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Abstract
Innate immune responses are induced in plants and animals through perception of Damage Associated Molecular Patterns. These immune responses are suppressed by pathogens during infection. A number of studies have focussed on identifying functions of plant pathogenic bacteria that are involved in suppression of Pathogen Associated Molecular Pattern induced immune responses. In comparison, there is very little information on functions used by plant pathogens to suppress Damage Associated Molecular Pattern induced immune responses. Xanthomonas oryzae pv. oryzae, a gram negative bacterial pathogen of rice, secretes hydrolytic enzymes such as LipA (Lipase/Esterase) that damage rice cell walls and induce innate immune responses. Here, we show that Agrobacterium mediated transient transfer of the gene for XopN, a X. oryzae pv. oryzae type 3 secretion (T3S) system effector, results in suppression of rice innate immune responses induced by LipA. A xopN- mutant of X. oryzae pv. oryzae retains the ability to suppress these innate immune responses indicating the presence of other functionally redundant proteins. In transient transfer assays, we have assessed the ability of 15 other X. oryzae pv. oryzae T3S secreted effectors to suppress rice innate immune responses. Amongst these proteins, XopQ, XopX and XopZ are suppressors of LipA induced innate immune responses. A mutation in any one of the xopN, xopQ, xopX or xopZ genes causes partial virulence deficiency while a xopN- xopX- double mutant exhibits a greater virulence deficiency. A xopN- xopQ- xopX- xopZ- quadruple mutant of X. oryzae pv. oryzae induces callose deposition, an innate immune response, similar to a X. oryzae pv. oryzae T3S- mutant in rice leaves. Overall, these results indicate that multiple T3S secreted proteins of X. oryzae pv. oryzae can suppress cell wall damage induced rice innate immune responses.
Citation: Sinha D, Gupta MK, Patel HK, Ranjan A, Sonti RV (2013) Cell Wall Degrading Enzyme Induced Rice Innate Immune Responses Are Suppressed by the Type 3 Secretion System Effectors XopN, XopQ, XopX and XopZ of Xanthomonas oryzae pv. oryzae. PLoS ONE 8(9): e75867. https://doi.org/10.1371/journal.pone.0075867
Editor: Esteban Chaves-Olarte, Universidad de Costa Rica, Costa Rica
Received: April 23, 2013; Accepted: August 16, 2013; Published: September 26, 2013
Copyright: © 2013 Sinha et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by grants to RVS from the Department of Biotechnology (DBT), Government of India and the Plant-Microbe and Soil Interactions project of the Council of Scientific and Industrial Research (CSIR). DS and MKG were supported by doctoral and post-doctoral fellowships, respectively, from the DBT. AR was supported by a doctoral fellowship from CSIR. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
The innate immune systems of plants and animals are activated by the perception of danger signals in the form of pathogen associated molecular patterns (PAMPs) and damage-associated molecular patterns (DAMPs). PAMPs are indispensable, structurally conserved molecular features that are unique to a broad class of microbes and typify ‘non-self’ because they are not present in the host [1] whereas DAMPs are mostly endogenous molecules which are released upon tissue injury that occurs during growth, stress and pathogen entry [2]. Pattern recognition receptors (PRRs) are involved in perception of PAMPs and DAMPs. In animals, recognition of either PAMPs or DAMPs activates the innate immune system and results in various inflammatory responses [3]. In plants, the perception of these danger signals results in the activation of the first layer of the plant innate immune system which is termed as PAMP-triggered immunity or PTI [4,5]. Suppression of PTI appears to be a crucial attribute of plant pathogens. A number of studies have shown that Gram negative plant pathogenic bacteria suppress PTI using proteins that are secreted into plant cells via the type 3 secretion system (T3S).
The gram negative bacterial genus Xanthomonas is comprised of bacteria that cause almost ~ 400 different plant diseases. These bacteria secrete a number of effector proteins into their host cells using the T3S. These include both TAL (transcription activator-like) effectors and non-TAL effectors. Unlike TAL effectors which benefit xanthomonads by altering host gene transcription, the non-TAL effectors appear to function in suppression of host innate immunity, presumably by interfering with signaling events. The biochemical functions of the majority of non-TAL effectors are unknown, although a few of them are known to have enzymatic activity. AvrBs2 has putative glycerophosphoryldiester phosphodiesterase activity [6] whereas XopQ is predicted to have a inosine-uridine nucleoside N-ribohydrolase activity [7].
The role of individual non-TAL effectors of xanthomonads in suppression of host innate immunity and promotion of virulence has been examined. The non-TAL effectors of Xanthomonas campestris pv. vesicatoria such as XopN [8], XopJ [9], XopB and XopS [10] have been shown to suppress PAMP induced innate immune responses such as callose deposition in host plants. Suppression of plant defense responses has been also reported by X. campestris pv. vesicatoria effector XopX when expressed ectopically in Nicotiana benthamiana [11] and XopD, a SUMO protease, that promotes pathogen growth at later stages of infection in the host plant tomato [12]. In addition, upon ectopic expression, X. oryzae pv. oryzae effectors XopZ [13] and XopR [14] have been reported to suppress PAMP induced callose deposition in N. benthamiana and Arabidopsis respectively. Furthermore, mutations in many of these effector proteins renders the pathogen partially virulence deficient and impaired in symptom development on their respective hosts. Other T3S secreted non-TAL effectors which have been reported to have a role in virulence and symptom development are HpaF [15], AvrXv4 [16] and AvrXccC [17]. In contrast to the large body of work that is available on suppression of PTI, very little information is available about the functions involved in suppression of DAMP triggered innate immunity (DTI) either in xanthomonads or in other plant pathogens.
The plant cell wall is a formidable barrier for plant pathogens. Plant cell wall degradation is a key aspect of microbial plant pathogenesis. Plant pathogenic fungi and bacteria secrete a cocktail of specific hydrolytic enzymes like cellulases, xylanases, polygalacturonases, pectate lyases, pectin esterases etc. to sever different components of the plant cell wall [18]. However, these cell wall degrading enzymes are double edged swords, as the cell wall degradation products that are released by their action serve as marks of infection that are sensed by the plant as DAMPs and results in activation of potent innate immune responses [19,20].
The rice pathogen, Xanthomonas oryzae pv. oryzae, secretes several cell wall degrading enzymes including a lipase/esterase (LipA), cellulase (ClsA), cellobiosidase (CbsA), and xylanase (XynB), using a Type 2 secretion (T2S) system [21–23]. Mutations in genes for each of these individual T2S secreted proteins cause a reduction in X. oryzae pv. oryzae virulence indicating that they are important for the ability of this pathogen to cause disease. Purified preparations of enzymes LipA, ClsA and CbsA have been shown to induce innate immune responses such as callose deposition and programmed cell death in rice tissues [22]. Enzyme activity is required for induction of innate immunity as seen from the observation that a point mutation (S176A) in the active site of the LipA protein results in loss of enzyme activity and ability to induce immune responses [23]. X. oryzae pv. oryzae can suppress cell wall damage induced innate immune responses using a T3S system. The T3S- mutant is itself an inducer of innate immunity and a T2S- T3S- double mutant is compromised in induction of innate immunity suggesting that T2S secreted proteins play an important role in induction of innate immunity during infection [22]. The X. oryzae pv. oryzae T3S secreted effectors (T3Es) that are involved in suppression of cell wall damage induced rice innate immunity have not yet been identified.
In this study, we tested the ability of 16 different T3S secreted non-TAL effectors of X. oryzae pv. oryzae [24] to suppress cell wall damage induced innate immunity in rice. We found that Agrobacterium mediated transient transfer of xopN gene of X. oryzae pv. oryzae suppressed cell wall damage induced programmed cell death in rice roots and callose deposition in rice leaves mediated by enzyme LipA. However, the ability of a xopN- mutant to suppress innate immunity induced by LipA indicated the presence of other functionally redundant T3S effectors. We thus screened 15 other T3S secreted proteins of X. oryzae pv. oryzae and identified XopQ, XopX and XopZ proteins as suppressors of LipA induced innate immunity in rice. For the remaining 12 effectors, namely XopF, XopK, XopP, XopR, XopT, XopU, XopV, XopW, XopY, XopAA, XopAB and AvrBs2, no evidence for suppressor activity was found although it cannot be completely ruled out. This is the first report showing role of bacterial T3Es in suppression of DTI in host-pathogen interactions.
Results
XopN protein of X. oryzae pv. oryzae suppresses cell wall damage induced programmed cell death in rice roots
In a previously published study of Xanthomonas T3S effectors, mutation of the xopN gene of the tomato pathogen X. campestris pv. vesicatoria was found to affect virulence [7]. It had also been suggested, based on the presence of ARM/HEAT repeats, that the XopN protein might modulate plant signal transduction by interfering with host proteins containing these repeats. Therefore, we decided to first address the ability of X. oryzae pv. oryzae XopN protein to suppress host defence responses induced by cell wall degrading enzyme, LipA.
Localized programmed cell death (PCD) is an important host defence response against pathogen attack [25]. In a previous study, it was shown that a PCD is induced in rice roots by treatment with X. oryzae pv. oryzae secreted hydrolytic enzymes such as LipA (Lipase/esterase A) [22]. The extent of PCD was assessed by staining with propidium iodide (PI) and visualization under a confocal laser scanning microscope. We cloned the xopN gene into the MCS (multiple cloning site) of the binary vector pUbi-C1300 [26] wherein its expression is under the control of the maize ubiquitin promoter. Rice roots treated with LipA (Figure 1B) took up PI and the PI stained material was dispersed within the cell, indicating nuclear fragmentation. Buffer (Figure 1A) treated rice roots excluded PI and showed only cell wall associated fluorescence. Rice roots that were pre-treated with Agrobacterium strain EHA105/pUbi-xopN followed by treatment with LipA (Figure 1C) excluded PI and exhibited only cell wall associated fluorescence indicating absence of any cell death. In contrast, LipA (Figure 1D) treatment caused extensive cell death in roots which had been pre-treated with Agrobacterium strain EHA105/pUbi (empty vector).
(A) to (D) Rice roots were treated with one of the following: buffer (A); LipA (B); pretreatment with EHA105/pUbi-xopN followed by treatment with LipA (C); pretreatment with EHA105/pUbi followed by treatment with LipA (D). Treated roots were subsequently stained with propidium iodide (PI) and sectioned using confocal microscopy. Internalisation of PI is indicative of defense response-associated programmed cell death in rice roots. Scale bar measures 20µm. (E) to (H) Rice leaves were infiltrated with one of the following: buffer (E); LipA (F); EHA105/pUbi-xopN along with LipA (G); EHA105/pUbi along with LipA (H). The treated leaves were subsequently stained with aniline blue and visualized under an epifluorescence microscope. White dots in these pictures are indicative of callose deposition. Scale bar measures 100µm. (I) Mean and standard deviation were calculated for number of callose deposits observed in an area of 0.60 mm2. Data were collected from at least five leaves per treatment in each experiment (three experiments indicated as ExpI, ExpII and ExpIII) and two to three different viewing areas from the infiltrated region of each leaf. Statistically significant differences at P < 0.05 (Student’s two-tailed t test for independent means) were obtained from leaves infiltrated with EHA105/pUbi-xopN along with LipA as compared to leaves treated with LipA alone. These differences were not observed in leaves infiltrated with EHA105/pUbi along with LipA as compared to leaves treated with LipA alone. WT Xoo = wild type X. oryzae pv. oryzae. WT Xoo = wild type X. oryzae pv. oryzae.
RT-PCR analysis was performed to confirm that xopN transcripts were expressed in rice roots treated with EHA105/pUbi-xopN (Figure S1). A 123 bp product was obtained after RT-PCR with RNA isolated from rice roots treated with EHA105/pUbi-xopN but was not observed in roots treated with EHA105/pUbi. Also, as expected, a 158 bp RT-PCR product of the rice GAPDH gene was obtained from rice roots that were pre-treated with Agrobacterium (either EHA105/pUbi-xopN or EHA105/pUbi) (Figure S1A).
XopN protein of X. oryzae pv. oryzae suppresses LipA induced callose deposition in rice leaves
Callose deposition is a basal defense response to strengthen the cell wall and is characterized by deposition of a β-1, 3-glucan polymer around the site of pathogen entry [27]. Upon aniline blue staining, callose deposits appear as bright spots when viewed under an epifluorescence microscope. Infiltration of LipA results in induction of callose deposition in rice leaves [22]. We assessed whether Agrobacterium mediated transient transfer of the xopN gene would result in suppression of LipA induced callose deposition. Rice leaves, hand infiltrated with purified LipA (Figure 1F) exhibited substantially higher amounts of callose deposits compared with leaves infiltrated with buffer (Figure 1E) alone. Co-infiltration of LipA (Figure 1G) along with Agrobacterium strain EHA105/pUbi-xopN resulted in suppression of callose deposition to a level that is observed in buffer (Figure 1E) infiltrated leaves. Rice leaves co-infiltrated with LipA (Figure 1H) and Agrobacterium strain EHA105/pUbi (empty vector) exhibited higher amounts of callose deposits that were no different from those observed in leaves infiltrated with LipA (Figure 1F) alone (Figure 1I). These data indicated that transient transfer of the xopN gene of X. oryzae pv. oryzae suppresses callose deposition that is induced by treatment with cell wall degrading enzyme (LipA) in rice leaves.
A xopN- mutant of X. oryzae pv. oryzae retains the ability to suppress rice innate immunity
A xopN gene disruption mutant of X. oryzae pv. oryzae (xopN-) was isolated by homologous plasmid integration. We next tested the ability of a X. oryzae pv. oryzae xopN- mutant to suppress LipA induced innate immunity. To address this issue, rice roots were pre-treated with either xopN- or wild type followed by treatment with purified LipA. The roots were then stained with PI and viewed under a confocal laser scanning microscope. As expected, roots treated with buffer (Figure 2A) exhibited only cell wall associated fluorescence whereas roots treated with purified LipA (Figure 2B) exhibited extensive cell death. Interestingly, pretreatment with either the xopN- (Figure 2C) or wild type (Figure 2D) strains resulted in suppression of LipA induced cell death. Although some of the cells took up PI, the extent of intracellular dispersion of PI staining material was limited as compared to that observed in roots treated with LipA (Figure 2B) alone. This prompted us to check if the X. oryzae pv. oryzae xopN- mutant can also suppress innate immune response associated callose deposition. Co-infiltration of rice leaves with either xopN- (Figure 2G) or wild type (Figure 2H) along with LipA resulted in lesser amounts of callose deposition as compared to infiltration with LipA (Figure 2F) alone. This indicated that a xopN- mutant is proficient in suppression of LipA induced callose deposition in rice leaves (Figure 2I).
(A) to (D) Rice roots were treated with one of the following: buffer (A); LipA (B); pretreatment with xopN- mutant followed by treatment with LipA (C); pretreatment with wild type followed by treatment with LipA (D). Treated roots were subsequently stained with propidium iodide (PI) and viewed under a confocal microscope. Internalisation of PI is indicative of defense response-associated programmed cell death. Scale bar measures 20µm. (E) to (H) Rice leaves were infiltrated with one of the following: buffer (E); LipA (F); xopN- mutant along with LipA (G); wild type along with LipA (H). The infiltrated leaves were stained for callose and visualised under an epifluorescence microscope. Callose deposits appeared as sharp white spots in the viewed field. Scale bar measures 100µm. (I) Mean and standard deviation were calculated for number of callose deposits from an area of 0.60 mm2. Data were collected from at least five leaves per treatment in each experiment (three experiments indicated as ExpI, ExpII and ExpIII) and two to three different viewing areas from the infiltrated region of each leaf. Statistically significant differences at P < 0.05 (Student’s two-tailed t test for independent means) were observed in values obtained from leaves infiltrated with xopN- mutant (or wild type) along with LipA as compared to leaves infiltrated with LipA alone. WT Xoo = wild type X. oryzae pv. oryzae.
Transient expression of xopQ, xopX or xopZ genes of X. oryzae pv. oryzae suppresses cell wall damage induced PCD in rice roots
The ability of a X. oryzae pv. oryzae xopN- mutant to suppress innate immune responses induced by LipA indicated the presence of other functionally redundant T3S effectors. We therefore assessed the ability of 15 non-TAL T3S effectors of X. oryzae pv. oryzae, from the set of previously identified X. oryzae pv. oryzae T3S effectors [24], to suppress LipA induced PCD in rice roots. The genes for 15 of these non-TAL T3S effectors (xopF, xopK, xopP, xopQ, xopR, xopT, xopU, xopV, xopW, xopX, xopY, xopZ, xopAA, xopAB and avrBs2) were cloned into the Agrobacterial T-DNA vector as described in materials and methods. Rice roots were individually pretreated with Agrobacterium strain EHA105 carrying the genes for each of these individual T3S effectors cloned into a T-DNA vector. These roots were subsequently treated with LipA enzyme followed by PI staining and sectioning under confocal laser scanning microscope. As expected, rice roots treated with LipA + 17-β-estradiol (Est) (Figure 3B) exhibited dispersed intracellular PI staining indicating extensive cell death whereas buffer (+Est) (Figure 3A) treated roots showed only cell wall associated fluorescence indicating no cell death. The rice roots pretreated with Agrobacterium strain EHA105 carrying pMDC7-xopQ (Figure 3C), pMDC7-xopX (Figure 3E) or pMDC7-xopZ (Figure 3G) in the presence of Est followed by LipA treatment exhibited cell wall associated fluorescence with no intracellular PI staining. However, in the absence of Est, roots pretreated with these strains followed by LipA treatment showed dispersed intracellular PI staining indicating extensive cell death (Figure 3D, F and H respectively). This indicates that induction of expression of xopQ, xopX or xopZ genes is sufficient for suppression of LipA induced PCD. Pretreatment with EHA105 carrying Agrobacterial T-DNA vector with any of the following genes xopF, xopK, xopP, xopR, xopT, xopU, xopV, xopW, xopY, xopAA, xopAB or avrBs2 did not result in suppression of PCD either in the presence or absence of Est (data not shown). Thus, only XopQ, XopX and XopZ appear to function as suppressors of LipA induced PCD in rice roots. RT-PCR analysis was performed to confirm that xopQ, xopR, xopX and xopZ transcripts were expressed in rice roots treated with EHA105/pMDC7-xopQ/R/X/Z gene only in the presence of estradiol (Figure S1B). RT-PCR analysis also indicated that the xopP gene is expressed in rice roots following transient assays using EHA105/pUbi-xopP (Figure S1A). The xopP and xopR genes were chosen for expression analysis as representatives of T3S effectors which do not suppress cell death in the transient transfer assay. The results indicate that, at least for xopP and xopR and possibly for the other T3S effectors that do not suppress cell death, the absence of suppression is not due to lack of expression of the gene in rice roots during transient assays.
Rice roots were treated with the following: buffer + Estradiol (Est; A); LipA + Est (B); pretreatment with EHA105/pMDC7-xopQ with Est (C); EHA105/pMDC7-xopX with Est (E) and EHA105/pMDC7-xopZ with Est (G) followed by treatment with LipA and Est (C, E and G); pretreatment with EHA105/pMDC7-xopQ (D); EHA105/pMDC7-xopX (F) and EHA105/pMDC7-xopZ (H) followed by treatment with LipA (D, F and H). The roots were subsequently stained with propidium iodide (PI) and visualized under a confocal microscope. Dispersed intracellular PI staining is indicative of programmed cell death in rice roots. Scale bar measures 20µm.
Transient expression of xopQ, xopX or xopZ genes of X. oryzae pv. oryzae suppresses cell wall damage induced callose deposition in rice leaves
We then proceeded to assess whether transient transfer of any of these 15 non-TAL effectors would suppress LipA induced callose deposition in rice leaves. Co-infiltration of LipA along with Agrobacterium strain EHA105 carrying pMDC7-xopQ (Figure 4C), pMDC7-xopX (Figure 4E) or pMDC7-xopZ (Figure 4G) in the presence of Est resulted in significantly less callose deposition than that observed in LipA and Est (Figure 4B) infiltrated rice leaves. In contrast to this, rice leaves co infiltrated with LipA along with Agrobacterium strain EHA105 carrying pMDC7-xopQ (Figure 4D), pMDC7-xopX (Figure 4F) or pMDC7-xopZ (Figure 4H) in the absence of Est exhibited levels of callose deposits that were similar to those observed in leaves infiltrated with LipA and Est (Figure 4B) (Figure 4I). As observed for the suppression of LipA induced PCD in rice roots, co-infiltration of LipA and EHA105/carrying Agrobacterial T-DNA vector with any of the following genes xopF, xopK, xopP, xopR, xopT, xopU, xopV, xopW, xopY, xopAA, xopAB or avrBs2 did not result in suppression of callose deposition either in the presence or absence of Est (data not shown). These data indicated that xopX, xopQ or xopZ genes were able to suppress LipA induced callose deposition in rice leaves.
Rice leaves were infiltrated with one of the following: buffer + Estradiol (Est; A); LipA + Est (B); EHA105/pMDC7-xopQ + LipA with Est (C) or without Est (D); EHA105/pMDC7-xopX + LipA with Est (E) or without Est (F); EHA105/pMDC7-xopZ + LipA with Est (G) or without Est (H). The leaves were subsequently stained with aniline blue and visualized under an epifluorescence microscope. Callose deposition is seen as white spots in these pictures. Scale bar measures 100µm. (I) Mean and standard deviation were calculated for number of callose deposits observed in an area of 0.60 mm2. Data were collected from at least five leaves per treatment in each experiment (three experiments indicated as ExpI, ExpII and ExpIII) and two to three different viewing areas from the infiltrated region of each leaf. Statistically significant differences at P < 0.05 (Student’s two-tailed t test for independent means) were obtained from leaves co-infiltrated with LipA and EHA105 containing pMDC7-xopQ, pMDC7-xopX or pMDC7-xopZ in the presence of Est as compared to the absence of Est.
A xopN- xopQ- xopX- xopZ- quadruple mutant of X. oryzae pv. oryzae induces callose deposition in rice leaves
A T3S deficient strain of X. oryzae pv. oryzae has been shown to be an inducer of innate immune responses in rice [22]. This has been attributed to its inability to suppress host immune responses induced by DAMPs and possibly PAMPs. The experiments described above indicate that the T3S effectors XopN, XopQ, XopX and XopZ are involved in suppression of LipA induced innate immunity in rice. This prompted us to construct a xopN- xopQ- xopX- xopZ- quadruple mutant of X. oryzae pv. oryzae and determine if it is able to, like a T3S- mutant, induce innate immunity in rice. The ability to induce callose deposition was assessed by infiltrating rice leaves with wild type X. oryzae pv. oryzae, xopN- xopQ- xopX- xopZ- quadruple mutant or T3S- mutant. Infiltration of wild type X. oryzae pv. oryzae (Figure 5B) resulted in induction of a basal level of callose deposition that is no different from that observed in water (Figure 5A) infiltrated leaves. Rice leaves infiltrated with xopN- xopQ- xopX- xopZ- quadruple mutant (Figure 5C) exhibited higher amounts of callose deposits which were similar in amounts to those observed in leaves infiltrated with the T3S- mutant (Figure 5D). In addition, like the T3S- mutant, the xopN- xopQ- xopX- xopZ- quadruple mutant induced PCD in rice roots (Figure S2). These data indicate that a X. oryzae pv. oryzae quadruple mutant that is defective in all four of the xopN, xopQ, xopX and xopZ genes induces innate immune responses such as callose deposition and PCD to the same extent as a T3S- mutant strain of X. oryzae pv. oryzae.
Rice leaves were infiltrated with one of the following: water (A); wild type Xoo (B); xopN- xopQ- xopX- xopZ- quadruple mutant (C) and T3S- mutant (D). The treated leaves were subsequently stained with aniline blue and visualized under an epifluorescence microscope. White dots in these pictures are indicative of callose deposition. Scale bar measures 100µm. (E) Mean and standard deviation were calculated for number of callose deposits observed in a leaf area of 0.60 mm2. Data were collected from at least five leaves per treatment in each experiment (three experiments indicated as ExpI, ExpII and ExpIII) and two to three different viewing areas from the infiltrated region of each leaf. Statistically significant differences at P < 0.05 (Student’s two-tailed t test for independent means) were obtained from leaves infiltrated with a xopN- xopQ- xopX- xopZ- quadruple mutant as compared to leaves treated with either water or wild type. These differences were not observed in leaves infiltrated with xopN- xopQ- xopX- xopZ- quadruple mutant as compared to leaves treated with T3S- mutant. WT Xoo = wild type X. oryzae pv. oryzae.
In order to assess the effect of addition of a single effector to the quadruple mutant, we introduced the xopN gene into the xopN- xopQ- xopX- xopZ- quadruple mutant and assessed the ability of the xopN complemented strain to induce callose deposition in rice leaves. Rice leaves infiltrated with either xopN- xopQ- xopX- xopZ-/xopN+ or xopQ- xopX- xopZ- triple mutant exhibited similar amounts of callose deposits which were lower than those observed in leaves infiltrated with xopN- xopQ- xopX- xopZ- quadruple mutant. Infiltration of a xopN- xopQ- xopX- xopZ-/pHM1 (vector control) strain resulted in callose amounts similar to those observed in xopN- xopQ- xopX- xopZ- infiltrated leaves (Figure S3). These data indicate that the enhanced ability of the quadruple mutant to induce immune responses is due to loss of an intact xopN gene and not due to a strange recombination event that might have occurred during creation of the xopN mutation in the triple mutant background during generation of the quadruple mutant. Furthermore, the ability to induce callose deposition was assessed for X. oryzae pv. oryzae xopN-, xopQ-, xopX- or xopZ- single mutant strains. The number of callose deposits in rice leaves infiltrated with any single X. oryzae pv. oryzae effector mutant was comparable to those observed in wild type infiltrated leaves (Figure S4). Similarly, the number of callose deposits in rice leaves infiltrated with either one of two double mutants (xopN- xopX- and xopQ- xopX-) or the triple mutant (xopQ- xopX- xopZ-) were comparable to those observed in wild type infiltrated leaves (data not shown). These data demonstrate that multiple T3S effectors are required for full suppression of rice immune responses.
Mutations in xopN, xopQ, xopX and xopZ genes affect virulence of X. oryzae pv. oryzae on rice
A xopX- mutant of X. oryzae pv. oryzae was isolated by creating an inframe deletion in the xopX gene of the wild type strain described in materials and methods. A xopN- xopX- double mutant of X. oryzae pv. oryzae was created by homologous plasmid integration of pK18mob-xopN in the xopX- background. The virulence of X. oryzae pv. oryzae strains xopN- mutant, xopN-/xopN+; which carries xopN for complementation, xopN-/pHM1; vector control, xopX- mutant, xopX-/xopX+; which carries xopX for complementation, xopX-/pHM1; vector control and xopN- xopX- double mutant was assessed by clip inoculation of rice leaves. Lesion lengths were measured 7 days after inoculation (DAI). At 7 DAI, the xopN- mutant and xopX- mutant strains showed lesions significantly reduced in length as compared to lesions produced by wild type indicating a partial virulence deficiency. The partial virulence deficiency exhibited by xopN- mutant and xopX- mutants was complemented by the respective genes in trans as the lesions observed in rice leaves clip inoculated with strains xopN-/xopN+ and xopX-/xopX+ were significantly longer than that seen in rice leaves inoculated with the xopN- mutant and xopX- mutant strains. The lesion lengths caused by the xopN- xopX- double mutant strain were significantly reduced compared to the lesions produced by either xopN- mutant or xopX- mutant strains (Figure 6A). This demonstrates that mutations in xopN and xopX genes caused a partial virulence deficiency that can be complemented by the expression of respective genes in trans and a xopN- xopX- double mutant exhibited much more pronounced virulence deficiency than either of the single mutants.
Leaves of susceptible rice variety Taichung-Native 1 (TN-1) were clip inoculated with the following X. oryzae pv. oryzae strains: (A) wild type, xopN- mutant, xopN-/xopN+ (complemented strain), xopN-/pHM1 (vector control), xopX- mutant, xopX-/xopX+ (complemented strain), xopX-/pHM1 (vector control) or xopN- xopX- double mutant strains; (B) wild type, xopQ- mutant, xopQ-/xopQ+ (complemented strain), xopQ-/pHM1 (vector control), xopZ- mutant, xopZ-/xopZ+ (complemented strain) or xopZ-/pHM1 (vector control). Lesion lengths were measured 7 days post inoculation. Error bars indicate the standard deviation of readings from at least 10 inoculated leaves. Similar results were obtained in independent experiments. A Student’s two-tailed t test for independent means was performed for the following values: wild type with each of the single mutants and the double mutant with each of the single mutants with correction for multiple comparisons, mutant with empty vector and complemented strains for each single mutant. The brackets on the graphs indicate the comparisons that were made. All compared values are significantly different at P < 0.05 level.
The virulence proficiency of strains with single mutations in the xopQ and xopZ genes was also assessed by inoculation of rice leaves. The results indicate that mutations in either xopQ or xopZ cause a partial virulence deficiency on rice (Figure 6B). Introduction of complementing clones carrying xopQ or xopZ genes into their respective mutants leads to enhanced virulence on rice.
Discussion
DAMPs released following plant cell wall degradation during pathogen attack serve as a mark of infection and induce innate immune responses in the host. These DAMP induced host defense responses are suppressed by the pathogen during infection. Jha et al. [22] showed the involvement of the type 3 secretion system (T3S) of X. oryzae pv. oryzae in suppression of cell wall damage induced innate immune responses in rice. We began our search for T3S effectors (T3Es) of X. oryzae pv. oryzae that can suppress cell wall damage induced innate immune responses of rice by testing each of the 16 T3Es of X. oryzae pv. oryzae that were reported by Furutani and co-workers [24] to be translocated into plant cells. In this study, we have demonstrated that Agrobacterium mediated transient expression of any one of the X. oryzae pv. oryzae genes, xopN, xopQ, xopX and xopZ, results in suppression of rice innate immune responses such as callose deposition and PCD that are induced by treatment with the cell wall degrading enzyme, LipA. For 12 other genes (namely xopF, xopK, xopP, xopR, xopT, xopU, xopV, xopW, xopY, xopAA, xopAB and avrBs2-like protein) no evidence of suppressor activity was found under these assay conditions. It is possible that these proteins might function in suppression of innate immune responses induced by either PAMPs [28] or other kinds of DAMPs such as the AtPEP1 peptide [29]. At least for XopR this appears to be true as Akimoto-Tomiyama et al. [14] have demonstrated that XopR is a suppressor of flagellin induced innate immunity in Arabidopsis. The possibility that some of these twelve genes might encode functions that act together (for example as a protein complex) in host cells to suppress innate immunity cannot be ruled out as our experimental methodology would not permit us to identify proteins that act in such a fashion.
Jha and co-workers have demonstrated that a T3S- mutant of X. oryzae pv. oryzae functions as an inducer of rice innate immunity [22]. This appears to occur because this mutant is unable to suppress immune responses induced by plant cell wall degrading enzymes that it secretes and also because it produces some other DAMPs or PAMPs. We demonstrate in this paper that a xopN- xopQ- xopX- xopZ- quadruple mutant of X. oryzae pv. oryzae induces callose deposition and PCD to the same extent as a T3S- mutant. This indicates that the xopN, xopQ, xopX and xopZ gene products play a major role in the suppression of host innate immunity during infection. X. oryzae pv. oryzae strains having mutations in any one of the genes xopN, xopQ, xopX or xopZ retain the ability to suppress LipA induced innate immunity in rice. This indicates a functional redundancy amongst these four gene products with regard to their ability to suppress LipA induced immune responses.
As the suppression of host defence responses is very crucial for the pathogen to cause disease, the T3Es that are suppressors of host innate immunity should have a role in bacterial virulence on plants. We show that single mutations in the xopN, xopQ, xopX or xopZ genes cause partial virulence deficiency of X. oryzae pv. oryzae on rice. Song and Yang [13] have earlier shown that xopZ deficiency in X. oryzae pv. oryzae strain PXO99A results in partial loss of virulence on rice. Taken together, these results indicate that the xopN, xopQ, xopX and xopZ genes are required for full virulence on rice. A xopN- xopX- double mutant exhibits an even greater virulence deficiency than either one of the single mutants. This indicates that these effectors may contribute independently in promoting virulence on rice. The virulence deficiency associated with each of the single mutations is in contrast to our observation that the single mutants are proficient at suppression of LipA induced innate immunity. This suggests that each of the four effector genes has a role in suppressing immune responses that are independent of those induced by LipA or cell wall damage. The possibility that each of these four effectors has some other role in promoting virulence of X. oryzae pv. oryzae, other than in suppression of innate immunity, cannot also be ruled out.
Why might X. oryzae pv. oryzae need multiple T3Es to suppress cell wall damage induced innate immunity? The presence of a few functionally redundant proteins can be advantageous to the pathogen as it may ensure suppression of LipA/cell wall damage induced innate immunity even if any one of the effector functions is for some reason compromised. Also, multiple effectors may ensure foolproof suppression of host innate immunity by targeting the host signal transduction pathways at multiple steps. Our results indicate that XopN protein of X. oryzae pv. oryzae suppresses innate immune responses induced by treatment with LipA. We have also shown that XopN suppresses innate immune responses induced by CbsA (cellosiosidase), another cell wall degrading enzyme secreted by X. oryzae pv. oryzae (DIPANWITA SINHA and RAMESH SONTI, unpublished results). This suggests that signaling pathways for DAMPs released by each of these cell wall degrading enzymes might be converging in the cell. Kim and co-workers showed that XopN protein of X. campestris pv. vesicatoria suppresses PTI in tomato [8]. The fact that XopN suppresses PTI and DTI suggests the possibility that certain plant functions with which XopN can interact are common to signalling pathways induced by PAMPs and DAMPs.
Specific biochemical activities have not yet been demonstrated for XopN, XopX, XopZ and XopQ proteins. However, XopQ is predicted to have nucleoside hydolase (IU-NH) activity [7]. It has been speculated that the XopQ effector might be functioning to perturb signaling cascades that lead to defence responses in the host by scavenging or sequestering a nucleoside that may act as a messenger in signaling/metabolic networks [7]. The XopN protein of X. campestris pv. vesicatoria shows structural homology to proteins containing tandemly repeated α-helices known as ARM/HEAT repeats [7] and found to interact with a 14-3-3 adapter protein of tomato [8,30]. The ARM/HEAT repeats are typically found in eukaryotic proteins that function in diverse cellular signaling networks such as Arabidopsis homologs of nuclear transport protein importin-β [31] and AtCAND1 which functions in regulation of auxin signaling [32]. Furthermore, it has been shown that different isoforms of 14-3-3s interact with bacterial effector proteins in various plant-pathogen interactions to modulate plant innate immunity [30,33,34]. It is possible that the XopN protein of X. oryzae pv. oryzae also interacts with rice 14-3-3s during suppression of innate immunity. XopX is a methionine rich protein whereas the XopZ protein is a conserved hypothetical protein without any known motifs. It is possible that XopX and XopZ proteins do not have specific biochemical activities but exert their effects by disrupting signalling pathways through interaction with specific host proteins.
The non-TAL effectors of xanthomonads have been further categorized into core effectors and non-core/variable effectors [35]. XopR, XopK, XopL, XopN, XopP, XopQ, XopX, XopZ and AvrBs2 have been categorized as core effectors as they are found to be conserved in all Xanthomonas spp. (whose genomes have been sequenced) with the exception of X. albilineans str. GPEPC73 which has none of these effectors [36] and X. campestris pv. armoraciae which has only XopR and XopP [35]. The core effectors might be important for virulence and pathogen fitness in a wide range of host plants. Variable effectors are not uniformly distributed across xanthomonads suggesting their possible role in specific host-pathogen interactions. The observation that XopN, XopQ, XopX and XopZ effectors are involved in suppression of cell wall damage induced innate immunity and the fact that they are found in a wide variety of xanthomonads points to the possibility that suppression of cell wall damage induced innate immunity is a key prerequisite for successful infection in a large number of plants.
Ectopic expression of the xopZ gene of X. oryzae pv. oryzae PXO99A strain suppressed defense-related callose deposition induced by a T3S- mutant of X. oryzae pv. oryzae in a non-host plant N. benthamiana [13]. X. oryzae pv. oryzae PXO99A strain has two identical paralogs of the xopZ gene [37] because of a 212 kb duplication in the PXO99A genome that includes the xopZ gene. A double mutant in the xopZ1 and xopZ2 genes of X. oryzae pv. oryzae, and not either of the single mutants, resulted in reduced lesion formation and growth in rice. Introduction of either one of these two genes complemented the mutant phenotype and restored full virulence to the double mutant. In our study, we have shown that transient expression of X. oryzae pv. oryzae xopZ gene in rice results in suppression of cell wall damage induced innate immunity. Our observation that a single mutation in the xopZ gene is sufficient to affect virulence indicates that the wild type X. oryzae pv. oryzae (the strain from India used in our study) carries a single copy of xopZ. In this respect, the wild type strain used in this study is similar to X. oryzae pv. oryzae strain KACC 100331 from Korea [38] and X. oryzae pv. oryzae strain MAFF 311018 from Japan [39] which have single copies of XopZ. Neither Song and Yang [13] nor Zhao et al. [40] observed a reduction in symptoms for xopN, xopQ or xopX mutants of X. oryzae pv. oryzae. We suggest that some other, as yet unidentified function, present in the genetic backgrounds of the wild type strains used in those studies is redundant with these three effectors and that this function is not present in the genetic background of the wild type strain used in our study.
In summary, we have found that four proteins of X. oryzae pv. oryzae namely XopN, XopQ, XopX and XopZ are suppressors of cell wall damage induced innate immunity in rice. This is the first report showing suppression of cell wall damage induced innate immunity by bacterial T3Es in any plant-pathogen interaction. The mechanisms by which these proteins interfere with the elaboration of cell wall damage induced rice innate immunity remains to be determined.
Materials and Methods
Bacterial strains, plasmids and growth conditions
The E. coli and X. oryzae pv. oryzae strains used in this study are listed in Table 1. The Agrobacterial strains used in this study are listed in Table 2. The plasmids used in this study are listed in Tables 3, 4 and 5. Oligonucleotide primers used in this study are listed in Tables S1 and S2. X. oryzae pv. oryzae strains were grown at 28°C in peptone sucrose (PS) medium, and E. coli strains were grown at 37°C in Luria Bertani (LB) medium as described previously [41]. Agrobacterium tumefaciens strains were grown in tryptone yeast extract mannitol (TYM) medium with appropriate antibiotics. The concentrations of antibiotics used in this study were as follows: rifampicin (Rf), 50 µg/ml; ampicillin (Ap), 100 µg/ml; spectinomycin (Sp), 50 µg/ml; kanamycin (Km) 50 µg/ml for E. coli and 15 µg/ml for X. oryzae pv. oryzae.
| Strains | Relevant characteristicsa | Reference/Source |
|---|---|---|
| E. coli DH5α | ||
| DH5α | λ– f80dlacZDM15 D(lacZYA-argF)U169 recA1 endA hsdR17 (rK– mK–) supE44 thi-1 gyrA relA1 | Invitrogen |
| S17-1 | RP4-2 Tc::Mu-Km::Tn7 pro hsdR recA Tra+ used as a mobilizing strain | [52] |
| X. oryzae pv. oryzae | ||
| BXO1 | wild type; Indian isolate | Laboratory* |
| Wild type | rif-2; derivative of BXO1 | Laboratory* |
| xopN- | xopN::pK18mob rif-2; Kmr; XopN-, derivative of wild type | This work |
| xopN-/xopN+ | xopN::pK18mob rif-2/pDS2; xopN+, Kmr, Spr; derivative of xopN- | This work |
| xopN-/pHM1 | xopN::pK18mob rif-2/pHM1; Kmr, Spr; derivative of xopN- | This work |
| xopX- | ∆xopX (243 aa-in-frame deletion) rif-2; XopX-, derivative of wild type | This work |
| xopX-/xopX+ | ∆xopX rif-2/pDS4; xopX+, Kmr, Spr; derivative of xopX- | This work |
| xopX-/pHM1 | ∆xopX rif-2/pHM1; Kmr, Spr; derivative of xopX- | This work |
| xopQ- | ∆xopQ (171 aa-in-frame deletion) rif-2; XopQ-, derivative of wild type | This work |
| xopQ-/xopQ+ | ∆xopQ rif-2/pDS6 XopQ+, derivative of xopQ- | This work |
| xopQ-/pHM1 | ∆xopQ rif-2/pHM1; XopQ-, derivative of xopQ- | This work |
| xopZ- | ∆xopZ (431 aa-in-frame deletion) rif-2; XopZ-, derivative of wild type | This work |
| xopZ-/xopZ+ | ∆xopZ rif-2/pDS8; XopZ+, derivative of xopZ- | This work |
| xopZ-/pHM1 | ∆xopZ rif-2/pHM1; XopZ-, derivative of xopZ- | This work |
| xopN- xopX- | xopN::pK18mob rif-2; Kmr; XopN- XopX-; derivative of xopX- | This work |
| xopQ- xopX- | ∆xopQ rif-2; XopQ- XopX-, derivative of xopX- | This work |
| xopQ- xopX- xopZ- | ∆xopZ rif-2; XopQ-XopX- XopZ-, derivative of xopQ- xopX- | This work |
| xopN- xopQ- xopX- xopZ- | xopN::pK18mob rif-2; Kmr; XopN- XopQ-XopX- XopZ-derivative of xopQ- xopX- xopZ- | This work |
| xopN- xopQ- xopX- xopZ-/xopN+ | xopN- xopQ- xopX- xopZ- rif-2/pDS2; XopN+, Kmr, Spr; derivative of xopN- xopQ-xopX- xopZ- | This work |
| xopN-xopQ- xopX- xopZ-/pHM1 | xopN- xopQ- xopX- xopZ- rif-2/pHM1; Kmr, Spr; derivative of xopN- xopQ- xopX- xopZ- | This work |
| T3S- | hrpB6: :bla rif-2; T3S- Hrp-, Apr derivative of wild type | [22] |
Table 1. Bacterial strains used in this study.
| A. tumefaciens Strains | Relevant characteristicsa | Reference/Source |
|---|---|---|
| EHA101 | C58, pTiBo542; T-region::aph, Kmr; A281 derivative harbouring pEHA10, T-DNA replaced with nptII, super-virulent | [53] |
| EHA105 | Kms, derivative of EHA101 | [54] |
| EHA105/ pUbi-xopN | EHA105 carrying plasmid pUbi-xopN ; Kmr | This work |
| EHA105/ pUbi-xopP | EHA105 carrying plasmid pUbi-xopP ; Kmr | This work |
| EHA105/ pUbi-xopW | EHA105 carrying plasmid pUbi-xopW ; Kmr | This work |
| EHA105/ pUbi-xopY | EHA105 carrying plasmid pUbi-xopY ; Kmr | This work |
| EHA105/ pUbi-xopT | EHA105 carrying plasmid pUbi-xopT ; Kmr | This work |
| EHA105/ pUbi-xopAA | EHA105 carrying plasmid pUbi-xopAA ; Kmr | This work |
| EHA105/ pUbi-xopAB | EHA105 carrying plasmid pUbi-xopAB ; Kmr | This work |
| EHA105/ pUbi | EHA105 carrying plasmid pUbi (vector control); Kmr | This work |
| EHA105/ pMDC7-xopR | EHA105 carrying plasmid pMDC7-xopR; Spr | This work |
| EHA105/ pMDC7-xopV | EHA105 carrying plasmid pMDC7-xopV; Spr | This work |
| EHA105/ pMDC7-xopK | EHA105 carrying plasmid pMDC7-xopK; Spr | This work |
| EHA105/ pMDC7-xopF | EHA105 carrying plasmid pMDC7-xopF; Spr | This work |
| EHA105/ pMDC7-xopQ | EHA105 carrying plasmid pMDC7-xopQ; Spr | This work |
| EHA105/ pMDC7-xopU | EHA105 carrying plasmid pMDC7-xopU; Spr | This work |
| EHA105/ pMDC7-xopX | EHA105 carrying plasmid pMDC7-xopX; Spr | This work |
| EHA105/ pMDC7-xopZ | EHA105 carrying plasmid pMDC7-xopZ; Spr | This work |
| EHA105/ pMDC7-avrBs2 | EHA105 carrying plasmid pMDC7-avrBs2; Spr | This work |
Table 2. Bacterial strains used in this study.
| Plasmids | Relevant characteristicsa | Reference/Source |
|---|---|---|
| pK18mob | pUC18 derivative; Mob+ Tra- Kmr; does not replicate in Xoo | [45] |
| pK18mobSacB | derivative of pK18mob, sucrose sensitive | [45] |
| pHM1 | Broad host range cosmid vector (~13.3 kb); Spr | [48] |
| PUbi | pUbi-C1300 binary cloning vector; Kmr | [26] |
| pMDC7 | 17-β-estradiol inducible binary cloning vector; Spr | [51] |
| pENTR/D/TOPO | cloning vector; Kmr | Invitrogen |
| pDS1 | pK18mob with 497-bp internal fragment of xopN gene of wild type strain of Xoo cloned into SmaI site of pk18mob | This work |
| pDS2 | pHM1 with 2225-bp fragment containing full length xopN gene from genomic DNA of wild type strain of Xoo cloned into HindIII and SacI sites of pHM1; Spr | This work |
| pDS3 | pK18mobSacB with 1473-bp fragment of xopX gene of wild type strain of Xoo with an inframe internal deletion of 729-bp (243aa) and insertion of 12 bp XbaI site cloned into HindIII site of pk18mobSacB | This work |
| pDS4 | pHM1 with 2190-bp fragment containing full length xopX gene from genomic DNA of wild type strain of Xoo cloned into HindIII and SacI sites of pHM1; Spr | This work |
| pDS5 | pK18mobSacB with 882-bp fragment of xopQ gene of wild type strain of Xoo with an inframe internal deletion of 513-bp (171aa) and insertion of 12 bp XbaI site cloned into HindIII site of pk18mobSacB; Kmr | This work |
| pDS6 | pHM1 with 1422-bp fragment containing full length xopQ gene from genomic DNA of wild type strain of Xoo cloned into HindIII and SacI sites of pHM1; Spr | This work |
| pDS7 | pK18mobSacB with 2570-bp fragment of xopZ gene of wild type strain of Xoo with an inframe internal deletion of 1293-bp (431aa) and insertion of 12 bp XbaI site cloned into HindIII site of pk18mobSacB | This work |
| pDS8 | pHM1 with 3894-bp fragment containing full length xopZ gene from genomic DNA of wild type strain of Xoo cloned into HindIII and SacI sites of pHM1; Spr | This work |
| pUbi-xopN | pUbi-C1300 with 2193-bp fragment containing full length xopN gene from genomic DNA of wild type strain of Xoo cloned into SmaI site of pUbi-C1300; Kmr | This work |
Table 3. Plasmids used in this study.
| Plasmids | Relevant characteristicsa | Reference/Source |
|---|---|---|
| pUbi-xopW | pUbi-C1300 with 624-bp fragment containing full length xopW gene from genomic DNA of wild type strain of Xoo cloned into KpnI and SacI site of pUbi-C1300; Kmr | This work |
| pUbi-xopY | pUbi-C1300 with 848-bp fragment containing full length xopY gene from genomic DNA of wild type strain of Xoo cloned into KpnI and SacI site of pUbi-C1300; Kmr | This work |
| pUbi-xopT | pUbi-C1300 with 964-bp fragment containing full length xopT gene from genomic DNA of wild type strain of Xoo cloned into KpnI and SacI site of pUbi-C1300; Kmr | This work |
| pUbi-xopAA | pUbi-C1300 with 1746-bp fragment containing full length xopAA gene from genomic DNA of wild type strain of Xoo cloned into KpnI and SacI site of pUbi-C1300; Kmr | This work |
| pUbi-xopAB | pUbi-C1300 with 623-bp fragment containing full length xopAB gene from genomic DNA of wild type strain of Xoo cloned into KpnI and SacI site of pUbi-C1300; Kmr | This work |
| pUbi-xopP | pUbi-C1300 with 2194-bp fragment containing full length xopP gene from genomic DNA of wild type strain of Xoo cloned into SmaI site of pUbi-C1300; Kmr | This work |
| pENTR-avrBs2 | pENTR/D/TOPO with 708-bp fragment containing full length avrBs2 gene from genomic DNA of wild type strain of Xoo; Kmr | This work |
| pENTR-xopK | pENTR/D/TOPO with 2538-bp fragment containing full length xopK gene from genomic DNA of wild type strain of Xoo; Kmr | This work |
| pENTR-xopZ | pENTR/D/TOPO with 3867-bp fragment containing full length xopZ gene from genomic DNA of wild type strain of Xoo; Kmr | This work |
| pENTR-xopU | pENTR/D/TOPO with 2958-bp fragment containing full length xopU gene from genomic DNA of wild type strain of Xoo; Kmr | This work |
| pENTR-xopV | pENTR/D/TOPO with 996-bp fragment containing full length xopV gene from genomic DNA of wild type strain of Xoo; Kmr | This work |
| pENTR-xopX | pENTR/D/TOPO with 2190-bp fragment containing full length xopX gene from genomic DNA of wild type strain of Xoo; Kmr | This work |
| pENTR-xopR | pENTR/D/TOPO with 1314-bp fragment containing full length xopR gene from genomic DNA of wild type strain of Xoo; Kmr | This work |
Table 4. Plasmids used in this study.
| Plasmids | Relevant characteristicsa | Reference/Source |
|---|---|---|
| pENTR-xopQ | pENTR/D/TOPO with 1392-bp fragment containing full length xopQ gene from genomic DNA of wild type strain of Xoo; Kmr | This work |
| pENTR-xopF | pENTR/D/TOPO with 1986-bp fragment containing full length xopF gene from genomic DNA of wild type strain of Xoo; Kmr | This work |
| pMDC7-avrBs2 | pMDC7 with 708-bp fragment containing full length avrBs2 gene obtained from recombination of pENTR-avrBs2 with pMDC7; Spr | This work |
| pMDC7-xopK | pMDC7 with 2538-bp fragment containing full length xopK gene obtained from recombination of pENTR-xopK with pMDC7; Spr | This work |
| pMDC7-xopV | pMDC7 with 996-bp fragment containing full length xopV gene obtained from recombination of pENTR-xopV with pMDC7; Spr | This work |
| pMDC7-xopZ | pMDC7 with 3867-bp fragment containing full length xopZ gene obtained from recombination of pENTR-xopZ with pMDC7; Spr | This work |
| pMDC7-xopX | pMDC7 with 2190-bp fragment containing full length xopX gene obtained from recombination of pENTR-xopX with pMDC7; Spr | This work |
| pMDC7-xopR | pMDC7 with 1314-bp fragment containing full length xopR gene obtained from recombination of pENTR-xopR with pMDC7; Spr | This work |
| pMDC7-xopQ | pMDC7 with 1392-bp fragment containing full length xopQ gene obtained from recombination of pENTR-xopQ with pMDC7; Spr | This work |
| pMDC7-xopU | pMDC7 with 2958-bp fragment containing full length xopU gene obtained from recombination of pENTR-xopU with pMDC7; Spr | This work |
| pMDC7-xopF | pMDC7 with 1986-bp fragment containing full length xopF gene obtained from recombination of pENTR-xopF with pMDC7; Spr | This work |
Table 5. Plasmids used in this study.
Molecular biological techniques
Genomic DNA was isolated as described by Leach and co-workers [42]. Plasmid DNA was isolated by using either a Qiagen (Hilden, Germany) plasmid midi-kit or alkaline lysis method [43]. High-fidelity Phusion polymerase from Finnzymes (Thermo scientific, Rockford, IL, USA) was used for PCR amplification of insert DNA for all cloning purposes while Taq polymerase was used for all other applications. Restriction digestions were done with enzymes from New England Biolabs (NEB, Beverly, MA, USA). PCR products and restriction enzyme-digested DNA fragments were purified using a QIAquick PCR purification kit and a QIAquick nucleotide removal kit (Qiagen), respectively. Ligation with T4 DNA ligase, agarose gel electrophoresis, and transformation of E. coli were performed as described previously [43].
DNA sequencing and bioinformatics tools
DNA sequencing was done with an ABI Prism 3700 automated DNA sequencer (PerkinElmer, Foster City, CA, USA). BLAST algorithm in the NCBI database [44] was used for homology and conserved domain searches. No new DNA sequence has been generated in this study.
Construction and complementation of xopN-, xopQ-, xopX- and xopZ-, mutants of X. oryzae pv. oryzae
A xopN- mutant of X. oryzae pv. oryzae was generated by gene disruption using homologous plasmid integration of a suicide vector pK18mob [45]. A 497-bp internal fragment of the xopN gene was amplified by PCR using genomic DNA of X. oryzae pv. oryzae wild type strain and the gene-specific XopN1F/XopN1R (Table S1) oligonucleotide primer pair. This fragment was cloned into the SmaI digested blunt-ended pK18mob cloning vector to obtain recombinant plasmid pDS1. The plasmid pDS1 was then electroporated into wild type and clones were selected for kanamycin resistance to obtain a xopN- mutant by plasmid integration. Gene disruption was confirmed by PCR using xopN gene-specific flanking primers XopNF/XopNR in combination with vector-specific primers M13F and M13R and sequencing of PCR products. The xopN gene fragment was cloned in the same transcriptional orientation as the lacZ promoter of pK18mob vector in pDS1 so that mutation caused by pDS1 integration does not have a polar effect on downstream genes due to activity of the outwardly directed lacZ promoter [46,47].
For xopN- mutant complementation, a 2225-bp DNA fragment containing the full length of xopN gene was amplified by PCR using primers XopN2F/XopN2R and total genomic DNA of X. oryzae pv. oryzae as template. The amplified DNA fragment was cloned as a HindIII-SacI fragment into the broad host range vector pHM1 [48] to create the recombinant plasmid pDS2. The pDS2 construct and the pHM1 vector were individually introduced into the xopN-mutant strain by electroporation and selection for spectinomycin resistance. The presence of pDS2 was confirmed by PCR using xopN gene-specific flanking primers XopN2F/XopN2R and universal primers M13F/M13R and sequencing of PCR products. The confirmed clones were designated as xopN-/xopN+ (xopN-/pDS2; for complementation) and xopN-/pHM1 (xopN-/pHM1; vector control) and studied further.
A xopX- mutant of X. oryzae pv. oryzae was isolated by creating an inframe deletion in the xopX gene. For this purpose, 729 and 732 bp fragments of the xopX gene were amplified by PCR using genomic DNA of wild type strain and the gene-specific XopXS1F/XopXS1R and XopXS3F/XopXS3R primer pairs, respectively. The primers XopXS1F and XopXS3R were having an engineered site for restriction enzyme HindIII at their 5’ and 3’ ends, respectively. Similarly, the primers XopXS1R and XopXS3F were having an engineered site for restriction enzyme XbaI at their 3’ and 5’ ends, respectively. The amplified fragments were digested with XbaI restriction enzyme. The XbaI-digested 729 and 732 bp fragments were ligated and the ligated product was PCR amplified using the gene-specific XopXS1F/XopXS3R primer pair. A 1473 bp fragment was obtained which included a 12 bp insertion that contains the XbaI site. The 1461bp fragment, which now contained HindIII sites at the 5’ and 3’ ends, was digested with HindIII restriction enzyme and cloned into the HindIII site of the pK18mobsacB cloning vector to obtain the recombinant plasmid pDS3. Sequencing of pDS3 confirmed that no other changes had occurred in the target xopX sequence except an inframe deletion of 729 bp (243 aa) and insertion of 12 bp (XbaI restriction enzyme site along with adapter sequences). This construct was then transferred from E. coli S17-1 to wild type via biparental mating. The transformants were plated on nutrient agar (Difco, Detroit, MI, USA) plates containing Km. Single recombinant colonies that were kanamycin-resistant and sucrose-sensitive were grown and passaged thrice in nutrient broth without Km and sucrose. Saturated bacterial cultures were dilution plated on PSA plates containing 1% sucrose to obtain double recombinant strains that were sucrose-resistant and kanamycin-sensitive. The inframe deletion that had been incorporated into the xopX gene on the X. oryzae pv. oryzae chromosome was confirmed by PCR using xopX gene-specific flanking primers XopXS1F/XopXS3R and sequencing of PCR products. One of the confirmed mutant clones was designated xopX- mutant and chosen for further study. Using a similar strategy, xopQ- and xopZ- mutants of X. oryzae pv. oryzae were isolated by creating inframe deletions in the xopQ and xopZ genes. Briefly, 420 and 450 bp fragments of the xopQ gene were PCR amplified using genomic DNA of wild type strain and the gene-specific XopQS1F/XopQS1R and XopQS3F/XopQS3R primer pairs, respectively. These PCR amplified fragments were then ligated as XbaI-digested fragments. Similarly, 1304 and 1254 bp PCR fragments of the xopZ gene were obtained using genomic DNA of wild type strain and the gene specific XopZS1F/XopZS1R and XopZS3F/XopZS3R primer pairs, respectively. These PCR amplified fragments were digested with XbaI and ligated to each other. The corresponding ligated products of xopQ and xopZ genes were PCR amplified as 882 and 2570 bp fragments which included a 12 bp insertion that contains the XbaI site, using XopQS1F/XopQS3R and XopZS1F/XopZS3R primer pairs, respectively. These fragments were digested with HindIII and cloned individually into the HindIII site of pK18mobsacB to obtain the recombinant plasmids pDS5 and pDS7, respectively. The constructs pDS5 and pDS7 were confirmed to carry no other changes in the target xopQ and xopZ gene sequences except inframe deletions of 513 bp (171 aa) and 1293 bp (431 aa), respectively, and insertions of 12 bp (XbaI restriction enzyme site along with adapter sequences). These constructs were then transferred from E. coli S17-1 to wild type via biparental mating and marker free xopQ- and xopZ- mutants were generated following the steps as described above for generation of xopX- mutant strain. The inframe deletions that had been incorporated into the xopQ and xopZ genes on the X. oryzae pv. oryzae chromosome were confirmed by PCR using xopQ and xopZ gene-specific flanking primers XopQS1F/XopQS3R and XopZS1F/XopZS3R respectively, and sequencing of PCR products. The mutants for xopQ and xopZ genes were designated as xopQ- and xopZ-, respectively.
For xopX- mutant complementation, a 2190 bp DNA fragment containing the full length of xopX gene was amplified by PCR using primers XopX2F/XopX2R and total genomic DNA of X. oryzae pv. oryzae as template. The amplified DNA fragment was cloned as a HindIII-SacI fragment into the broad host range vector pHM1 [48] to create the recombinant plasmid pDS4. The pDS4 plasmid and pHM1 vector were individually introduced into the xopX- mutant strain by electroporation and the recombinants were isolated by selection for spectinomycin resistance. The presence of pDS4 was confirmed by PCR using xopX gene-specific flanking primers XopX2F/XopX2R and universal primers M13F/M13R and sequencing of PCR products. The confirmed clones were designated as xopX-/xopX+ (xopX-/pDS4; for complementation) and xopX-/pHM1 (xopX-/pHM1; vector control) and studied further. A similar strategy was used for complementation of xopQ- and xopZ- mutants. Briefly, the full length copies of xopQ and xopZ genes were PCR amplified from X. oryzae pv. oryzae genomic DNA using primer pairs, XopQ2F/XopQ2R and XopZ2F/XopZ2R, respectively. PCR fragments of xopQ and xopZ genes were individually cloned as HindIII-SacI fragment in vector pHM1 to create the constructs pDS6 and pDS8, respectively. The pDS6 and pDS8 constructs were individually introduced by electroporation into the xopQ- mutant and xopZ- mutants, respectively, to get spectinomycin resistant recombinant clones. The presence of pDS6 and pDS8 was confirmed by PCR using respective gene-specific flanking primers XopQ2F/XopQ2R and XopZ2F/XopZ2R, and universal primers M13F/M13R and sequencing of PCR products. The confirmed clones for complementation of xopQ- and xopZ- mutants were designated as xopQ-/xopQ+ (xopQ-/pDS6) and xopZ-/xopZ+ (xopZ-/pDS8) respectively. For vector control, pHM1 vector was individually introduced by electroporation into the xopQ- mutant and the xopZ- mutant. Spectinomycin resistant clones were designated as xopQ- /pHM1 (vector control) and xopZ- /pHM1 (vector control) and used for further study.
Construction of xopN- xopX- double and xopN- xopQ- xopX- xopZ- quadruple mutants of X. oryzae pv. oryzae
A xopN- xopX- double mutant of X. oryzae pv. oryzae was isolated by gene disruption of xopN using homologous plasmid integration in a xopX- mutant strain. The construct pDS1 was electroporated into electrocompetent cells of xopX- mutant strain to obtain a xopN- xopX- double mutant by plasmid integration. The xopN gene disruption in xopN- xopX- mutant strain was confirmed as described above for the mutation in xopN- strain.
A xopQ- xopX- double mutant of X. oryzae pv. oryzae was isolated by creating an inframe deletion of 513 bp (171 aa) in the xopQ gene in the genome of xopX- mutant strain. For this purpose, the construct pDS5 was transferred from E. coli S17-1 to xopX- mutant via biparental mating. An inframe deletion was created in the xopQ gene in the genetic background of the xopX- mutant. One of the confirmed clones was designated as xopQ- xopX- double mutant strain.
In a similar way, a xopQ- xopX- xopZ- triple mutant of X. oryzae pv. oryzae was generated by incorporating an inframe deletion of 1293 bp (431 aa) in the xopZ gene in the genome of xopQ- xopX- double mutant strain. To achieve this, biparental mating was set up to mobilize the construct pDS7 from E. coli S17-1 to xopQ- xopX- double mutant. The inframe deletion that had been incorporated in the xopZ gene in the genomic background of xopQ- xopX- double mutant strain was confirmed as described earlier for isolating the xopZ- mutant strain. One of the confirmed clones was designated as a xopQ- xopX- xopZ- triple mutant of X. oryzae pv. oryzae. A xopN- xopQ- xopX- xopZ- quadruple mutant of X. oryzae pv. oryzae was isolated by disrupting the xopN gene using homologous plasmid integration in the xopZ- xopQ- xopX- triple mutant strain. A disruption of the xopN gene was achieved by electroporating the construct pDS1 into xopQ- xopX- xopZ- triple mutant strain and selecting for kanamycin resistant transformants. Generation of the xopN- mutant was confirmed by PCR using xopN gene-specific flanking primers XopNF/XopNR in combination with vector-specific primers M13F and M13R and sequencing the PCR products. One of the confirmed clones was designated as xopN- xopQ- xopX- xopZ- quadruple mutant of X. oryzae pv. oryzae. For complementation of xopN- xopQ- xopX- xopZ- quadruple mutant with xopN gene, the pDS2 plasmid was introduced into the xopN- xopQ- xopX- xopZ- quadruple mutant by electroporation and selection of spectinomycin resistant colonies. The presence of pDS2 was confirmed by PCR. As a control, the pHM1 vector was introduced into the xopN- xopQ- xopX- xopZ- quadruple mutant in a similar manner.
Cell death assay
Surface sterilized rice (Taichung Native-1; a susceptible rice variety) seeds were germinated on 0.5% sterile agar in Petri dishes for 2 to 3 days. Root tips, 1 to 2 cm long, were excised from the seedlings and treated with 200 µl of either purified LipA (500 µg/ml) or buffer (10 mM phosphate buffer, pH 6.0). After incubation for 18-20 h, roots were washed and stained with propidium iodide (PI) for 20 min and mounted in 50% glycerol on glass slides. The samples were viewed under a LSM-510 Meta confocal microscope (Carl Zeiss, Germany) using 63 × oil immersion objectives and He-Ne laser at 543 nm excitation to detect PI internalization. Longitudinal optical sections of 1.0 µm thickness were acquired and further projected to obtain the image of 2 to 3 µm total thickness. All images were analyzed using LSM software and further edited using Photoshop (Adobe, San Jose, CA, USA).
Preinoculation with Agrobacterium tumefaciens EHA105 strains or X. oryzae pv. oryzae strains
X. oryzae pv. oryzae strains were grown in PS broth to saturation, pelleted, washed with buffer (10 mM phosphate buffer, pH 6.0) and resuspended in buffer. The cells from saturated cultures of Agrobacterium strains grown in TYM broth were pelleted, washed following centrifugation and resuspended in induction medium (10 mM MES, pH 5.6, 10 mM MgCl2, and 150 µM acetosyringone; Sigma) and then incubated in a shaker for 2 h at 28°C [8]. Rice roots were pretreated with either suspensions of Agrobacterium strains for 4-5 h in induction media, in the presence or absence of 17-β-estradiol (20 µM final concentration), or X. oryzae pv. oryzae strains dissolved in phosphate buffer for 2 h at 28°C. After rinsing with fresh buffer, the roots were treated with purified LipA (~500 µg/ml) for 18-20 h at 28°C and processed further for confocal analyses as described above. As controls, rice roots pretreated with either Agrobacterium strains or X. oryzae pv. oryzae strains and subsequently treated with buffer for 18-20 h at 28°C were also analysed by confocal microscopy. All the bacterial strains were used at a final concentration of OD=1.5. At least 200 µl volumes of either of LipA, buffer or culture were used to treat the rice roots.
Callose deposition assay
Leaves of 10-day old rice seedlings were infiltrated using the blunt end of a 1 ml syringe with one of the following : buffer, water, purified LipA (~100 µg/ml) and saturated culture of X. oryzae pv. oryzae T3S- mutant strain. Bacteria were collected from saturated cultures of Agrobacterium strains, washed and resuspended in induction medium (10 mM MES, pH 5.6, 10 mM MgCl2 and 150 µM acetosyringone) and then incubated in a shaker for 2 h at 28°C before infiltration [8]. Agrobacterium strains were recollected from induction medium by centrifugation and processed further. Rice leaves were coinfiltrated with Agrobacterium strains resuspended in buffer containing purified LipA (~100 µg/ml). Agrobacterium strains containing the pMDC7 vector were resuspended in purified LipA (~100 µg/ml) with and without 17-β-estradiol (20 µM final concentration). All the bacterial strains (X. oryzae pv. oryzae and Agrobacterium) were used to final concentration of OD=1.0. After 20-24 h, the infiltrated zones (~1× 1 cm) were cut from the leaves, destained with 70% ethanol at 65°C, stained with 0.5% aniline blue for 4 h and observed under an Axioplan2 epifluorescence microscope (Carl Zeiss, Germany) using a blue filter (excitation wavelength of 365 nm) and ×10 objective [49].
Virulence assay
For virulence analysis various X. oryzae pv. oryzae strains were grown to saturation in PS broth supplemented with appropriate antibiotics. The cells were pelleted down by centrifugation, washed and resuspended in sterile water at a concentration of OD=1.0. Surgical scissors dipped in these bacterial suspensions were used to clip the leaf tips of greenhouse-grown, 40-day-old plants of the susceptible rice variety Taichung Native-1 (TN-1) [50]. Lesion lengths were measured 7 days after inoculation.
Cloning of T3S effectors of X. oryzae pv. oryzae into Agrobacterial T-DNA vectors
Full length xopN and xopP genes were amplified by PCR using genomic DNA of wild type strain of X. oryzae pv. oryzae and the corresponding gene-specific oligoneucletide primer pair (Table S1) and cloned into the SmaI site of the binary vector pUbi-C1300 [26] between the maize ubiquitin promoter and nos3’ terminator to obtain recombinant plasmids pUbi-xopN and pUbi-xopP respectively. Full length xopW, xopY, xopT, xopAA and xopAB genes were PCR amplified using genomic DNA of wild type X. oryzae pv. oryzae strain and the corresponding gene-specific oligonucleotide primer pairs (Table S1). The PCR products were cloned individually as KpnI-SacI fragments into the binary vector pUbi-C1300 to obtain the recombinant plasmids pUbi-xopW, pUbi-xopY, pUbi-xopT, pUbi-xopAA and pUbi-xopAB respectively. Positive clones were screened using gene-specific and vector-specific primers and confirmed by sequencing. The full length genes of xopR, xopV, xopK, xopF, xopQ, xopU, xopX, xopZ and avrBs2 were PCR amplified from genomic DNA of wild type X. oryzae pv. oryzae strain with engineered 5’ CACC overhang were cloned individually into cloning vector pENTR/D/TOPO (Invitrogen, Carlsbad, CA, USA) to obtain plasmids pENTR-xopR, pENTR-xopV, pENTR-xopK, pENTR-xopF, pENTR-xopQ, pENTR-xopU, pENTR-xopX, pENTR-xopZ and pENTR-avrBs2 respectively. Positive clones in E. coli DH5α were screened using gene-specific primers and confirmed by sequencing. Plasmids from these clones were isolated and recombined into the 17-β-estradiol inducible binary cloning vector pMDC7 [51] by Gateway LR reaction (Invitrogen) to obtain recombinant plasmids pMDC7-xopR, pMDC7-xopV, pMDC7-xopK, pMDC7-xopF, pMDC7-xopQ, pMDC7-xopU, pMDC7-xopX, pMDC7-xopZ and pMDC7-avrBs2 respectively. Clones obtained in E. coli DH5α were screened using PCR with appropriate primer pairs and confirmed by sequencing. Plasmids containing cloned genes in the binary vectors (either pUbi-C1300 or pMDC7) were isolated and further electroporated into electrocompetent cells of A. tumefaciens strain EHA105.
RT-PCR analysis to determine expression of xop genes of X. oryzae pv. oryzae in rice roots
Rice roots were treated with Agrobacterium EHA105 strains carrying any one of xopN, xopP, xopQ, xopR, xopX or xopZ genes on the T-DNA vector. The xopQ, xopR, xopX and xopZ genes are cloned in a T-DNA vector, pMDC7, wherein the expression of the cloned gene is under the induction of 17-β-Estradiol (Est). The xopN and xopP is cloned in T-DNA vector pUbi-C1300, wherein its expression is under the control of maize ubiquitin promoter. Accordingly, as negative controls, for the genes cloned in Est inducible vector (pMDC7), rice roots were treated with Agrobacterial strains in the absence of Est, whereas for genes cloned in vector pUbi-C1300, rice roots were treated with Agrobacterium strain containing an empty vector. Total RNA was isolated from rice tissue treated with different Agrobacterium EHA105 strains (with or without Est wherever needed) using Trizol reagent (Invitrogen) according to the manufacturer’s instructions. The quality of isolated RNA was assessed by agarose gel electrophoresis and quantitated using spectrophotometer (Nanodrop ND-1000, Thermo Scientific). 5 µg of total RNA samples were treated with RNasefree DNaseI (Promega) for 1 h at 37°C to remove any DNA contamination. After inactivation of DNaseI, 1 µg RNA was used for cDNA synthesis using SuperscriptIII (Invitrogen) RT enzyme as per the manufacturer’s instructions and oligo (dT) primers. Subsequently, each cDNA was used as template for PCR amplification with Taq polymerase using gene-specific primers (Table S2) designed to amplify fragments of each gene of interest. The DNaseI treated RNA that was not reverse transcribed was used as template in PCR as negative control to show that the RT-PCR products obtained were not because of any DNA contamination in the cDNA samples. The amplification condition used was 95°C for 5 min followed by 28 cycles of 94°C for 30 sec, 58°C for 30 sec, 72°C for 45 sec, again followed by 72°C for 10 min. The RT-PCR amplified products were analysed by agarose gel electrophoresis and staining with ethidium bromide.
Supporting Information
Figure S1.
Expression of xopN, xopP xopQ, xopR, xopX and xopZ genes of Xanthomonas oryzae pv. oryzae in rice roots following Agrobacterium mediated transient transfer. cDNA was synthesised from total RNA isolated from rice roots treated with one of the following: EHA105/pUbi-xopN; EHA105/pUbi-xopP; EHA105/pUbi (empty vector); EHA105/pMDC7-xopQ with Estradiol (Est) or without Est; EHA105/pMDC7-xopR with Est or without Est; EHA105/pMDC7-xopX with Est or without Est; EHA105/pMDC7-xopZ with Est or without Est. Subsequently, each cDNA was used as a template for PCR amplification with Taq polymerase using gene-specific primers (Table S2) designed to amplify a 118-164 bp fragment of each gene of interest. (A) PCR products of 123 bp (XopNRTF/XopNRTR primer pair) and 164 bp (XopPRTF/XopPRTR primer pair) were obtained using, as a template, cDNA prepared with RNA from roots treated with EHA105/pUbi-xopN and EHA105/pUbi-xopP, respectively. These products were not obtained when cDNA prepared from roots treated with EHA105/pUbi was used as a template. PCR product of 158 bp (GAPDHF/GAPDHR primer pair which amplifies a fragment from the rice GAPDH gene) was obtained using cDNA prepared from roots treated with any of the three Agrobacterial strains. (B) PCR products of 148 bp (XopQRTF/XopQRTF primer pair), 128 bp (XopRRTF/XopRRTF primer pair), 143 bp (XopXRTF/XopXRTF primer pair) and 149 bp (XopZRTF/XopZRTF primer pair) were obtained using, as a template, cDNA prepared with RNA from roots treated with EHA105/pMDC7-xopQ, EHA105/pMDC7-xopR, EHA105/pMDC7-xopX and EHA105/pMDC7-xopZ in the presence of Est but not in the absence of Est, respectively. A PCR product of 158 bp (GAPDHF/GAPDHR primer pair) was obtained using, as a template, cDNA obtained from roots treated with any of the above vectors either in the presence or absence of estradiol.
https://doi.org/10.1371/journal.pone.0075867.s001
(TIF)
Figure S2.
A xopN- xopQ- xopX- xopZ- quadruple mutant of Xanthomonas oryzae pv. oryzae induces PCD in rice roots. Rice roots were treated with one of the following: wild type X. oryzae pv. oryzae (A); xopN- xopQ- xopX- xopZ- quadruple mutant (B); T3S- mutant (C). Treated roots were subsequently stained with propidium iodide (PI) and viewed under a confocal microscope. Internalisation of PI is indicative of defense response-associated programmed cell death in rice roots. Scale bar measures 20µm.
https://doi.org/10.1371/journal.pone.0075867.s002
(TIF)
Figure S3.
Complementation with the xopN gene reduces ability of the xopN- xopZ- xopQ- xopX- quadruple mutant to induce callose deposition in rice leaves. Rice leaves were infiltrated with one of the following: xopQ- xopX- xopZ- triple mutant, xopN- xopQ- xopX- xopZ- quadruple mutant, xopN- xopQ- xopX- xopZ- /xopN+ (quadruple mutant complemented with xopN gene) and xopN- xopQ- xopX- xopZ-/pHM1 (quadruple mutant with pHM1 plasmid; vector control). The leaves were subsequently stained with aniline blue and visualized under an epifluorescence microscope. Callose deposits were quantified from 0.60 mm2 area of an infiltrated leaf. Data were collected from atleast five leaves in each experiment (three experiments indicated as ExpI, ExpII and ExpIII) and 2-3 different viewing areas from the infiltrated region of each leaf. Statistically significant differences at P < 0.05 (Student’s two-tailed t test for independent means) were obtained from leaves infiltrated with either xopN- xopQ- xopX- xopZ-/xopN+ or xopQ- xopX- xopZ- triple mutant as compared to leaves treated with a xopN- xopQ- xopX- xopZ- quadruple mutant. Statistically significant differences were not observed in the following comparisons: either xopN- xopQ- xopX- xopZ-/xopN+ with xopQ- xopX- xopZ- triple mutant or xopN- xopQ- xopX- xopZ- with xopN- xopZ- xopQ- xopX-/pHM1.
https://doi.org/10.1371/journal.pone.0075867.s003
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Figure S4.
xopN-, xopQ-, xopX- or xopZ- single mutants of Xanthomonas oryzae pv. oryzae induce callose deposition at a basal level. Rice leaves were infiltrated with one of the following: wild type X. oryzae pv. oryzae, xopN- mutant, xopQ- mutant, xopX- mutant, xopZ- mutant. The leaves were subsequently stained with aniline blue and visualized under an epifluorescence microscope. Callose deposits were quantified from 0.60 mm2 area of an infiltrated leaf. Data were collected from atleast five leaves in each experiment and 2-3 different viewing areas from the infiltrated region of each leaf. Data from one experiment are represented. Similar results were obtained in independent experiments.
https://doi.org/10.1371/journal.pone.0075867.s004
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Table S1.
List of oligonucleotide primers used in this study.
https://doi.org/10.1371/journal.pone.0075867.s005
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Table S2.
List of oligonucleotide primers used for RT-PCR.
https://doi.org/10.1371/journal.pone.0075867.s006
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Acknowledgments
We thank Max Dow for providing the plasmid pK18mobsacB. We thank Nam Hai Chua for providing the plasmid pMDC7. We thank Pamela Ronald and R. Rajeshwari for providing the plasmid pUbi-C1300. We acknowledge the help of C. Subbalakshmi and V. Krishna Kumari for help in enzyme purification, and R. Nandini for confocal analysis.
Author Contributions
Conceived and designed the experiments: DS RVS. Performed the experiments: DS MKG HKP AR. Analyzed the data: DS RVS. Contributed reagents/materials/analysis tools: DS. Wrote the manuscript: DS RVS.
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