Plant NLR receptor proteins and their potential in the development of durable genetic resistance to biotic stresses

Amanda Cristina de Araújo, Fernando Campos De Assis Fonseca, Michelle Guitton Cotta, Gabriel Sergio Costa Alves, Robert Neil Gerard Miller
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引用次数: 26

Abstract

In order to meet global food security demands in the next decades, considerable changes are required for sustainable agriculture in the context of plant disease, with sufficient food production depending on the development of durable genetically disease resistant crops. For this, further advances are required in our understanding of the plant innate immune system and how plants respond to invading pathogenic micro-organisms. Over the past 20 years, considerable research has been conducted into the characterization and cloning of plant nucleotide-binding, leucine-rich repeat (NLR) immune receptors. These intracellular receptors can recognize directly or indirectly pathogen effector proteins, resulting in effector-triggered immunity (ETI). Elucidation, however, of the diversity of NLR resistance gene families and the molecular basis of NLR-driven effector recognition and defense signaling is incomplete. Here, we present a summary of the understanding of NLR structure, function, genomic organization and diversity in plants. Recent advances in target enrichment approaches for NLR characterization and function validation are highlighted in the context of NLR engineering possibilities for accelerated durable genetic resistance to biotic stresses.

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植物NLR受体蛋白及其在生物胁迫持久遗传抗性发展中的潜力
为了满足未来几十年的全球粮食安全需求,在植物病害的情况下,需要对可持续农业进行重大变革,粮食生产的充足与否取决于培育耐久的遗传抗病作物。为此,我们需要进一步了解植物先天免疫系统以及植物如何对入侵的致病微生物作出反应。在过去的20年里,对植物核苷酸结合的富含亮氨酸重复序列(NLR)免疫受体的鉴定和克隆进行了大量的研究。这些细胞内受体可以直接或间接识别病原体效应蛋白,从而导致效应触发免疫(ETI)。然而,对NLR抗性基因家族的多样性以及NLR驱动效应物识别和防御信号的分子基础的阐明尚不完整。本文就植物NLR的结构、功能、基因组组织和多样性等方面的研究进展作一综述。在NLR工程可能加速对生物胁迫的持久遗传抗性的背景下,强调了NLR表征和功能验证的靶标富集方法的最新进展。
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