QTL mapping in field plant populations reveals a genetic basis for frequency- and spatially-specific fungal pathosystem resistance

Fungal pathogens pose significant challenges to agro-ecosystem productivity. The wild tobacco, Nicotiana attenuata , has been grown for over two decades at an experimental field station in its native habitat, leading to the emergence of a high-mortality sudden wilt disease caused by a Fusarium-Alternaria pathosystem. By using an Advanced Intercross Recombinant Inbred Line (AI-RIL) mapping population of N. attenuata planted in the infected field site, we found two significant loci associated with plant susceptibility to the fungi. A functional characterization of several genes in these loci identified RLXL (intracellular ribonuclease LX-like) as an important factor underlying plant pathogen resistance. Virus-induced silencing of RLXL reduced leaf wilting in plants inoculated with an in vitro culture of Fusarium species. Assessing the significance of the RLXL -associated allele in mixed field populations indicated that, among 4-plant subpopulations, those harboring a single plant with the RLXL -deficiency allele exhibited the highest survival rates. Within these populations, a living RLXL -deficient plant improved the survival of RLXL- producing plants located diagonally, while the mortality of the adjacent plants remained as high as in all other subpopulations. Taken together, these findings provide evidence for the genetic basis for a frequency- and spatially-dependent population pathogen resistance mechanism.