FERONIA: A Malectin-Domain Receptor Kinase with Intricate Signaling Mechanisms and Profound Importance to Plant Wellness.

IF 2.5 3区 工程技术 Q2 BIOLOGY
Yale Journal of Biology and Medicine Pub Date : 2025-03-31 eCollection Date: 2025-03-01 DOI:10.59249/PWYT9677
Alice Y Cheung, Hen-Ming Wu
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引用次数: 0

Abstract

Plants have evolved elaborate signaling networks, believed to be necessitated by the diversity and complexity of their morphology, developmental and reproductive strategies, and the need to cope with an ever-changing environment from which they are rooted and cannot escape. Their receptor-like kinase superfamilies, with members numbering in the hundreds to more than a thousand, exemplify how plants have evolved their signaling versatility. FERONIA (FER) receptor kinase from model Arabidopsis is a member of the Malectin-domain receptor kinase family conserved among plants. FER has a perplexingly broad functional range, impacting growth to reproduction throughout the plant life cycle, and survival when encountering biotic and abiotic stressors from the environment, such as pathogens and climatic adversity. Efforts to understand FER signaling have brought to light novel signaling strategies at the continuum of the plant cell wall and plasma membrane, and a network of cytoplasmic and nuclear pathways that together support its biological roles. The discussion here focuses on the cell surface mechanisms, including a sugar-peptide interaction-driven liquid-liquid phase separation process along the cell wall-plasma membrane interface and a plasma membrane-linked signaling node comprised of FER, a glycosylphosphatidylinositol-anchored protein, the RHO GTPase molecular switch and a generator for reactive oxygen species (ROS). The emerging recognition of how the broader FER-related receptor kinase family could impact plant wellness and agricultural productivity is also discussed.

FERONIA:一种具有复杂信号机制和对植物健康具有深远意义的马来素结构域受体激酶。
植物已经进化出了复杂的信号网络,这被认为是它们形态、发育和繁殖策略的多样性和复杂性以及应对不断变化的环境的需要所必需的。它们的受体样激酶超家族,成员数从数百到1000多个,说明了植物是如何进化出信号多功能性的。FERONIA (FER)受体激酶来自模式拟南芥,是植物中保守的Malectin-domain receptor kinase家族成员。FER具有令人困惑的广泛功能范围,影响植物整个生命周期的生长到繁殖,以及在遇到来自环境的生物和非生物应激源(如病原体和气候逆境)时的生存。了解FER信号传导的努力已经揭示了植物细胞壁和质膜连续体中的新信号传导策略,以及细胞质和核通路网络,这些通路共同支持其生物学作用。本文主要讨论细胞表面机制,包括沿细胞壁-质膜界面的糖-肽相互作用驱动的液-液相分离过程,以及由糖基磷脂酰肌醇锚定蛋白FER、RHO GTPase分子开关和活性氧(ROS)发生器组成的质膜连接信号节点。对更广泛的ferr相关受体激酶家族如何影响植物健康和农业生产力的新认识也进行了讨论。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Yale Journal of Biology and Medicine
Yale Journal of Biology and Medicine Biochemistry, Genetics and Molecular Biology-General Biochemistry,Genetics and Molecular Biology
CiteScore
5.00
自引率
0.00%
发文量
41
期刊介绍: The Yale Journal of Biology and Medicine (YJBM) is a graduate and medical student-run, peer-reviewed, open-access journal dedicated to the publication of original research articles, scientific reviews, articles on medical history, personal perspectives on medicine, policy analyses, case reports, and symposia related to biomedical matters. YJBM is published quarterly and aims to publish articles of interest to both physicians and scientists. YJBM is and has been an internationally distributed journal with a long history of landmark articles. Our contributors feature a notable list of philosophers, statesmen, scientists, and physicians, including Ernst Cassirer, Harvey Cushing, Rene Dubos, Edward Kennedy, Donald Seldin, and Jack Strominger. Our Editorial Board consists of students and faculty members from Yale School of Medicine and Yale University Graduate School of Arts & Sciences. All manuscripts submitted to YJBM are first evaluated on the basis of scientific quality, originality, appropriateness, contribution to the field, and style. Suitable manuscripts are then subject to rigorous, fair, and rapid peer review.
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