Integrating High throughput Sequencing into Survey Design Reveals Turnip Yellows Virus and Soybean Dwarf Virus in Pea (Pisum Sativum) in the United Kingdom

There is only limited knowledge of the presence and incidence of viruses in peas within the United Kingdom, therefore high-throughput sequencing (HTS) in combination with a bulk sampling strategy and targeted testing was used to determine the virome in cultivated pea crops. Bulks of 120 leaves collected from twenty fields from around the UK were initially tested by HTS, and presence and incidence of virus was then determined using specific real-time reverse-transcription PCR assays by testing smaller mixed-bulk size samples. This study presents the first finding of turnip yellows virus (TuYV) in peas in the UK and the first finding of soybean dwarf virus (SbDV) in the UK. While TuYV was not previously known to be present in UK peas, it was found in 13 of the 20 sites tested and was present at incidences up to 100%. Pea enation mosaic virus-1, pea enation mosaic virus-2, pea seed-borne mosaic virus, bean yellow mosaic virus, pea enation mosaic virus satellite RNA and turnip yellows virus associated RNA were also identified by HTS. Additionally, a subset of bulked samples were re-sequenced at greater depth to ascertain whether the relatively low depth of sequencing had missed any infections. In each case the same viruses were identified as had been identified using the lower sequencing depth. Sequencing of an isolate of pea seed-borne mosaic virus from 2007 also revealed the presence of TuYV and SbDV, showing that both viruses have been present in the UK for at least a decade, and represents the earliest whole genome of SbDV from Europe. This study demonstrates the potential of HTS to be used as a surveillance tool, or for crop-specific field survey, using a bulk sampling strategy combined with HTS and targeted diagnostics to indicate both presence and incidence of viruses in a crop.

Quantitative Trait Locus Mapping of Resistance to Turnip Yellows Virus in Brassica rapa and Brassica oleracea and Introgression of These Resistances by Resynthesis Into Allotetraploid Plants for Deployment in Brassica napus

Turnip yellows virus (TuYV) is aphid-transmitted and causes considerable yield losses in oilseed rape (OSR, Brassica napus, genome: AACC) and vegetable brassicas. Insecticide control of the aphid vector is limited due to insecticide resistance and the banning of the most effective active ingredients in the EU. There is only one source of TuYV resistance in current commercial OSR varieties, which has been mapped to a single dominant quantitative trait locus (QTL) on chromosome A04. We report the identification, characterisation, and mapping of TuYV resistance in the diploid progenitor species of OSR, Brassica rapa (genome: AA), and Brassica oleracea (genome: CC). Phenotyping of F1 populations, produced from within-species crosses between resistant and susceptible individuals, revealed the resistances were quantitative and partially dominant. QTL mapping of segregating backcross populations showed that the B. rapa resistance was controlled by at least two additive QTLs, one on chromosome A02 and the other on chromosome A06. Together, they explained 40.3% of the phenotypic variation. In B. oleracea, a single QTL on chromosome C05 explained 22.1% of the phenotypic variation. The TuYV resistance QTLs detected in this study are different from those in the extant commercial resistant varieties. To exploit these resistances, an allotetraploid (genome: AACC) plant line was resynthesised from the interspecific cross between the TuYV-resistant B. rapa and B. oleracea lines. Flow cytometry confirmed that plantlets regenerated from the interspecific cross had both A and C genomes and were mixoploid. To stabilise ploidy, a fertile plantlet was self-pollinated to produce seed that had the desired resynthesised, allotetraploid genome AACC. Phenotyping of the resynthesised plants confirmed their resistance to TuYV. Genotyping with resistance-linked markers identified during the mapping in the progenitors confirmed the presence of all TuYV resistance QTLs from B. rapa and B. oleracea. This is the first report of TuYV resistance mapped in the Brassica C genome and of an allotetraploid AACC line possessing dual resistance to TuYV originating from both of its progenitors. The introgression into OSR can now be accelerated, utilising marker-assisted selection, and this may reduce selection pressure for TuYV isolates that are able to overcome existing sources of resistance to TuYV.

Strawberry, a new natural host of Brassica yellows virus in China

Brassica yellows virus (BrYV; genus Polerovirus, family Solemoviridae) has an icosahedral spherical virion with a positive-sense single-stranded RNA genome and it is distinguished from turnip yellows virus (TuYV) based on differences in ORF0 and ORF5 (Xiang et al., 2011). To investigate the occurrence and distribution of viruses infecting strawberry (Fragaria ananassa) in the main production areas in China, a survey of nine greenhouses (667 m2 each) was conducted in the cities of Yantai and Beijing, China in August 2020. About 1% of strawberry plants in each greenhouse showed virus-like symptoms of chlorotic spots; 89 symptomatic leaf samples were randomly collected for virus testing. Total RNA was extracted from a pool of eight samples of four different cultivars (Hokowase: 2, Mibao: 2, Sagahonoka: 2, Monterey: 2) from Yantai using RNAprep Pure Plant Plus Kit (TianGen, China). A cDNA library was constructed by NEBNext® Ultra™ Directional RNA Library Prep Kit for Illumina® (NEB, USA) after ribosomal RNA-depletion using an Epicentre Ribo-Zero™ rRNA Removal Kit (Epicentre, USA). High-throughput sequencing was done on Illumina Hiseq 4000, generating 70,931,850 high-quality 150 bp paired-end reads. Clean reads were de novo assembled by Trinity (v2.2.0) and the resulting contigs were screened by BLASTn and BLASTx against GenBank database as described previously (Grabherr et al., 2013). A total of 1,432,164 high-quality reads unmapped to the strawberry genome were obtained and assembled into 93 contigs (ranging from 33 to 8,031 nt). Seven of these contigs (277 to 1,254 nt) shared 98.2 to 100% nt identities with BrYV-A (accession no. HQ388348) and covered 89.5% of the genome of BrYV-A. Subsequent analyses indicated the presence of Strawberry pallidosis-associated virus and Strawberry mottle virus in the analyzed sample, both have been reported in strawberry in China (Shi et al., 2018; Fan et al., 2021). To confirm BrYV infection, total RNA was isolated from the eight samples used for HTS and reverse transcription polymerase chain reaction (RT-PCR) was conducted with two pairs of specific primers (CP and rtp, Supplementary Table 1) designed based on the assembled contigs. PCR products with expected sizes (587 and 609 bp) were observed in one sample (cv. Mibao). BLASTn analysis indicated that the amplicons (accession no. MW548437 and MW548438) shared 98.6% and 99.3% nt identity with BrYV-A, respectively. To obtain the complete sequence of the putative BrYV isolate, the gaps were bridged and the terminal sequences were determined using 5ʹ and 3ʹ RACE kits (Clontech, China) based on the assembled contigs. The complete genome sequence of the putative BrYV isolate has a length of 5,666 nt (accession no. MZ666129) and shares more than 94.3% nt identities with other BrYV isolates. Phylogenetic analysis indicated that the isolate grouped closely with BrYV and further from TuYV (Figure S1). In addition, 11 samples (cv. Benihoppe) of the remaining 81 symptomatic strawberry samples tested positive for BrYV by RT-PCR with the two pairs of primers mentioned above. The sequences (accession no. MZ407232 and MZ407233) revealed 99.5% and 99.3% nt identities with MW548437 and MW548438. To the best of our knowledge, this is the first report of natural infection of BrYV in strawberry plants. Our findings expand the host range of BrYV, but disease association is difficult to establish due to presence of mixed infection and non-fulfillment of Koch's postulates.

Molecular features of RNA silencing against phloem-restricted polerovirus TuYV enable amplification of silencing signal from host transcripts

In plants and some animal lineages, RNA silencing is an efficient and adaptable defense mechanism against viruses. To counter it, viruses encode suppressor proteins that interfere with RNA silencing. Phloem-restricted viruses are spreading at an alarming rate and cause substantial reduction of crop yield, but how they interact with their hosts at the molecular level is still insufficiently understood. Here, we investigate the antiviral response against phloem-restricted turnip yellows virus (TuYV) in the model plant Arabidopsis thaliana. Using a combination of genetics, deep sequencing, and mechanical vasculature enrichment, we show that the main axis of silencing active against TuYV involves 22-nt vsiRNA production by DCL2, and their preferential loading into AGO1. Unexpectedly, and despite the viral encoded VSR P0 previously shown to mediate degradation of AGO proteins, vascular AGO1 undergoes specific post-translational stabilization during TuYV infection. We also identify vascular novel secondary siRNA produced from conserved plant transcripts and initiated by DCL2-processed AGO1-loaded vsiRNA, supporting a viral strategy to modulate host response. Collectively, our work uncovers the complexity of antiviral RNA silencing against phloem-restricted TuYV and prompts a re-assessment of the role of its suppressor of silencing P0 during genuine infection

Fine Characterization of a Resistance Phenotype by Analyzing TuYV-Myzus persicae-Rapeseed Interactions

Turnip yellows virus (TuYV), transmitted by Myzus persicae, can be controlled in rapeseed fields by insecticide treatments. However, the recent ban of the neonicotinoids together with the description of pyrethrinoid-resistant aphids has weakened insecticide-based control methods available to farmers. Since the deployment of insecticides in the 1980s, few research efforts were made to breed for rapeseed cultivars resistant to aphid-borne viral diseases. Thus, only few rapeseed cultivars released in Europe were reported to be TuYV-resistant, and the resistance phenotype of these cultivars was poorly characterized. In this study, several epidemiological parameters (infection rate, latency period, etc.) associated to the TuYV-resistance of the cv. Architect were estimated. Results showed a partial resistance phenotype for plants inoculated at the 2-/4-leaves stages and a resistance phenotype for plants inoculated at a more advanced growing stage. Moreover, analysis of infected plants highlighted (i) a poor quality of infected cv. Architect as a source of virus for transmission and (ii) an extended latency period for infected plants. Thus, dynamics of virus spread in the field should to be slower for Architect compared to susceptible rapeseed cultivars, which should lead to the maintenance of a higher proportion of healthy plants in the field.

Novel sources of turnip yellows virus resistance in Brassica and impacts of temperature on their durability

Turnip yellows virus (TuYV; family Solemoviridae, genus Polerovirus) is the most widespread and economically damaging virus of canola (Brassica napus L.) production in Australia. However, no Australian commercial seed companies currently market TuYV-resistant canola cultivars and little information is available on the susceptibility of those available. To identify potential sources of TuYV resistance, 100 B. napus accessions from the ERANET-ASSYST diversity set were screened in the field and five of these were selected for further phenotyping via aphid inoculation. Furthermore, 43 Australian canola cultivars, six B. napus genotypes with previously reported resistance, and 33 B. oleracea and B. rapa cultivars were phenotyped. All Australian cultivars were susceptible except for ATR Stingray. Stronger resistance to TuYV infection (IR) was identified in diversity set accessions Liraspa-A, SWU Chinese 3 and SWU Chinese 5. As indicated by lower relative ELISA absorbance values (R-E405) in infected plants, resistance to TuYV accumulation (AR) often accompanied IR. Moderate IR was identified in four B. oleracea and one B. rapa cultivars. Very strong AR was identified in four B. oleracea cultivars and AR of some degree was common across many cultivars of this species tested. The impact of temperature during the inoculation access period or post-inoculation incubation on the resistance identified was examined. Infection rates were significantly higher in resistant B. napus genotypes when inoculated at 16°C than at 26°C suggesting an increase in aphid transmission efficiency. IR in B. napus genotypes was strong when incubated at 16°C but weakened at elevated temperatures with almost total breakdown in most genotypes at 30°C. However, infected plants of B. napus and B. oleracea genotypes with AR maintained lower R-E405 than susceptible controls at all temperatures tested. Novel sources of resistance identified in this study offer potential as breeding material in Australia and abroad.

Feeding Behavior and Virus-transmission Ability of Insect Vectors Exposed to Systemic Insecticides

The majority of plant viruses depend on Hemipteran vectors for their survival and spread. Effective management of these insect vectors is crucial to minimize the spread of vector-borne diseases, and to reduce crop damage. The aim of the present study was to evaluate the effect of various systemic insecticides on the feeding behavior of Bemisia tabaci and Myzus persicae, as well as their ability to interfere with the transmission of circulative viruses. The obtained results indicated that some systemic insecticides have antifeeding properties that disrupt virus transmission by their insect vectors. We found that some of the tested insecticides significantly reduced phloem contact and sap ingestion by aphids and whiteflies, activities that are closely linked to the transmission of phloem-limited viruses. These systemic insecticides may play an important role in reducing the primary and secondary spread of tomato yellow leaf curl virus (TYLCV) and turnip yellows virus (TuYV), transmitted by B. tabaci and M. persicae, respectively.