2014
DOI: 10.1371/journal.pone.0098911
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Genome-Wide Mapping of Virulence in Brown Planthopper Identifies Loci That Break Down Host Plant Resistance

Abstract: Insects and plants have coexisted for over 350 million years and their interactions have affected ecosystems and agricultural practices worldwide. Variation in herbivorous insects' virulence to circumvent host resistance has been extensively documented. However, despite decades of investigation, the genetic foundations of virulence are currently unknown. The brown planthopper (Nilaparvata lugens) is the most destructive rice (Oryza sativa) pest in the world. The identification of the resistance gene Bph1 and i… Show more

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Cited by 45 publications
(42 citation statements)
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References 59 publications
(73 reference statements)
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“…A genetic linkage map was constructed based on the segregation data. Finally, the red gene was mapped to a location between SSR markers BM20 and NLGS182 (Figure 4) on chromosome 9 according to Jing et al's map [10] or to the linkage group 2 according to our previous map [9]. This is the first study to successfully locate the red gene in the genome of this important insect pest of rice using markerbased genetic mapping.…”
Section: Mapping Of the Red-eye Mutant Genementioning
confidence: 97%
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“…A genetic linkage map was constructed based on the segregation data. Finally, the red gene was mapped to a location between SSR markers BM20 and NLGS182 (Figure 4) on chromosome 9 according to Jing et al's map [10] or to the linkage group 2 according to our previous map [9]. This is the first study to successfully locate the red gene in the genome of this important insect pest of rice using markerbased genetic mapping.…”
Section: Mapping Of the Red-eye Mutant Genementioning
confidence: 97%
“…Based on the presence of eye color of the BPH, we generated two groups of 29 brown-eyed (B) and 29 red-eyed (R) progenies from the F 2 population. A total of 387 SSR markers from Jairin et al [9] and Jing et al [10] covering 14 chromosomes of the BPH were selected to identify the R and B groups. The genetic linkage map was calculated by Join Map 4 [15] using genotype data from 95 F 2 individuals derived from crosses of KLS13/KBI13.…”
Section: Tagging and Mapping Of The Red-eye Mutant Genementioning
confidence: 99%
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“…Similarly, combining genes introgressed from wild rice species together with those from traditional varieties might improve durability; however, resistance genes from wild rice have been shown to be ineffective against certain planthopper populations, despite never having been deployed in farmers' fields. These recommendations assume that virulence to major genes is determined by gene-for-gene mechanisms [48,49]. However, if planthoppers adapt to defense mechanisms (irrespective of underlying genetics) then pyramiding arbitrary gene combinations might play little role in determining durability.…”
Section: Aspects Of Virulence Adaptation In Nilaparvata Lugensmentioning
confidence: 99%