smaller divisions, were delineated. A strong correlation was observed between this grouping and the tentative phylogenies for the other conserved proteins as well as the arrangement of genes encoding these proteins in the virus genome. A comparable correlation with the polymerase phylogeny was not found for genes encoding virion components or for genome expression strategies. It is surmised that several types of arrangement of the "shell" genes as well as basic mechanisms of expression could have evolved independently in different evolutionary lineages. The grouping revealed by phylogenetic analysis may provide the basis for revision of virus classification, and phylogenetic taxonomy of positive-strand RNA viruses is outlined. Some of the phylogenetically derived divisions of positive-strand RNA viruses also include double-stranded RNA viruses, indicating that in certain cases the type of genome nucleic acid may not be a reliable taxonomic criterion for viruses. Hypothetical evolutionary scenarios for positive-strand RNA viruses are proposed. It is hypothesized that all positive-strand RNA viruses and some related double-stranded RNA viruses could have evolved from a common ancestor virus that contained genes for RNA-dependent RNA polymerase, a chymotrypsin-related protease that also functioned as the capsid protein, and possibly an RNA helicase.

Comparison of the 5' and 3' termini of tomato ringspot virus RNA1 and RNA2: evidence for RNA recombination

The sequences of the 5' terminal 1140 and 3' terminal 1546 nt of tomato ringspot virus (TomRSV) RNA1 have been determined. These sequences share a high degree of nucleotide sequence similarity with the previously determined TomRSV RNA2 sequence. Eighty-eight percent of the 5' terminal 907 nt of TomRSV RNA1 and RNA2 contain identical nucleotide residues; the first 459 nt are identical at all positions, whereas the next 447 nt are identical at only 75.8% of the nucleotide positions. The region of similarity includes not only the 5' nontranslated leader but also sequence probably encoding polyproteins. The 3' terminal 1533 nt of TomRSV RNA1 and RNA2 are identical and are noncoding. The sequences common to RNA1 and RNA2 account for almost 35% of the total genomic sequence. It is possible that the similar sequences at both ends of TomRSV RNA1 and RNA2 are a result of recombination between these two genomic RNA components.

Synthesis and proteolytic processing of arabis mosaic nepovirus, cherry leaf roll nepovirus, and strawberry latent ringspot nepovirus proteins in reticulocyte lysate

The genomic RNA components of three nepoviruses, arabis mosaic (ArMV), cherry leaf roll (CLRV), and strawberry latent ringspot (SLRV), were translated in rabbit reticulocyte lysate. Each component (except the RNA-2 of CLRV) directed the synthesis of proteins that corresponded in size to their theoretical coding capacity. The RNA-1 components of all three viruses were translated to yield polyproteins of Mr 250k, which were autocatalytically processed to yield up to five cleavage products. The primary products of translation of the RNA-2 components of ArMV (Mr 115k and 105k), CLRV (Mr 165k) and SLRV (Mr 99k and 96k) were polyproteins that were stable on incubation, but which underwent proteolytic processing in the presence of the corresponding RNA-1 and its translation products. These polyproteins were immunoprecipitated using antisera to appropriate virions indicating that the RNA-2 sequences encode the coat protein cistrons.