Functional characterization of PETIOLULE‐LIKE PULVINUS (PLP) gene in abscission zone development in Medicago truncatula and its application to genetic improvement of alfalfa

生物 截形苜蓿 脱落 叶柄(昆虫解剖学) 花梗 传单(植物学) 苜蓿 苜蓿 基因 突变体 植物 短柄草属 细胞生物学 遗传学 共生 细菌 膜翅目 基因组
作者
Juan Du,Shaoyun Lu,Maofeng Chai,Chuanen Zhou,Liang Sun,Yuhong Tang,Jin Nakashima,Jaydeep Kolape,Zhaozhu Wen,Marjan Behzadirad,Tian-Xiu Zhong,Juan Sun,Yunwei Zhang,Zeng‐Yu Wang
出处
期刊:Plant Biotechnology Journal [Wiley]
卷期号:19 (2): 351-364 被引量:17
标识
DOI:10.1111/pbi.13469
摘要

Alfalfa (Medicago sativa L.) is one of the most important forage crops throughout the world. Maximizing leaf retention during the haymaking process is critical for achieving superior hay quality and maintaining biomass yield. Leaf abscission process affects leaf retention. Previous studies have largely focused on the molecular mechanisms of floral organ, pedicel and seed abscission but scarcely touched on leaf and petiole abscission. This study focuses on leaf and petiole abscission in the model legume Medicago truncatula and its closely related commercial species alfalfa. By analysing the petiolule-like pulvinus (plp) mutant in M. truncatula at phenotypic level (breakstrength and shaking assays), microscopic level (scanning electron microscopy and cross-sectional analyses) and molecular level (expression level and expression pattern analyses), we discovered that the loss of function of PLP leads to an absence of abscission zone (AZ) formation and PLP plays an important role in leaflet and petiole AZ differentiation. Microarray analysis indicated that PLP affects abscission process through modulating genes involved in hormonal homeostasis, cell wall remodelling and degradation. Detailed analyses led us to propose a functional model of PLP in regulating leaflet and petiole abscission. Furthermore, we cloned the PLP gene (MsPLP) from alfalfa and produced RNAi transgenic alfalfa plants to down-regulate the endogenous MsPLP. Down-regulation of MsPLP results in altered pulvinus structure with increased leaflet breakstrength, thus offering a new approach to decrease leaf loss during alfalfa haymaking process.

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