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Oryza genome evolution through a tetraploid lens

Alice Fornasiero, Tao Feng, Noor Al-Bader, Aseel Alsantely, Saule Mussurova, Nam V. Hoang, Gopal Misra, Yong Zhou, Leonardo Fabbian, Nahed Mohammed, Luis F. Rivera, Manjula Thimma, Víctor Llaca, Praveena Parakkal, David Kudrna, Dario Copetti, Shanmugam Rajasekar, Seunghee Lee, Jayson Talag, Chandler Sobel-Sorenson, Marie‐Christine Carpentier, Olivier Panaud, Millicent D. Alexandrov Sanciangco, Jianwei Zhang, Andrea Zuccolo, M. Eric Schranz, Rod A. Wing

2025Nature Genetics21 citationsDOIOpen Access PDF

Abstract

Oryza is a remarkable genus comprising 27 species and 11 genome types, with ~3.4-fold genome size variation, that possesses a virtually untapped reservoir of genes that can be used for crop improvement and neodomestication. Here we present 11 chromosome-level assemblies (nine tetraploid, two diploid) in the context of ~15 million years of evolution and show that the core Oryza (sub)genome is only ~200 Mb and largely syntenic, whereas the remaining nuclear fractions (~80–600 Mb) are intermingled, plastic and rapidly evolving. For the halophyte Oryza coarctata, we found that despite detection of gene fractionation in the subgenomes, homoeologous genes were expressed at higher levels in one subgenome over the other in a mosaic form, demonstrating subgenome equivalence. The integration of these 11 new reference genomes with previously published genome datasets provides a nearly complete view of the consequences of evolution for genome diversification across the genus. Chromosome-level genome assemblies of nine tetraploid and two diploid wild Oryza species provide insights into genome evolution within the genus Oryza and the potential for crop improvement and neodomestication.

Topics & Concepts

BiologyOryza sativaGenomeOryzaEvolutionary biologyGeneticsComputational biologyGeneGenomics and Phylogenetic StudiesChromosomal and Genetic VariationsProtist diversity and phylogeny