Suppression of a Phospholipase D Gene, OsPLD{beta}1, Activates Defense Responses and Increases Disease Resistance in Rice

doi:10.1104/pp.108.131979

Suppression of a Phospholipase D Gene, OsPLDβ1, Activates Defense Responses and Increases Disease Resistance in Rice¹^,[C]^,[W]^,[OA]

Takeshi Yamaguchi^*, Masaharu Kuroda, Hiromoto Yamakawa, Taketo Ashizawa, Kazuyuki Hirayae, Leona Kurimoto, Tomonori Shinya and Naoto Shibuya

National Agricultural Research Center, Joetsu, Niigata 943–0193, Japan (T.Y., M.K., H.Y., T.A., K.H.); and Department of Life Sciences, Faculty of Agriculture, Meiji University, Kawasaki, Kanagawa 214–8571, Japan (L.K., T.S., N.S.)

ABSTRACT

TOP
ABSTRACT
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

Phospholipase D (PLD) plays an important role in plants, includingresponses to abiotic as well as biotic stresses. A survey ofthe rice (Oryza sativa) genome database indicated the presenceof 17 PLD genes in the genome, among which OsPLD ${alpha}$ 1, OsPLD ${alpha}$ 5, andOsPLDβ1 were highly expressed in most tissues studied.To examine the physiological function of PLD in rice, we madeknockdown plants for each PLD isoform by introducing gene-specificRNA interference constructs. One of them, OsPLDβ1-knockdownplants, showed the accumulation of reactive oxygen species inthe absence of pathogen infection. Reverse transcription-polymerasechain reaction and DNA microarray analyses revealed that theknockdown of OsPLDβ1 resulted in the up-/down-regulationof more than 1,400 genes, including the induction of defense-relatedgenes such as pathogenesis-related protein genes and WRKY/ERFfamily transcription factor genes. Hypersensitive response-likecell death and phytoalexin production were also observed ata later phase of growth in the OsPLDβ1-knockdown plants.These results indicated that the OsPLDβ1-knockdown plantsspontaneously activated the defense responses in the absenceof pathogen infection. Furthermore, the OsPLDβ1-knockdownplants exhibited increased resistance to the infection of majorpathogens of rice, Pyricularia grisea and Xanthomonas oryzaepv oryzae. These results suggested that OsPLDβ1 functionsas a negative regulator of defense responses and disease resistancein rice.

Phospholipase D (PLD) is one of the representative phospholipasesin plants and hydrolyzes phospholipids to generate phosphatidicacid (PA) and a free-head group. In recent years, PLD has beensuggested to be involved in many plant cellular processes, suchas membrane degradation (Ryu and Wang, 1995

), membrane tethering(Dhonukshe et al., 2003

; Gardiner et al., 2003

), and signalingfor stress and hormone responses (Testerink and Munnik, 2005

;Wang, 2005

; Bargmann and Munnik, 2006

; Wang et al., 2006

). PA,which can be directly generated by the action of PLD, has beenrecognized as an important lipid second messenger. PA mediatesthe generation of reactive oxygen species (ROS; Sang et al.,2001

; Yamaguchi et al., 2003

) and activates wound-activatedmitogen-activated protein kinase (Lee et al., 2001

). SeveralPA targets have been functionally characterized in plant cells(Testerink and Munnik, 2005

Plant PLDs are a family of heterologous enzymes (Wang, 2005).In Arabidopsis (Arabidopsis thaliana), 12 PLD genes were reported,seven of which were directly cloned and the others were predictedby searching the BLAST database (National Center for BiotechnologyInformation; http://www.ncbi.nml.nih.gov/). They can be classifiedinto six types, PLD ${alpha}$ (3), β(2), ${gamma}$ (3), ${delta}$ , ${epsilon}$ , and ${zeta}$ (2), based ontheir gene architectures, sequence similarities, domain structures,and biochemical properties (Wang, 2005). The function of eachplant PLD has been studied using knockout, knockdown, and overexpressionof corresponding genes, resulting in the identification of thephysiological functions of several PLDs. PLD ${alpha}$ has been reportedto be involved in the signaling for abscisic acid, ethylene,wounding, freezing, drought, and hyperosmotic stress (Testerinkand Munnik, 2005; Wang, 2005; Hong et al., 2008). PLD ${alpha}$ was alsoshown to positively regulate ROS generation (Sang et al., 2001)and to be involved in the loss of seed viability by aging (Devaiahet al., 2007). PLDβ was suggested to be involved in theregulation of seed germination in rice (Oryza sativa; Li etal., 2007). Involvement of PLD ${delta}$ in the regulation of variousresponses such as drought, hydrogen peroxide, freezing, andUV irradiation has been reported (Testerink and Munnik, 2005;Wang, 2005). PLD ${delta}$ has also been shown to play an important rolein the reorganization of microtubules as well as their associationwith plasma membrane (Dhonukshe et al., 2003; Gardiner et al.,2003). PLD ${zeta}$ has been suggested to regulate root hair growth andpatterning (Ohashi et al., 2003), phosphate recycling duringphosphate starvation (Li et al., 2006), vesicle trafficking,and auxin response (Li and Xue, 2007).

For defense responses in plants, activation of PLD was observedby the challenge of a pathogen in rice leaves (Young et al.,1996) and the addition of defense elicitors in tomato (Solanumlycopersicum) cells (Van der Luit et al., 2000) and rice cells(Yamaguchi et al., 2003). In addition, the pathogen- and elicitor-inducedPLD activation involved the recruitment of PLD to the membrane(Young et al., 1996; Yamaguchi et al., 2005). Concerning theexpression of PLD genes in defense responses, induction of PLDβgenes was reported in the elicitor treatment of cultured tomatocells (Laxalt et al., 2001) and tobacco (Nicotiana tabacum)cells (Suzuki et al., 2007). De Torres Zabela et al. (2002)reported the induction of Arabidopsis PLD ${alpha}$ , -β, and - ${gamma}$ genesby the challenge of a pathogen in the leaves. McGee et al. (2003)also showed the induction of rice PLD ${alpha}$ genes by the challengeof a pathogen in the leaves. In addition, the pathogen- andelicitor-induced PLD activation involved the recruitment ofPLD to the membrane (Young et al., 1996; Yamaguchi et al., 2005).

Concerning the function of the reaction product of PLD, PA,in defense responses, it has been reported that PA can induceROS generation in Arabidopsis (Sang et al., 2001) and rice (Yamaguchiet al., 2003) and the expression of defense-related genes (Yamaguchiet al., 2005). On the other hand, 1-butanol, which inhibitsthe generation of PA by PLD, suppressed the elicitor-inducedROS generation and phytoalexin production in rice cells (Yamaguchiet al., 2005). Based on these findings, it has been expectedthat PLD positively regulates defense responses in plants. Onthe contrary, Bargmann et al. (2006) reported that xylanaseelicitor-induced ROS generation was increased in PLDβ-suppressedtomato cells. Although these findings indicate that plant PLDsplay important roles in defense signaling, most evidence remainscircumstantial and the potential role of each PLD isoform isstill obscure. Moreover, there is no evidence for the involvementof PLDs in the disease resistance against pathogens.

In this study, we generated a series of knockdown plants foreach PLD isoform in rice and analyzed their phenotypes for defenseresponses. We report here that the knockdown of a single gene,OsPLDβ1, resulted in ROS generation and expression of defensegenes, followed by spontaneous lesion formation and phytoalexinproduction in the absence of pathogen infection. Furthermore,the knockdown transgenic plant showed a marked increase in thedisease resistance to the blast fungus, Pyricularia grisea,and the bacterial blight, Xanthomonas oryzae pv oryzae (Xoo).These results clearly indicate that OsPLDβ1 functions asa negative regulator of defense responses and is involved inthe disease resistance in rice.

RESULTS

TOP
ABSTRACT
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

Analysis of the Rice PLD Gene Family

Multisequence alignment analysis was carried out to examinethe phylogenetic relationship of the 17 PLD genes from riceand 12 genes from Arabidopsis. The phylogeny is shown as a rootedUPGMA tree in Figure 1 . In Figure 1, we basically followedthe terminology for PLD family members proposed by Wang (2005)for Arabidopsis PLDs to facilitate the comparison of correspondinggenes in these two model plants. Rice PLDs can be grouped intoeight types, PLD ${alpha}$ , -β, - ${delta}$ , - ${epsilon}$ , - ${zeta}$ , - ${eta}$ , - ${theta}$ , and - ${iota}$ (Fig. 1), basedon their predicted sequence homology with Arabidopsis PLDs (Fig. 1).The 16 PLD genes except OsPLD ${eta}$ 2 have two HKD motifs, which constitutethe highly conserved domain in the PLD family and are used todefine the PLD superfamily (Qin and Wang, 2002). Fourteen PLDgenes except OsPLD ${zeta}$ 1, OsPLD ${zeta}$ 2, and OsPLD ${iota}$ contain a C2 domain thatis a Ca²⁺- and phospholipid-binding domain. OsPLD ${zeta}$ 1 and OsPLD ${zeta}$ 2contain the PX and PH domains, which are present in mammalianPLDs as well (Wang, 2005). The remaining one, OsPLD ${iota}$ , containstwo HKD motifs but does not contain C2 or PH-PX domains. Homologuesof OsPLD ${iota}$ are present in the genomes of Phytophthora species(Meijer and Govers, 2006), Vitis vinifera, and Medicago truncatula.The phylogenetic relationship of rice PLDs in Figure 1 was partiallydifferent from the result recently reported by Li et al. (2007).In our analysis, OsPLD ${eta}$ 1 and OsPLD ${eta}$ 2 or OsPLD ${epsilon}$ and AtPLD ${epsilon}$ were groupedinto the same class, which corresponds to the results reportedby Elias et al. (2002).

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Figure 1. A phylogenetic tree of PLDs in rice and Arabidopsis. The phylogenetic tree was constructed from the matrix of amino acid sequence similarities calculated with the UPGMA program of the Wisconsin University Genetics Computer Group. Rice PLDs were classified based on their similarity to Arabidopsis PLDs. The numbers following rice PLD genes indicate The Institute for Genomic Research locus identifiers and GenBank accession numbers of the corresponding genes. [See online article for color version of this figure.]

To characterize the expression patterns of PLD genes in rice,expression of the 16 rice PLD genes except OsPLD ${iota}$ was analyzedusing cultured cells, roots, leaf sheaths, leaf blades, andimmature seeds under normal growth conditions. The accumulationof their mRNA in each tissue was evaluated using quantitativereverse transcription (RT)-PCR. The expression of 16 PLD geneswas detected in most tissues analyzed (Supplemental Table S1).OsPLDβ1 was highly expressed in all tissues analyzed (Fig. 2 ).OsPLD ${alpha}$ 1 and OsPLD ${alpha}$ 5 were also highly expressed in most tissues,although a higher expression of OsPLD ${alpha}$ 1 mRNA in the culturedcells was observed. Higher expression of OsPLD ${alpha}$ 4 and OsPLD ${delta}$ 1 wasdetected in roots and leaf sheaths, respectively. These resultsdemonstrated that the PLD isoforms have overlapping but distinctpatterns of expression in the different tissues/organs undernormal growth conditions. On the other hand, the expressionlevels of OsPLD ${epsilon}$ , OsPLD ${delta}$ 2, OsPLD ${delta}$ 3, OsPLD ${eta}$ 1, and OsPLD ${theta}$ were verylow in all tissues studied (Supplemental Table S1).

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Figure 2. Expression analysis of rice PLD genes. Wild-type rice plants were grown in the greenhouse under normal growth conditions for 50 d, and total RNA was extracted from the roots, leaf sheaths, and leaf blades. Immature seeds were harvested from plants at 10 d after flowering. The values were standardized to the expression level of a rice polyubiquitin gene (RUBIQ1). The values represent averages of triplicate experiments, and the error bars indicate SD. [See online article for color version of this figure.]

Similar studies in Arabidopsis and tomato showed that AtPLD ${alpha}$ 1and AtPLD ${gamma}$ 1 in Arabidopsis and LePLD ${alpha}$ 2 and LePLD ${alpha}$ 3 in tomato wereall highly expressed in most tissues. In contrast to the ratherubiquitous expression of OsPLDβ1 in rice, the expressionof both AtPLDβ1 and LePLDβ1 was very low under normalgrowth conditions (Fan et al., 1999

; Laxalt et al., 2001

). Thismay relate to the fact that rice lacks ${gamma}$ -type PLD in the genome,which was extensively expressed in Arabidopsis and tomato. Forrice PLDs, Li et al. (2007)

reported similar results with thosereported here, although the expression profile was significantlydifferent for some PLD isoforms, probably reflecting the differencesin the plant materials such as cultivar and growth conditions.

Accumulation of ROS in the OsPLDβ1-Knockdown Transgenic Rice

As an initial step to characterize the function of each PLDisoform in rice, we made knockdown plants for eight PLD genesin rice, OsPLD ${alpha}$ 1, - ${alpha}$ 3, - ${alpha}$ 4, - ${alpha}$ 5, - ${epsilon}$ , -β1, -β2, and - ${delta}$ 2,by introducing gene-specific RNA interference (RNAi) constructs.More than 10 lines were established for each gene, and at leastfive independent lines were used for the analysis of the phenotypesof the T1 transgenic plants grown under normal conditions ina greenhouse. Among them, OsPLDβ1-knockdown plants showeda marked enhancement in the generation of ROS. The amount ofhydrogen peroxide (H₂O₂) in the leaves of OsPLDβ1-knockdownplants (20 or 30 d after seeding) was approximately 2-fold higherthan that in the vector control plants (Fig. 3A ). Quantitativeanalysis of OsPLDβ1 mRNA in the leaves of the plant confirmeda clear suppression of OsPLDβ1 expression (Fig. 3B). Fiveindependent knockdown lines gave similar results (SupplementalFig. S1). No difference in the appearance of the leaves wasobserved between the OsPLDβ1-knockdown plants and the vectorcontrol plants at this stage (data not shown).

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Figure 3. The phenotype of the OsPLDβ1-knockdown plants grown for 30 d under normal growth conditions. A, Accumulation of H₂O₂ in the leaves of 20- and 30-d-old knockdown (#7; shaded columns) and vector control (white columns) plants. H₂O₂ was analyzed using a quantitative H₂O₂ assay kit. The values represent averages of triplicate experiments, and the error bars indicate SD. B, Accumulation of OsPLDβ1 mRNA in the leaves of the knockdown (#7; RNAi; shaded column) and vector control (Control; white column) plants was determined by quantitative RT-PCR. The values were standardized to the expression level of a rice polyubiquitin gene (RUBIQ1). The values represent averages of triplicate experiments, and the error bars indicate SD. C, PLD activity in the leaf extracts of the knockdown (#7; RNAi; shaded columns) and vector control (Cont; white columns) plants was determined using NBD-PC (PC-PLD) or NBD-PE (PE-PLD) as a substrate in the presence of 1-butanol (final concentration, 0.1% [v/v]) as described in "Materials and Methods." The values represent averages of triplicate experiments, and the error bars indicate SD. [See online article for color version of this figure.]

The analysis of PLD activity in the leaf extracts showed thatthe PLD activity of the OsPLDβ1-knockdown plants was decreasedto half of the vector control level. However, this decreaseof PLD activity was observed only for phosphatidylcholine-specific(PC-) PLD activity but not for phosphatidylethanolamine-specific(PE-) PLD activity (Fig. 3C). These results indicate that theknockdown of OsPLDβ1 really reflects the change of in plantaPLD activity and that the in vivo substrate of OsPLDβ1is PC.

To examine whether the higher accumulation of H₂O₂ in the OsPLDβ1-knockdownplants is caused by the down-regulation of scavenging activityof ROS, we analyzed the catalase- and peroxidase-like activitiesin the leaf extracts of the OsPLDβ1-knockdown and vectorcontrol plants. No difference in the enzyme activities was observedbetween these plants (data not shown), indicating that the knockdownof OsPLDβ1 probably affected ROS generating rather thanscavenging activity.

Up-Regulation of Defense-Related Genes in the OsPLDβ1-Knockdown Plants

We also analyzed whether the expression of defense-related geneswas up-regulated in these OsPLDβ1-knockdown plants. QuantitativeRT-PCR analysis of three typical defense-related genes, probenazole-inducibleprotein1, chitinase, and thaumatin-like protein, in the leavesof 30-d-old plants (i.e. 30 d after seeding) showed that theexpression of these genes was dramatically increased in theOsPLDβ1-knockdown plants, concomitant with the decreaseof OsPLDβ1 expression (Fig. 4A ). Global changes in thegene expression induced by OsPLDβ1 knockdown were furtheranalyzed for the leaves from 30-d-old plants using a rice 44KDNA microarray. Figure 4B summarizes the up- and down-regulationof those genes in each category, whose expression was changedmore than three times compared with that of the vector controlplants. Approximately 1,400 genes changed their expression significantlyin the OsPLDβ1-knockdown plants under such conditions (SupplementalTable S2). More than 600 genes with the annotated functions,notably those associated with defense responses, signal transduction,and a number of transcription factors, were up-regulated inthe OsPLDβ1-knockdown plants. These defense-related genesincluded those for PR-1, β-glucanase, chitinase, PR-4,thaumatin-like protein, and probenazol-inducible proteins. Inaddition, a number of transcription factor genes belonging tothe WRKY and ERF families were also up-regulated. These genesare well known to be up-regulated during the defense responses(Van Loon and Van Strien, 1999; Maleck et al., 2001). On theother hand, many cell cycle-related genes, such as ${alpha}$ - and β-expansingenes, were down-regulated (Fig. 4B; Supplemental Table S2).These results are similar to the previous observations on theelicitor-induced gene responses in rice cells (Akimoto-Tomiyamaet al., 2003; Desaki et al., 2006). These data, therefore, indicatethat the knockdown of OsPLDβ1 resulted in the inductionof defense-related genes in the absence of pathogen infections,a novel observation that, to our knowledge, has not been reportedfor any plant PLD. Recently, Li et al. (2007) reported thatOsPLDβ1 plays a positive role in the abscisic acid responseand that the suppression of OsPLDβ1 resulted in the up-regulationof GAmyb (X98355) and ${alpha}$ -amylase (AK101744) genes during seedgermination. However, the up-regulation of the GAmyb gene aswell as the ${alpha}$ -amylase gene was not observed in either the seedlingsor leaves of OsPLDβ1-knockdown plants by DNA microarrayanalysis (data not shown), probably reflecting the differencesin the experimental systems.

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Figure 4. Expression of defense-related genes (A) and changes of gene expression (B) in the OsPLDβ1-knockdown plants grown for 30 d after seeding under normal growth conditions. A, Total RNA was prepared from the leaves of knockdown (#7; RNAi) and vector control (Control) plants grown for 30 d, and the expression levels of probenazol-inducible protein (PBZ1), chitinase (RCC), and thaumatin-like protein (TLP) genes were analyzed by quantitative RT-PCR. The values were standardized to the expression level of a rice polyubiquitin gene (RUBIQ1). The values represent averages of triplicate experiments, and the error bars indicate SD. B, Classification of up- and down-regulated genes in the knockdown plants (#7) obtained from the DNA microarray analysis. Total RNA was prepared from the leaves of knockdown and vector control plants grown for 30 d and used for the microarray analysis. The duplicate experiments were conducted using two independent plants. Genes for which expression in the knockdown plants was increased or decreased more than three times compared with that in the vector control plants were classified according to their annotations. Data represent the sums of up-regulated (shaded columns) and down-regulated (white columns) genes. The numbers are averages of duplicate experiments. [See online article for color version of this figure.]

It was also observed that the expression of OsPLDβ2, aclosely related PLD isoform in rice, was significantly up-regulatedin the OsPLDβ1-knockdown plants (Supplemental Fig. S2).The exact biological significance of this phenomenon is notclear, but it might reflect the cellular response to compensatefor the knockdown of OsPLDβ1. In spite of the up-regulationof OsPLDβ2 expression, PC-PLD activity of the knockdownplant was clearly suppressed (Fig. 3C), indicating that OsPLDβ1is the major PLD isoform contributing to this activity.

Induction of Hypersensitive Response-Like Reactions in the OsPLDβ1-Knockdown Plants

When the knockdown plants for eight PLD genes were grown furtherin a greenhouse, small reddish brown lesions became visibleover the surface of the leaves only in the OsPLDβ1-knockdownplants approximately 40 d after seeding, although such a phenotypewas not visible for the 30-d-old plants, where the up-regulationof various defense genes and the H₂O₂ accumulation were alreadystarted (Fig. 5A ). Similar results were observed for 51 of55 independent OsPLDβ1-knockdown lines, although the densityof the lesions was different among them. Quantitative analysisof OsPLDβ1 mRNA in the leaves of OsPLDβ1-knockdownlines, all of which developed the lesions, showed a clear suppressionof OsPLDβ1 expression, as shown in Figure 5B (RNAi). Incontrast, the vector control plants did not show the developmentof lesions at all (Fig. 5A, Control; 22 lines were analyzedand gave similar results). These results indicate that the developmentof the lesions in the OsPLDβ1-knockdown plants is due tothe down-regulation of OsPLDβ1, directly or indirectly.

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Figure 5. The phenotype of the OsPLDβ1-knockdown plants grown for 50 d under normal growth conditions. A, The phenotypes of the leaves of the knockdown (#7; RNAi) and vector control (Control) plants. B, Accumulation of OsPLDβ1 mRNA in the leaves of the knockdown (#7; RNAi; shaded column) and vector control (Control; white column) plants was determined by quantitative RT-PCR. The values were standardized to the expression level of a rice polyubiquitin gene (RUBIQ1). The values represent averages of triplicate experiments, and the error bars indicate SD.

Suppression of OsPLDβ1 Induces Phytoalexin Production

To examine whether phytoalexin production is up-regulated inthe OsPLDβ1-knockdown plants, we analyzed the amount ofmomilactone A, a major phytoalexin of rice (Cartwright et al.,1977), in the leaves of 50-d-old OsPLDβ1-knockdown plantsand vector control plants. As shown in Figure 6 (RNAi b),momilactone A concentration in the OsPLDβ1-knockdown plantswith visible lesions was approximately 100 times higher comparedwith the vector control plants. On the other hand, the amountof momilactone A in the leaves of the OsPLDβ1-knockdownplants without the lesions was only slightly increased comparedwith the vector control plants (RNAi a). These results indicatethat the phytoalexin production is up-regulated in the OsPLDβ1-knockdownplants but starts mostly after the development of the lesions.

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Figure 6. Accumulation of phytoalexin in the OsPLDβ1-knockdown plants grown for 50 d under normal growth conditions. The phytoalexin fraction was prepared from the leaves of these plants and analyzed for the major rice phytoalexin, momilactone A, by liquid chromatography-mass spectrometry as described in "Materials and Methods." For knockdown plants (#7; RNAi), a indicates the leaves with very few lesions and b indicates the leaves with numerous lesions. The values represent averages of triplicate experiments, and the error bars indicate SD. [See online article for color version of this figure.]

Suppression of OsPLDβ1 Enhances Disease Resistance against Rice Bacterial Blight as Well as Rice Blast

Susceptibility of the OsPLDβ1-knockdown rice plants toa virulent blast fungus was evaluated to see whether the activationof defense responses induced by the OsPLDβ1 knockdown resultedin an increase of disease resistance. The OsPLDβ1-knockdownand vector control plants (at the three- to six-leaf stage)were inoculated with P. grisea (teleomorph Magnaporthe grisea)race 007, a major fungal pathogen and compatible to the ricevariety used in this experiment, and the disease symptoms wereevaluated 7 d later. Contrary to the development of extensivelesions in the leaves of the vector control plants, the OsPLDβ1-knockdownplants displayed remarkably decreased lesion formation, irrespectiveof the age of the tested plants (20 or 30 d old; Fig. 7, A and C ).Quantification of the lesion area indicated that the developmentof susceptible-type lesions in the OsPLDβ1-knockdown plantswas decreased more than 7-fold compared with the vector controlplants (Fig. 7, B and D), indicating an evident increase ofdisease resistance against rice blast infection. Similar resultswere obtained with other OsPLDβ1-knockdown lines, wherethe degree of disease resistance seemed to correlate with thedegree of OsPLDβ1 knockdown (Supplemental Fig. S3; correlationcoefficient = 0.904). To examine whether the OsPLDβ1-knockdownplants also show disease resistance against other pathogens,we tested their response to rice bacterial blight infection,Xoo, using the uppermost fully extended leaves of 50-d-old plants(Fig. 7, E and F). Similar to the case of blast infection, lesionformation caused by the bacterial blight was dramatically decreased(4.4-fold decrease) in the OsPLDβ1-knockdown plants (Fig. 7E).In addition, the population of Xoo in the OsPLDβ1-knockdownplants was decreased more than 10-fold compared with the vectorcontrol plants at 15 d after Xoo inoculation (Supplemental Fig.S4). These results clearly show that the suppression of OsPLDβ1enhanced disease resistance against a broad range of pathogens,including bacteria and oomycetes. It is noteworthy that theseexperiments were performed with the uppermost fully extendedleaves, where the hypersensitive response (HR)-like cell deathand the phytoalexin accumulation were not yet visible.

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Figure 7. Increased disease resistance of the OsPLDβ1-knockdown plants to pathogen infections and the expression patterns of OsPLDβ1 in response to rice blast infection. A and C, Typical disease symptoms on the extended leaves of 20-d-old (A) and 30-d-old (C) knockdown (#7; RNAi) and vector control (Control) plants at 1 week after rice blast inoculation. B and D, Quantification of the lesion area in the leaves of the knockdown (RNAi; shaded columns) and vector control (Control; white columns) plants shown in A and C, respectively. The values represent the percentage of lesion area to the whole leaf area. The values represent averages of four (B) or five (D) replicate experiments, and the error bars indicate SD. E, Typical disease symptoms on the uppermost fully extended leaves of the 50-d-old knockdown (#7; RNAi) and vector control (Control) plants at 2 weeks after rice bacterial blight inoculation. F, Quantification of the lesion area in the leaves of the knockdown (RNAi; shaded column) and vector control (Control; white column) plants shown in E. The values represent averages of four replicate experiments, and the error bars indicate SD. G, The temporal expression patterns of OsPLDβ1 in 30-d-old wild-type rice plants treated with P. grisea. Accumulation of OsPLDβ1 mRNA in the extended leaves treated with (shaded columns) or without (white columns) rice blast inoculation for the indicated days was determined by quantitative RT-PCR. The values represent averages of triplicate experiments, and the error bars indicate SD.

The expression of OsPLDβ1 itself was induced by the inoculationof P. grisea to the wild-type rice leaves (Fig. 7G). The expressionof OsPLDβ1 reached a maximum (3.6-fold increase) at 1 dafter inoculation, preceding the susceptible lesion formation.

DISCUSSION

TOP
ABSTRACT
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

Knockdown of OsPLDβ1 Activates Defense Responses and Increases Disease Resistance in Rice

In this paper, we show that the knockdown of a rice PLD gene,OsPLDβ1, resulted in the activation of defense responsesand increased disease resistance in rice. We establish the knockdownplants for eight PLD genes in rice, OsPLD ${alpha}$ 1, - ${alpha}$ 3, - ${alpha}$ 4, - ${alpha}$ 5, - ${epsilon}$ , -β1,-β2, and - ${delta}$ 2, which were listed in the database when westarted this work, using RNAi. Among them, only OsPLDβ1-knockdownplants showed the activation of typical defense responses suchas ROS generation and defense gene expression in the absenceof pathogen infection, followed by the development of HR-likelesions and phytoalexin production in a later growth stage.The fact that the induction of ROS generation as well as defensegene expression in the OsPLDβ1-knockdown plants precededthe HR-like lesion formation indicates that the knockdown ofOsPLDβ1 directly affected the upstream part of these defenseresponses, rather than through HR cell death. Concerning theinduction of HR-like lesion formation, various mutants or transgenicplants that exhibit a lesion-mimic phenotype have been reported,providing a good model system to study the molecular mechanismsof HR in plants (Lorrain et al., 2003). However, it has notbeen reported that the knockdown or knockout of the genes involvedin phospholipid signaling leads to the lesion-mimic phenotypeassociated with defense responses.

The OsPLDβ1-knockdown plants exhibited increased diseaseresistance to major pathogens of rice, P. grisea and Xoo, beforethe formation of visible spontaneous lesions (Fig. 7). In thisrespect, the OsPLDβ1-knockdown plants are similar to thebarley (Hordeum vulgare) mlo (Wolter et al., 1993) and ricecdr3 (Takahashi et al., 1999) mutants, which exhibit resistanceto fungal pathogens before the formation of visible lesions.Interestingly, the up-regulated genes in the OsPLDβ1-knockdownplants included those genes for transcription factors that havebeen reported to be induced by the pathogen infection/elicitortreatment and play an important role for defense signaling,such as WRKY45 and WRKY71. Shimono et al. (2007) recently showedthat the overexpression of WRKY45 enhanced blast resistance,and Liu et al. (2007) showed that the overexpression of WRKY71enhanced resistance to virulent bacterial pathogens. The expressionlevels of OsWRKY71 and OsWRKY45 genes in the OsPLDβ1-knockdownplants increased 8.7- and 3.8-fold compared with that in thevector control plant, respectively (Supplemental Table S2),indicating that the up-regulation of these genes may contributeto the induction of defense-related genes and the enhancementof blast resistance.

No significant difference was observed between the growth ofthe vector control and OsPLDβ1-knockdown plants, such asplant height, number of leaves, and heading date after seeding,although the seed weight of the OsPLDβ1-knockdown plantsseemed to be slightly decreased compared with that of the vectorcontrol plants (Supplemental Table S3). These results suggestedthat the suppression of OsPLDβ1 increased disease resistanceof rice without a significant effect on growth and development.

Concerning the up-regulation of OsPLDβ1 by the infectionof a compatible pathogen (Fig. 7G), it is worth rememberingthat some negative regulator genes for defense responses, suchas rice spl11 and Arabidopsis WRKY48, were up-regulated in responseto pathogen infection (Zeng et al., 2004; Xing et al., 2008).As the induction of defense reactions such as HR potentiallyhas an adverse effect on normal growth, these responses mustbe induced when plants are infected with pathogens and alsobe down-regulated properly. Thus, the induction of negativeregulators such as OsPLDβ1 by pathogen infection may constitutepart of such a negative feedback loop.

OsPLDβ1, a Negative Regulator of Defense Responses?

It has been suggested that the activation of PLD and the resultingPA generation during pathogen infection/elicitor treatment playa positive role in the mobilization of defense responses. Wepreviously reported that the elicitor treatment of rice cellsactivated PC-PLD and induced PA generation (Yamaguchi et al.,2003, 2005). The addition of PA itself directly induced ROSgeneration and expression of defense-related genes in the absenceof the elicitor treatment. Sang et al. (2001) also reportedthat the suppression of AtPLD ${alpha}$ 1 decreased the level of ROS generationand that the addition of PA recovered the ROS generation inArabidopsis leaves. Our results described here, however, indicatethat OsPLDβ1 negatively regulates defense responses, probablyat the upstream part of the defense signaling cascade. Bargmannet al. (2006) also reported that the knockdown of a tomato PLDβgene, LePLDβ1, resulted in the up-regulation of ROS generation,although in the presence of xylanase elicitor. Although thecontribution of other isoforms of rice PLDs, such as OsPLDβ2,in the up-regulation of defense responses in the OsPLDβ1-knockdownrice cannot be excluded, these results seem to indicate theinvolvement of PLDβ1 in the negative regulation of defenseresponses in plants. Our results also indicate that OsPLDβ1seems to suppress defense responses in rice even under normalgrowth conditions; however, it is not clear whether this isthe case for tomato as well. As already described, the expressionlevel of OsPLDβ1 was very high in most tissues studied(Fig. 2), whereas that of LePLDβ1 was very low (Laxaltet al., 2001). These differences in the expression levels ofPLDβ1 genes might cause the differences in their regulationof defense responses in the corresponding plants under normalgrowth conditions.

These results indicate that plant PLDs are involved in the positiveand negative regulation of defense responses, probably dependingon the corresponding isoforms. Similar observations have beenreported in the responses against freezing or oxidative stressin Arabidopsis. It was reported that the knockdown of PLD ${alpha}$ 1 inArabidopsis enhanced freezing tolerance, whereas the knockoutof PLD ${delta}$ weakened freezing tolerance (Wang, 2005). Wang (2005)also indicated that AtPLD ${alpha}$ 1 is involved in ROS generation, whereasAtPLD ${delta}$ is involved in the suppression of ROS-promoted programmedcell death. Which isoforms of PLDs are involved in the oppositeregulation of these defense responses should be clarified furtherin future studies.

Possible Mechanisms for the Different Functions of PLD Isoforms

If plant PLDs play opposite roles in plant defense signaling,as discussed above, what can be the explanation for such mechanisms?One possibility is the different localization of each PLD isoform,which enables the regulation of different target proteins downstreamof each PLD. Several papers have indicated that the differentPLD isoforms localize in different organelles/membranes in plantcells. In rice, OsPLD ${alpha}$ 1 was detected in the cell wall, membranes,and chloroplasts, whereas OsPLD ${alpha}$ 4 and OsPLD ${alpha}$ 5 were predominantlydetected in the chloroplasts of the leaves (McGee et al., 2003).AtPLD ${alpha}$ 1 in Arabidopsis was detected in the plasma membrane, intracellularmembranes, mitochondria, and clathrin-coated vesicles (Fan etal., 1999). AtPLDβ1 was reported to bind actin in vitro,which is a major component of a microfilament in the cells (Kusneret al., 2003). Bargmann et al. (2006) showed that the fusionprotein of tomato LePLDβ1 and GFP was detected in the cytosolof cultured cells, whereas treatment with xylanase elicitorinduced the relocalization to punctate structures within thecytosol. They proposed a possibility that plant PLDβ1 mayform a tether between vesicular membranes and the actin cytoskeleton(Bargmann et al., 2006). These results suggest that the cellularlocalization is different between PLD ${alpha}$ and PLDβ, indicatingthe different physiological functions of these PLDs.

In addition to the different localization of PLD isoforms, differentmodes of regulation of each PLD may be a factor controllingthe function of each PLD. For example, it is well known thatthe Ca²⁺ dependence of activation is very different among PLDisoforms (Qin and Wang, 2002). Similarly, PLDβ1, PLD ${gamma}$ 1,and PLD ${zeta}$ 1 require phosphatidylinositol 4,5-bisP for the activation,whereas other isoforms do not (Qin and Wang, 2002). These resultsindicate that different PLDs are involved in the different physiologicalresponses downstream of these second messengers.

Different molecular species of PA may also be generated by differentPLD isoforms, as differences in the substrate preference amongPLD isoforms have been reported (Qin and Wang, 2002). More recently,Hong et al. (2008) reported that the molecular species of PAgenerated by the action of AtPLD ${alpha}$ 3 are clearly different fromthose by AtPLD ${alpha}$ 1 in Arabidopsis. This observation suggests thatthe differences in the molecular species of PA generated bythese PLDs might reflect differences in the functions of thePLD isoforms. Furthermore, different phospholipid compositionsof organelle membranes might also contribute to the generationof different PAs by PLD isoforms, resulting in the differencesin PA target proteins.

Although the results obtained in this study with knockdown transgenicplants indicate that OsPLDβ1 negatively regulates defenseresponses in rice, it is not clear whether OsPLDβ1 is actuallyinvolved in the defense regulation under physiological conditions,and this should be clarified in future studies. The fact thatthe knockdown of OsPLDβ1 resulted in the activation ofvarious defense responses, including the up-/down-regulationof numerous genes, ROS generation, followed by HR cell deathand phytoalexin production, indicates that OsPLDβ1 regulatesthe defense responses at the upstream part of the signal transductionpathways. The analysis of the mechanism of negative regulationof defense responses by OsPLDβ1, including the survey ofdownstream components in OsPLDβ1 signaling, should be thesubject of future studies as well.

MATERIALS AND METHODS

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RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

Plant and Fungal Materials

The rice (Oryza sativa japonica ‘Nipponbare’, blastresistance gene: Pik-s) was used in this study. The sterilizedtransgenic or wild-type rice seeds were germinated for 2 weekson Murashige and Skoog (MS) agar medium with or without 50 mgL^–1 hygromycin, respectively. The resulting plants weretransferred to soil and grown in a greenhouse (25°C/27°C,solar radiation).

A strain of Pyricularia grisea (teleomorph Magnaporthe grisea,‘Ina 86-137’, race 007) and Xanthomonas oryzae pvoryzae (‘T-7133’, Japanese race IIIa) were usedas fungal and bacterial pathogens, respectively. Both Ina 86-137and T-7133 are compatible with Nipponbare.

DNA Database Search and Computer Analysis

To identify the members of the PLD gene family in rice, we searchedthe following databases: DNA Data Bank of Japan (http://www.ddbj.nig.ac.jp),National Center for Biotechnology Information (http://www.ncbi.nml.nih.gov/blast/Genome),and National Institute of Agrobiological Sciences (http://cdna01.dna.affrc.go.jp/cDNA/).Multisequence alignment analysis for the deduced amino acidsequences was carried out using Genetyx (Software Development).

RNA Extraction and Real-Time PCR

Total RNAs for first-strand cDNA synthesis were isolated fromrice tissues by the SDS-phenol method. The isolated RNA (5 µg)was reverse transcribed (SuperScript II; Invitrogen) using anoligo(dT)₁₃ primer. An aliquot of the first-strand cDNA mixturecorresponding to 10 ng of the total RNA was used as a templatefor real-time PCR analysis. The reaction was carried out onthe Smart Cycler System (Cepheid) with the SYBER premix ExTaq(Takara Bio) according to the manufacturer's instructions. Thegene-specific primers designed for each gene are listed in SupplementalTable S4. The amplified bands were cloned directly into pGEM-Tvector (Promega) and sequenced to confirm that they were indeedthe fragments of the intended genes. A calibration curve foreach gene was obtained by performing real-time PCR with severaldilutions of the cloned cDNA fragment. The specificity of theindividual PCR amplification was checked using a heat dissociationprotocol from 65°C to 95°C following the final cycleof PCR. The results obtained for the different cDNAs were standardizedto the expression level of a rice polyubiquitin gene (RUBIQ1;Wang et al., 2000).

DNA Constructs and Rice Transformation

The OsPLDβ1-RNAi vector was constructed by generating aninverted hairpin loop into the pZH2Bik binary vector, whichwas modified to contain the rice ubiquitin promoter (OsmUbiP),the intron of a rice aspartic protease gene (RAP intron; Asakuraet al., 1995), and the Nos terminator (T-Nos), in the sequencefrom pPZP202 (Hajdukiewicz et al., 1994). A 343-bp fragmentcorresponding to nucleotides 2,323 to 2,665 of OsPLDβ1,which does not overlap with the amplified OsPLDβ1-specificfragment (1,973–2,314) in the real-time PCR experimentsdescribed in Supplemental Table S4, was amplified using thefollowing oligonucleotides: 5'-GAATGCATGAGACGAGTTCGC-3' (forward)and 5'-CCTTTTCTTGTCATGTCCTACT-3' (reverse). The PCR fragmentwas ligated in the reverse orientation into pZH2bik vector betweenOsmUbiP and RAP intron and between RAP intron and T-Nos. Theresulting vector contains the RNAi intermediate sequence downstreamof the rice ubiquitin promoter. The empty vector, pZH2Bik, wasalso used to generate vector control plants. The other ricePLD gene-specific RNAi vectors were also constructed accordingto the same methods described above. To confirm the gene specificity,part of the cDNA including the 3' noncoding region, the sequenceof which is different for each PLD gene, was amplified usingeach primer set (Supplemental Table S5) and inserted into thevector.

Agrobacterium tumefaciens EHA105 carrying the above constructwas used to transform Nipponbare rice. The Agrobacterium-mediatedtransformation was performed according to the method of Toki(1997) using vigorously growing callus derived from mature embryos.Transformed calli were selected on MS agar medium containing50 mg L^–1 hygromycin. Regenerated plants were grown ina greenhouse, and T0 transgenic seeds were harvested 40 d afterflowering. T1 transgenic plants carrying the transgene wereselected by germinating seeds on MS agar medium containing 50mg L^–1 hygromycin for 2 weeks, and then selected plantswere transferred to soil and grown in a greenhouse (25°C–30°C,solar radiation).

Determination of H₂O₂ Accumulation and Scavenging Activity

A 50-mg sample of leaf tissue harvested from 30- to 50-d-oldplants was cut into small pieces (5 x 5 mm) and immediatelyhomogenized with 5% (w/v) aqueous trichloroacetic acid containingEGTA (10 mM) on ice. The extract was centrifuged at 10,000gat 4°C for 10 min, and the amount of H₂O₂ in the supernatantwas analyzed using a quantitative H₂O₂ assay kit (BioxytechH₂O₂-560; Oxis International).

ROS-scavenging activity was determined using 10 mM H₂O₂ as asubstrate. A 20-mg sample of leaf tissue harvested from 30-to 50-d-old plants was cut into small pieces (5 x 5 mm) andimmediately homogenized with 0.5 mL of 25 mM Tris-HCl buffer(pH 7.5) containing 10 mM EGTA, 1 mM dithiothreitol, 1 mM phenylmethylsulfonylfluoride, and 0.3 M Suc for 1 min on ice. The homogenate wascentrifuged at 10,000g at 4°C for 10 min, and the supernatantwas stored as the cellular extract fraction at –20°Cuntil analysis. Protein content in each fraction was determinedaccording to Bradford (1976). The standard reaction mixturecontained 1.0 to 1.5 µg of cellular protein and 10 mMH₂O₂ in a final volume of 50 µL. Reactions were performedat 37°C for 10 min, and the amount of H₂O₂ in the supernatantwas analyzed using a quantitative H₂O₂ assay kit.

Measurement of in Vitro PLD Activity

PLD activity in the cellular extract fraction described abovewas determined using fluorescent lipids (Avanti Polar Lipids)as a substrate as described previously (Yamaguchi et al., 2004)with a slight modification. 7-Nitro-2-1,3-benzoxadiazol-4-ylamino (NBD)-PC (14:0 12:0) and NBD-PE (14:0 12:0) were storedat –20°C in chloroform. Prior to use, they were driedand emulsified by sonication in 5 mM sodium cholate. The standardreaction mixture contained 25 mM HEPES (pH 7.0), 10 to 15 µgof cellular protein, 0.1 mM NBD-PC or NBD-PE, and 1-butanol(final concentration, 0.1% [v/v]) in a final volume of 50 µL.Reactions were performed at 37°C for 30 min and then stoppedby the addition of 0.25 mL of CHCl₃:methanol:HCl (100:100:0.6,v/v). After 0.1 mL of 1 N HCl containing 5 mM EGTA was added,the mixture was vortexed and centrifuged at 10,000g for 1 min.The solvent layer was then recovered and dried under vacuum.The samples were applied to a thin-layer chromatography plate(20 x 10 cm) and developed with the organic upper phase of ethylacetate:iso-octane:aceticacid:water (12:2:3:10, v/v). Fluorescently labeled phosphatidylbutanol(PtdBut) was visualized using a UV transilluminator, and theregions corresponding to PtdBut were marked. The marked spotswere scraped from the plates and placed in 0.5 mL of CHCl₃:methanol:water(5:5:1, v/v), vortexed, and centrifuged for 5 min at 10,000g.The supernatant was dried under vacuum and emulsified by sonicationin 5 mM sodium cholate. The fluorescence (excitation, 460 nm;emission, 534 nm) from the eluted PtdBut was measured with afluorescence spectrophotometer (Versa Fluor; Bio-Rad). The spotsof PtdBut were identified by comparison with the standards (AvantiPolar Lipids) visualized by iodine vapor. A standard curve wasconstructed using a range of NBD-PC concentrations.

Microarray Analysis

Microarray analyses were performed using a 60-mer rice oligomicroarraycontaining 44K features (Agilent Technologies). The total RNAused for the analysis was prepared from leaves of 30-d-old plantsby the SDS-phenol method. The RNA extracts were fluorescentlylabeled and hybridized to the microarray slides according tothe manufacturer's protocol. The slides were then scanned byan Agilent scanner. To assess reproducibility, two independentexperiments were conducted using two independent plants. Dataindicating a less than 3-fold increase in fluorescence betweenCy5 and Cy3 in each experiment were excluded from further analysis.Genes whose expression in the knockdown plants was increasedor decreased more than three times compared with that in thevector control plants are listed in Supplemental Table S2.

Determination of Phytoalexin

A 50-mg sample of leaf tissue harvested from 50-d-old plantswas cut into small pieces (5 x 5 mm) and extracted with 0.5mL of 70% (v/v) methanol at room temperature for 24 h. Aftercentrifugation at 10,000g for 10 min, the supernatant was analyzedwith a liquid chromatography-mass spectrometry system. An HP1100 HPLC apparatus (Hewlett-Packard) equipped with an InertsilODS 3 column (4.6 x 250 mm; GL Science) was used. Elution with80% (v/v) aqueous acetonitrile (containing 0.1% [v/v] formicacid) was carried out at a flow rate of 1.0 mL min^–1.Mass spectrometry was performed using a Mariner electrosprayionization-time of flight mass spectrometer (Applied Biosystems)in the positive-ion mode.

Inoculation of P. grisea and Xoo on Rice Plants

Inoculation of blast fungus on rice plants was performed accordingto the methods of Ashizawa et al. (2005). The isolate of P.grisea (Ina 86-137) was transferred to oatmeal agar plates andincubated at 25°C for 14 d in the dark. The aerial hyphaeon these plates were removed by gently brushing the agar surface,and then the plates were incubated for 72 h at 25°C underwhite fluorescent light. To prepare the conidial suspension,the conidia formed on the surface were collected by adding distilledwater containing 0.02% (w/v) Tween 20. The OsPLDβ1-knockdownand vector control plants grown for 20 or 30 d after seeding(the three- to six-leaf stage) under normal growth conditionswere sprayed with 10 mL of a conidial suspension per plant (10⁴conidia mL^–1 in distilled water containing 0.02% Tween20) using an atomizer with a fine nozzle. The sprayed plantswere kept in a moist chamber at 100% relative humidity in thedark at 25°C for 20 h and then moved to a greenhouse (25°C/27°C,solar radiation). The disease symptoms were observed for 1 to2 weeks after inoculation, and the area of diseased leaf lesionswas measured.

Inoculation of bacterial blight was performed according to themethods of Kauffman et al. (1973). The isolate of Xoo (T-7133)was grown on PPGA medium (Nishiyama and Ezuka, 1977). The uppermostfully extended leaves of OsPLDβ1-knockdown and vector controlplants grown for 50 d after seeding under normal growth conditionswere inoculated with a bacterial suspension (10⁸ cells mL^–1)by the leaf-clipping method. The disease symptoms were observedfor 2 weeks after the inoculation, and the area of the diseasedleaf lesions was measured. To determine the bacterial populations,the inoculated leaves were harvested at 0, 5, and 15 d afterXoo inoculation and surface sterilized with 70% (v/v) ethanoland 3% (v/v) sodium hypochlorite solution. The leaves were cutinto small pieces and resuspended in 10 mL of water to harvestbacteria separately. Diluted extract (0.05 mL) was incubatedon PSA medium (5 g L^–1 Bacto peptone, 15 g L^–1 Suc,5 g L^–1 soluble starch, 0.5 g L^–1 calcium nitrate,and 15 g L^–1 agar, pH 7.0) at 28°C for 4 to 6 d, andthe number of colonies formed on the agar plate was counted.

Sequence data from this article can be found in the GenBank/EMBLdata libraries under accession numbers listed in SupplementalTables S4 and S5.

Supplemental Data

The following materials are available in the online versionof this article.

Supplemental Figure S1. Accumulation of H₂O₂and OsPLDβ1mRNA in the leaves of 30-d-old OsPLDβ1-knockdownplants.

Supplemental Figure S2. Accumulation of OsPLDβ1and OsPLDβ2mRNA in the OsPLDβ1-knockdown plants.

Supplemental Figure S3. Comparison between blast resistanceand mRNA levels of OsPLDβ1 in the OsPLDβ1-knockdownplants.

Supplemental Figure S4. Growth curve of Xoo in theOsPLDβ1-knockdownand vector control plants.

SupplementalTable S1. The expression analysis of rice PLD genes.

SupplementalTable S2. DNA microarray analysis of OsPLDβ1-knockdownplants.

Supplemental Table S3. Growth and development parametersofthe vector control and OsPLDβ1-knockdown plants.

SupplementalTable S4. Gene-specific PCR primers used for quantitativeRT-PCRamplification.

Supplemental Table S5. Gene-specific PCR primersused for theconstruction of RNAi vectors.

ACKNOWLEDGMENTS

We thank Drs. Yoshiaki Nagamura (National Institute of AgrobiologicalSciences), Morifumi Hasegawa (Ibaraki University), and TatsuroHirose (National Agricultural Research Center) for their usefuladvice on microarray analysis, phytoalexin analysis, and quantitativeRT-PCR, respectively. Ken Nagata (Meiji University) contributedto the DNA database search and computer analysis.

Received November 25, 2008; accepted March 11, 2009; published March 13, 2009.

FOOTNOTES

¹ This work was supported by the Ministry of Agriculture, Forestry,and Fisheries, Japan, by the Ministry of Education, Culture,Sports, Science, and Technology, Japan, to T.Y., and by theProgram for the Promotion of Basic Research Activities for InnovativeBioscience to N.S.

The author responsible for distribution of materials integralto the findings presented in this article in accordance withthe policy described in the Instructions for Authors (www.plantphysiol.org)is: Takeshi Yamaguchi (tkyama{at}affrc.go.jp).

^[C] Some figures in this article are displayed in color online butin black and white in the print edition.

^[W] The online version of this article contains Web-only data.

^[OA] Open Access articles can be viewed online without a subscription.

www.plantphysiol.org/cgi/doi/10.1104/pp.108.131979

^{^*} Corresponding author; e-mail tkyama{at}affrc.go.jp.

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Suppression of a Phospholipase D Gene, OsPLDβ1, Activates Defense Responses and Increases Disease Resistance in Rice1,[C],[W],[OA]

Suppression of a Phospholipase D Gene, OsPLDβ1, Activates Defense Responses and Increases Disease Resistance in Rice¹^,[C]^,[W]^,[OA]