Application of a Reverse Genetic System for Beet Necrotic Yellow Vein Virus to Study Rz1 Resistance Response in Sugar Beet

Liebe, Sebastian; Wibberg, Daniel; Maiß, E.; Varrelmann, Mark

doi:10.3389/fpls.2019.01703

Cited by 18 publications

(35 citation statements)

References 52 publications

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“…Galein et al (2018) examined the variability and pathogenicity of BNYVV isolates from an area containing A-, B-and P-types, and found that P-type virus (with RNA5) showed the highest aggressiveness, although there is the complexity of genome reassortments between different types of BNYVV strains. Furthermore, Liebe et al (2020) showed that the presence of P-type RNA5 in the background of the A-type virus clone increased virus accumulation in the resistant plants, suggesting that this P-type RNA5 is involved in Rz1-RB. The present study here has provided more definite evidence on the effect of RNA3 and RNA5 on virus accumulation levels in Rz1-RB.…”

Section: Discussionmentioning

confidence: 98%

Pathogenetic roles of beet necrotic yellow vein virus RNA5 in the exacerbation of symptoms and yield reduction, development of scab‐like symptoms, and Rz1‐resistance breaking in sugar beet

Tamada

Uchino

Kusume³

et al. 2020

Plant Pathology

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Beet necrotic yellow vein virus (BNYVV) generally has a four-segmented positivesense RNA genome (RNAs 1-4), but some European and most Asian strains have an additional segment, RNA5. This study examined the effect of RNA5 and RNA3 on different sugar beet cultivars using a Polymyxa-mediated inoculation system under field and laboratory conditions. In field tests, the degree of sugar yield served as an index for assessing the virulence of BNYVV strains. Japanese A-II type isolates without RNA5 caused mostly 15%-90% sugar yield reductions, depending on the susceptibility of sugar beet cultivars, whereas the isolates with RNA5 induced more than 90% yield losses in the seven susceptible cultivars, but small yield losses in one Rz1-resistant and Rizor cultivars. However, a laboratory-produced isolate containing RNA5 but lacking RNA3 caused higher yield losses in Rizor than in susceptible plants, and induced scab-like symptoms on the root surface of both susceptible and resistant plants. In laboratory tests, A-II type isolates without RNA5 had low viral RNA accumulation levels in roots of Rizor and Rz1-resistant plants at early stages of infection, but in the presence of RNA5, viral RNA3 accumulation levels increased remarkably. This increased RNA3 accumulation was not observed in roots of the WB42 accession with the Rz2 gene. In contrast, the presence of RNA3 did not affect RNA5 accumulation levels. Collectively, this study demonstrated that RNA5 is involved in the development of scab-like symptoms and the enhancement of RNA3 accumulation, and suggests these characteristics of RNA5 are associated with Rz1-resistance breaking.

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Section: Discussionmentioning

confidence: 98%

Pathogenetic roles of beet necrotic yellow vein virus RNA5 in the exacerbation of symptoms and yield reduction, development of scab‐like symptoms, and Rz1‐resistance breaking in sugar beet

Tamada

Uchino

Kusume³

et al. 2020

Plant Pathology

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“…The nucleotides at this location are considered to be among the most hypervariable within all eukaryotic viruses [ 25 , 34 , 43 ], a feature observed in our own recent study [ 17 ]. Moreover, recent associative [ 16 , 17 , 34 ] and functional [ 5 , 44 ] evidence suggests that variability in this region may account for the ability for some strains of the virus to circumvent dominant resistance genes in the sugar beet crop. As additional cases exist where a specific tetrad has been observed in both Rz-gene controlled and Rz-gene breaking isolates (e.g., tetrad ACHG [ 17 ]), it is possible that other changes in the genome may operate in conjunction with mutations in the tetrad motif or independent of this element in compromising host resistance.…”

Section: Discussionmentioning

confidence: 99%

“…The two largest RNAs of the BNYVV genome, RNAs 1 and 2, collectively represent over 70% of the virus genome and encode the replication, packaging, cell–cell movement, and silencing suppression functions of the virus. In contrast to most other biologically-active clones of BNYVV that provide infection through transient genome transcription consequent to Agrobacterium infiltration (i.e., “agro-infection”; [ 44 , 45 , 46 ]), we chose to employ in vitro production of capped RNA transcriptions as the means to produce inoculum for the infection in recipient cells in a manner more consistent with that found in nature. Along with previous reports of others who used NGS data in the construction of clones from which infectious RNA was produced either through in vitro transcription or via agro-infection [ 47 ], our study validates this approach in constructing clones for the study of BNYVV.…”

Section: Discussionmentioning

confidence: 99%

RNAseq Analysis of Rhizomania-Infected Sugar Beet Provides the First Genome Sequence of Beet Necrotic Yellow Vein Virus from the USA and Identifies a Novel Alphanecrovirus and Putative Satellite Viruses

Weiland

Poudel

Flobinus

et al. 2020

Viruses

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“Rhizomania” of sugar beet is a soilborne disease complex comprised of beet necrotic yellow vein virus (BNYVV) and its plasmodiophorid vector, Polymyxa betae. Although BNYVV is considered the causal agent of rhizomania, additional viruses frequently accompany BNYVV in diseased roots. In an effort to better understand the virus cohort present in sugar beet roots exhibiting rhizomania disease symptoms, five independent RNA samples prepared from diseased beet seedlings reared in a greenhouse or from field-grown adult sugar beet plants and enriched for virus particles were subjected to RNAseq. In all but a healthy control sample, the technique was successful at identifying BNYVV and provided sequence reads of sufficient quantity and overlap to assemble > 98% of the published genome of the virus. Utilizing the derived consensus sequence of BNYVV, infectious RNA was produced from cDNA clones of RNAs 1 and 2. The approach also enabled the detection of beet soilborne mosaic virus (BSBMV), beet soilborne virus (BSBV), beet black scorch virus (BBSV), and beet virus Q (BVQ), with near-complete genome assembly afforded to BSBMV and BBSV. In one field sample, a novel virus sequence of 3682 nt was assembled with significant sequence similarity and open reading frame (ORF) organization to members within the subgenus Alphanecrovirus (genus Necrovirus; family Tombusviridae). Construction of a DNA clone based on this sequence led to the production of the novel RNA genome in vitro that was capable of inducing local lesion formation on leaves of Chenopodium quinoa. Additionally, two previously unreported satellite viruses were revealed in the study; one possessing weak similarity to satellite maize white line mosaic virus and a second possessing moderate similarity to satellite tobacco necrosis virus C. Taken together, the approach provides an efficient pipeline to characterize variation in the BNYVV genome and to document the presence of other viruses potentially associated with disease severity or the ability to overcome resistance genes used for sugar beet rhizomania disease management.

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“…Severe disease symptoms are the reduced size of the roots and typical constrictions (funnel or ‘wineglass’‐like shape) of the infected taproots sometimes with nodules (small tumorous growths) along the taproot. Necrosis of vascular tissues (Figure 1) (Liebe et al., 2020) starting with a pale yellow to dark brown discoloration and necrotic rings may also occur. In less heavily infested plants, symptoms may affect only one lateral root of the plant (McGrann et al., 2009; Rush et al., 2006; Neher and Gallian, 2014; EPPO, 2006).…”

Section: Pest Categorisationmentioning

confidence: 99%

Pest categorisation of beet necrotic yellow vein virus

Dehnen‐Schmutz¹,

Serio²,

Gonthier³

et al. 2020

EFS2

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Following a request from the EU Commission, the Panel on Plant Health performed a categorisation of beet necrotic yellow vein virus ( BNYVV ), the causal agent of the sugar beet rhizomania disease. The virus is currently listed in Annex III as a protected zone ( PZ ) quarantine pest of the Commission Implementing Regulation ( EU ) 2019/2072. The identity of the BNYVV is well established. BNYVV is a soil‐borne virus transmitted by the obligate root plasmodiophorid endoparasite Polymyxa betae . BNYVV is widely distributed in the EU , but is not reported in the following EU PZ s: Ireland, France (Brittany), Portugal (Azores), Finland and Northern Ireland. The virus may enter, become established and spread in the PZ s via P. betae resting spores with soil and growing media as such or attached to machinery and with roots and tubercles of species other than B. vulgaris and with plants for planting. Introduction of BNYVV would have a negative impact on sugar beet and other beet crops in PZ s, because of yield and sugar content reduction. Phytosanitary measures are available to reduce the likelihood of entry and spread in the PZ s. Once the virus and its plasmodiophorid vector have entered a PZ , their eradication would be difficult due to the persistence of viruliferous resting spores in the soil. The main knowledge gaps or uncertainties identified concerning the presence of BNYVV in the PZ s and the incidence and distribution of BNYVV in Switzerland, a country to which a range of specific requirements do not apply. BNYVV meets all the criteria that are within the remit of EFSA to qualify as a potential protected zone union quarantine pest. Plants for planting are not considered as a main means of spread, and therefore BNYVV does not satisfy all the criteria evaluated by EFSA to qualify as potential Union regulated non‐quarantine pest.

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Application of a Reverse Genetic System for Beet Necrotic Yellow Vein Virus to Study Rz1 Resistance Response in Sugar Beet

Cited by 18 publications

References 52 publications

Pathogenetic roles of beet necrotic yellow vein virus RNA5 in the exacerbation of symptoms and yield reduction, development of scab‐like symptoms, and Rz1‐resistance breaking in sugar beet

Pathogenetic roles of beet necrotic yellow vein virus RNA5 in the exacerbation of symptoms and yield reduction, development of scab‐like symptoms, and Rz1‐resistance breaking in sugar beet

RNAseq Analysis of Rhizomania-Infected Sugar Beet Provides the First Genome Sequence of Beet Necrotic Yellow Vein Virus from the USA and Identifies a Novel Alphanecrovirus and Putative Satellite Viruses

Pest categorisation of beet necrotic yellow vein virus

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