Transmission from seed to seedling and elimination of alfalfa viruses.

Introduction: Viral diseases have become a vital factor limiting the development of the alfalfa (Medicago sativa) industry. Six viruses infecting alfalfa with a high incidence rate are Alfalfa mosaic virus (AMV), Medicago sativa alphapartitivirus 1 (MsAPV1), Medicago sativa alphapartitivirus 2 (MsAPV2), Medicago sativa deltapartitivirus 1 (MsDPV1), Medicago sativa amalgavirus 1 (MsAV1), and Cnidium vein yellowing virus 1 (CnVYV1). The purpose of this study was to develop preventive measures against these viruses by investigating their transmission through alfalfa seeds. Methods: In this study, we investigated the transmission rate of alfalfa viruses from seed to seedling by PCR, determined the location of viruses in seed by dissecting seed embryos and seed coat, tracked the changes of viruses in seedlings, and finally discover effective elimination measures for alfalfa viruses from 16 measures. Results and discussion: Our results demonstrated that all these six viruses could be transmitted from alfalfa seeds to seedlings with the transmission rate ranging from 44.44% to 88.89%. For AMV, MsAPV2, and MsAV1, the viral load was significantly higher in the seed coats than in the seed embryos; however, it did not show significant differences between these two parts of the seeds for MsAPV1, MsDPV1, and CnVYV1. Dynamic accumulation analysis of AMV and MsAPV2 indicated that the viral load in plants increased continuously in the early growth stage, making it important to inactivate these viruses prior to their seed-to-seedling transmission. Sixteen treatments including physical, chemical, and combinations of physical and chemical measures were compared in terms of their elimination efficiency on AMV and MsAPV2 and impacts on seed germination. The results showed that soaking alfalfa seeds in sterile distilled water for 2h + 2% NaClO for 1h or 2% NaClO for 1h were more promisingly applicable because it could significantly reduce AMV and MsAPV2 particles in both seeds and seedlings. Our data revealed a route of virus transmission in alfalfa and shed light on the discovery of a highly efficient method for the management of alfalfa viral diseases.

Grapevine Virome of the Don Ampelographic Collection in Russia Has Concealed Five Novel Viruses.

In this study, an analysis of the virome of 51 grapevines from the Don ampelographic collection named after Ya. I. Potapenko (Russia) was performed using high-throughput sequencing of total RNA. A total of 20 previously described grapevine viruses and 4 viroids were identified. The most detected were grapevine rupestris stem pitting-associated virus (98%), hop stunt viroid (98%), grapevine Pinot gris virus (96%), grapevine yellow speckle viroid 1 (94%), and grapevine fleck virus (GFkV, 80%). Among the economically significant viruses, the most present were grapevine leafroll-associated virus 3 (37%), grapevine virus A (24%), and grapevine leafroll-associated virus 1 (16%). For the first time in Russia, a grapevine-associated tymo-like virus (78%) was detected. After a bioinformatics analysis, 123 complete or nearly complete viral genomes and 64 complete viroid genomes were assembled. An analysis of the phylogenetic relationships with reported global isolates was performed. We discovered and characterized the genomes of five novel grapevine viruses: bipartite dsRNA grapevine alphapartitivirus (genus Alphapartitivirus, family Partitiviridae), bipartite (+) ssRNA grapevine secovirus (genus Fabavirus, family Secoviridae) and three (+) ssRNA grapevine umbra-like viruses 2, -3, -4 (which phylogenetically occupy an intermediate position between representatives of the genus Umbravirus and umbravirus-like associated RNAs).

Occurrence, Distribution, and Transmission of Alfalfa Viruses in China.

Alfalfa (Medicago sativa L.) is one of the most important quality forages worldwide and is cultivated throughout China. Alfalfa is susceptible to a variety of viral diseases during its growth, which has caused huge amounts of commercial losses. However, the profile of the alfalfa virus in China remains ambiguous and the viruses transmitted by Odontothrips loti (Haliday), dominant insect pests in alfalfa, are also poorly understood. In the present study, virus diversity was investigated in the primary alfalfa-growing areas in China. A total of 18 alfalfa viruses were identified through RNA-sequencing (RNA-seq) and reverse transcription-polymerase chain reaction (RT-PCR). Two new plant viruses, Medicago sativa virus 1 (MsV1) and Medicago sativa luteovirus 1 (MsLV1), were detected for the first time. Another four viruses, including the Alfalfa ringspot-associated virus (ARaV), Alfalfa virus F (AVF), Alfalfa enamovirus 1 (AEV1), and Alfalfa deltaparitivirus (ADPV), were reported in China for the first time as well. Both Alfalfa mosaic virus (AMV) and Medicago sativa alphapartitivirus 2 (MsAPV2) are the dominant pathogens, with an infection incidence of 91.7-100%, and 74.4-97.2%, respectively. Additionally, O. loti with first- and second-instar nymphs were shown to acquire the AMV within 0.25 h of feeding on a virus-infected alfalfa. Transmission by thrips to healthy alfalfa plants was also demonstrated. Additionally, we clarified the dynamic changes in the AMV in pre-adult stages of O. loti, which indicated that the AMV is propagated in the nymph stage of O. loti. These findings provide valuable information for understanding the alfalfa virome, confirm the role thrips O. loti plays in alfalfa virus transmission, and improve our fundamental knowledge and management of diseases in China.

Six Novel Mycoviruses Containing Positive Single-Stranded RNA and Double-Stranded RNA Genomes Co-Infect a Single Strain of the Rhizoctoniasolani AG-3 PT.

Six novel mycoviruses that collectively represent the mycovirome of Rhizoctonia solani anastomosis group (AG)-3 PT strain ZJ-2H, which causes potato black scurf, were identified through metatranscriptome sequencing and putatively designated as Rhizoctonia solani fusarivirus 4 [RsFV4, positive single-stranded RNA (+ssRNA)], Rhizoctonia solani fusarivirus 5 (RsFV5, +ssRNA), Rhizoctonia solani mitovirus 40 (RsMV40, +ssRNA), Rhizoctonia solani partitivirus 10 [RsPV10, double-stranded RNA (dsRNA)], Rhizoctonia solani partitivirus 11 (RsPV11, dsRNA), and Rhizoctonia solani RNA virus 11 (RsRV11, dsRNA). Whole genome sequences of RsFV4, RsMV40, RsPV10, RsPV11, and RsRV11, as well as a partial genome sequence of RsFV5, were obtained. The 3'- and 5'- untranslated regions of the five mycoviruses with complete genome sequences were folded into stable stem-loop or panhandle secondary structures. RsFV4 and RsFV5 are most closely related to Rhizoctonia solani fusarivirus 1 (RsFV1), however, the first open reading frame (ORF) of RsFV4 and RsFV5 encode a hypothetical protein that differs from the first ORF of RsFV1, which encodes a helicase. We confirmed that RsPV10 and RsPV11 assemble into the spherical virus particles (approximately 30 nm in diameter) that were extracted from strain ZJ-2H. This is the first report that +ssRNA and dsRNA viruses co-infect a single strain of R. solani AG-3 PT.

Molecular characterization of the complete genome of a novel partitivirus hosted by the saprobic mushroom Leucocybe candicans.

Virus communities of uncultivated fungi stay largely unknown. In the current study, we characterized a new partitivirus species detected in the basidiomycetous, saprobic mushroom Leucocybe candicans, named "Leucocybe candicans partitivirus 1" (LcPV1). The full-length genome of LcPV1, determined using deep sequencing and RLM-RACE approaches, consists of two dsRNA segments with each having the same size of 1984 bp. Both dsRNA genome segments comprise a single open reading frame (ORF), encoding an RNA-dependent RNA polymerase (RdRp), and a capsid protein (CP), respectively. Based on BLASTp search, the sequences of the RdRp and CP show the highest identity (50.09% and 35.71% similarity, respectively) to those of partitiviruses reported from an oomycetous, plant pathogenic, stramenopile algae Plasmopara viticola and basidiomycetous, plant pathogenic fungus Ceratobasidium sp., respectively. Phylogenetic analyses performed based on the RdRp and CP sequences revealed that LcPV1 falls within a cluster that includes different alphapartitivirus species from the family Partitiviridae. In this study, we propose that LcPV1 is a new member of a species belonging to the genus Alphapartitivirus. To our knowledge, this is the first study reporting on a new fungal virus (mycovirus) identified in the basidiomycetous, saprobic mushroom Leucocybe candicans.

Full-length genome characterization of a novel alphapartitivirus detected in the ectomycorrhizal fungus Hygrophorus penarioides.

Virus populations of ectomycorrhizal fungi remain poorly studied. In the present study, we characterized a new partitivirus isolated from the basidiomycetous, ectomycorrhizal fungus Hygrophorus penarioides, named "Hygrophorus penarioides partitivirus 1" (HpPV1). The whole genome of HpPV1, determined by merging deep sequencing and RLM-RACE approaches, comprised two dsRNA segments of 2053 bp and 2072 bp, respectively. Both dsRNA genome segments included a single open reading frame (ORF), encoding a putative RNA-dependent RNA polymerase (RdRp), and a capsid protein (CP), respectively. Based on BLASTp search, the sequences of the RdRp and CP exhibits the highest similarity (67.49% and 75.61% identity, respectively) to those of partitiviruses identified from an ascomycetous ectomycorrhizal fungus Sarcosphaera coronaria. Phylogenetic analyses performed based on the CP and RdRp sequences demonstrated that HpPV1 clusters within a clade that includes members of the genus Alphapartitivirus, belonging to the family Partitiviridae. Here, we propose that HpPV1 is a new member of the genus Alphapartitivirus. This is the first study reporting on a new partitivirus identified from the basidiomycetous, ectomycorrhizal fungus Hygrophorus penarioides.

Two novel partitiviruses that accumulate differentially in Rosellinia necatrix and Entoleuca sp. infecting avocado.

Rosellinia necatrix is responsible for the white rot root disease of avocado in Southern Spain. Entoleuca sp. is a fungus isolated from roots of these same trees, but it is not pathogenic in avocado. Here, we describe two new species of partitiviruses detected in isolates of the avocado sympatric fungi Entoleuca sp. and R. necatrix, termed Entoleuca partitivirus 1 (EnPV1), genus Alphapartitivirus, and Entoleuca partitivirus 2 (EnPV2), genus Betapartitivirus. For both R. necatrix and Entoleuca sp., the dsRNA of the RdRp genomic segment of EnPV1 accumulates at a higher rate than the CP dsRNA, except for a set of Entoleuca sp. isolates where titers of the CP dsRNA are 35-50 times higher than those of the RdRp dsRNA and between 250-380 times higher than the CP dsRNA titers found in the rest of Entoleuca sp. and R. necatrix isolates. For EnPV2, the accumulation rates of the RdRp dsRNA in Entoleuca sp., is in most of the cases, higher than the CP dsRNA. In contrast, in R. necatrix isolates, EnPV2 dsRNA2 generally accumulates at a higher rate. Genetic analysis of the partitiviruses revealed that there is no apparent variation in the nucleotide sequences among the strains. RNA silencing of the partitiviruses appears to be limited in Entoleuca sp., as shown by small RNA sequencing. Finally, the investigation of the presence of these partitiviruses in a fungal collection revealed that they have no role in the pathogenicity of R. necatrix in avocado or in the avirulence of Entoleuca sp. in this host.

Redefining the medicago sativa alphapartitiviruses genome sequences.

In alfalfa samples analyzed by hightroughput sequencing, four de novo assembled contigs encoding gene products showing identities to alphapartitiviruses proteins were found based on BlastX analysis. The predicted amino acid (aa) sequences of two contigs presented 99-100% identity to the RNA-dependent RNA polymerase (RdRp) and the capsid protein (CP) of the recently reported medicago sativa alphapartitivirus 1 (MsAPV1). In addition, the remaining two contigs shared only 56% (CP) and 70% (RdRp) pairwise aa identity with the proteins of MsAPV1, suggesting that these samples presented also a novel Alphapartitivirus species. Further analyses based on complete genome segments termini and the presence/absence of alphapartitivirus RNA in several samples and public alfalfa RNA datasets corroborated the identification of two different alphapartitivirus members. Our results likely indicate that the reported MsAPV1 genome was previously reconstructed with genome segments of two different alphapartitiviruses. Overall, we not only revisited the MsAPV1 genome sequence but also report a new tentative alphapartitivirus species, which we propose the name medicago sativa alphapartitivirus 2. In addition, the RT-PCR detection of both MsAPV1 and MsAPV2 in several alfalfa cultivars suggests a broad distribution of both viruses.

Complete Nucleotide Sequence of a Partitivirus from Rhizoctonia solani AG-1 IA Strain C24.

The complete genome of a novel double-stranded (ds) RNA mycovirus, named as Rhizoctonia solani partitivirus 5 (RsPV5), isolated from rice sheath blight fungus R. solani AG-1 IA strain C24, was sequenced and analysed. RsPV5 consists of two segments, dsRNA-1 (1899 nucleotides) and dsRNA-2 (1787 nucleotides). DsRNA-1 has an open reading frame (ORF) 1 that potentially codes for a protein of 584 amino acid (aa) containing the conserved motifs of a RNA-dependent RNA polymerase (RdRp), and dsRNA-2 also contains a ORF 2, encoding a putative capsid protein (CP) of 513 aa. Phylogenetic analysis revealed that RsPV5 clustered together with six other viruses in an independent clade of the genus Alphapartitivirus, indicating that RsPV5 was a new member of the genus Alphapartitivirus, within the family Partitiviridae.

ICTV Virus Taxonomy Profile: Partitiviridae.

The Partitiviridae is a family of small, isometric, non-enveloped viruses with bisegmented double-stranded (ds) RNA genomes of 3-4.8 kbp. The two genome segments are individually encapsidated. The family has five genera, with characteristic hosts for members of each genus: either plants or fungi for genera Alphapartitivirus and Betapartitivirus, fungi for genus Gammapartitivirus, plants for genus Deltapartitivirus and protozoa for genus Cryspovirus. Partitiviruses are transmitted intracellularly via seeds (plants), oocysts (protozoa) or hyphal anastomosis, cell division and sporogenesis (fungi); there are no known natural vectors. This is a summary of the International Committee on Taxonomy of Viruses (ICTV) Report on the taxonomy of the Partitiviridae, which is available at www.ictv.global/report/partitiviridae.

Identification of novel RNA viruses in alfalfa (Medicago sativa): an Alphapartitivirus, a Deltapartitivirus, and a Marafivirus.

Genomic RNA molecules of plant RNA viruses are often co-isolated with the host RNAs, and their sequences can be detected in plant transcriptome datasets. Here, an alfalfa (Medicago sativa) transcriptome dataset was analyzed and three new RNA viruses were identified, which were named Medicago sativa alphapartitivirus 1 (MsAPV1), Medicago sativa deltapartitivirus 1 (MsDPV1), and Medicago sativa marafivirus 1 (MsMV1). The RNA-dependent RNA polymerases of MsAPV1, MsDPV1, and MsMV1 showed about 68%, 58%, and 46% amino acid sequence identity, respectively, with their closest virus species. Sequence similarity and phylogenetic analyses indicated that MsAPV1, MsDPV1, and MsMV1 were novel RNA virus species that belong to the genus Alphapartitivirus of the family Partitiviridae, the genus Deltapartitivirus of the family Partitiviridae, and the genus Marafivirus of the family Tymoviridae, respectively. The bioinformatics procedure applied in this study may facilitate the identification of novel RNA viruses from plant transcriptome data.

A novel alphapartitivirus detected in Japanese pear.

Pyrus pyrifolia cryptic virus (PpCV) had been previously reported from Japanese pear (Pyrus pyrifolia). In analyses of Japanese pear, two other double-stranded (ds) RNA molecules (dsRNA4 and 5) were observed along with the three dsRNA segments from PpCV on an electrophoretic profile of isolated dsRNA. When the purified dsRNA sample was deep sequenced by a next-generation sequencer, two de novo assembled contigs corresponding to dsRNA4 and 5, with predicted amino acid sequences showing homologies to the RNA-dependent RNA polymerase and the capsid protein of Rose partitivirus, respectively, were found by BLAST analysis. The relationships between the two contigs and dsRNA4, 5 were confirmed by northern blot analyses with probes amplified using primers designed from the contigs. Terminal sequence analyses by rapid amplification of cDNA ends revealed that dsRNA4 and 5 were 1945 and 1788 bp long, respectively. The 5' terminal sequences (GUCAAAUU) of dsRNA4 and 5 were conserved. Based on genome size and phylogenetic analyses, the newly found virus is thought to be a member of the genus Alphapartitivirus. Thus, it has been designated as Pyrus pyrifolia partitivirus 2.

Two alphapartitiviruses co-infecting a single isolate of the plant pathogenic fungus Rhizoctonia solani.

Seven dsRNA segments were detected from a single Rhizoctonia solani strain HG81. From the full-length cDNA sequences of four smaller dsRNA segments, the genomes of two related partitiviruses, designated as Rhizoctonia solani partitivirus 3 (RsPV3) and RsPV4, were determined. The genomes of RsPV3 and RsPV4 are both composed of two separate dsRNA segments, with each segment possessing a single open reading frame (ORF). ORF1 from RsPV3 and RsPV4 encodes a putative RNA-dependent RNA polymerase, while ORF2 of RsPV3 and RsPV4 encodes a putative capsid protein. RsPV3 and RsPV4 share high sequence identity with viruses classified within the genus Alphapartitivirus, family Partitiviridae.

The challenges of using high-throughput sequencing to track multiple bipartite mycoviruses of wild orchid-fungus partnerships over consecutive years.

The bipartite alpha- and betapartitiviruses are recorded from a wide range of fungi and plants. Using a combination of dsRNA-enrichment, high-throughput shotgun sequencing and informatics, we report the occurrence of multiple new partitiviruses associated with mycorrhizal Ceratobasidium fungi, themselves symbiotically associated with a small wild population of Pterostylis sanguinea orchids in Australia, over two consecutive years. Twenty-one partial or near-complete sequences representing 16 definitive alpha- and betapartitivirus species, and further possible species, were detected from two fungal isolates. The majority of partitiviruses occurred in fungal isolates from both years. Two of the partitiviruses represent phylogenetically divergent forms of Alphapartitivirus, suggesting that they may have evolved under long geographical isolation there. We address the challenge of pairing the two genomic segments of partitiviruses to identify species when multiple partitiviruses co-infect a single host.

Genome Sequence of Spinach Cryptic Virus 1, a New Member of the Genus Alphapartitivirus (Family Partitiviridae), Identified in Spinach.

A distinct double-stranded RNA (dsRNA) cryptic virus, named spinach cryptic virus 1 (SpCV1), was identified from spinach transcriptome datasets. The SpCV1 genome has two dsRNA genome segments. The larger dsRNA1 has an open reading frame for a conserved RNA-dependent RNA polymerase (RdRp). The smaller dsRNA2 encodes a putative coat protein (CP). The sequence identity of SpCV1 RdRp and CP to the closest cryptic virus is 81% and 60%, respectively. Phylogenetic analysis indicates that SpCV1 is a novel member of the genus Alphapartitivirus (family Partitiviridae).

Natural infection of the soil-borne fungus Rosellinia necatrix with novel mycoviruses under greenhouse conditions.

Fungi are an important component of the soil ecosystem. Mycoviruses have numerous potential impacts on soil fungi, including phytopathogenic fungal species. However, the diversity and ecology of mycoviruses in soil fungi is largely unexplored. Our previous work has shown that the soil-borne phytopathogenic fungus Rosellinia necatrix was infected with several novel mycoviruses after growing for 2-3 years in an apple orchard. In this study, we investigated whether natural infection of R. necatrix with mycoviruses occurs under limited conditions. Virus-free R. necatrix isolates were grown in a small bucket containing soil samples for a short time (1.5-4.5 months) under greenhouse conditions. Screening of dsRNA mycoviruses among 365 retrieved isolates showed that four, including 6-31, 6-33, 6-35, and 7-11, harbored virus-like dsRNAs. Molecular characterization of the dsRNAs revealed that three retrieved isolates, 6-31, 6-33, and 6-35 were infected with a novel endornavirus and isolate 7-11 is infected with a novel partitivirus belonging to the genus Alphapartitivirus. These novel mycoviruses had no overt biological impact on R. necatrix. Overall, this study indicates that natural infections of R. necatrix with new mycoviruses can occur under experimental soil conditions.

A novel mycovirus closely related to viruses in the genus Alphapartitivirus confers hypovirulence in the phytopathogenic fungus Rhizoctonia solani.

We report here the biological and molecular attributes of a novel dsRNA mycovirus designated Rhizoctonia solani partitivirus 2 (RsPV2) from strain GD-11 of R. solani AG-1 IA, the causal agent of rice sheath blight. The RsPV2 genome comprises two dsRNAs, each possessing a single ORF. Phylogenetic analyses indicated that this novel virus species RsPV2 showed a high sequence identity with the members of genus Alphapartitivirus in the family Partitiviridae, and formed a distinct clade distantly related to the other genera of Partitiviridae. Introduction of purified RsPV2 virus particles into protoplasts of a virus-free virulent strain GD-118 of R. solani AG-1 IA resulted in a derivative isogenic strain GD-118T with reduced mycelial growth and hypovirulence to rice leaves. Taken together, it is concluded that RsPV2 is a novel dsRNA virus belonging to Alphapartitivirus, with potential role in biological control of R. solani.