Identifying a large number of high-yield genes in rice by pedigree analysis, whole-genome sequencing, and CRISPR-Cas9 gene knockout

Repeated artificial selection of a complex trait facilitates the identification of genes underlying the trait, especially if multiple selected descendant lines are available. Here we developed a pedigree-based approach to identify genes underlying the Green Revolution (GR) phenotype. From a pedigree...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 115; no. 32; pp. E7559 - E7567
Main Authors Huang, Ju, Li, Jing, Zhou, Jun, Wang, Long, Yang, Sihai, Hurst, Laurence D., Li, Wen-Hsiung, Tian, Dacheng
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 07.08.2018
SeriesPNAS Plus
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Summary:Repeated artificial selection of a complex trait facilitates the identification of genes underlying the trait, especially if multiple selected descendant lines are available. Here we developed a pedigree-based approach to identify genes underlying the Green Revolution (GR) phenotype. From a pedigree analysis, we selected 30 cultivars including the “miracle rice” IR8, a GR landmark, its ancestors and descendants, and also other related cultivars for identifying high-yield genes. Through sequencing of these genomes, we identified 28 ancestral chromosomal blocks that were maintained in all the high-yield cultivars under study. In these blocks, we identified six genes of known function, including the GR gene sd1, and 123 loci with genes of unknown function. We randomly selected 57 genes from the 123 loci for knockout or knockdown studies and found that a high proportion of these genes are essential or have phenotypic effects related to rice production. Notably, knockout lines have significant changes in plant height (P < 0.003), a key GR trait, compared with wild-type lines. Some gene knockouts or knockdowns were especially interesting. For example, knockout of Os10g0555100, a putative glucosyltransferase gene, showed both reduced growth and altered panicle architecture. In addition, we found that in some retained chromosome blocks several GR-related genes were clustered, although they have unrelated sequences, suggesting clustering of genes with similar functions. In conclusion, we have identified many high-yield genes in rice. Our method provides a powerful means to identify genes associated with a specific trait.
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1J.H. and J.L. contributed equally to this work.
Reviewers: M.D.P., New York University; M.B.T., Berea College; and J.Z., University of Michigan.
Author contributions: J.H., J.L., L.D.H., W.-H.L., and D.T. designed research; J.H., J.L., J.Z., and D.T. performed research; J.Z. contributed new reagents/analytic tools; J.H., J.L., L.W., and S.Y. analyzed data; and J.H., J.L., S.Y., L.D.H., W.-H.L., and D.T. wrote the paper.
Contributed by Wen-Hsiung Li, June 18, 2018 (sent for review April 11, 2018; reviewed by Michael D. Purugganan, Milton Brian Traw, and Jianzhi Zhang)
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1806110115