The RING- type E3 ligase RIE1 sustains leaf longevity by specifically targeting AtACS7 to fine- tune ethylene production in Arabidopsis

Article

Tang, Xianglin; Mei, Yuanyuan; He, Kaixuan; Liu, Ran; Lv, Xiaoyan; Zhao, Yujia; Li, Wenjing; Wang, Qian; Gong, Qinshan; Li, Shengnan; Xu, Chang; Zheng, Xu; Cao, Qingyu; Wang, Dan; Wang, Ning Ning

Nankai University

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA

0027-15331

10.1073/pnas.2411271121

2024-11-26

Ethylene is widely recognized as a positive regulator of leaf senescence. However, how plants coordinate the biosynthesis of ethylene to meet the requirements of senescence progression has not been determined. The rate- limiting enzyme in the ethylene biosynthesis pathway is ACC synthase. AtACS7 was previously considered one of the major contributors to the synthesis of senescence ethylene in Arabidopsis. However, the brake signal that fine- tunes the expression of AtACS7 to ensure optimal ethylene production during leaf development has yet to be identified. In the present study, the RING- H2 zinc- finger protein RIE1 was found to specifically interact with and ubiquitinate AtACS7, among all functional ACSs in Arabidopsis, to promote its degradation. Overexpression of RIE1 markedly decreased ethylene biosynthesis and delayed leaf senescence, whereas loss of function of RIE1 significantly increased ethylene emission and accelerated leaf senescence. The ethylene- related phenotypes of RIE1 overexpressing or knockout mutants were effectively rescued by the ethylene precursor ACC or the competitive inhibitor of ACS, respectively. In particular, AtACS7- induced precocious leaf senescence was strongly enhanced by the loss of RIE1 but was significantly attenuated by the overexpression of RIE1. The specific regions of interaction between AtACS7 and RIE1, as well as the major ubiquitination sites of AtACS7, were further investigated. All results demonstrated that RIE1 functions as an important modulator of ethylene biosynthesis during leaf development by specifically targeting AtACS7 for degradation, thereby enabling plants to produce the optimal levels of ethylene needed.