Stress‐ and pathway‐specific impacts of impaired jasmonoyl‐isoleucine (JA‐Ile) catabolism on defense signalling and biotic stress resistance
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serval:BIB_A106CC37CE3F
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Article: article from journal or magazin.
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Title
Stress‐ and pathway‐specific impacts of impaired jasmonoyl‐isoleucine (JA‐Ile) catabolism on defense signalling and biotic stress resistance
Journal
Plant, Cell & Environment
Publication state
Published
Issued date
06/2020
Volume
43
Number
6
Pages
1558-1570
Language
english
Abstract
Jasmonate synthesis and signalling are essential for plant defense upregulation upon herbivore or microbial attacks. Stress-induced accumulation of jasmonoyl-isoleucine (JA-Ile), the bioactive hormonal form triggering transcriptional changes, is dynamic and transient because of the existence of potent removal mechanisms. Two JA-Ile turnover pathways operate in Arabidopsis, consisting in cytochrome P450 (CYP94)mediated oxidation and deconjugation by the amidohydrolases IAR3/ILL6. Understanding their impacts was previously blurred by gene redundancy and compensation mechanisms. Here we address the consequences of blocking these pathways on jasmonate homeostasis and defenses in double-2ah, triple-3cyp mutants, and a quintuple-5ko line deficient in all known JA-Ile-degrading activities. These lines reacted differently to either mechanical wounding/insect attack or fungal infection. Both pathways contributed additively to JA-Ile removal upon wounding, but their impairement had opposite impacts on insect larvae feeding. By contrast, only the ah pathway was essential for JA-Ile turnover upon infection by Botrytis, yet only 3cyp was more fungus-resistant. Despite building-up extreme JA-Ile levels, 5ko displayed near-wild-type resistance in both bioassays. Molecular analysis indicated that restrained JA-Ile catabolism resulted in enhanced defense/resistance only when genes encoding negative regulators were not simultaneously overstimulated. This occurred in discrete stress- and pathway-specific combinations, providing a framework for future defense-enhancing strategies.
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02/06/2020 13:41
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03/06/2020 6:09