Chromosome-scale genome assembly provides insights into rye biology, evolution, and agronomic potential

M. Timothy Rabanus-Wallace,Bernd Hackauf,Martin Mascher,Thomas Lux,Thomas Wicker,Heidrun Gundlach,Mariana Báez,Andreas Houben,Klaus F.X. Mayer,Liangliang Guo,Jesse Poland,Curtis J. Pozniak,Sean Walkowiak,Joanna Melonek,Coraline Praz,Mona Schreiber,Hikmet Budak,Matthias Heuberger,Burkhard Steuernagel,Brande Wulff,Andreas Börner,Brook Byrns,Jana Čížková,D. Brian Fowler,Allan Fritz,Axel Himmelbach,Gemy Kaithakottil,Jens Keilwagen,Beat Keller,David Konkin,Jamie Larsen,Qiang Li,Beata Myśków,Sudharsan Padmarasu,Nidhi Rawat,Uğur Sesiz,Biyiklioglu Sezgi,Andy Sharpe,Hana Šimková,Ian Small,David Swarbreck,Helena Toegelová,Natalia Tsvetkova,Anatoly V. Voylokov,Jan Vrána,Eva Bauer,Hanna Bolibok-Bragoszewska,Jaroslav Doležel,Anthony Hall,Jizeng Jia,Viktor Korzun,André Laroche,Xue-Feng Ma,Frank Ordon,Hakan Özkan,Monika Rakoczy-Trojanowska,Uwe Scholz,Alan H. Schulman,Dörthe Siekmann,Stefan Stojałowski,Vijay Tiwari,Manuel Spannagl,Nils Stein

biorxiv（2019）

引用 117|浏览11

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摘要

We present a chromosome-scale annotated assembly of the rye ( L. inbred line ‘Lo7’) genome, which we use to explore Triticeae genomic evolution, and rye’s superior disease and stress tolerance. The rye genome shares chromosome-level organization with other Triticeae cereals, but exhibits unique retrotransposon dynamics and structural features. Crop improvement in rye, as well as in wheat and triticale, will profit from investigations of rye gene families implicated in pathogen resistance, low temperature tolerance, and fertility control systems for hybrid breeding. We show that rye introgressions in wheat breeding panels can be characterised in high-throughput to predict the yield effects and trade-offs of rye chromatin.

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