Indirect activation of a plant nucleotide binding site–leucine-rich repeat protein by a bacterial protease

Ade, Jules; DeYoung, Brody J.; Golstein, Catherine; Innes, Roger W.

doi:10.1073/pnas.0608779104

Cited by 365 publications

(416 citation statements)

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“…From these data, a picture emerges in which the LRR domain is not only involved in pathogen recognition, but also plays a role in maintaining an autoinhibited resting state in the absence of pathogens via its interactions with the other domains (Bendahmane et al, 2002;Hwang and Williamson, 2003;Ade et al, 2007;Qi et al, 2012). A similar role as regulatory domain has been found for the sensor domains of other NLRs, such as the mammalian Apaf1 (Hu et al, 1998).…”

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confidence: 75%

“…Previous studies have shown that the CC/TIR, NB-ARC, and LRR domains in plant immune receptors interact and cooperate with each other in an interdependent manner Leister et al, 2005;Ade et al, 2007;Rairdan et al, 2008). From these data, a picture emerges in which the LRR domain is not only involved in pathogen recognition, but also plays a role in maintaining an autoinhibited resting state in the absence of pathogens via its interactions with the other domains (Bendahmane et al, 2002;Hwang and Williamson, 2003;Ade et al, 2007;Qi et al, 2012).…”

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confidence: 81%

“…This mechanism seems to be conserved between proteins from organisms as distant as bacteria, metazoans, and plants (Rairdan and Moffett, 2007;Danot et al, 2009;Takken and Tameling, 2009). The conformational change coincides with the exchange of bound ADP for ATP in the NB-ARC, probably stabilizing the active conformation (Tameling et al, 2006;Ade et al, 2007). Hydrolysis of the bound ATP is hypothesized to return the domains to their inactive state.…”

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confidence: 99%

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Structural Determinants at the Interface of the ARC2 and Leucine-Rich Repeat Domains Control the Activation of the Plant Immune Receptors Rx1 and Gpa2

et al. 2013

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Many plant and animal immune receptors have a modular nucleotide-binding-leucine-rich repeat (NB-LRR) architecture in which a nucleotide-binding switch domain, NB-ARC, is tethered to a LRR sensor domain. The cooperation between the switch and sensor domains, which regulates the activation of these proteins, is poorly understood. Here, we report structural determinants governing the interaction between the NB-ARC and LRR in the highly homologous plant immune receptors Gpa2 and Rx1, which recognize the potato cyst nematode Globodera pallida and Potato virus X, respectively. Systematic shuffling of polymorphic sites between Gpa2 and Rx1 showed that a minimal region in the ARC2 and N-terminal repeats of the LRR domain coordinate the activation state of the protein. We identified two closely spaced amino acid residues in this region of the ARC2 (positions 401 and 403) that distinguish between autoactivation and effector-triggered activation. Furthermore, a highly acidic loop region in the ARC2 domain and basic patches in the N-terminal end of the LRR domain were demonstrated to be required for the physical interaction between the ARC2 and LRR. The NB-ARC and LRR domains dissociate upon effector-dependent activation, and the complementary-charged regions are predicted to mediate a fast reassociation, enabling multiple rounds of activation. Finally, we present a mechanistic model showing how the ARC2, NB, and N-terminal half of the LRR form a clamp, which regulates the dissociation and reassociation of the switch and sensor domains in NB-LRR proteins.Resistance (R) proteins play a central role in the recognition-based immune system of plants. Unlike vertebrates, plants lack an adaptive immune system with highly specialized immune cells. Instead, they rely on an innate immune system in which each cell is autonomous. Two types of immune receptors can be distinguished in plants, pathogen-associated molecular patterns recognition receptors that detect conserved molecular patterns in plant pathogens and intracellular R proteins that recognize specific effectors employed by pathogens as modifiers of host metabolism or defense mechanisms (Jones and Dangl, 2006). Effector-triggered activation of R proteins leads to an array of protective responses, often culminating in programmed cell death at the site of infection (Greenberg and Yao, 2004), thereby preventing further ingress of the pathogen. Pathogens have evolved mechanisms to evade recognition by R proteins and to regain their virulence (Dodds and Rathjen, 2010). This continuous coevolutionary process between host and pathogen has resulted in a reservoir of highly diverse R proteins in plants, enabling them to counteract a wide range of pathogens and pests.The most common class of R proteins consists of nucleotide-binding (NB)-leucine-rich repeat (LRR) proteins with a tripartite domain architecture, which roughly corresponds to an N-terminal response domain (a coiled coil [CC] or Toll/Interleukin-1 receptor [TIR] domain) involved in downstream signaling, a central molecula...

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confidence: 75%

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confidence: 81%

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confidence: 99%

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Structural Determinants at the Interface of the ARC2 and Leucine-Rich Repeat Domains Control the Activation of the Plant Immune Receptors Rx1 and Gpa2

et al. 2013

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“…PBS1 is cleaved by an effector of the pathogen Pseudomonas syringae, activating the nucleotidebinding site (NB)-LRR protein, RPS5, which triggers programmed cell death (Warren et al, 1999;Swiderski and Innes, 2001;Shao et al, 2003;Ade et al, 2007). A recent study has revealed that, like PBS1, BIK1 and several PBS1-like (PBL) RLCKs are also substrates of the bacterial AvrPphB protease effector .…”

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confidence: 99%

“…Although receptor-like cytoplasmic kinases (RLCKs) account for at least 125 of the 610 annotated RLKs in Arabidopsis (Arabidopsis thaliana), much remains to be learned about their functions within cell signaling complexes (Shiu and Bleecker, 2001;Goring and Walker, 2004;Shiu et al, 2004;Jurca et al, 2008). Several of the 46 RLCKs assigned to the class VII subfamily have been found to function in pathogen response and developmental signaling pathways (Swiderski and Innes, 2001;Shao et al, 2003;Murase et al, 2004;Muto et al, 2004;Veronese et al, 2006;Ade et al, 2007;Lu et al, 2010;Zhang et al, 2010;Liu et al, 2011).…”

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confidence: 99%

CAST AWAY, a Membrane-Associated Receptor-Like Kinase, Inhibits Organ Abscission in Arabidopsis

et al. 2011

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Receptor-like kinase-mediated cell signaling pathways play fundamental roles in many aspects of plant growth and development. A pair of Arabidopsis (Arabidopsis thaliana) leucine-rich repeat receptor-like kinases (LRR-RLKs), HAESA (HAE) and HAESA-LIKE2 (HSL2), have been shown to activate the cell separation process that leads to organ abscission. Another pair of LRR-RLKs, EVERSHED (EVR) and SOMATIC EMBRYOGENESIS RECEPTOR-LIKE KINASE1, act as inhibitors of abscission, potentially by modulating HAE/HSL2 activity. Cycling of these RLKs to and from the cell surface may be regulated by NEVERSHED (NEV), a membrane trafficking regulator that is essential for organ abscission. We report here the characterization of CAST AWAY (CST), a receptor-like cytoplasmic kinase that acts as a spatial inhibitor of cell separation. Disruption of CST suppresses the abscission defects of nev mutant flowers and restores the discrete identity of the trans-Golgi network in nev abscission zones. After organ shedding, enlarged abscission zones with obscured boundaries are found in nev cst flowers. We show that CST is a dual-specificity kinase in vitro and that myristoylation at its amino terminus promotes association with the plasma membrane. Using the bimolecular fluorescence complementation assay, we have detected interactions of CST with HAE and EVR at the plasma membrane of Arabidopsis protoplasts and hypothesize that CST negatively regulates cell separation signaling directly and indirectly. A model integrating the potential roles of receptor-like kinase signaling and membrane trafficking during organ separation is presented.

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Resistance to Bacterial Pathogens in Plants

Ade

Innes

2007

Encyclopedia of Life Sciences

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To successfully infect a plant, pathogens must overcome three layers of defense: (1) preformed physical barriers; (2) a cell‐surface‐based surveillance system that detects conserved pathogen molecules and (3) an intracellular surveillance system that detects effector proteins injected into host cells. Bacterial plant pathogens overcome the first layer either by invading through natural openings and wounds, and/or by secreting hydrolytic enzymes that break down surface layers. Bacteria typically overcome the second layer by injecting effectors that interfere with defense signaling. Bacteria overcome the third layer either by modifying or eliminating existing effectors, or by evolving new effectors that suppress defense activation.

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Indirect activation of a plant nucleotide binding site–leucine-rich repeat protein by a bacterial protease

Cited by 365 publications

References 44 publications

Structural Determinants at the Interface of the ARC2 and Leucine-Rich Repeat Domains Control the Activation of the Plant Immune Receptors Rx1 and Gpa2

Structural Determinants at the Interface of the ARC2 and Leucine-Rich Repeat Domains Control the Activation of the Plant Immune Receptors Rx1 and Gpa2

CAST AWAY, a Membrane-Associated Receptor-Like Kinase, Inhibits Organ Abscission in Arabidopsis

Resistance to Bacterial Pathogens in Plants

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