Diversity and Pathobiology of an Ilarvirus Unexpectedly Detected in Diverse Plants and Global Sequencing Data

High-throughput sequencing (HTS) and sequence mining tools revolutionized virus detection and discovery in recent years, and implementing them with classical plant virology techniques results in a powerful approach to characterize viruses. An example of a virus discovered through HTS is Solanum nigrum ilarvirus 1 (SnIV1) (Bromoviridae), which was recently reported in various solanaceous plants from France, Slovenia, Greece, and South Africa. It was likewise detected in grapevines (Vitaceae) and several Fabaceae and Rosaceae plant species. Such a diverse set of source organisms is atypical for ilarviruses, thus warranting further investigation. In this study, modern and classical virological tools were combined to accelerate the characterization of SnIV1. Through HTS-based virome surveys, mining of sequence read archive datasets, and a literature search, SnIV1 was further identified from diverse plant and non-plant sources globally. SnIV1 isolates showed relatively low variability compared with other phylogenetically related ilarviruses. Phylogenetic analyses showed a distinct basal clade of isolates from Europe, whereas the rest formed clades of mixed geographic origin. Furthermore, systemic infection of SnIV1 in Solanum villosum and its mechanical and graft transmissibility to solanaceous species were demonstrated. Near-identical SnIV1 genomes from the inoculum (S. villosum) and inoculated Nicotiana benthamiana were sequenced, thus partially fulfilling Koch's postulates. SnIV1 was shown to be seed-transmitted and potentially pollen-borne, has spherical virions, and possibly induces histopathological changes in infected N. benthamiana leaf tissues. Overall, this study provides information to better understand the diversity, global presence, and pathobiology of SnIV1; however, its possible emergence as a destructive pathogen remains uncertain. [Formula: see text] Copyright © 2023 The Author(s). This is an open access article distributed under the CC BY 4.0 International license.

Carrot populations in France and Spain host a complex virome rich in previously uncharacterized viruses

High-throughput sequencing (HTS) has proven a powerful tool to uncover the virome of cultivated and wild plants and offers the opportunity to study virus movements across the agroecological interface. The carrot model consisting of cultivated (Daucus carota ssp. sativus) and wild carrot (Daucus carota ssp. carota) populations, is particularly interesting with respect to comparisons of virus communities due to the low genetic barrier to virus flow since both population types belong to the same plant species. Using a highly purified double-stranded RNA-based HTS approach, we analyzed on a large scale the virome of 45 carrot populations including cultivated, wild and off-type carrots (carrots growing within the field and likely representing hybrids between cultivated and wild carrots) in France and six additional carrot populations from central Spain. Globally, we identified a very rich virome comprising 45 viruses of which 25 are novel or tentatively novel. Most of the identified novel viruses showed preferential associations with wild carrots, either occurring exclusively in wild populations or infecting only a small proportion of cultivated populations, indicating the role of wild carrots as reservoir of viral diversity. The carrot virome proved particularly rich in viruses involved in complex mutual interdependencies for aphid transmission such as poleroviruses, umbraviruses and associated satellites, which can be the basis for further investigations of synergistic or antagonistic virus-vector-host relationships.

Molecular and Biological Characterization of Novel and Known Family Secoviridae Members Infecting Lettuce

High-throughput sequencing of two lettuces showing virus-like symptoms in France provided evidence of infection by members of the family Secoviridae. One plant (JG1) had a complex mixed infection that involved, among others, a novel waikavirus (lettuce waikavirus 1) and two isolates of a sequivirus related to lettuce mottle virus (LeMoV). The second lettuce plant (JG2) was singly infected by LeMoV. Complete genomic sequences were obtained for all four isolates and, in addition, near complete genome sequences were obtained for other LeMoV or LeMoV-related isolates (from French cultivated and wild lettuces and from a Brazilian cultivated lettuce) and for two isolates of another family Asteraceae-infecting sequivirus, dandelion yellow mosaic virus (DaYMV). Analysis of these genomic sequences allows the proposal of tentative genome organization for the various viruses and clarification of their phylogenetic relationships. Sequence and host range comparisons point to significant differences between the two sequivirus isolates identified in the JG1 plant and LeMoV isolates from France and Brazil, suggesting they belong to a novel species for which the name lettuce star mosaic virus is proposed.

Identification of Seven Additional Genome Segments of Grapevine-Associated Jivivirus 1

Jiviruses are a group of recently described viruses characterized with a tripartite genome and having affinities with Virgaviridae (RNA1 and 2) and Flaviviridae (RNA3). Using a combination of high-throughput sequencing, datamining and RT-PCR approaches, we demonstrate here that in grapevine samples infected by grapevine-associated jivivirus 1 (GaJV-1) up to 7 additional molecules can be consistently detected with conserved 5' and 3' non-coding regions in common with the three previously identified GaJV-1 genomic RNAs. RNA4, RNA5, RNA6, RNA7, RNA8 and RNA10, together with a recombinant RNArec7-8, are all members of a family sharing a previously non recognized conserved protein domain, while RNA9 is part of a distinct family characterized by another conserved motif. Datamining of pecan (Carya illinoinensis) public transcriptomic data allowed the identification of two further jiviviruses and the identification of supplementary genomic RNAs with homologies to those of GaJV-1. Taken together, these results reshape our vision of the divided genome of jiviviruses and raise novel questions about the function(s) of the proteins encoded by jiviviruses supplementary RNAs.

First report of ash shoestring-associated virus (ASaV) infecting European ash (Fraxinus excelsior L.) in France

Ash shoestring-associated virus (ASaV) is a recently described Emaravirus with five genome segments identified in Germany and Switzerland from European ash (Fraxinus excelsior) or South European flowering ash (F. ornus) trees with chlorotic spots or mosaics and leaf curling or leaf shoestring symptoms [1]. In summer 2021 several European ash trees with severe leaf mosaic and deformation were observed 50 km south east of Bordeaux (France). Double stranded RNAs were purified from the leaves of one of the trees (2021-432) and analyzed by Illumina high throughput sequencing (HTS, 2x150 nt) as described [2]. Following quality trimming, reads were assembled de novo (CLC Genomics Workbench 21, Qiagen) and contigs annotated by BlastX analysis. Contigs homologous to ASaV genomic RNAs 2 to 5 were identified. For ASaV RNA2, four contigs were identified which could be manually assembled to yield a single scaffold while a single contig was obtained for RNAs 3, 4 and 5. The RNA2 scaffold assembled 1,206 reads for an average coverage of 58.2x, while the corresponding values for RNAs 3 to 5 were respectively 21,381 reads (1,529x), 18,146 reads (1,266x) and 1,234 reads (97.4x). While no contig was identified for ASaV RNA1 (or for other viruses), mapping of reads on an RNA1 reference (OU466880) allowed to identify 25 reads for this genomic segment (average coverage 0.4x). In total, ASaV reads represented 3.9% of the ca. 1 million reads obtained from the ash sample. The RNAs 2 to 5 scaffolds for isolate 2021-432 have been deposited in GenBank (OP501824-7). They show between 94.6% and 97.6% nucleotide identity with the corresponding RNAs of a reference isolate (OU466881-4). In order to validate the presence of ASaV in the original tree, PCR primers were designed based on RNAs 1 and 3 sequences. Primers ASaV1-F (5'-ATTATTCACAGTATGAAAGGG-3') and ASaV1-R (5'-GGTGTGGAGAATATCAAACC-3') amplify a 286 nt RNA1 fragment, while primers ASaV3-F (5'-GCTATACCCAGCTGAGGTGC-3') and ASaV3-R (5'-GTGTGCAATTCTATCAGCCTC-3') amplify a 322 nt RNA3 fragment. Amplicons of the expected size were obtained and directly sequenced. The RNA3 amplicon sequence was identical to the corresponding region of the HTS contig, while the RNA1 amplicon was 97.5% identical to the OU466880 reference sequence. The same primer pairs and a third one, ASaV4-F (5'- GAGGTTGCTTTGATGTCAGG -3') and ASaV4-R (5'- TGCCTCTCCGATGGTGATG -3'), amplifying a 411 nt RNA4 fragment, were used to test a European ash (2022-91) showing similar mosaic and shoestring symptoms collected in spring 2022 about 170 km south of Bordeaux. Again, amplifications were positive and the sequences of the amplicons showed 94.3 to 96.5% nt identity with the corresponding regions of the reference ASaV isolate and 93.9 to 94.3% identity with the French 2021-432 isolate. The PCR amplicon sequences for the two French isolates have been deposited in GenBank (OP501828-32). To our knowledge, these results represent the first report of a natural infection of ASaV in European ash in France. Identification of the virus in two ash populations about 150 km apart suggests the virus maybe widespread. The finding of ASaV in an ash tree with severe leaf symptoms and in which no other virus was identified by HTS supports its role as the causal agent of the symptoms observed. Ash trees in Europe are already threatened by the invasive ash dieback agent [3] and ASaV represents a further potential threat that deserves to be evaluated.

First report of barley virus G infecting winter barley (Hordeum vulgare L.) in France

As part of a cereals virome project high throughput sequencing (HTS)-based viral indexing was performed on plants with symptoms of barley yellow dwarf disease collected in June (2017-2020) in the main French cereals production areas. Total RNAs from 32 individual plants were purified (RNeasy Plant Mini Kit, Qiagen, Courtaboeuf, France) and Illumina sequenced (2x150 nt) following ribodepletion (Genewiz-Azenta, Leipzig, Germany). Following quality trimming, reads for each sample were de novo assembled (CLC Genomics Workbench 21, Qiagen) [1] and contigs annotated by BlastX analysis. In four winter barley samples collected in 2018 (18-58, 18-325 and 18-326) and 2019 (19-30A), besides contigs representing diverse viruses such as barley yellow dwarf viruses-PAV and PAS, Hordeum vulgare endornavirus, cereal yellow dwarf virus-RPV (18-326), wheat dwarf virus (18-325 and 18-326) and a novel Polerovirus (18-58 and 18-326), large contigs with high identity to barley virus G (BVG) were identified. BVG, a tentative Polerovirus, was initially reported in barley in South Korea in 2016 [2] and has so far been identified in a few other hosts including wheat, oat, maize, proso and foxtail millets as well as switchgrass. It has been reported from the USA and Australia [3] and, in Europe, from the Netherlands, Germany, Hungary and Greece [4]. Large BVG scaffolds representing near complete genomes could be reconstructed for each sample, integrating a total of 128.339, 7.188, 8.078 and 20.073 reads, for samples 19-30A, 18-58, 18325 and 18-326 respectively. Given that between 17.2 and 20.5 million reads had been obtained per sample, these values translate into between 0.04% (18-58 and 18-325) and 0.6% (19-30A) of total reads, and to average coverages of between 158x (18-58) and 2866x (19-30A) for the genomic scaffolds. The four assembled sequences (5584-5610 nt) have been deposited in GenBank (ON419453-ON419456). They are nearly identical (98.4 to 99.5% nt identity) and share between 97.7% and 98.5% nt identity with a barley reference isolate from the South Korea (NC_029906). To confirm the presence of BVG, a primer pair was designed based on available BVG sequences. Primers BVG-F(5'-CTAGCCCAACGAGTTGCGGG-3') and BVG-R(5'-GGTACAGAAGCTCTACGGTTC-3') amplifying a 394 nt were used in a two-step RT-PCR on new RNA extracts obtained from the 18-325 and 18-326 infected plants. The amplicons were directly sequenced and showed respectively 99.2% (ON419457, 18-325) and 100% (18-326) nt identity with the corresponding de novo scaffolds. The four analyzed samples have been collected respectively in 2018 (18-58, 18-325, 18-326) and 2019 (19-30A) in three different regions of France (Auvergne-Rhône-Alpes, Occitanie and Centre-Val de Loire), indicating a wide distribution and a persistence over time of BVG in France. To our knowledge, this represents the first report of a natural infection of BVG in cultivated winter barley in France. Presence of BVG may have been overlooked in a range of situation, as indicated by its retrospective discovery in a 34 years old Australian sample [3], possibly explaining its broad distribution in France. While the mixed infection status of the analyzed plants precludes any conclusion on its pathogenicity in French cereals, BVG has been reported to be associated with a range of symptoms in various hosts so that further studies to evaluate its prevalence and impact in France and to begin to understand its epidemiology are clearly warranted by the present results.

Host range and molecular variability of the sadwavirus dioscorea mosaic associated virus

Dioscorea mosaic associated virus (DMaV) is a member of the genus Sadwavirus, family Secoviridae, that is associated with mosaic symptoms in Dioscorea rotundata in Brazil. The genome of a DMaV isolate detected in D. trifida in Guadeloupe was sequenced by high-throughput sequencing. Using an RT-PCR-based detection assay, we found that DMaV infects D. alata, D. bulbifera, D. cayenensis-rotundata, D. esculenta, and D. trifida accessions conserved in Guadeloupe and Côte d'Ivoire and displays a very high level of molecular diversity in a relatively small region of the genome targeted by the assay. We also provide evidence that DMaV is also present in D. rotundata in Benin and in D. alata in Nigeria.

Genome characterization and diversity of trifolium virus 1: identification of a novel legume-infecting capulavirus

A novel geminivirus was identified in France and Spain in asymptomatic plants of white clover (Trifolium repens) and shrub medick (Medicago arborea). Its genome has the hallmarks of a capulavirus, and its relationship to other capulaviruses was confirmed by phylogenetic analysis. White clover isolates formed a tight cluster in the phylogenetic tree, while shrub medick isolates formed two distinct, more divergent groups with sequence identity values close to the species cutoff. These three groups have likely participated in recombination events involving alfalfa leaf curl virus and French bean severe leaf curl virus. The name "trifolium virus 1" (TrV1) is proposed for this new Capulavirus. Three TrV1 genotypes (TrV1-A, TrV1-B, and TrV1-C) were clearly distinguished.

First report of lettuce necrotic leaf curl virus infecting cultivated lettuce in France

Lettuce necrotic leaf curl virus (LNLCV, genus Torradovirus, family Secoviridae) has a bipartite single-stranded RNA genome and has so far only been reported in the Netherlands in open field lettuce (Verbeek et al. 2014). It was the first Torradovirus described from non-tomato host and, contrary to whitefly-transmitted tomato torradoviruses, aphids are its natural vectors (Verbeek et al. 2017). In October 2019, a symptomatic lettuce (JG3, cv. "Tregoney") was collected in an open field in southwestern France. Symptoms included stunted and deformed leaves with light necrosis and yellow spotting along minor veins of older leaves. Double-stranded RNAs were purified from JG3 leaves as described (Marais et al. 2018) and a cDNA library prepared and analyzed by Illumina NovaSeq sequencing. Analysis of sequence data identified two nearly fully assembled RNAs integrating respectively 28.9% and 60.9% of the sequencing reads and sharing respectively 85.5% and 83.3% nucleotide (nt) identity with the RNAs 1 and 2 of the LNLCV reference isolate, (NC_035214 and NC_035219, respectively). To confirm the presence of LNLCV in the original JG3 plant, it was used to mechanically inoculate indicator Nicotiana benthamiana, Chenopodium quinoa and C. amaranticolor plants. Only N. benthamiana developed symptoms, in the form of smaller and yellowed leaves. All inoculated plants were tested one month post-inoculation for the presence of LNLCV. Total RNAs were extracted according to Foissac et al. (2005) and used for RT-PCR tests with primers designed from the alignment between NC_035214 and our RNA1 sequence (LNLCV-S 5'-ATATTTTCCAAGTTGGAGGCTC-3' and LNLCV-R 5'-AGTRACAAAGGGACTAACTG-3'). LNLCV was detected in 3 out of 4 inoculated N. benthamiana plants. The full length RNA1 sequence (7577 nt) and the near complete RNA2 (5286 nt, lacking 3 nt at the 5' end as compared to NC_035219) could be assembled from the JG3 sequencing data and have been deposited in GenBank (MW172270 and MW172271, respectively). The lettuce JG3 isolate RNA1 shows 86.5% nt identity with the reference isolate while the taxonomically informative protease-polymerase regions share 96.8% aa identity. JG3 RNA2 shares 84.8% nt identity with NC_035219 while the movement protein and capsid subunits share respectively 92.5% and 98.3% aa identity. The smaller upstream ORF that slightly overlaps with the large MP-CP1/2/3 ORF is also conserved and shows 94.8% aa identity with the reference isolate. To our knowledge, this represents the first report of a natural infection of LNLCV in cultivated lettuce in France and anywhere outside the Netherlands. Since no other viruses were detected in the sequence dataset, LNLCV is most likely responsible for the mild necrosis and leaf deformation symptoms observed on the JG3 plant that appear to be similar to those initially described for LNLCV (Verbeek et al. 2014). While the pathogenicity of LNLCV in lettuce appears to be firmly established, further studies are needed to establish its distribution and prevalence, to understand why this pathogenic and aphid-transmitted virus is not more widely reported and whether it has the potential to increase in impact as a potential emerging agent on field lettuce crops.

Unravelling the virome in birch: RNA-Seq reveals a complex of known and novel viruses

To unravel the virome in birch trees of German and Finnish origin exhibiting symptoms of birch leaf-roll disease (BRLD), high-throughput sequencing (HTS) was employed. In total five viruses, among which three were so far unknown, were detected by RNAseq. One to five virus variants were identified in the transcriptome of individual trees. The novel viruses were genetically—fully or partially—characterized, belonging to the genera Carlavirus, Idaeovirus and Capillovirus and are tentatively named birch carlavirus, birch idaeovirus, and birch capillovirus, respectively. The recently discovered birch leafroll-associated virus was systematically detected by HTS in symptomatic seedlings but not in symptomless ones. The new carlavirus was detected only in one of the three symptomatic seedlings. The novel putative Capillovirus was detected in all seedlings—irrespective of their BLRD status—while the Idaeovirus was identified in a plant without leaf symptoms at the time of sampling. Further efforts are needed to complete Koch’s postulates and to clarify the possible association of the detected viruses with the BLR disease. Our study elucidates the viral population in single birch seedlings and provides a comprehensive overview for the diversities of the viral communities they harbor, to date.

Complete genome sequence of lettuce chordovirus 1 isolated from cultivated lettuce in France

Double-stranded RNAs purified from cultivated (Lactuca sativa) or wild (L. serriola) lettuce from southwest France were analyzed by high-throughput sequencing. For both samples, BLAST annotation revealed contigs with homology to Betaflexiviridae family members. The full genome sequence of the isolate from cultivated lettuce (JG1) was completed (8,536 nucleotides [nt], excluding the poly(A) tail). The sequence of the 3' half of the genome (4,800 nt) of a wild lettuce isolate (P22) was determined and found to share 95.1% nt sequence identity with the JG1 isolate. The JG1 genome contains four open reading frames, encoding a replicase, a movement protein, a capsid protein, and a protein of unknown function, respectively. Based on genome organization and phylogenetic relationships, the lettuce virus is most closely related to the recently described carrot chordoviruses 1 and 2 in the family Betaflexiviridae. Considering the species demarcation criteria in this family, the two lettuce viruses represent isolates of a new chordovirus species for which the name "lettuce chordovirus 1" (LeCV1) is proposed.

Genome characterization of a divergent isolate of the mycovirus Botrytis virus F from a grapevine metagenome

As part of a grapevine metagenome study, total RNA extracted from grapevine phloem scrapings was analyzed by Illumina sequencing. For one 420A rootstock sample, reads mapping against a reference database and BLAST annotation of contigs identified the presence of a divergent isolate of Botrytis virus F (BVF). The full genome sequence of this isolate (IVC-5-77) was determined (6,828 nucleotides [nt], excluding the poly(A) tail) and shown to be collinear with that of the BVF reference isolate, with the two open reading frames encoding a replication-associated protein (REP) and a coat protein (CP). The IVC-5-77 isolate, however, is very divergent, showing only 81.3-81.6% nucleotide sequence identity to the two other sequenced BVF isolates. The internal non-coding region was also found to be highly variable between BVF isolates. Analysis of the RNASeq reads demonstrated that close to 20% of them belong to Botrytis cinerea, the putative host of the IVC-5-77 isolate. These results extend our knowledge of the diversity and variability of BVF and demonstrate its detectability, together with that of its B. cinerea host, in total RNA RNASeq data from grapevine phloem scrapings.

Biological and Genetic Characterization of New and Known Necroviruses Causing an Emerging Systemic Necrosis Disease of Corn Salad (Valerianella locusta) in France

An emerging systemic necrosis disease of corn salad was first observed in the Nantes region of France in the late 2000s. Classical virology and high-throughput sequencing approaches demonstrated that the disease is associated with four different necroviruses: tobacco necrosis virus A (TNVA), tobacco necrosis virus D (TNVD), olive mild mosaic virus (OMMV), and a novel recombinant Alphanecrovirus for which the name corn salad necrosis virus (CSNV) is proposed. Satellite tobacco necrosis virus was also frequently observed. Koch's postulates were completed for all four agents, each one alone being able to cause systemic necrosis of varying severity in corn salad. OMMV was the most frequently observed virus and causes the most severe symptoms. TNVA was the second, both in terms of prevalence and symptom severity while TNVD and CSNV were only rarely observed and caused the less severe symptoms. The emergence of this systemic disease may have been favored by the short and repeated cropping cycles used for corn salad, possibly allowing the selection of necrovirus isolates with an improved ability to systemically invade this specialty crop.

High-Throughput Sequencing Reveals Further Diversity of Little Cherry Virus 1 with Implications for Diagnostics

Little cherry virus 1 (LChV1, Velarivirus, Closteroviridae) is a widespread pathogen of sweet or sour cherry and other Prunus species, which exhibits high genetic diversity and lacks a putative efficient transmission vector. Thus far, four distinct phylogenetic clusters of LChV1 have been described, including isolates from different Prunus species. The recent application of high throughput sequencing (HTS) technologies in fruit tree virology has facilitated the acquisition of new viral genomes and the study of virus diversity. In the present work, several new LChV1 isolates from different countries were fully sequenced using different HTS approaches. Our results reveal the presence of further genetic diversity within the LChV1 species. Interestingly, mixed infections of the same sweet cherry tree with different LChV1 variants were identified for the first time. Taken together, the high intra-host and intra-species diversities of LChV1 might affect its pathogenicity and have clear implications for its accurate diagnostics.

Complete genomic sequence of Raphanus sativus cryptic virus 4 (RsCV4), a novel alphapartitivirus from radish

The present work reports the discovery and complete genome sequencing of a virus from symptomless radish seedlings, classifiable as a novel member of the genus Alphapartitivirus, family Partitiviridae. Total RNA extracted from germinating seedlings was sequenced using Illumina technology. Bioinformatic analysis of the RNA-seq data revealed two contigs representing the near full-length genomic sequences of two genomic RNAs representing a new virus. Analysis of the genome sequence (excluding the polyA tail, RNA1: 1976 nt and RNA2: 1751 nt, respectively) showed a genomic organization typical of viruses classed within the Partitiviridae, with each genomic RNA encoding a single open reading frame (ORF). Phylogenetic analysis of the RNA dependent RNA polymerase (RNA1 ORF) and of the capsid protein (RNA2 ORF) clearly showed the new virus can be classified within the genus Alphapartitivirus, but sequence divergence establishes it as a new species, for which the name "Raphanus sativus cryptic virus 4" is proposed.

Complete Nucleotide Sequence of Artichoke latent virus Shows it to be a Member of the Genus Macluravirus in the Family Potyviridae

Complete genomic sequences of Artichoke latent virus (ArLV) have been obtained by classical or high-throughput sequencing for an ArLV isolate from Italy (ITBr05) and for two isolates from France (FR37 and FR50). The genome is 8,278 to 8,291 nucleotides long and has a genomic organization comparable with that of Chinese yam necrotic mosaic virus (CYNMV), the only macluravirus fully sequenced to date. The cleavage sites of the viral polyprotein have been tentatively identified by comparison with CYNMV, confirming that macluraviruses are characterized by the absence of a P1 protein, a shorter and N-terminally truncated coat protein (CP). Sequence comparisons firmly place ArLV within the genus Macluravirus, and confirm previous results suggesting that Ranunculus latent virus (RALV), a previously described Macluravirus sp., is very closely related to ArLV. Serological relationships and comparisons of the CP gene and of the partial RaLV sequence available all indicate that RaLV should not be considered as a distinct species but as a strain of ArLV. The results obtained also suggest that the spectrum of currently used ArLV-specific molecular hybridization or polymerase chain reaction detection assays should be improved to cover all isolates and strains in the ArLV species.

First Report of the Presence of Plum pox virus Rec Strain in France

Plum pox virus (PPV) is the most detrimental virus in stone fruit crops (Prunus sp.). At least nine monophyletic PPV strains are recognized, three of which, PPV-D, PPV-M, and PPV-Rec, have broad distributions (2). PPV-Rec is characterized by a unique founding recombination event and has been reported mostly from Central and South-Central Europe (2). It is generally considered poorly adapted to peach, and the weak and transient symptoms it causes in the GF305 peach seedling indicator may complicate its biological detection (2). During surveys in the Alsace region of France in spring 2013, a plum orchard with trees (Prunus domestica cv. Quetsche d'Alsace 3066) showing dubious leaf symptoms possibly reminiscent of PPV infection was identified. Testing of material from this plant by ELISA (Bioreba AG, Switzerland) gave clear positive reactions, putting the overall infection rate of the orchard at 6.25%, while a second nearby orchard was found infected at a rate of 0.8%. The presence of PPV was confirmed by polymerase chain reaction (PCR) amplification using either the P1-P2 polyvalent primer pair or the P3M-P4b primer pair, which allows the specific amplification of isolates of the Rec and M strains (1). Sequencing of the 467-nt-long P3M-P4b PCR product (Genbank Accession No. KM035763), which spans the end of the NIb gene and the N-terminal hypervariable end of the coat protein gene, provided clear identification of the PPV isolate as belonging to the Rec strain, since it contained all the PPV-Rec specific mutations in the amplified region and showed 98.7 to 97.7% identity with a range of PPV Rec isolates mostly originating from the Balkans. Identification as a PPV-Rec isolate was also confirmed using a strain-specific reverse-transcription-PCR assay (3). This is, to our knowledge, the first report of the presence of PPV-Rec in France. This finding is worrisome given that PPV-Rec is considered well adapted to plum (2), the most important Prunus crop in Alsace. Further surveillance in Alsace during 2014 failed to provide evidence for the presence of PPV-Rec in other areas of the region away from the initial infection focus, which is currently undergoing eradication efforts. References: (1) T. Candresse et al. Phytopathology 88:198, 1998. (2) J. A. García et al. Mol. Plant Pathol. 15:226, 2014. (3) Z. Subr et al. Acta Virol. 48:173, 2004.

Key mutations in the cylindrical inclusion involved in lettuce mosaic virus adaptation to eIF4E-mediated resistance in lettuce

We previously showed that allelic genes mol¹ and mo1² used to protect lettuce crops against Lettuce mosaic virus (LMV) correspond to mutant alleles of the gene encoding the eukaryotic translation initiation factor 4E. LMV resistance-breaking determinants map not only to the main potyvirus virulence determinant, a genome-linked viral protein, but also to the C-terminal region of the cylindrical inclusion (CI), with a key role of amino acid at position 621. Here, we show that the propagation of several non-lettuce isolates of LMV in mo1¹ plants is accompanied by a gain of virulence correlated with the presence in the CI C terminus of a serine at position 617 and the accumulation of mutations at positions 602 or 627. Whole-genome sequencing of native and evolved isolates showed that no other mutation could be associated with adaptation to mo1 resistance. Site-directed mutagenesis pinpointed the key role in the virulence of the combination of mutations at positions 602 and 617, in addition to position 621. The impact of these mutations on the fitness of the virus was evaluated, suggesting that the durability of mo1 resistance in the field relies on the fitness cost associated with the resistance-breaking mutations, the nature of the mutations, and their potential antagonistic effects.

Adaptation of lettuce mosaic virus to Catharanthus roseus involves mutations in the central domain of the VPg

An isolate of Lettuce mosaic virus (LMV, a Potyvirus) infecting Madagascar periwinckle (Catharanthus roseus) was identified and characterized by Illumina deep sequencing. LMV-Cr has no close affinities to previously sequenced LMV isolates and represents a novel, divergent LMV clade. Inoculation experiments with other representative LMV isolates showed that they are unable to infect C. roseus, which was not known to be a host for LMV. However, three C. roseus variants of one of these isolates, LMV-AF199, could be selected and partially or completely sequenced. These variants are characterized by the accumulation of mutations affecting the C-terminal part of the cylindrical inclusion (CI) helicase and the central part of the VPg. In particular, a serine to proline mutation at amino acid 143 of the VPg was observed in all three independently selected variants and is also present in the LMV-Cr isolate, making it a prime candidate as a host-range determinant. Other mutations at VPg positions 65 and 144 could also contribute to the ability to infect C. roseus. Inoculation experiments involving a recombinant LMV expressing a permissive lettuce eukaryotic translation initiation factor 4E (eIF4E) suggest that eIF4E does not contribute to the interaction of most LMV isolates with C. roseus.

Distribution of Barley yellow dwarf virus-PAV in the Sub-Antarctic Kerguelen Islands and Characterization of Two New Luteovirus Species

A systematic search for viral infection was performed in the isolated Kerguelen Islands, using a range of polyvalent genus-specific PCR assays. Barley yellow dwarf virus (BYDV) was detected in both introduced and native grasses such as Poa cookii. The geographical distribution of BYDV and its prevalence in P. cookii were analyzed using samples collected from various sites of the archipelago. We estimate the average prevalence of BYDV to be 24.9% in P. cookii, with significant variability between sites. BYDV genetic diversity was assessed using sequence information from two genomic regions: the P3 open reading frame (ORF) (encoding the coat protein) and the hypervariable P6 ORF region. The phylogenetic analysis in the P3 region showed that BYDV sequences segregate into three major lineages, the most frequent of which (Ker-I cluster) showed close homology with BYDV-PAV-I isolates and had very low intra-lineage diversity (0.6%). A similarly low diversity was also recorded in the hypervariable P6 region, suggesting that Ker-I isolates derive from the recent introduction of BYDV-PAV-I. Divergence time estimation suggests that BYDV-PAV-I was likely introduced in the Kerguelen environment at the same time frame as its aphid vector, Rhopalosiphum padi, whose distribution shows good overlap with that of BYDV-Ker-I. The two other lineages show more than 22% amino acid divergence in the P3 region with other known species in the BYDV species complex, indicating that they represent distinct BYDV species. Using species-specific amplification primers, the distribution of these novel species was analyzed. The high prevalence of BYDV on native Poaceae and the presence of the vector R. padi, raises the question of its impact on the vulnerable plant communities of this remote ecosystem.

First Report of Barley yellow dwarf virus and Cereal yellow dwarf virus Affecting Cereal Crops in Azerbaijan

A field survey was conducted during the 2010/2011 growing season at the Absheron experimental station of the Genetic Resources Institute of Azerbaijan. A total of 49 cereal samples with yellowing and reddening symptoms were obtained from 12 bread wheats (Triticum aestivum), 25 durum wheats (T. durum), 11 wild or cultivated wheat relatives (T. dicoccoides, T. beoticum, T. monococcum, and T. turgidum), and one oat (Avena sativa). Samples were tested by tissue-blot immunoassay (2) using antisera against 7 cereal-infecting viruses: Barley stripe mosaic virus (BSMV), Wheat dwarf virus (WDV), Wheat streak mosaic virus (WSMV), Barley yellow mosaic virus (BaYMV), Barley yellow striate mosaic virus (BYSMV), Maize streak virus (MSV), and Barley yellow dwarf virus (BYDV). Strong positive reactions against the BYDV-PAV polyclonal antiserum were shown by 43 samples. To confirm, total RNAs from 10 of the positive samples (three bread wheat, three durum wheat, the oat, and one sample each of T. beoticum, T. turgidum, and T. dicoccoides) were submitted to RT-PCR with two primer pairs adapted in part from (3). Primers Luteo1F 5'TTCGGMSARTGGTTGTGGTCCA 3' and YanR-new 5'TGTTGAGGAGTCTACCTATTTNG 3' (adapted from primer YanR (3)) allow the specific amplification of viruses of the genus Luteovirus (including BYDV) while primers Luteo2F 5'TCACSTTCGGRCCGWSTYTWTCAG 3' (adapted from primer Shu2a-F (3)) and YanR-new are specific for the genus Polerovirus (including Cereal yellow dwarf virus, CYDV). All 10 tested samples gave a positive amplification at the expected size (~545 bp) with the first primer pair, while only two samples, one from oat and one from the wild wheat relative T. dicoccoides, gave a positive amplification of the expected size (~383 bp) with the second primer pair. Sequencing of amplification products obtained with the Luteo1F/YanR-new primer pair confirmed the presence of BYDV-PAV in all samples (GenBank JX275850 to JX275857). The Azeri isolates were all similar (0 to 1.7% nucleotide divergence) except for one isolate (JX275855, from T. turgidum, 2.4 to 3.2% divergence). An Azeri BYDV-PAV isolate (JX275851, from bread wheat) showed 100% identity with a Latvian isolate (AJ563414) and with two isolates from Morocco (AJ007929 and AJ007918). These isolates belong to a group of widespread PAV isolates and are 99% identical with isolates from Sweden, the United States, China, France, and New Zealand. Sequencing of products obtained with the Luteo2F/YanR-new primers (JX294311 and JX294312) identified CYDV-RPV. The two Azeri sequences show ~3% nucleotide divergence and their closest relatives in GenBank are a range of CYDV-RPV isolates mostly from the United States, including EF521848 and EF521830, with ~4 to 5% divergence. Presence of CYDV was also confirmed using amplification with a CYD-specific primer pair (CYDV-fw-New 5'TTGTACCGCTTGATCCACGG 3' et CYDV-rev-New 5'GTCTGCGCGAACCATTGCC 3', both adapted from (1)) and sequencing of the amplification products. This is, to our knowledge, the first report of BYDV-PAV and CYDV-RPV infecting cultivated cereals and wild or cultivated wheat relatives in Azerbaijan. These viruses are responsible for serious disease losses in cereal crops worldwide (4). Their full impact on crops in Azerbaijan is yet to be seen. References: (1) M. Deb and J. M. Anderson. J. Virol. Meth. 148:17, 2008. (2) K. M. Makkouk and A. Comeau. Eur. J. Plant Pathol. 100:71, 1994. (3) C. M. Malmstrom and R. Shu. J. Virol. Meth. 120:69, 2004. (4) W. A. Miller and L. Rasochovà. Ann. Rev. Phytopathol. 35:167, 1997.

The determinant of potyvirus ability to overcome the RTM resistance of Arabidopsis thaliana maps to the N-terminal region of the coat protein

In Arabidopsis thaliana Columbia (Col-0) plants, the restriction of Tobacco etch virus (TEV) long-distance movement involves at least three dominant RTM (restricted TEV movement) genes named RTM1, RTM2, and RTM3. Previous work has established that, while the RTM-mediated resistance is also effective against other potyviruses, such as Plum pox virus (PPV) and Lettuce mosaic virus (LMV), some isolates of these viruses are able to overcome the RTM mechanism. In order to identify the viral determinant of this RTM-resistance breaking, the biological properties of recombinants between PPV-R, which systemically infects Col-0, and PPV-PSes, restricted by the RTM resistance, were evaluated. Recombinants that contain the PPV-R coat protein (CP) sequence in an RTM-restricted background are able to systemically infect Col-0. The use of recombinants carrying chimeric CP genes indicated that one or more PPV resistance-breaking determinants map to the 5' half of the CP gene. In the case of LMV, sequencing of independent RTM-breaking variants recovered after serial passages of the LMV AF199 isolate on Col-0 plants revealed, in each case, amino acid changes in the CP N-terminal region, close to the DAG motif. Taken together, these findings demonstrate that the potyvirus CP N-terminal region determines the outcome of the interaction with the RTM-mediated resistance.

Further characterization of a new recombinant group of Plum pox virus isolates, PPV-T, found in orchards in the Ankara province of Turkey

Sixteen Plum pox virus (PPV) isolates collected in the Ankara region of Turkey were analyzed using available serological and molecular typing assays. Surprisingly, despite the fact that all isolates except one, which was a mix infection, were typed as belonging to the PPV-M strain in four independent molecular assays, nine of them (60%) reacted with both PPV-M specific and PPV-D specific monoclonal antibodies. Partial 5' and 3' genomic sequence analysis on four isolates demonstrated that irrespective of their reactivity towards the PPV-D specific monoclonal antibody, they were all closely related to a recombinant PPV isolate from Turkey, Ab-Tk. All three isolates for which the relevant genomic sequence was obtained showed the same recombination event as Ab-Tk in the HC-Pro gene, around position 1566 of the genome. Complete genomic sequencing of Ab-Tk did not provide evidence for additional recombination events in its evolutionary history. Taken together, these results indicate that a group of closely related PPV isolates characterized by a unique recombination in the HC-Pro gene is prevalent under field conditions in the Ankara region of Turkey. Similar to the situation with the PPV-Rec strain, we propose that these isolates represent a novel strain of PPV, for which the name PPV-T (Turkey) is proposed. Given that PPV-T isolates cannot be identified by currently available typing techniques, it is possible that their presence has been overlooked in other situations. Further efforts should allow a precise description of their prevalence and of their geographical distribution in Turkey and, possibly, in other countries.

First Report of Cherry virus A in Prunus mume in China

Natural infections of Cherry virus A (CVA) have been reported in sweet (Prunus avium) and sour cherry (P. cerasus) from a number of European countries, North America, and Japan. CVA has been detected occasionally in other Prunus hosts such as peach, plum, and apricot (1). In the spring of 2007, samples from four Japanese apricot (Prunus mume) trees from the Jiangsu Province of China were analyzed by a polyvalent reverse transcriptase-PCR assay that amplifies a short region of the polymerase gene of viruses from several genera in the family Flexiviridae (2). Sequencing of the amplified products identified CVA in three samples. Two isolates (GenBank Accession Nos. EU730949 and EU730950) were closely related and highly homologous (97.5 to 99.3% identity) to noncherry isolates of CVA (GenBank Accession Nos AY792509 and DQ445275 to DQ445292). The third isolate (GenBank Accession No. EU730951) was approximately 90% identical to the other P. mume isolates and showed the highest identity (92.3%) to a cherry isolate (GenBank Accession No AF413923). CVA infection of the P. mume samples was confirmed by two CVA-specific primer pairs targeting genomic regions corresponding to the movement or coat protein genes. Since the samples showed mixed infections with Plum pox virus (PPV) or Asian Prunus virus 1 (APV1), potential CVA symptomatology could not be evaluated. To our knowledge, these results are the first identification of CVA in China and in P. mume, extending the geographical distribution and natural host range of this virus. Additional work is needed to evaluate whether CVA poses a threat to P. mume production or whether, as in other identified hosts, CVA is largely latent. References: (1) M. Barone et al. Plant Dis. 90:1459, 2006. (2) X. Foissac et al. Phytopathology 95:617, 2005.

Frequent Occurrence of Lettuce mosaic virus in Cape Daisy (Osteospermum sp.) in Tunisia

The potyvirus Lettuce mosaic virus (LMV) is a common pathogen of lettuce crops worldwide, but it also infects other Asteraceae spp. including ornamentals (2,3,4). Cape daisies (Osteospermum sp.) are widely grown perennial ornamentals reported to be natural hosts of LMV (2,4), which causes faint leaf mosaic and sometimes mild flower breaking. A preliminary observation of mosaic symptoms prompted a large-scale survey during the spring of 2005 in Cape daisies grown in the Tunis metropolitan area and the south of Tunisia (Djerba, Medenine). Two hundred seventy-one samples (Tunis: 14 sites, 219 samples; South: 9 sites, 52 samples) were randomly collected from nurseries, roadway plantings, and home gardens and analyzed. Ninety-three samples (Tunis: 40%, South: 12%; overall: 34%) showed distinct mosaic symptoms. LMV infection was verified by immuno-tissue printing on all collected samples (1), providing evidence for even higher infection levels (Tunis: 60%; South: 25%; overall: 56%). This technique, therefore, allowed the detection of symptomless infection in a significant proportion of samples. It should however, be stressed that symptoms can be very difficult to observe in water-stressed plants, a situation frequently observed in Tunisia. Subsequent PCR analysis with LMV-specific primers (1) of a subset of 24 symptomatic and tissue-print-positive samples confirmed LMV infection in all cases. This is to our knowledge, the first report of LMV infection in Cape daisies in Tunisia. The very high rate of infection observed suggests that these popular ornamentals might constitute a reservoir of LMV as previously reported in the United States (4). References: (1) H. Fakhfakh et al. J. Plant Pathol. 83:3, 2001. (2) R. Jordan and M. Guaragna. (Abstr.) Phytopathology 96(suppl.):S56, 2006. (3) O. Le Gall. No. 399 in: Description of Plant Viruses. A. T. Jones et al., eds. CMI/AAB, Kew, Surrey, UK, 2003. (4) D. C. Opgenorth et al. Plant Dis. 75:751, 1991.

First Report of the Presence of Plum pox virus Rec Strain in Turkey

Plum pox virus (PPV) is a detrimental virus in stone fruit crops. Six strains of PPV are recognized, one of which, PPV-Rec, represents a group of isolates sharing a unique founding recombination event (2). This strain has been reported only from central and south-central Europe. Its distribution is of interest because PPV-Rec is reported to induce only weak and transient symptoms in GF305 peach seedlings, which may complicate its detection using this widely used indicator (2). During a field trip in May 2006, a Japanese plum (Prunus salicina) tree showing leaf symptoms reminiscent of PPV infection was identified in Isparta, Turkey. A leaf sample tested by a serological lateral flow PPV Pocket Diagnostic (Central Science Laboratory, Sand Hutton, UK) gave a weak positive reaction. The presence of PPV was confirmed by grafting onto GF305 peach and by PCR amplification and sequencing of a short P3M-P4b PCR product (1; positions 8446 to 8912 on PPV-BOR3; GenBank Accession No. AY028309) spanning the end of the NIb gene and the N-terminal hypervariable end of the coat protein gene. Comparison of the sequence obtained (GenBank Accession No. EF051630) with databases unambiguously identified the isolate as belonging to the Rec strain because it contained all the PPV-Rec specific mutations in the amplified region. In keeping with this identification, the symptoms observed in GF305 were very weak, consisting only of slight vein clearing on a few leaves. This is, to our knowledge, the first report of the presence of PPV-Rec in Turkey. References: (1) T. Candresse et al. Phytopathology 88:198, 1998. (2) M. Glasa et al. J. Gen. Virol. 85:2671, 2004.

Further characterization of two sequiviruses infecting lettuce and development of specific RT-PCR primers

Lettuce mottle virus (LeMoV) and dandelion yellow mosaic virus (DaYMV) infect lettuce in South America and Europe, respectively. LeMoV and DaYMV possess isometric particles, occur at low concentrations in plants and have narrow host ranges. Partial genome sequences of both viruses were obtained using purified viral preparations and universal primers for members of the family Sequiviridae. DaYMV and LeMoV sequences were analyzed and showed identity with other members of the family. Universal primers that detect both viruses and specific primers for LeMoV and DaYMV were designed and used in RT-PCR-based diagnostic assays. These results provide the first molecular data on the LeMoV and DaYMV genomes and suggest that LeMoV is a member of the genus Sequivirus, probably distinct from DaYMV.

Asian prunus viruses: New related members of the family Flexiviridae in Prunus germplasm of Asian origin

Serological reactivity to Plum pox virus (PPV) antisera has been described in several Prunus sources of Asian origin that are free of PPV infection. Using polyvalent or specific PCR assays, the presence of three closely related agents in two of these sources, Prunus mume cv. Bungo and P. persica cv. Ku Chu'a Hung, was demonstrated. Similarities in genome organization and sequence comparisons indicate that these agents should be regarded as members of the genus Foveavirus, their only singular trait being a very large (>800 nt) 3' non-coding region (NCR), as compared to the ca. 130-180 nt 3' NCR observed in other Foveaviruses. The three agents are very divergent from known Foveaviruses but are also significantly removed one from the others, with overall nucleotide sequence identity levels in the sequenced region of ca. 74-76% and of only 60.8-67.5% in their complete CP gene (61.9-71.3% amino acid sequence identity). Given the species discrimination criteria in the family Flexiviridae, these three agents should be regarded as three related yet distinct new viruses belonging to the Foveavirus genus, for which the names Asian prunus virus 1, 2 and 3 are proposed. Evidence is provided for the presence of variants of these new viruses in other Prunus germplasm of Asian origin.

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.

Molecular characterization of banana virus X (BVX), a novel member of the Flexiviridae family

A novel virus was identified in banana (Musa spp). Analysis of the last 2917 nucleotides of its positive strand genomic RNA showed five open reading frames corresponding, from 5' to 3', to a truncated ORF coding for a replication-associated protein, three ORFs coding for a movement-associated triple gene block (TGB) and a capsid protein (CP) gene. This genome organization is similar to that of some members of the Flexiviridae family such as potexviruses and foveaviruses. This virus was named Banana virus X (BVX). Comparative sequence analysis showed that BVX is only distantly related to other members of the Flexiviridae family, in which it appears to define a new genus. BVX produces defective RNAs derived from its genomic RNA by non-homologous recombination. Three distinct pairs of donor/acceptor recombination sites involving short direct nucleotide repeats were characterized, accounting for deletions of 1268, 1358 and 1503 nucleotides. Contrary to the situation encountered for Potexviruses, these recombination sites are located within the TGB1 and CP genes and result in a truncated TGB1 protein.

Polyvalent degenerate oligonucleotides reverse transcription-polymerase chain reaction: a polyvalent detection and characterization tool for trichoviruses, capilloviruses, and foveaviruses

ABSTRACT A polyvalent nested reverse transcription-polymerase chain reaction (RT-PCR) test using degenerate primers containing inosine (polyvalent degenerate oligonucleotides [PDO]) was developed for filamentous fruit tree viruses belonging to the genera Trichovirus, Capillovirus, and Foveavirus. The 362-bp product was amplified from nucleic acid extracts obtained from Prunus and Malus leaf samples. All the viruses targeted were detected, demonstrating the polyvalence of the test. The variability of a collection of Apple chlorotic leaf spot virus isolates was analyzed using the sequence of the PDO RT-PCR amplified cDNAs. The technique was also used to screen stone fruit materials infected with known agents or with virus-like graft-transmissible diseases of unknown etiology. The results obtained further validated the broad specificity of the assay, with positive amplification obtained for uncharacterized or partially characterized viruses associated with cherry and peach disorders. Sequencing the amplified PCR products either directly or after cloning allowed the identification of variants of known agents and the tentative identification of two new agents, a Trichovirus and a Foveavirus. In addition, sequence comparisons demonstrated that the sequence of the targeted region is phylogenetically informative and of predictive taxonomic value.

First Report on the Natural Occurrence of Cherry virus A in Mirabelle Plum (Prunus domestica var. insititia)

Cherry virus A (CVA) is a member of the Capillovirus genus (2). It was discovered serendipitously during cloning of the little cherry agent (2) and has since been shown to be relatively widespread in sweet and sour cherry (Prunus cerasus and P. avium) (2,3). It is currently unclear whether CVA is associated with any specific symptoms in these hosts. Although it can be transmitted by grafting and thus propagated in peach, it has not been reported to naturally infect any host other than cherry. Using a degenerate reverse transcription-polymerase chain reaction (RT-PCR) technique targeting a conserved region of the RNA-dependent RNA polymerase (RdRp) and allowing the amplification of members of the Trichovirus, Capillovirus, and Foveavirus genera of filamentous plant viruses (1), a number of symptomatic Prunus spp. germplasm were evaluated. Among these, a cv. Mirabelle dorée accession (Prunus domestica var. insititia P332) of French origin exhibited severe symptoms of rosetting, severe leaf and fruit deformation, and yellow mosaic occasionally turning necrotic. RT-PCR conducted on symptomatic samples produced an amplification product of the expected size (362 bp) in several independent experiments. Sequencing of these products yielded a single sequence (GenBank Accession No. AY792509) with 88.1% nucleotide identity and 93.2% amino acid identity with the type strain of CVA (2). Presence of a CVA isolate was independently confirmed using a CVA-specific PCR assay directly on the original plum material or following experimental transmission by grafting on several new hosts including apricot (P. armeniaca cv. Priana) and plum (P. domestica cv. Prune d'Ente). To our knowledge, this is the first report of natural infection of CVA in plum. The symptoms observed in the infected plum are reminiscent of those caused by severe Prune dwarf virus (PDV) strains. Infection by PDV was confirmed using a PDV-specific PCR assay. The contribution, if any, of CVA to the symptoms observed remains to be evaluated. These findings suggest that the possible presence of CVA in noncherry Prunus spp. hosts should be taken into consideration by quarantine and certification programs. References: (1) X. Foissac et al. Acta Hortic. 550:3743, 2001. (2) W. Jelkmann. J. Gen. Virol. 76:2015, 1995. (3) M. J. Kirby et al. Plant Pathol. 50:6, 2001.

Characterization of Apricot pseudo-chlorotic leaf spot virus, A Novel Trichovirus Isolated from Stone Fruit Trees

ABSTRACT A trichovirus closely related to Apple chlorotic leaf spot virus (ACLSV) was detected in symptomatic apricot and Japanese plum from Italy. The Sus2 isolate of this agent cross-reacted with anti-ACLSV polyclonal reagents but was not detected by broad-specificity anti- ACLSV monoclonal antibodies. It had particles with typical trichovirus morphology but, contrary to ACLSV, was unable to infect Chenopodium quinoa and C. amaranticolor. The sequence of its genome (7,494 nucleotides [nt], missing only approximately 30 to 40 nt of the 5' terminal sequence) and the partial sequence of another isolate were determined. The new virus has a genomic organization similar to that of ACLSV, with three open reading frames coding for a replication-associated protein (RNA-dependent RNA polymerase), a movement protein, and a capsid protein, respectively. However, it had only approximately 65 to 67% nucleotide identity with sequenced isolates of ACLSV. The differences in serology, host range, genome sequence, and phylogenetic reconstructions for all viral proteins support the idea that this agent should be considered a new virus, for which the name Apricot pseudo-chlorotic leaf spot virus (APCLSV) is proposed. APCLSV shows substantial sequence variability and has been recovered from various Prunus sources coming from seven countries, an indication that it is likely to have a wide geographical distribution.

Candidate genes and QTLs for sugar and organic acid content in peach [ Prunus persica (L.) Batsch]

The identification of genes involved in variation of peach fruit quality would assist breeders in creating new cultivars with improved fruit quality. Major genes and quantitative trait loci (QTLs) for physical and chemical components of fruit quality have already been detected, based on the peach [ Prunus persica (L.) Batsch] cv. Ferjalou Jalousia((R)) (low-acid peach) x cv. Fantasia (normally-acid nectarine) F(2) intraspecific cross. Our aim was to associate these QTLs to structural genes using a candidate gene/QTL approach. Eighteen cDNAs encoding key proteins in soluble sugar and organic acid metabolic pathways as well as in cell expansion were isolated from peach fruit. A single-strand conformation polymorphism strategy based on specific cDNA-based primers was used to map the corresponding genes. Since no polymorphism could be detected in the Ferjalou Jalousia((R)) x Fantasia population, gene mapping was performed on the almond [ Prunus amygdalus ( P. dulcis)] cv. Texas x peach cv. Earlygold F(2) interspecific cross from which a saturated map was available. Twelve candidate genes were assigned to four linkage groups of the peach genome. In a second step, the previous QTL detection was enhanced by integrating anchor loci between the Ferjalou Jalousia((R)) x Fantasia and Texas x Earlygold maps and data from a third year of trait assessment on the Ferjalou Jalousia((R)) x Fantasia population. Comparative mapping allowed us to detect a candidate gene/QTL co-location. It involved a cDNA encoding a vacuolar H(+)-pyrophosphatase ( PRUpe;Vp2) that energises solute accumulation, and QTLs for sucrose and soluble solid content. This preliminary result may be the first step in the future development of marker-assisted selection for peach fruit sucrose and soluble solid content.

Molecular characterization of foveaviruses associated with the cherry necrotic mottle leaf disease and complete sequencing of an European isolate of Cherry green ring mottle virus

Analysis of the P1C124 source (associated with the cherry necrotic mottle leaf (CNML) disease) revealed the presence of two different viral agents. The complete nucleotide sequence of one of these agents, P1A, had an overall nucleotide sequence similarity of 83% with a previously sequenced North American isolate of Cherry green ring mottle virus (CGRMV) and should therefore be regarded as an European isolate of CGRMV. Approximately 2 kb of the 5' end of the genome of the second agent, P1B, were also sequenced and were shown to be 82% homologous with Cherry necrotic rusty mottle virus (CNRMV), another member of the Foveavirus genus. The possible involvement of CGRMV-P1A and of CNRMV-P1B in the etiology of the CNML disease is discussed.

Characterization of two different apricot latent virus variants associated with peach asteroid spot and peach sooty ringspot diseases

Peach asteroid spot (PAS) and peach sooty ringspot (PSRS) are two diseases of stone fruit trees of unknown aetiology. The use of a cRNA probe of the newly described Apricot latent virus (ApLV), a tentative member of the Foveavirus genus, indicated the presence of cross-hybridizing agents in PAS isolate LA2 and in PSRS isolates Caserta 12 and Clava J4. Analysis of dsRNA patterns revealed in each case the presence of a major dsRNA band of about 9.6 kbp. The purified dsRNAs were used to obtain cDNA clones for isolates LA2 and Caserta 12. Sequence analysis of a 1.1 kbp cDNA clone from isolate LA2 showed very high homology with the known ApLV sequence, indicating that this isolate represents a closely related variant of ApLV. Sequence analysis of a 3.06 kbp Caserta 12 cDNA clone representing the 3' region of the genome revealed a genomic organization similar to that reported for other members of the Foveavirus genus, including the triple gene block and a large, 43.6 kDa coat protein. Sequence comparison with the CP gene of ApLV, the only sequenced region so far for this virus, showed an overall homology of 78%. These results indicate that the foveavirus represented by the Caserta 12 isolate of PSRS disease may be regarded as a distant variant of ApLV. The present results indicate that the viral agents associated with peach asteroid spot and peach sooty ringspot diseases might be variants of the recently described ApLV.