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. 2020 Nov;6(11):1375-1388.
doi: 10.1038/s41477-020-00787-9. Epub 2020 Oct 26.

Genetic elucidation of interconnected antibiotic pathways mediating maize innate immunity

Yezhang Ding #  1 Philipp R Weckwerth #  1 Elly Poretsky  1 Katherine M Murphy  2 James Sims  3 Evan Saldivar  1 Shawn A Christensen  4 Si Nian Char  5 Bing Yang  5   6 Anh-Dao Tong  1 Zhouxin Shen  1 Karl A Kremling  7 Edward S Buckler  7   8 Tom Kono  9 David R Nelson  10 Jörg Bohlmann  11 Matthew G Bakker  12   13 Martha M Vaughan  12 Ahmed S Khalil  1 Mariam Betsiashvili  1 Keini Dressano  1 Tobias G Köllner  14 Steven P Briggs  1 Philipp Zerbe  2 Eric A Schmelz  1 Alisa Huffaker  15
Affiliations

Genetic elucidation of interconnected antibiotic pathways mediating maize innate immunity

Yezhang Ding et al. Nat Plants. 2020 Nov.

Abstract

Specialized metabolites constitute key layers of immunity that underlie disease resistance in crops; however, challenges in resolving pathways limit our understanding of the functions and applications of these metabolites. In maize (Zea mays), the inducible accumulation of acidic terpenoids is increasingly considered to be a defence mechanism that contributes to disease resistance. Here, to understand maize antibiotic biosynthesis, we integrated association mapping, pan-genome multi-omic correlations, enzyme structure-function studies and targeted mutagenesis. We define ten genes in three zealexin (Zx) gene clusters that encode four sesquiterpene synthases and six cytochrome P450 proteins that collectively drive the production of diverse antibiotic cocktails. Quadruple mutants in which the ability to produce zealexins (ZXs) is blocked exhibit a broad-spectrum loss of disease resistance. Genetic redundancies ensuring pathway resiliency to single null mutations are combined with enzyme substrate promiscuity, creating a biosynthetic hourglass pathway that uses diverse substrates and in vivo combinatorial chemistry to yield complex antibiotic blends. The elucidated genetic basis of biochemical phenotypes that underlie disease resistance demonstrates a predominant maize defence pathway and informs innovative strategies for transferring chemical immunity between crops.

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