The Amino-Proximal Region of the Coat Protein of Cucumber Vein Yellowing Virus (Family Potyviridae) Affects the Infection Process and Whitefly Transmission

Most plant viruses rely on vector transmission for their spread and specific interactions between vector and virus have evolved to regulate this relationship. The whitefly Bemisia tabaci- transmitted cucumber vein yellowing virus (CVYV; genus Ipomovirus, family Potyviridae) is endemic in the Mediterranean Basin, where it causes significant losses in cucurbit crops. In this study, the role of the coat protein (CP) of CVYV for B. tabaci transmission and plant infection was investigated using a cloned and infectious CVYV cDNA and a collection of point and deletion mutants derived from this clone. Whitefly transmission of CVYV was abolished in a deletion mutant lacking amino acids in position 93–105 of the CP. This deletion mutant caused more severe disease symptoms compared to the cDNA clone representing the wild-type (wt) virus and movement efficiency was likewise affected. Two virus mutants carrying a partially restored CP were transmissible and showed symptoms comparable to the wt virus. Collectively, our data demonstrate that the N-terminus of the CVYV CP is a determinant for transmission by the whitefly vector and is involved in plant infection and symptom expression.

An Importin-β-like Protein from Nicotiana benthamiana Interacts with the RNA Silencing Suppressor P1b of the Cucumber Vein Yellowing Virus, Modulating Its Activity

During a plant viral infection, host–pathogen interactions are critical for successful replication and propagation of the virus through the plant. RNA silencing suppressors (RSSs) are key players of this interplay, and they often interact with different host proteins, developing multiple functions. In the Potyviridae family, viruses produce two main RSSs, HCPro and type B P1 proteins. We focused our efforts on the less known P1b of cucumber vein yellowing virus (CVYV), a type B P1 protein, to try to identify possible factors that could play a relevant role during viral infection. We used a chimeric expression system based on plum pox virus (PPV) encoding a tagged CVYV P1b in place of the canonical HCPro. We used that tag to purify P1b in Nicotiana-benthamiana-infected plants and identified by mass spectrometry an importin-β-like protein similar to importin 7 of Arabidopsis thaliana. We further confirmed the interaction by bimolecular fluorescence complementation assays and defined its nuclear localization in the cell. Further analyses showed a possible role of this N. benthamiana homolog of Importin 7 as a modulator of the RNA silencing suppression activity of P1b.

Potato yellowing virus. [Distribution map].

A new distribution map is provided for Potato yellowing virus. Bromoviridae: Ilarvirus. Hosts: potato (Solanum tuberosum), wild Solanum spp. Information is given on the geographical distribution in South America (Bolivia, Chile, Colombia, Ecuador, Peru).

Specificity of resistance and tolerance to cucumber vein yellowing virus in melon accessions and evidence for resistance breaking associated with a single mutation in VPg

Cucumber vein yellowing virus (CVYV) is an emerging virus on cucurbits in the Mediterranean Basin, against which few resistance sources are available, particularly in melon. The melon accession PI 164323 displays complete resistance to isolate CVYV-Esp, and accession HSD 2458 presents a tolerance, i.e. very mild symptoms in spite of virus accumulation in inoculated plants. The resistance is controlled by a dominant allele Cvy-11, while the tolerance is controlled by a recessive allele cvy-2, independent from Cvy-11. Before introducing the resistance or tolerance in commercial cultivars through a long breeding process, it is important to estimate their specificity and durability. Upon inoculation with eight molecularly diverse CVYV isolates, the resistance was found to be isolate-specific since many CVYV isolates induced necrosis on PI 164323, whereas the tolerance presented a broader range. A resistance-breaking isolate inducing severe mosaic on PI 164323 was obtained. This isolate differed from the parental strain by a single amino acid change in the VPg coding region. An infectious CVYV cDNA clone was obtained, and the effect of the mutation in the VPg cistron on resistance to PI 164323 was confirmed by reverse genetics. This represents the first determinant for resistance-breaking in an ipomovirus. Our results indicate that the use of the Cvy-11 allele alone will not provide durable resistance to CVYV and that, if used in the field, it should be combined with other control methods such as cultural practices and pyramiding of resistance genes to achieve long-lasting resistance against CVYV.

Complete genome sequence and construction of an infectious full-length cDNA clone of a cucumber vein yellowing virus (CVYV) isolate from Portugal

Cucumber vein yellowing virus (CVYV) is a member of the genus Ipomovirus in the family Potyviridae. In the National Center for Biotechnology Information (NCBI) database, three complete genome sequences of CVYV isolates from Spain (NC_006941), Israel (KT276369), and Jordan (JF460793) are available. In this study, we report the complete sequence of an isolate of CVYV from Portugal (DSMZ PV-0776) along with the construction of an infectious full-length cDNA clone via Gibson assembly. The sequence of CVYV Portugal shows the closest relationship to a CVYV isolate from Spain (genome, 99.7% identity; polyprotein, 99.7% identity). The CVYV full-length cDNA clone was introduced by electroporation into Rhizobium radiobacter and infiltrated into the cotyledons of Cucumis sativus plantlets, resulting in symptoms resembling those of the wild-type virus. Transmission of the infectious CVYV full-length clone by the whitefly Bemisia tabaci was confirmed. This first report confirming the infectivity of a CVYV cDNA clone provides the opportunity to study gene functions in a consistent genomic background.

Spread of bacterial and virus yellowing diseases of sugar beet in South and Central Germany from 2017–2020

From 2017 to 2020 an extensive monitoring for bacterial and viral yellowing diseases was carried out in southern and central Germany. The monitoring recorded for the first time the infestation of sugar beets with yellowing viruses and the disease „Syndrome Basses Richesses“ (SBR). To map the yellowing virus infestation, samples were examined for the presence of several virus species (BYV, BtMV, poleroviruses). The disease SBR was investigated in this study using the more common γ-3 proteobacterium “Candidatus Arsenophonus phytopathogenicus”. In this study samples were chosen, which showed yellowing symptoms. The coordination of the sampling was carried out by the Association of Hessian-Palatinate Sugar Beet Growers. Results clearly show the extent of the heavily infested area from SBR to southern Hesse, Rhine-Hesse and Franconia. The spread of SBR can be explained by the migration of the leafhopper Pentastiridius leporinus. Furthermore, the regional and parallel spread of mixed infections of both yellowing diseases was shown for the first time, which probably contributed to the strong sugar yield losses observed in practice. Causes and effects of mixed infections of both yellowing diseases require further research. Over the four-year study period, a continuous increase in SBR infections was observed. Therefore, the need for development of appropriate management systems to control SBR is very high.

First report of Cnidium officinale as a natural host plant of Apple stem grooving virus in South Korea

Cnidium officinale is a perennial plant in the family Apiaceae. It is native to China and cultivated in China, Japan, and Korea for its roots for medicinal purposes. In August 2019, 63 C. officinale plants showing symptoms of vein chlorosis, yellowing and chlorotic spots (Supplementary Fig. 1) were collected from commercial farms in Bonghwa and Youngyang, Gyeongsangbuk-do, South Korea. Reverse transcription and polymerase chain reaction (RT-PCR) was performed to confirm the presence of apple stem grooving virus (ASGV), cnidium vein yellowing virus 1, cnidium vein yellowing virus 2, lychnis mottle virus, and Cnidium virus X with specific primers (Supplementary Table 1). Forty-one out of the sixty-three samples were positive for ASGV in mixed infection with one or more of the other four viruses. Nicotiana benthamiana plants mechanically inoculated with the crude sap of one of the ASGV-infected C. officinale plants showed mosaic symptom on upper leaves 10 days post inoculation (dpi). Infection was confirmed by RT-PCR and Sanger sequencing. N. benthamiana plants systemically infected with ASGV-CO-kr1 isolate alone were used for subsequent sequencing and host range test. Twenty-day old seedlings of 23 species of plants (two to 14 species for each family) from the families Solanaceae, Chenopodiaceae, Cucurbitaceae, Fabaceae and Amaranthaceae (Supplementary Table 2) were mechanically inoculated with sap of ASGV-CO-kr1-infected N. benthamiana plants. ASGV-CO-kr1 infected all tested 23 species as confirmed by symptomology, RT-PCR, and Sanger sequencing at 10 to 20 dpi. The MP and CP genes of ASGV-CO-kr1 were amplified by RT-PCR with specific primers 4300-4325F/5642-5666R and 5592-5612F/6475-6499R, respectively (Supplementary Table 1). The amplicons were cloned and sequenced (GenBank accession numbers: MP = MW889883 and CP = MW889884). Multiple sequence alignment using the MegAlign program in DNASTAR showed that the complete CP and MP genes of ASGV-CO-kr1 shared 89.9%-99.7% and 83.1%-99.5% identities, respectively at the nucleotide (nt) level and they shared 92.4%-99.6% and 93.8%-99.4% identities, respectively at amino acid (aa) level with corresponding sequences of 34 other ASGV isolates from various host plants and countries. Phylogenetic analysis with the Maximum Likelihood method using the MEGA X program (Kumar et al., 2018) showed that ASGV-CO-kr1 grouped with isolates Cuiguan (KR185346), BH (LC480456), and YY (LC480457) based on the CP aa sequences, while it grouped with isolates SG (LC475148) and TL101 (MH108976) based on the MP aa sequences. ASGV is known to naturally infect apples, European pear, Asian pear, citrus, apricot, cherry, kiwifruit, loquat, lily, and lotus (Clover et al., 2003; He et al., 2019; Hu et al., 2017; Liu et al., 2017; Yanase et al., 1975). To the best of our knowledge, this is the first report of the natural infection of ASGV in C. officinale. C. officinale plants are propagated by root division, so they are susceptible to infection with viruses. The result of this study is important for generating virus-free seedlings to produce C. officinale.

First Report of Macrophomina phaseolina, Fusarium brachygibbosum, and Lasiodiplodia theobromae Causing Fungal Watermelon Vine Decline in Southwest and West-Central Florida

Wilt and vine decline symptoms were observed on watermelon plants in Glades and Hardee Counties in Florida in spring 2017 that resembled viral watermelon vine decline caused by squash vein yellowing virus (SqVYV). When no SqVYV was detected, greenhouse studies and morphological and molecular analyses revealed three fungal pathogens, Macrophomina phaseolina, Fusarium brachygibbosum, and Lasiodiplodia theobromae, that were not previously reported on watermelon in Florida. A previously reported oomycete, Pythium spinosum, was also detected in some, but not all isolates, and but when applied independently, resulted in disease incidence that was comparable to the untreated check, ruling it out as a primary causal agent of the symptoms observed in the field. In one of three experiments, seedlings inoculated with a combination of Macrophomina phaseolina, Fusarium brachygibbosum, and Pythium spinosum suffered the highest disease severity based on AUDPC values. In another experiment, seedlings inoculated with F. brachygibbosum exhibited the most severe symptoms and rapid disease development following inoculation. When seeds were inoculated with either a single or a combination of the isolated fungi, those inoculated with L. theobromae resulted in seedlings with the greatest disease severity. This is the first report of these three fungal pathogens on watermelon in Florida.

First report of squash vein yellowing virus naturally infecting butternut squash (Cucurbita moschata) in Texas

Virus diseases are major constraints to the production of cucurbits in the Texas Lower Rio Grande Valley. In September 2020, a ~8.1 ha butternut squash (Cucurbita moschata) field in Hidalgo County, Texas, was observed with virus-like symptoms of vein yellowing, leaf curl, mosaic, and foliar chlorosis. The proportion of plants with virus-like symptoms in this field was estimated at 30% and seven samples (symptomatic = 5; non-symptomatic = 2) were collected randomly for virus diagnosis. Initially, equimolar mixtures of total nucleic acid extracts (Dellaporta et. al. 1983) from two symptomatic samples from this field and extracts from 12 additional symptomatic samples from six other fields across south and central Texas was used to generate one composite sample for diagnosis by high throughput sequencing (HTS). The TruSeq Stranded Total RNA with Ribo-Zero Plant Kit (Illumina) was used to construct cDNA library from the composite sample, which was then sequenced on the Illumina NextSeq 500 platform. More than 26 million single-end HTS reads (75 nt each) were obtained and their bioinformatic analyses (Al Rwahnih et al. 2018) revealed several virus-like contigs belonging to different species (data not shown). Among them, 6 contigs that ranged in length from 429 to 3,834 nt shared 96 to 100% identities with isolates of squash vein yellowing virus (SqVYV), genus Ipomovirus, family Potyviridae. To confirm the HTS results, total nucleic acid extracts from the cucurbit samples from all seven fields (n = 46) were used for cDNA synthesis with random hexamers and the PrimeScript 1st strand cDNA Synthesis Kit (Takara Bio). A 1-μL aliquot of cDNA was used in 12.5-μL PCR reaction volumes with PrimeSTAR GXL DNA Polymerase (Takara Bio) and two pairs of SqVYV-specific primers designed based on the HTS derived contigs. The primer pairs SqYVV-v4762: 5′-CTGGATTCTGCTGGAAGATCA & SqYVV-c5512: 5′-CCACCATTAAGGCCATCAAAC and SqYVV-v8478: 5′-TTTCTGGGCAAACAAACATGG & SqYVV-c9715: 5′-TTCAGCGACGTCAAGTGAG targeted ~0.75 kb and ~1.2 kb fragments of the cylindrical inclusion (CI) and the complete coat protein (CP) gene sequences of SqVYV, respectively. The expected DNA band sizes were obtained only from the five symptomatic butternut squash samples from the Hidalgo Co. field. Two amplicons per primer pair from two samples were cloned into pJET1.2/Blunt vector (Life Technologies) and bidirectionally Sanger sequenced, generating 753 nt partial CI specific sequences (MW584341-342) and 1,238 nt that encompassed the complete CP (MW584343-344) of SqVYV. In pairwise comparisons, the partial CI sequences shared 100% nt/aa identity with each other and 98-99% nt/aa identity with corresponding sequences of SqVYV isolate IL (KT721735). The CP cistron of TX isolates shared 100% nt/aa identity with each other and 90-98% nt (97-100% aa) identities with corresponding sequences of several SqVYV isolates in GenBank, with isolates IL (KT721735) and Florida (EU259611) being at the high and low spectrum of nt/aa identity values, respectively. This is the first report of SqVYV in Texas, naturally occurring in butternut squash. SqVYV was first discovered in Florida (Adkins et al. 2007) and subsequently reported from few other states in the U.S. (Adkins et al. 2013; Egel and Adkins 2007; Batuman et al. 2015), Puerto Rico (Acevedo et al. 2013), and locations around the world. The finding shows an expansion of the geographical range of SqVYV and adds to the repertoire of cucurbit-infecting viruses in Texas. Further studies are needed to determine the prevalence of SqVYV in Texas cucurbit fields and an assessment of their genetic diversity.