Chitin-Induced Dimerization Activates a Plant Immune Receptor

Liu, Tingting; Liu, Zixu; Song, Chuanjun; Hu, Yunfei; Han, Zhifu; She, Ji; Fan, Fangfang; Wang, Jiawei; Jin, Changwen; Chang, Junbiao; Zhou, Jian‐Min; Chai, Jijie

doi:10.1126/science.1218867

Cited by 537 publications

(560 citation statements)

References 39 publications

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“…By comparison with RTKs, SRK9 homodimerization, though also contributed by the direct contacts between two SRK9 molecules, is mainly mediated by two independent SCR9 molecules. Despite this difference, our data support the idea that ligand-induced dimerization is important for the activation of an RK [32,33]. The dimerization model suggests that interaction between an SRK and an SCR may not always be translated into activation of the SRK, because their interaction may not necessarily result in receptor homodimerization.…”

Section: Discussionsupporting

confidence: 58%

Structural basis for specific self-incompatibility response in Brassica

Han

et al. 2016

Cell Res

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Self-incompatibility (SI) is a widespread mechanism in flowering plants which prevents self-fertilization and inbreeding. In Brassica, recognition of the highly polymorphic S-locus cysteine-rich protein (SCR; or S-locus protein 11) by the similarly polymorphic S-locus receptor kinase (SRK) dictates the SI specificity. Here, we report the crystal structure of the extracellular domain of SRK9 (eSRK9) in complex with SCR9 from Brassica rapa. SCR9 binding induces eSRK9 homodimerization, forming a 2:2 eSRK:SCR heterotetramer with a shape like the letter "A". Specific recognition of SCR9 is mediated through three hyper-variable (hv) regions of eSRK9. Each SCR9 simultaneously interacts with hvI and one-half of hvII from one eSRK9 monomer and the other half of hvII from the second eSRK9 monomer, playing a major role in mediating SRK9 homodimerization without involving interaction between the two SCR9 molecules. Single mutations of residues critical for the eSRK9-SCR9 interaction disrupt their binding in vitro. Our study rationalizes a body of data on specific recognition of SCR by SRK and provides a structural template for understanding the co-evolution between SRK and SCR.

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Section: Discussionsupporting

confidence: 58%

Structural basis for specific self-incompatibility response in Brassica

Han

et al. 2016

Cell Res

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“…Structurally, AtCERK1, an RLK, is composed of a transmembrane domain, three tandem LysMs in its ectodomain and an intracellular serine/threonine kinase domain (Miya et al 2007; Wan et al 2008) in Arabidopsis . Chitin-induced AtCERK1 homodimerisation has been proved to be necessary for its activation (Liu et al 2012). The chitin-induced signalling in Arabidopsis also required two other LysM-RLKs, named AtLYK4 and AtLYK5 (Wan et al 2012; Cao et al 2014).…”

Section: Resistance and Signalling In Plantsmentioning

confidence: 99%

“…The perception of shorter oligosaccharides such as chitotetraose could instead rely on monomeric receptors (Miyata et al 2014; Shinya et al 2015) as into each receptor’s LysM domain, half of this oligomer molecule (C4) fits (Liu et al 2012; Shinya et al 2015). …”

Section: Resistance and Signalling In Plantsmentioning

confidence: 99%

Chitin and chitin-related compounds in plant–fungal interactions

Pusztahelyi

2018

Mycology

132

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Chitin is the second abundant polysaccharide in the world after cellulose. It is a vital structural component of the fungal cell wall but not for plants. In plants, fungi are recognised through the perception of conserved microbe-associated molecular patterns (MAMPs) to induce MAMP-triggered immunity (MTI). Chitin polymers and their modified form, chitosan, induce host defence responses in both monocotyledons and dicotyledons. The plants’ response to chitin, chitosan, and derived oligosaccharides depends on the acetylation degree of these compounds which indicates possible biocontrol regulation of plant immune system. There has also been a considerable amount of recent research aimed at elucidating the roles of chitin hydrolases in fungi and plants as chitinase production in plants is not considered solely as an antifungal resistance mechanism. We discuss the importance of chitin forms and chitinases in the plant–fungal interactions and their role in persistent and possible biocontrol.Abbreviations ET, ethylene; GAP, GTPase-activating protein; GEF, GDP/GTP exchange factor; JA, jasmonic acid; LysM, lysin motif; MAMP, microbe-associated molecular pattern; MTI, MAMP-triggered immunity; NBS, nucleotide-binding site; NBS-LRR, nucleotide-binding site leucine-rich repeats; PM, powdery mildew; PR, pathogenesis-related; RBOH, respiratory burst oxidase homolog; RLK, receptor-like kinase; RLP, receptor-like protein; SA, salicylic acid; TF, transcription factor.

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“…For example, the LysM-RLK chitin elicitor receptor kinase 1 of A. thaliana (AtCERK1) interacts with other receptor proteins to mediate responses to different signals. This protein can bind chitooligosaccharides (COs) [4], but it also interacts with two CO-binding LysM-RLKs with dead kinase domains (AtLYK5/ AtLYK4) [5] and with two peptidoglycan-binding LysM receptor-like proteins (AtLYM1/AtLYM3) [6] to mediate defense responses to these GlcNAc-containing signals. In contrast, OsCERK1 from rice …”

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confidence: 99%

LYR3, a high‐affinity LCO‐binding protein of Medicago truncatula, interacts with LYK3, a key symbiotic receptor

et al. 2016

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Edited by Julian Schroeder LYR3, LYK3, and NFP are lysin motif-containing receptor-like kinases (LysM-RLKs) from Medicago truncatula, involved in perception of symbiotic lipo-chitooligosaccharide (LCO) signals. Here, we show that LYR3, a highaffinity LCO-binding protein, physically interacts with LYK3, a key player regulating symbiotic interactions. In vitro, LYR3 is phosphorylated by the active kinase domain of LYK3. Fluorescence lifetime imaging/F€ orster resonance energy transfer (FLIM/FRET) experiments in tobacco protoplasts show that the interaction between LYR3 and LYK3 at the plasma membrane is disrupted or inhibited by addition of LCOs. Moreover, LYR3 attenuates the cell death response, provoked by coexpression of NFP and LYK3 in tobacco leaves.Keywords: FLIM/FRET; lipo-chitooligosaccharides; LysM-RLK; Medicago truncatula; membrane receptor complex; phosphoproteomics The extracellular domains of plant RLKs are built up of different protein domains which serve as sensors for endogenous and outer stimuli, as diverse as peptides, hormones, (peptido-) glycans, and (lipo-) chitooligosaccharides. Two prevalent extracellular protein domains consist of either leucine-rich repeats (LRRs) or lysin motifs (LysMs), which might interact with peptides or with N-acetyl-D-glucosamine (GlcNAc)-containing compounds, respectively [1,2].Recent advances in functional and structural analyses of plant RLKs, particularly in Arabidopsis, suggest that plant RLKs act in multimeric complexes [3]. For example, the LysM-RLK chitin elicitor receptor kinase 1 of A. thaliana (AtCERK1) interacts with other receptor proteins to mediate responses to different signals. This protein can bind chitooligosaccharides (COs) [4], but it also interacts with two CO-binding LysM-RLKs with dead kinase domains (AtLYK5/ AtLYK4) [5] and with two peptidoglycan-binding LysM receptor-like proteins (AtLYM1/AtLYM3) [6] to mediate defense responses to these GlcNAc-containing signals. In contrast, OsCERK1 from rice

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Chitin-Induced Dimerization Activates a Plant Immune Receptor

Cited by 537 publications

References 39 publications

Structural basis for specific self-incompatibility response in Brassica

Structural basis for specific self-incompatibility response in Brassica

Chitin and chitin-related compounds in plant–fungal interactions

LYR3, a high‐affinity LCO‐binding protein of Medicago truncatula, interacts with LYK3, a key symbiotic receptor

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