Rice yellow mottle virus (RYMV) causes high losses to rice production in Africa. Several sources of varietal high resistance are available but the emergence of virulent pathotypes that are able to overcome one or two resistance alleles can sometimes occur. Both resistance spectra and viral adaptability have to be taken into account to develop sustainable rice breeding strategies against RYMV. In this study, we extended previous resistance spectrum analyses by testing the rymv1-4 and rymv1-5 alleles that are carried by the rice accessions Tog5438 and Tog5674, respectively, against isolates that are representative of RYMV genetic and pathogenic diversity. Our study revealed a hypervirulent pathotype, named thereafter pathotype T9, that is able to overcome all known sources of high resistance. This pathotype, which is spatially localized in West-Central Africa, appears to be more abundant than previously suspected. To better understand the adaptive processes of pathotype T9, molecular determinants of resistance breakdown were identified via Sanger sequencing and validated through directed mutagenesis of an infectious clone. These analyses confirmed the key role of convergent nonsynonymous substitutions in the central part of the viral genome-linked protein to overcome RYMV1-mediated resistance. In addition, deep-sequencing analyses revealed that resistance breakdown does not always coincide with fixed mutations. Actually, virulence mutations that are present in a small proportion of the virus population can be sufficient for resistance breakdown. Considering the spatial distribution of RYMV strains in Africa and their ability to overcome the RYMV resistance genes and alleles, we established a resistance-breaking risk map to optimize strategies for the deployment of sustainable and resistant rice lines in Africa.First reported 50 years ago, Rice yellow mottle virus (RYMV) is a major biotic constraint to rice cultivation in Africa (Séré et al. 2013). RYMV is a viral species of genus Sobemovirus that is responsible for high rice production losses in agroecosystems in most rice-growing countries of Africa (Kouassi et al. 2005;Traoré et al. 2015). Highly adapted to the two cultivated rice species, Asian rice Oryza sativa and African rice O. glaberrima, RYMV has a narrow host range that also includes other wild Poaceae species (Bakker 1974). RYMV possesses a single-stranded RNA genome that is organized into five open reading frames (ORF) (Fig. 1A). Highly diverse, RYMV is classified into six major strains with a strong geographical distribution. Strains S1 and S2/S3 are found in West and West-Central Africa whereas strains S4, S5, and S6 are present exclusively in East Africa (Pinel-Galzi et al. 2015). This spatial pattern of RYMV diversity is explained by the absence of seedborne transmission and of long-distance movement (Allarangaye et al. 2006;Fargette et al. 2006;Konaté et al. 2001). In addition to short-distance propagation that is mainly mediated by beetles, RYMV is transmitted by contact during agricultur...
Surveys were conducted in rice fields in Benin, Cote d'Ivoire, Mali, Nigeria, Togo and Niger to assess the importance of Rice yellow mottle virus (RYMV). Diseased leaf samples were collected. In Togo, surveys were made mainly in the southern part of the country, and in Benin, all areas where rice is grown were covered. Leaf samples were serologically confirmed by ACP ELISA as bearing RYMV, propagated and all conserved. One hundred and forty‐eight (148) Beninese and 27 Togolese strains were serotyped. They were also phenotyped on three susceptible accessions including IR 64, four resistant lines with known alleles on RYMV 1 gene namely TOG 5681 (rymv 1‐3), TOG 5672 (rymv 1‐4 and RYMV 2), TOG 5674 (rymv 1.5) and Gigante (rymv 1‐2). RYMV spots with 9–100% incidences were identified. Serotyping by triple antibody sandwich (TAS) ELISA indicated that two main groups S1 and S2 coexisted in Benin with S1 being prevalent. In Togo, 26 strains were S1 and only one was S2. Phenotyping of the 148 Beninese and 27 Togolese indicated that they all attacked the three susceptible accessions, while TOG 5681 (rymv 1‐3), TOG 5672 (rymv 1‐4 and RYMV 2), TOG 5674 (rymv 1‐5) and Gigante (rymv 1‐2) remained symptomless. The use of the genes/alleles above in these countries against the disease is discussed. Three representative Beninese strains were selected to screen 48 accessions for disease resistance. Nine accessions were as susceptible as IR 64 to all strains while six (NERICA 9, NERICA 12, NERICA 13, TOG 7291, WAB56‐50, CG 14 and Moroberekan) were very resistant. Susceptibility of the six ARICA and resistance of some NERICA lines could be explained by the fact that one or both parental lines were, respectively, susceptible or resistant to the strains.
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