Cellulose Binding Domains of a <i>Phytophthora</i> Cell Wall Protein Are Novel Pathogen-Associated Molecular Patterns

Gaulin, Elodie; Dramé, Nani; Lafitte, Claude; Torto-Alalibo, Trudy; Martinez, Yves; Ameline-Torregrosa, Carine; Khatib, Moustafa; Mazarguil, Honoré; Villalba-Mateos, François; Kamoun, Sophien; Mazars, Christian; Dumas, Bernard; Bottin, Arnaud; Esquerré-Tugayé, Marie-Thérèse; Rickauer, Martina

doi:10.1105/tpc.105.038687

Cited by 148 publications

(133 citation statements)

References 56 publications

(56 reference statements)

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“…These results were surprising because Pst DC3000, which carries >30 effector proteins, is already a highly virulent bacterial pathogen Buell et al, 2003). Moreover, ATR13-mediated suppression of callose deposition at Arabidopsis cell walls suggests that ATR13 may play a role in suppressing PTI activated by oomycete elicitors such as Nep1-like proteins or CBEL (Gaulin et al, 2006;Qutob et al, 2006). ATR13-mediated callose suppression is the first indication to date of the suppression of host PTI by an oomycete effector, and this suggests that the molecular functions of bacterial and oomycete effectors can overlap.…”

Section: Possible Roles Of Atr1 and Atr13 In H Parasitica Pathogenesmentioning

confidence: 77%

The Downy Mildew Effector Proteins ATR1 and ATR13 Promote Disease Susceptibility in Arabidopsis thaliana

et al. 2007

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The downy mildew (Hyaloperonospora parasitica) effector proteins ATR1 and ATR13 trigger RPP1-Nd/WsB-and RPP13-Nddependent resistance, respectively, in Arabidopsis thaliana. To better understand the functions of these effectors during compatible and incompatible interactions of H. parasitica isolates on Arabidopsis accessions, we developed a novel delivery system using Pseudomonas syringae type III secretion via fusions of ATRs to the N terminus of the P. syringae effector protein, AvrRPS4. ATR1 and ATR13 both triggered the hypersensitive response (HR) and resistance to bacterial pathogens in Arabidopsis carrying RPP1-Nd/WsB or RPP13-Nd, respectively, when delivered from P. syringae pv tomato (Pst) DC3000. In addition, multiple alleles of ATR1 and ATR13 confer enhanced virulence to Pst DC3000 on susceptible Arabidopsis accessions. We conclude that ATR1 and ATR13 positively contribute to pathogen virulence inside host cells. Two ATR13 alleles suppressed bacterial PAMP (for Pathogen-Associated Molecular Patterns)-triggered callose deposition in susceptible Arabidopsis when delivered by DC3000 DCEL mutants. Furthermore, expression of another allele of ATR13 in plant cells suppressed PAMP-triggered reactive oxygen species production in addition to callose deposition. Intriguingly, although Wassilewskija (Ws-0) is highly susceptible to H. parasitica isolate Emco5, ATR13 Emco5 when delivered by Pst DC3000 triggered localized immunity, including HR, on Ws-0. We suggest that an additional H. parasitica Emco5 effector might suppress ATR13-triggered immunity.

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Section: Possible Roles Of Atr1 and Atr13 In H Parasitica Pathogenesmentioning

confidence: 77%

The Downy Mildew Effector Proteins ATR1 and ATR13 Promote Disease Susceptibility in Arabidopsis thaliana

et al. 2007

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“…The Phytophthora cellulose binding elicitor lectin (CBEL) protein is a P/MAMP that is a potent inducer of innate immune responses (Khatib et al, 2004;Gaulin et al, 2006). CBEL is a cell wall glycoprotein from Phytophthora parasitica var nicotianae (Ppn), the causal agent of the black shank disease of tobacco.…”

Section: Other Endogenous Elicitors Of Innate Immunitymentioning

confidence: 99%

“…CBEL is a cell wall glycoprotein from Phytophthora parasitica var nicotianae (Ppn), the causal agent of the black shank disease of tobacco. This glycoprotein is widely conserved in the genus Phytophthora and elicits HR-like lesions, defense responses, and protection against subsequent infection with this oomycete in host tobacco and non-host Arabidopsis plants (Khatib et al, 2004;Gaulin et al, 2006). Interestingly, the cellulose binding domain (CBD) of CBEL is essential and suffi cient to induce immune responses.…”

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confidence: 99%

Necrotroph Attacks on Plants: Wanton Destruction or Covert Extortion?

Laluk

Mengiste

2010

The Arabidopsis Book

202

158

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Necrotrophic pathogens cause major pre-and post-harvest diseases in numerous agronomic and horticultural crops infl icting signifi cant economic losses. In contrast to biotrophs, obligate plant parasites that infect and feed on living cells, necrotrophs promote the destruction of host cells to feed on their contents. This difference underpins the divergent pathogenesis strategies and plant immune responses to biotrophic and necrotrophic infections. This chapter focuses on Arabidopsis immunity to necrotrophic pathogens. The strategies of infection, virulence and suppression of host defenses recruited by necrotrophs and the variation in host resistance mechanisms are highlighted. The multiplicity of intraspecifi c virulence factors and species diversity in necrotrophic organisms corresponds to variations in host resistance strategies. Resistance to host-specifi c necrotophs is monogenic whereas defense against broad host necrotrophs is complex, requiring the involvement of many genes and pathways for full resistance. Mechanisms and components of immunity such as the role of plant hormones, secondary metabolites, and pathogenesis-related proteins are presented. We will discuss the current state of knowledge of Arabidopsis immune responses to necrotrophic pathogens, the interactions of these responses with other defense pathways, and contemplate on the directions of future research.: e0136. of 34The Arabidopsis Book Infection by fungal necrotrophs generally involves stages of conidial attachment, germination, host penetration, primary lesion formation, lesion expansion, and tissue maceration followed by sporulation (Prins et al., 2000). Following germination, penetration may be achieved by active mechanisms such as appressoria formation and enzymatic degradation or passively through prior infection or wound sites as well as stomates (Prins et al., 2000). After entry, tissue is decomposed through further cellular dismantling using many of the lytic enzymes employed for initial penetration as well as toxic levels of reactive oxygen species (ROS). Many necrotrophs produce various low-molecular weight phytotoxic metabolites, ranging from host-specifi c to those having adverse effects on many diverse species (van Kan, 2006). Others secrete phytotoxic proteins known to induce necrosis, with the vast majority of broad host necrotrophs producing multiples of both (Pemberton and Salmond, 2004;Gijzen and Nurnberger, 2006;Choquer et al., 2007). Throughout infection, these fungi also actively manipulate host cellular machinery in order to suppress defenses and/or aid in disease progression. Some necrotrophs infl uence host phytohormone levels or employ their own hormone biosynthesis thereby disrupting defense signaling (Prins et al., 2000;Sharon et al., 2004). Others have adapted mechanisms to detoxify host metabolites that interfere with virulence (Morrissey and Osbourn, 1999).Overall, bacterial necrotrophs follow a similar mode of pathogenesis to their fungal counterparts, secreting virulence factors into host tissue to induc...

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“…Plants can recognize many different PAMPs from bacteria and fungi (Newman et al, 2013). PAMPs identified so far from oomycetes include b-glucans, heptaglucoside, transglutaminase (Pep13), cellulose binding elicitor lectins, and elicitins (Sharp et al, 1984;Yu, 1995;Enkerli et al, 1999;Klarzynski et al, 2000;Brunner et al, 2002;Gaulin et al, 2006;Zhang et al, 2014). Nevertheless, the mechanisms that allow plants to perceive oomycetes as non-self and to defend against infection remain only partly known.…”

Section: Introductionmentioning

confidence: 99%

A Phytophthora sojae Glycoside Hydrolase 12 Protein Is a Major Virulence Factor during Soybean Infection and Is Recognized as a PAMP

et al. 2015

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We identified a glycoside hydrolase family 12 (GH12) protein, XEG1, produced by the soybean pathogen Phytophthora sojae that exhibits xyloglucanase and b-glucanase activity. It acts as an important virulence factor during P. sojae infection but also acts as a pathogen-associated molecular pattern (PAMP) in soybean (Glycine max) and solanaceous species, where it can trigger defense responses including cell death. GH12 proteins occur widely across microbial taxa, and many of these GH12 proteins induce cell death in Nicotiana benthamiana. The PAMP activity of XEG1 is independent of its xyloglucanase activity. XEG1 can induce plant defense responses in a BAK1-dependent manner. The perception of XEG1 occurs independently of the perception of ethylene-inducing xylanase. XEG1 is strongly induced in P. sojae within 30 min of infection of soybean and then slowly declines. Both silencing and overexpression of XEG1 in P. sojae severely reduced virulence. Many P. sojae RXLR effectors could suppress defense responses induced by XEG1, including several that are expressed within 30 min of infection. Therefore, our data suggest that PsXEG1 contributes to P. sojae virulence, but soybean recognizes PsXEG1 to induce immune responses, which in turn can be suppressed by RXLR effectors. XEG1 thus represents an apoplastic effector that is recognized via the plant's PAMP recognition machinery.

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Cellulose Binding Domains of a Phytophthora Cell Wall Protein Are Novel Pathogen-Associated Molecular Patterns

Cited by 148 publications

References 56 publications

The Downy Mildew Effector Proteins ATR1 and ATR13 Promote Disease Susceptibility in Arabidopsis thaliana

The Downy Mildew Effector Proteins ATR1 and ATR13 Promote Disease Susceptibility in Arabidopsis thaliana

Necrotroph Attacks on Plants: Wanton Destruction or Covert Extortion?

A Phytophthora sojae Glycoside Hydrolase 12 Protein Is a Major Virulence Factor during Soybean Infection and Is Recognized as a PAMP

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