Osa-miR160a confers broad-spectrum resistance to fungal and bacterial pathogens in rice.
Qin FengHe WangXue-Mei YangZhang-Wei HuXin-Hui ZhouLing XiangXiao-Yu XiongXiao-Rong HeYong ZhuGuo-Bang LiJing-Hao ZhaoYun-Peng JiXiao-Hong HuMei PuShi-Xin ZhouWen-Ming WangJi-Wei ZhangYan-Yan HuangJing FanWen-Ming WangYan LiPublished in: The New phytologist (2022)
Rice production is threatened by multiple pathogens. Breeding cultivars with broad-spectrum disease resistance is necessary to maintain and improve crop production. Previously we found that overexpression of miR160a enhanced rice blast disease resistance. However, it is unclear whether miR160a also regulates resistance against other pathogens, and what the downstream signaling pathways are. Here, we demonstrate that miR160a positively regulates broad-spectrum resistance against the causative agents of blast, leaf blight and sheath blight in rice. Mutations of miR160a-targeted Auxin Response Factors result in different alteration of resistance conferred by miR160a. miR160a enhances disease resistance partially by suppressing ARF8, as mutation of ARF8 in MIM160 background partially restores the compromised resistance resulting from MIM160. ARF8 protein binds directly to the promoter and suppresses the expression of WRKY45, which acts as a positive regulator of rice immunity. Mutation of WRKY45 compromises the enhanced blast resistance and bacterial leaf blight resistance conferred by arf8 mutant. Overall, our results reveal that a microRNA coordinates rice broad-spectrum disease resistance by suppressing multiple target genes that play different roles in disease resistance, and uncover a new regulatory pathway mediated by the miR160a-ARF8 module. These findings provide new resources to potentially improve disease resistance for breeding in rice.