Characterization of -methyltransferases in the Biosynthesis of Phenylphenalenone Phytoalexins Based on the Telomere-to-telomere Gapless Genome of

Overview

Journal Hortic Res

Publisher Oxford University Press

Date 2024 Nov 4

PMID 39493361

Authors

Wanli Zhao

Junzhi Wu

Mei Tian

Shu Xu

Shuaiya Hu

Zhiyan Wei

Guyin Lin

Liang Tang

RuiYang Wang

Boya Feng

Bi Wang

Hui Lyu

Christian Paetz

Xu Feng

Jia-Yu Xue

Pirui Li

Yu Chen

Affiliations

Soon will be listed here.

Abstract

Phenylphenalenones (PhPNs), phytoalexins in wild bananas (Musaceae), are known to act against various pathogens. However, the abundance of PhPNs in many Musaceae plants of economic importance is low. Knowledge of the biosynthesis of PhPNs and the application of biosynthetic approaches to improve their yield is vital for fighting banana diseases. However, the processes of PhPN biosynthesis, especially those involved in methylation modification, remain unclear. is a herbaceous plant belonging to Musaceae, and due to the abundant PhPNs, their biosynthesis in has been the subject of much attention. In this study, we assembled a telomere-to-telomere gapless genome of as the reference, and further integrated transcriptomic and metabolomic data to mine the candidate genes involved in PhPN biosynthesis. To elucidate the diversity of PhPNs in , three screened -methyltransferases (Ml01G0494, Ml04G2958, and Ml08G0855) by phylogenetic and expressional clues were subjected to enzymatic assays. The results show that the three were all novel -methyltransferases involved in the biosynthesis of PhPN phytoalexins, among which Ml08G0855 was proved to function as a multifunctional enzyme targeting multiple hydroxyl groups in PhPN structure. Moreover, we tested the antifungal activity of PhPNs against and found that the methylated modification of PhPNs enhanced their antifungal activity. These findings provide valuable genetic resources in banana breeding and lay a foundation for improving disease resistance through molecular breeding.

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