The Plant Genome (Jun 2024)

Globally deployed sorghum aphid resistance gene RMES1 is vulnerable to biotype shifts but is bolstered by RMES2

  • Carl VanGessel,
  • Brian Rice,
  • Terry J. Felderhoff,
  • Jean Rigaud Charles,
  • Gael Pressoir,
  • Vamsi Nalam,
  • Geoffrey P. Morris

DOI
https://doi.org/10.1002/tpg2.20452
Journal volume & issue
Vol. 17, no. 2
pp. n/a – n/a

Abstract

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Abstract Durable host plant resistance (HPR) to insect pests is critical for sustainable agriculture. Natural variation exists for aphid HPR in sorghum (Sorghum bicolor), but the genetic architecture and phenotype have not been clarified and characterized for most sources. In order to assess the current threat of a sorghum aphid (Melanaphis sorghi) biotype shift, we characterized the phenotype of Resistance to Melanaphis sorghi 1 (RMES1) and additional HPR architecture in globally admixed populations selected under severe sorghum aphid infestation in Haiti. We found RMES1 reduces sorghum aphid fecundity but not bird cherry‐oat aphid (Rhopalosiphum padi) fecundity, suggesting a discriminant HPR response typical of gene‐for‐gene interaction. A second resistant gene, Resistance to Melanaphis sorghi 2 (RMES2), was more frequent than RMES1 resistant alleles in landraces and historic breeding lines. RMES2 contributes early and mid‐season aphid resistance in a segregating F2 population; however, RMES1 was only significant with mid‐season fitness. In a fixed population with high sorghum aphid resistance, RMES1 and RMES2 were selected for demonstrating a lack of severe antagonistic pleiotropy. Associations with resistance colocated with cyanogenic glucoside biosynthesis genes support additional HPR sources. Globally, therefore, an HPR source vulnerable to biotype shift via selection pressure (RMES1) is bolstered by a second common source of resistance in breeding programs (RMES2), which may be staving off a biotype shift and is critical for sustainable sorghum production.