Poster
Helen Brabham
2Blades / The Sainsbury Laboratory
Norwich, England, United Kingdom
Inmaculada Hernández-Pinzón
Consejo Superior de Investigaciones Científicas
Seville, Andalucia, Spain
Chizu Yanagihara
KANEKA CORPORATION
Iwata, Shizuoka, Japan
Noriko Ishikawa
KANEKA CORPORATION
Iwata, Shizuoka, Japan
Toshiyuki Komori
KANEKA CORPORATION
Iwata, Shizuoka, Japan
Oadi Matny
University of Minnesota
St. Paul, Minnesota, United States
Kamil Witek
Group leader
2Blades, The Sainsbury Laboratory
Norwich, England, United Kingdom
Alexis Feist
University of Minnesota
St. Paul, Minnesota, United States
Phon Green
The Sainsbury Laboratory
Norwich, England, United Kingdom
Antonín Dreiseitl
Agrotest Fyto Ltd
Kroměříž, Zlinsky kraj, Czech Republic
Naoki Takemori
KANEKA CORPORATION
Iwata, Shizuoka, Japan
Toshihiko Komari
KANEKA CORPORATION
Iwata, Shizuoka, Japan
Brian Steffenson, bsteffen@umn.edu
Professor
University of Minnesota
St. Paul, Minnesota, United States
Peter van Esse
2Blades
Norwich, England, United Kingdom
Matthew Moscou
USDA
St Paul, Minnesota, United States
Introducing functional resistance genes to enhance the plant immune system is highly effective for disease resistance, but identifying new immune receptors is resource intensive. We observed that functional immune receptors of the NLR class show a signature of high expression in uninfected plants across both monocot and dicot species. Here, by exploiting this signature combined with high-throughput transformation, we generated a wheat transgenic array of 995 NLRs from diverse grass species. Using this array, we confirm new resistance genes against the stem rust pathogen Puccinia graminis f. sp. tritici and the leaf rust pathogen Puccinia triticina, major threats to wheat production. Further screening with other pathogens has found multiple additional NLR candidates, highlighting the potential to deliver many functional NLRs for crop protection. This NLR collection is a valuable resource, revealing insights into NLR evolution, variation across donor species, and NLR-effector interactions. This pipeline facilitates the rapid identification of candidate NLRs and provides in-planta gene validation of resistance. The accelerated discovery of new NLRs from a large gene pool of diverse and non-domesticated plant species will enhance the development of disease resistant crops.