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

AlphaFold modeling of nepovirus 3C-like proteinases provides new insights into their diverse substrate specificities

The majority of picornaviral 3C proteinases (3Cpro) cleavage sites possess glutamine at the P1 position. Plant nepovirus 3C-like proteinases (3CLpro) show however much broader specificity, cleaving not only after glutamine, but also after several basic and hydrophobic residues. To investigate this difference, we employed AlphaFold to generate structural models of twelve selected 3CLpro, representing six substrate specificities. Generally, we observed favorable correlations between the architecture and charge of nepovirus proteinase S1 subsites and their ability to accept or restrict larger residues. The models identified a conserved aspartate residue close to the P1 residue in the S1 subsites of all nepovirus proteinases examined, consistent with the observed strong bias against negatively-charged residues at the P1 position of nepovirus cleavage sites. Finally, a cramped S4 subsite along with the presence of two unique histidine and serine residues explains the strict requirement of the grapevine fanleaf virus proteinase for serine at the P4 position.

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.

Known and New Emerging Viruses Infecting Blueberry

Blueberry (Vaccinium spp.) plants are exposed to existing and emerging viruses as a result of expanding acreage of blueberry plantations across the world, primarily in North America. Since blueberry is cultivated in areas where there are wild Vaccinium spp., there is increasing risk of virus movement between wild and cultivated blueberries. This is theoretically possible because viruses can spread from commercial cultivars to native species and vice versa causing the spread of existing and new viruses. The occurrence of these viruses in blueberry can be devastating to the industry considering the cost for cultivation and production of this perennial crop. However, the advent of high-throughput sequencing and bioinformatic sequence analysis have allowed for rapid identification of known and novel viruses in any crop including blueberry, thus facilitating proper intervention in response to serious viral diseases. In this paper, we aim to focus on the current status of known and novel viruses emerging in blueberry worldwide, which may impact the blueberry industry.

A Renaissance in Nepovirus Research Provides New Insights Into Their Molecular Interface With Hosts and Vectors

Nepoviruses supplied seminal landmarks to the historical trail of plant virology. Among the first agriculturally relevant viruses recognized in the late 1920s and among the first plant viruses officially classified in the early 1970s, nepoviruses also comprise the first species for which a soil-borne ectoparasitic nematode vector was identified. Early research on nepoviruses shed light on the genome structure and expression, biological properties of the two genomic RNAs, and mode of transmission. In recent years, research on nepoviruses enjoyed an extraordinary renaissance. This resurgence provided new insights into the molecular interface between viruses and their plant hosts, and between viruses and dagger nematode vectors to advance our understanding of some of the major steps of the infectious cycle. Here we examine these recent findings, highlight ongoing work, and offer some perspectives for future research.

Virus testing by PCR and RT-PCR amplification in berry fruit

Berry fruit crops are prone to infection by a wide range of viruses, with the list expanding every year, primarily because of the expansion of the crops to new geographic regions. Although some methods allow for virus detection in a nonspecific manner, the advent of cheap and effective nucleic acid sequencing technologies has allowed for the development of species-specific tests. This chapter describes methods for extraction of nucleic acids for molecular testing from a range of different berry fruit crops and lists oligonucleotide primers that have been developed for amplification of a large number of berry fruit viruses.

New and emerging viruses of blueberry and cranberry

Blueberry and cranberry are fruit crops native to North America and they are well known for containing bioactive compounds that can benefit human health. Cultivation is expanding within North America and other parts of the world raising concern regarding distribution of existing viruses as well as the appearance of new viruses. Many of the known viruses of these crops are latent or asymptomatic in at least some cultivars. Diagnosis and detection procedures are often non-existent or unreliable. Whereas new viruses can move into cultivated fields from the wild, there is also the threat that devastating viruses can move into native stands of Vaccinium spp. or other native plants from cultivated fields. The aim of this paper is to highlight the importance of blueberry and cranberry viruses, focusing not only on those that are new but also those that are emerging as serious threats for production in North America and around the world.

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.

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.

The complete nucleotide sequence of RNA2 of blackcurrant reversion nepovirus

The complete nucleotide sequence of blackcurrant reversion nepovirus (BRV) RNA2 was determined from cDNA clones. RNA2 was 6400 nucleotides (nt) in length excluding the 3' poly(A)-tail. It contained a single open reading frame of 4878 nts encoding a polypeptide of 1626 amino acids with a calculated M(r) of 178¿ omitted¿860. The genome organization of BRV RNA2 was similar to that of other nepoviruses, especially those with a large RNA2. The coat protein (CP) was located in the C-terminal region of the large polyprotein and contained amino acid motifs conserved among nepovirus CPs. Sequence comparisons revealed a proline (P) residue surrounded by hydrophobic amino acid residues located upstream of the CP. This P motif is conserved among the putative movement proteins of nepo-, como-, caulimo- and capilloviruses. An N-terminal domain of 350 amino acids of RNA2-encoded polyprotein shared 34 and 35% sequence identity with the N-terminal domains of tomato ringspot nepovirus RNA1- and RNA2-encoded polyproteins, respectively. Sequence identities between the N-terminal domains of BRV RNA2 and other nepoviral RNA2s were less than 20%; no common N-terminal motif was found.

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.

Mutagenesis of amino acids at two tomato ringspot nepovirus cleavage sites: effect on proteolytic processing in cis and in trans by the 3C-like protease

Tomato ringspot nepovirus (ToRSV) encodes two polyproteins that are processed by a 3C-like protease at specific cleavage sites. Analysis of ToRSV cleavage sites identified previously and in this study revealed that cleavage occurs at conserved Q/(G or S) dipeptides. In addition, a Cys or Val is found in the -2 position. Amino acid substitutions were introduced in the -6 to +1 positions of two ToRSV cleavage sites: the cleavage site between the protease and putative RNA-dependent RNA polymerase, which is processed in cis, and the cleavage site at the N-terminus of the movement protein, which is cleaved in trans. The effect of the mutations on proteolytic processing at these sites was tested using in vitro translation systems. Substitution of conserved amino acids at the -2, -1, and +1 positions resulted in a significant reduction in proteolytic processing at both cleavage sites. The effects of individual substitutions were stronger on the cleavage site processed in trans than on the one processed in cis. The cleavage site specificity of the ToRSV protease is discussed in comparison to that of related proteases.

Characterization of the coat protein gene of mite-transmitted blackcurrant reversion associated nepovirus

The nucleotide sequence of the 3' terminal 3105 nucleotides (nt) of RNA2 of blackcurrant reversion associated virus (BRAV), the first mite-transmitted member of the nepovirus group, has been determined. The sequence contains an open reading frame of 1744 nt in the virus-sense strand, a 3' untranslated region of 1360 nt and a 3' poly(A) tail. Analysis of the amino-terminal residues of purified coat protein (CP) suggests that the CP gene is located between nts 1361 and 2959 (from the 3' terminus) in the RNA2, and that Asp/Ser is the proteolytic cleavage site of CP in the RNA2 encoded polyprotein. The predicted translation product from the CP gene is a polypeptide of 533 amino acids with a calculated Mr of 57 561. The amino acid sequence of BRAV CP showed highest similarity to blueberry leaf mottle virus (BLMV), and tomato ringspot virus (ToRSV), two members of the proposed sub-group three of nepoviruses possessing large RNA2 components. Nucleic and amino acid sequence comparisons between BRAV CP and the CPs of other nepoviruses indicate that specific conserved nepovirus CP domains occur in the BRAV CP thus confirming that BRAV is a member of the subgroup three of nepoviruses. reserved.

Purification and properties of a new virus from black currant, its affinities with nepoviruses, and its close association with black currant reversion disease

ABSTRACT Black currant reversion is a virus-like disease whose causal agent has not been identified. In rooted cuttings of a black currant plant affected with the severe form of the disease, pronounced chlorotic line patterns and ringspots developed in newly emerging leaves. From such symptom-bearing leaves, a virus was mechanically transmitted with difficulty to Chenopodium quinoa and, from this host, to other herbaceous test plants. The virus was purified and partially characterized, and the purified viri-ons were used for antiserum production. Virus particles were isometric, approximately 27 nm in diameter, and sedimented as two nucleoprotein components. They contained a protein species with a molecular mass of 55 kDa, which was readily degraded into a 54-kDa protein and two major RNA components of about 6,700 and 7,700 nucleotides (nt), each with a poly(A) tail. Most of these properties are shared by nepoviruses, but the virus was serologically unrelated to 14 nepoviruses or putative nepovi-ruses tested. However, the deduced sequence of 1,260 nt at the 3' end of one of the viral RNA species was distinct from any known viral sequence, except that it contained short regions of homology to the 3' terminal sequences of RNAs of seven other nepoviruses and two comovi-ruses. To detect this virus in Ribes plants, primers were designed from the known sequence to amplify a 210-nt region of the cDNA of the virus RNA using an immunocapture reverse transcriptase polymerase chain reaction (IC-RT-PCR) protocol. Using this assay for the virus, we associated its presence with two recognized forms of black currant reversion disease occurring in Finland, Scotland, or New Zealand. We also detected the virus in vector gall mites from reverted plants and in black currant plants on which such vector mites had fed. However, the virus was not detected by IC-RT-PCR in known healthy Ribes plants; in Ribes plants free from reversion, but affected by three other distinct virus-like diseases of Ribes; or in plants infected with arabis mosaic, strawberry latent ringspot, or raspberry ringspot nepoviruses. These data suggest that this virus may be the causal agent of reversion disease, and it is tentatively called black currant reversion associated virus.

Nucleotide sequence of the coat protein genes of citrus mosaic virus

The sequence of the 3'-terminal 2,201 nucleotides of RNA2 of citrus mosaic virus (CiMV) was determined. The sequence contains a long open reading frame (ORF) of 1989 nucleotides in the virus-sense strand and at 3' untranslated region of 212 nucleotides upstream of a poly(A) tail. The N-terminal amino acid sequence of the two coat proteins was determined by Edman degradation and the corresponding coding regions were identified in the polyprotein. The larger coat protein with Mr 48,122 is encoded upstream of the smaller one with Mr 24,172. The coat proteins are apparently cleaved from the polyprotein at an Arg-Gly and a Thr-Asn bond. Although CiMV has properties in common with the comoviruses and nepoviruses, there is no significant sequence homology between the coat proteins of CiMV and those of either group. Furthermore, the coat proteins of CiMV lack homology with those of strawberry latent ringspot virus (SLRSV), which has been reported to be more distantly related to the como- and nepoviruses. This lack of homology distinguishes CiMV from the como- and nepoviruses, SLRSV and other viruses.

A multiple alignment of the capsid protein sequences of nepoviruses and comoviruses suggests a common structure

The amino acid sequences of the regions encoding the structural proteins of eleven nepoviruses and five comoviruses, two genera of the family Comoviridae, have been aligned. The properties predicted by computer analysis (three-dimensional-3D-structure, hydrophobicity) are also correlated along this alignment, and aligned to the experimentally determined 3D structure of two comoviruses. It can thus be assumed that the 3D structure of the unique nepovirus coat protein matches that of the bipartite protomer found in the comovirus particles. In this model, the spatial locations of two amino-acid motifs characteristic of nepoviruses are in close vicinity, at the external surface of the virion. The coat proteins of nepoviruses and comoviruses may thus share a common evolutionary origin. A phylogenetic analysis was made using the multiple alignment, allowing a better understanding of the molecular relationships between these two groups of viruses.