Summary
In the early 1970s, the Xa21 gene from the wild rice species Oryza longistaminata, drew attention of rice breeders because of its broad-spectrum resistance to diverse strains of a serious bacterial disease of rice in Asia and Africa, called bacterial blight disease, caused by the Gram-negative bacterium, Xanthomonas oryzae pv. oryzae (Xoo). In 1995, we isolated the gene controlling this resistance and in 2009 demonstrated that XA21 recognizes a highly conserved peptide, called Ax21 (activator of XA21-mediated immunity). Tyrosine sulfation of Ax21 is required for recognition by rice XA21. A decade of genetic, molecular, and biochemical studies have uncovered key components of the XA21-mediated signaling cascade. Ax21 recognition by XA21 at the cell surface induces phosphorylation–mediated events, which are predicted to alter subcellular localization and/or DNA-binding activity of a WRKY family of transcription factors. Because XA21 is representative of the large number of predicted pattern recognition receptors (PRRs) in rice (328), Arabidopsis (35) and other plant species, further characterization of XA21-mediated signaling pathways will contribute to elucidation of these important defense responses.
Introduction
Recognition of conserved microbial signatures [also called pathogen-associated molecular patterns (PAMPs)] by host sensors [(also called pattern recognition receptors (PRRs)] activates innate immune response. Plant and animal PRRs share conserved domains, such as leucine-rich repeats (LRRs) for PAMP recognition (Wang et al., 1998, Boller et al., 2009, Poltorak et al., 1998, Anderson et al., 1985, Gomez-Gomez et al., 2000, Song et al., 1995) and non-RD kinase domains that are either integral to the receptor (plants) or associated with it (animals) (Dardick et al., 2006). In plants, three PRR/PAMP interactions have been well-characterized. These are rice XA21 (Song et al., 1995), Arabidopsis flagellin sensitive 2 (FLS2) (Gomez-Gomez et al., 2000) and the Arabidopsis elongation factor (EF)-Tu receptor (EFR) (Zipfel et al., 2006). XA21, FLS2 and EFR recognize a sulfated peptide (axYS22) derived from the N-terminal region of Ax21 (Lee et al., 2009), the flg22 peptide derived from bacterial flagellin (Gomez-Gomez et al., 2000) and the elf18 peptide, derived from the EF-Tu protein (Zipfel et al., 2006), respectively.
In animals, the positional cloning of a spontaneous mutation that caused lipopolysaccharide resistance and susceptibility to Gram-negative infection led to the isolation of Toll-like receptor4 (TLR4), which shared striking structural similarities to XA21 (Poltorak et al., 1998, Song et al., 1995) and, like XA21, was an essential host sensor of microbial infection. To date, 13 human TLRs have now been described (Mishra et al., 2008) and all recognize PAMPs presented in invading microbes and activate corresponding PRR-mediated signaling pathways (Hornef et al., 2008).
In this review, we discuss the isolation and characterization of Ax21 and present a model for XA21-mediated immunity based on recent results.
Ax21 (activator of XA21-mediated immunity)
A screen for Xoo mutants defective in genes required for activation of XA21-mediated immunity (the rax genes), led to the identification of the raxA, raxB, and raxC encoding components of a bacterial type I secretion system. Xoo mutants carrying knockouts in any of these genes lose the ability to trigger XA21-mediated immunity and are no longer able to secrete Ax21 (Lee et al., 2006). Another class of rax mutants involved in sulfation, were also isolated. These include raxST, which encodes a protein with similarity to mammalian tyrosine sulfotransferases (da Silva et al., 2004) and the raxR and raxP genes, which encode genes critical for synthesis of 3’-phosphoadenosine 5’-phosphosulfate (PAPS). Based on these results, we hypothesized that RaxST utilizes PAPS to transfer a sulfuryl group to Ax21 (Lee et al., 2006).
These genetic screens were non-saturating because of the labor involved in the screen. It was necessary to grow rice plants for 6 weeks before inoculation because XA21-mediated resistance is only expressed at the adult stage and because scoring required another 10 days to assay symptom development. To quantify the response, we measured the length of bacterial induced lesions because a hypersensitive response, which is typical of many plant defense responses, cannot easily be observed in the XA21/Ax21 interaction. Thus, although the screens led to the identification of key genes controlling Ax21 activity and allowed us to establish increasingly focused models on the function of the putative Ax21, we failed to identify Ax21 itself.
Based on our model that Ax21 was likely a type I secreted, sulfated peptide, we switched to a biochemical approach. This was made possible both by the establishment of a new bioassay system (Lee et al., 2006) and by advances in proteomic analyses. Ax21 was isolated by analysis of bioactive fractions from Xoo strain PXO99Az using liquid chromatography-tandem mass spectrometry (LC-MS/MS). The identified peptides were derived from a 194-amino acid protein encoded by a gene designated ax21 (Lee et al., 2009). An Xoo mutant strain lacking ax21 is unable to trigger XA21-mediated immunity.
The Ax21 protein carries two predicted tyrosine sulfation sites. An Ax21-derived synthetic peptide (17-amino acid) containing a sulfated tyrosine-22 (axYS22) is sufficient for Ax21 activity, whereas peptides lacking tyrosine sulfation and peptide variants carrying alanine in place of the tyrosine are inactive (Lee et al., 2009). In vivo coimmunoprecipitation experiments demonstrated that axYS22 binds to XA21 in transgenic plants expressing an N-terminal Myc-epitope-tagged XA21 (Lee et al., 2009). Although all Xanthomonas species tested carry ax21 (Lee et al., 2009), Xoo strains lacking the sulfation and/or secretion systems can no longer elicit the XA21-mediated defense response (da Silva et al., 2004). These results indicate that sulfation on the axY22 peptide is critical for XA21/Ax21 recognition in rice.
Ax21 is present in all sequenced Xanthomonas species, in Xylella fastidiosa, the causal agent of Pierce’s disease on grapes, and in the human pathogen, Stenotrophomonas maltophilia (Lee et al., 2009). The amino acid sequence of axYS22 peptide is 100% conserved in all sequenced Xanthomonas species. X. fastidiosa and S. maltophilia peptides show 77% and 65% identity, respectively (Lee et al., 2009).
Thus, Ax21 satisfies a key aspect of the definition of PAMPs: it is conserved within a class of microbes (Beutler, 2004, Medzhitov, 2001). The specificity conferred by a post-translational modification, Tyr22 sulfation of axYS22, supports an emerging theme for PAMPs - that sequence variation and post-translational modifications such as glycosylation, acetylation, and sulfation can modulate PRR-dependent recognition (Sun et al., 2006, Kunze et al., 2004, Taguchi et al., 2003).
The non-RD kinase domain
XA21 is a receptor kinase which consists of LRR, transmembrane, juxtamembrane (JM), and intracellular kinase domains (Song et al., 1995). Kinases are classified as arginine-aspartate (RD) or non-RD kinases. RD kinases carry a conserved arginine (R) immediately preceding the catalytic aspartate (D) (6). In contrast to RD kinases, non-RD kinases typically carry a cysteine or glycine in place of the arginine. We previously reported that non-RD kinases are associated with the control of early signaling events in both plant and animal innate immunity (Dardick et al., 2006). For example, in humans, recognition of PAMPs at the cell surface is largely carried out by TLRs (Nurnberger et al., 2002). TLR1, TLR3, TLR5, TLR6, TLR7, TLR8, and TLR9 associate with the non-RD interleukin-1 receptor associated kinase (IRAK) family (Akira et al., 2004) and TLR3 and TLR4 associate with the non-RD receptor interacting-protein (RIP) kinases (Meylan et al., 2004) via adaptor proteins.
In plants, receptor kinases demonstrated to function in mediating innate immunity also fall into the non-RD class (Dardick et al., 2006) or are associated with non-RD receptor kinases (Chinchilla et al., 2007, Miya et al., 2007, Wan et al., 2008). Plant genome analyses have revealed the presence of a large family of the non-RD receptor kinases at the cell surface, with 35 encoded in the Arabidopsis genome and 328 found in the rice genome (Dardick et al., 2006). These include the Arabidopsis PRRs FLS2 and EFR (Gomez-Gomez et al., 2000, Zipfel et al., 2006), the rice XA26, Pid2 (Chen et al., 2006, Sun et al., 2004), and XA21 (Song et al., 1995). The Arabidopsis BRI1-associated receptor kinase 1 (BAK1) that associates with FLS2 is an RD kinase (Chinchilla et al., 2007, Li et al., 2002), suggesting that RD receptor kinases may need to associate with non-RD PRRs to transduce the immune response.
The majority of RD receptor kinase are regulated by autophosphorylation of the activation loop, a centrally located domain that is positioned close to the catalytic center (Adams, 2003). In contrast, non-RD receptor kinases, the activation loop is not autophosphorylated. These results suggest that this important class of non-RD kinases employ alternative mechanisms for activation (Dardick et al., 2006).
The XA21 LRR recognizes Ax21
Based on models for animal receptor kinase function, we proposed that the LRR domain of XA21 recognizes Ax21 and that this recognition activates downstream phosphorylation events (Ronald, 1997). In support of this hypothesis, we showed that a natural variant of XA21, called XA21 family member D (designated XA21D), which lacks the transmembrane and kinase domains, is able to confer partial resistance to Xoo expressing Ax21 (Wang et al., 1998). Xa21D is 99% identical to Xa21 LRR in nucleotide sequence and confers Ax21–specific resistance. Based on these results, we hypothesized that the XA21D and XA21 LRR domain bind directly to Ax21 (Wang et al., 1998). Due to the lack of both the transmembrane and kinase domain, the secreted XA21D was predicted form a heterodimer with an unidentified, endogenous receptor kinase (Wang et al., 1998). We hypothesized that, upon Ax21 binding to XA21D, the unidentified intracellular domain of the unidentified receptor kinase would be activated, partially transducing the defense response and leading to partial resistance phenotype (Wang et al., 1998).
In other words, the kinase activity of XA21 is at least partially dispensable for the innate immune response. Supporting this hypothesis, we subsequently demonstrated that a mutation in the conserved Lys736 residue (XA21K736E) in the XA21 kinase domain that is required for catalytic activity can still partially function in resistance, with levels of resistance similar to that observed for that of XA21D (Liu et al., 2002).
Despite this hypothesis , we have not yet identified an XA21 co-regulator. An important discovery in 2002 by two independent research groups identified such a co-regulator in Arabidopsis, called BAK1 (Li et al., 2002, Nam et al., 2002). Arabidopsis FLS2 form heterodimers with BAK1 demonstrating the existence of a co-regulator in Arabidopsis PRR-mediated immunity (Chinchilla et al., 2007, Heese et al., 2007). Further investigations demonstrated that BAK1 also functions with multiple PRRs including EFR (Chinchilla et al., 2007, Heese et al., 2007, Shan et al., 2008, Kemmerling et al., 2007). Taken together, the results of XA21D, XA21K736E and the studies of Arabidopsis BAK1 support the existence of a co-regulator functioning with XA21. Whether or not this hypothetical co-regulator can associate with the other predicted 328 non-RD receptor kinases in rice is an important question.
Activation of XA21 is regulated by the JM domain
It is now clear that the JM domain of receptor kinases can play an important role in regulating the function of kinase. For example, in animals, deletion of the JM domain of the ErbB-1 (epidermal growth factor receptor, an RD receptor kinase) results in a severe loss of tyrosine phosphorylation (Thiel et al., 2007). Two conserved tyrosine phosphorylation sites Tyr605 and Tyr611 of EphB2 (Eph receptor B2) are essential for EphB2 kinase autophosphorylation and biological responses (Zisch et al., 2000, Binns et al., 2000). Phosphorylation of the JM domain of the TβR-I (transforming growth factor β receptor, an RD receptor kinase) eliminates the binding site for the FKBP12 (12-kDa FK506-binding protein) inhibitor protein, leading to activation of the TβR-I kinase (Huse et al., 2001, Hubbard, 2001).
XA21/Ax21 binding is hypothesized to activate the non-RD kinase domain via JM domain regulation, leading to XA21 autophosphorylation and/or transphosphorylation of downstream target proteins (Xu et al., 2006a, Wang et al., 2006b). In support of this hypothesis several key residues have recently been shown to be critical for autophosphorylation or transphosphorylation. For example, autophosphorylation of the XA21 JM residues Ser686, Thr688, and Ser689 are important stabilizers of the XA21 protein (Xu et al., 2006a). Transgenic rice expressing XA21 mutants with either single or triple alanine-replacement mutant of these three sites display slightly compromised resistance compared to the wild type XA21 (Xu et al., 2006a). In addition, yeast two-hybrid studies have been shown that Thr705 in the XA21 JM region is required for binding to XA21 binding protein (XBs) including XB3, XB10, XB15, and XB24 (Park et al., 2008, Chen et al., 2010a). More recently, we have shown that the XA21 JM residue Thr705 is essential for XA21 autophosphorylation and XA21-mediated immunity (Chen et al., 2010a). The replacement of Thr705 by an alanine or a glutamic acid abolishes XA21 autophosphorylation and eliminates the interactions between XA21 and XB3, XB10, XB15, and XB24 in yeast or rice. These results suggest that after being autophosphorylated, Thr705 may transfer its phosphoryl group to another XA21 residue, which would activate XA21. Although Thr residues analogous to Thr705 of XA21 are present in the JM domains of most RD and non-RD receptor kinases in plants, this residue is not required for autophosphorylation of the Arabidopsis RD receptor kinase BRI1 (Chen et al., 2010a, Wang et al., 2006a). Additional research is needed to assess whether Thr705 autophosporylation is critical for function of other non-RD receptor kinases.
XA21-mediated signaling components: XB3, XA21 binding protein 3, a RING finger ubiquitin ligase
In animals, TLR1, TLR2, TLR4, and TLR6 signaling proceeds through adaptor molecule myeloid differentiation factor 88 (MyD88) (Brikos et al., 2008). MyD88 associated with TLRs to recruit the non-RD serine/threonine kinase, IRAK1. IRAK1 associates with tumor necrosis factor receptor associated factor 6 (TRAF6), a RING (really interesting new gene) finger ubiquitin ligase (Muzio et al., 2000). TRAF6 autoubiquitinates and activates downstream mitogen-activated protein kinase (MAPK) cascades, which mediate downstream events, such as degradation of inhibitor of nuclear factor κB (IκB) and release of nuclear factor κB (Bochud et al., 2007, Suzuki et al., 2002).
Similarly, in vitro assays have shown that the XA21 kinase transphosphorylates the RING finger ubiquitin ligase XB3 and that XB3 is autoubiquitinated in vitro. XB3 is required for effective XA21-mediated resistance (Wang et al., 2006b). Given the functional and structural parallels between XB3 and TRAF6, it is tempting to speculate that XB3 also activates a MAPK cascade. In support of the involvement of MAPK cascade in plant innate immunity, flg22 triggers a rapid and strong activation of MPK3, MPK4, and MPK6 in Arabidopsis (Droillard et al., 2004). On the basis of experiments using transient expression in protoplasts, the MAPK cascade MEKK1-MKK4/MKK5-MPK3/MPK6 was shown to be critical for the FLS2-mediated immune response (Asai et al., 2002). EFR-mediated immunity also induces a rapid activation of MAPKs (Zipfel et al., 2006). A direct role for a MAPK cascade in Xa21-mediated immunity has not yet been demonstrated.
XB10, a WRKY transcriptional factor
In animals, one of key mechanisms of PRR-triggered innate immunity is the activation of defense-related genes, as mediated by transcription factors (Arancibia et al., 2007). For example, PAMP-triggered TLRs leads to the activation of transcription factor NF-κB and the expression of immune response genes (Wan et al., 2010, Arancibia et al., 2007). In plants, which lack NR-κB orthologs, studies have shown that instead WRKY transcription factors are the key regulators (Eulgem, 2005). For example, in Arabidopsis, WRKY22 and WRKY29 function downstream of FLS2-mediated immune response. Overexpression of the AtWRKY29 constitutively activates the plant defense response against bacterial invasion (Asai et al., 2002). Also in Arabidopsis, loss of WRKY70 function compromises both basal defense responses to bacterial and fungal pathogens and RPP4 (recognition of Peronospora parasitica 4)-mediated race-specific resistance to Hyaloperonospora parasitica (Li et al., 2006, Li et al., 2004, Knoth et al., 2007). In barley, overexpression of either HvWRKY1 or HvWRKY2 compromises both the basal defense response and MLA10-mediated race-specific resistance to Blumeria graminis (Shen et al., 2007).
In rice, OsWRKY62 (XB10) has been shown to regulate XA21-mediated immune response (Peng et al., 2008), indicating another level of conservation between the Arabidopsis and rice PRR signaling pathways. Transgenic rice plants overexpressing OsWRKY62 are compromised in XA21-mediated immunity to Xoo, suppressing the activation of defense-related genes including OsPR1 and OsPR10 (Peng et al., 2008). These results indicate that OsWRKY62 can function as a negative regulator of innate immunity.
OsWRKY28, OsWRKY71 and OsWRKY76, together with OsWRKY62, comprise the rice WRKY IIa subfamily (Peng et al., 2010). Transgenic lines overexpressing all four genes showed resistance against Xoo, displaying activation of OsPR10 expression. These results indicate a functional interaction between WRKY IIa members in regulating plant innate immunity (Peng et al., 2010). WRKY IIa proteins contain putative leucine zipper motifs at the N-terminus, suggesting potential dimerizations between proteins. It has been shown that leucine zipper motifs are critical for the physical interaction of WRKY IIa protein in Arabidopsis (Xu et al., 2006b). Therefore, it may be that different combinatorial dimers formed by WRKY IIa proteins may exhibit different functions in regulating target gene expression (Peng et al., 2010). Although this study suggests a functional link between OsWRKYs and XA21 in XA21-mediated immunity to Xoo, the physical location of in vivo interaction remains to be elucidated.
XB15, a protein phosphatase 2C
Although PRR-mediated immune responses are clearly essential for innate immunity in both plants and animals, sustained or highly induced immune response can be harmful (Lang et al., 2007). It is therefore necessary that PRR signaling through non-RD kinases be under tight negative regulation.
In contrast to animals, where negative regulators have been shown to acting at multiple levels within TLR signaling cascades, negative regulation of plant innate immunity is not well understood. One important class of negative regulators are protein phosphatase 2Cs (PP2Cs), a group of serine/threonine phosphatases (Schweighofer et al., 2004). Arabidopsis PP2C, kinase-associated PP (KAPP), interacts with many receptor kinases including CLAVATA1 (CLV1), somatic embryogenesis receptor kinase 1, BRI1, BAK1, and FLS2 (Braun et al., 1997, Stone et al., 1998, Ding et al., 2007, Gomez-Gomez et al., 2001, Shah et al., 2002). Overexpression of KAPP in Arabidopsis results in loss of sensitivity to flagellin treatment, suggesting that KAPP negatively regulates the FLS2-mediated immune response (Gomez-Gomez et al., 2001). Although the rice KAPP protein emerged as a good candidate for being a negative regulator of the XA21-mediated innate immune response, it does not interact with XA21 (van der Knaap et al., 1999). Instead, another PP2C (XB15) was isolated from yeast two hybrid screen using the intracellular portion of XA21 as bait (Park et al., 2008). Additional in vitro biochemical experiments showed that XB15 can effectively dephosphorylated XA21 in a temporal- and dosage-dependent manner. Xb15 mutant line and Xb15 RNAi lines displayed spontaneous cell death in the absence of obvious stress and disease with constitutive expression of defense-related OsPR genes (Park et al., 2008). Overexpression of the Xb15 in an XA21 rice line compromised resistance to the Xoo, demonstrating that XB15 negatively regulates the XA21-mediated innate immune response (Park et al., 2008).
XB24, a novel ATPase
Recently, we have shown that XB24, a previously uncharacterized ATPase interacts with XA21 and regulates XA21-mediated immunity (Chen et al., 2010b). XA24 has no significant motifs except for a C-terminal ATP synthase alpha-and-beta-subunits signature (ATPase) motif with sequence PSINERESSS. None of plants and human proteins containing a conserved ATPase motif share similarity beyond the ATPase motif with XB24. XB24 displays significant ATP hydrolysis activity while XB24 mutant containing a single amino acid change Ser154 with Ala had only negligible ATPase activity, indicating that the XB24 protein possesses an ATPase activity and that amino acid Ser154 is essential for its ATPase activity (Chen et al., 2010b). XB24 promotes autophosphorylation of the XA21 protein in vitro. XB24 is not transphosphorylated by the XA21 protein in the absence or presence of Xoo expressing Ax21 (Chen et al., 2010b). Autophosphorylation of XA21 is enhanced in the presence of rice-expressed XB24 but not in the XB24 mutant, demonstrating that XB24 enhances XA21 autophosphorylation and that its ATPase activity is required for this function. In planta silencing of Xb24 expression enhances XA21-mediated disease resistance (Chen et al., 2010b).
Based on these results, we propose that XB24 physically associates with XA21 and promote phosphorylation of certain Ser/Thr sites on XA21, keeping the XA21 protein in an inactive state (Chen et al., 2010b). Upon recognition of Ax21, the XA21 kinase becomes activated, triggering downstream defense responses. The mechanism(s) for XA21 activation following perception of Ax21 likely requires dissociation of XA21 from XB24 and/or removal of the XB24-promoted phosphorylation. Together with our previously studies that the association between XB24 and XA21 is compromised while the association between XB15 and XA21 is enhanced upon Ax21 triggering (Park et al., 2008, Chen et al., 2010b), our model suggests that the regulation by XB24 occurs before Ax21 recognition while regulation by XB15 occurs after Ax21 recognition.
Another regulation in the endoplasmic reticulum: Quality control of XA21 BiP-heat shock protein 70
In animals, extracellular PRRs are translated on the endoplasmic reticulum (ER) membrane, enter the ER lumen, and undergo glycosylation (Akashi-Takamura et al., 2008, Ruddock et al., 2006). For further protein processing, before being translocated to the PM, newly synthesized PRRs interact with different ER chaperones that will assist them to fold properly and to avoid aggregation in a process called ER quality control (ER QC) (Ruddock et al., 2006, Meusser et al., 2005). Therefore, most TLRs interacts with at least one of ER-resident chaperones for the protein folding and trafficking. For example, ER chaperone protein, gp96, is required for functional expression of both intracellular and cell-surface TLRs including TLR2, TLR4, TLR5, TLR7, and TLR9 (Yang et al., 2007). In addition to ER chaperones, N-glycosylation, which is essential for the function of TLRs (Leifer et al., 2004), is also known to be important for correct protein folding and ER QC (Kleizen et al., 2004, Meusser et al., 2005).
In Arabidopsis, components in the ER QC, calreticulin3 (CRT3) and UDP-glucose: glycoprotein glycosyltransferase (UGGT), are required for EFR function, as loss of either CRT3 or UGGT leads to complete loss of EFR accumulation (Saijo et al., 2009, Li et al., 2009). In addition, ER protein complex compromising stromal-derived factor-2 (SDF2), heat shock protein 70 (HSP70) BiP, and co-chaperone HSP40 ERdj3B was indispensible for proper biogenesis of EFR, demonstrating a physiological involvement of ER QC and PRR function in plant (Nekrasov et al., 2009).
The involvement of ER QC and ER-associated degradation (ERAD) in XA21-mediated immunity was demonstrated through isolation of an in vivo XA21 protein complex (Park et al., 2010). An approximately 75 kDa protein co-immunoprecipiated with XA21 was identified as OsBiP3 through LC-MS/MS sequencing. Overexpression of BiP3 compromised XA21-mediated immunity. Transgenic lines overexpressing OsBiP3 displayed significantly decreased XA21 accumulation and inhibited a protein processing of XA21, suggesting that continuous and/or prolonged binding of overexpressed OsBiP3 results in XA21 degradation possibly via ERAD. This result also suggests that accumulation of BiPs is able to attenuate a receptor-mediated signal transduction pathway causing an ER stress by targeting the receptor to the ERAD. Supporting this hypothesis, BiP has been known to target permanently misfolded proteins for ERAD in mammals and yeast when prolonged ER stress induce excessive loading of unfolded and/or misfolded proteins (Kleizen et al., 2004).
To investigate if BiP3 overexpression affects signaling pathways mediated by other receptor kinases, we investigated OsBRI1-mediated responses to brassinolide. Although OsBRI1 shows an overall structural similarity with XA21 (He et al., 2000), unlike XA21 it falls into the RD class of kinases. We found that BiP3 overexpressing lines maintain sensitivity to brassinolide, indicating that BiP3 overexpression does not interfere with OsBRI1-mediated signaling. Taken together, these results indicate that altered BiP3 expression does not affect all RK-mediated signaling pathways and does not affect a general ER stress response.
Similar to Arabidopsis SDF2, OsSDF2 is involved in XA21-mediated immunity. XA21 transgenic lines silenced for OsSDF2 displayed severe disease symptoms after Xoo inoculation, indicating that XA21-mediated immunity is regulated by OsSDF2 (Park, unpublished data). It has been also shown that XA21 and EFR are highly glycosylated, which may occur in the ER during maturation (Nekrasov et al., 2009, Park et al., 2010). Therefore, the conserved requirements for the ER proteins, BiP and SDF2, for both XA21 and EFR biogenesis provides strong evidence that ER QC is involved in plant innate immunity, playing a role in PRR trafficking to the PM.
Perspectives
Recognition of PAMPs by PRRs is critical to both plant and animal survival. We have recently shown that Ax21 is a sulfated peptide that binds the rice PRR, XA21 (Lee et al., 2009). The high level of conservation of Ax21 in Xanthomonas, in Xylella and in the human pathogen Stenotrophomonas suggests a critical role for this protein in the biology of these pathogens. Preliminary studies suggest that Ax21 may function in quorum-sensing, a process where bacterial molecules can serve as signals to recognize bacterial population size, leading to changes in expression of specific genes (Bassler et al., 2006, Lee et al., 2006). Currently, we are further investigating such a function for Ax21.
Although PRR activation processes are believed to cause rapid phosphorylation of many proteins through mostly unknown regulatory networks, none of direct targets of PRRs have yet been reported (Boller et al., 2009, Gomez-Gomez et al., 2002). It is also unknown how PRR phosphorylation can activate ion channels and the NADPH oxidase complex. To answer these fundamental questions and further understand XA21-mediated immune response, identification of additional components in the XA21 complex is essential. One approach is to use phosphoproteomic analysis and quantitative LC-MS/MS phosphopeptide comparisons to identify proteins differentially phosphorylated after Ax21 treatment. Proteins that show unique phosphorylation patterns would be good candidates for XA21 direct target(s).
Because PAMPs are essential for survival or pathogenicity, they cannot be easily mutated without compromising microbial fitness (Kunze et al., 2004, Gomez-Gomez et al., 1999). Thus approaches directed at harnessing PRR-mediated immunity will be a useful strategy to develop enhanced resistance in agricultural crops. For example, rice varieties carrying Xa21 carry robust resistance to diverse strains of Xoo (Wang et al., 1996).
Non-RD domain, a newly recognized hallmark of receptor kinases that function as PRRs, are highly expanded in rice compared to Arabidopsis (35 in Arabidopsis and 328 in rice). For example, the LRR XII subfamily, which includes FLS2, EFR, and XA21, contains over 100 members in rice but only eight in Arabidopsis (Dardick et al., 2006). In addition, there are several non-RD receptor kinase subfamilies that are specific to rice and that are lacking in Arabidopsis. Thus although it appears that all Arabidopsis subfamilies have a rice counterpart, the converse is not true. Rice carries over 70 members of the WAKa, WAKc and WAKL families; none are present in Arabidopsis (Dardick et al., 2006). The large numbers of non-RD receptor kinases in rice suggest that there are probably equally large numbers of extracellular pathogen derived ligands yet to be discovered. To determine if the observed rice/Arabidopsis difference in the number of non-RD receptor kinases is similar between other monocotyledonous and dicotyledonous species, a comprehensive analysis of newly released plant genome sequences, including Medicago, Maize, Wheat, Brassica, Sorghum, Brachypodium, is needed (IBI, 2010, Paterson et al., 2009).
Acknowledgment
We thank Dr. Christopher Dardick at United States Department of Agriculture for critical comments for the manuscript. This work was supported by NIH grant GM055962 to PCR
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