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Abstract
AP2/ERF–type transcription factors regulate important functions of plant growth and development as well as responses to environmental stimuli. A rice AP2/ERF transcription factor, OsEREBP1 is a downstream component of a signal transduction pathway in a specific interaction between rice (Oryza sativa) and its bacterial pathogen, Xoo (Xanthomonas oryzae pv. oryzae). Constitutive expression of OsEREBP1 in rice driven by maize ubiquitin promoter did not affect normal plant growth. Microarray analysis revealed that over expression of OsEREBP1 caused increased expression of lipid metabolism related genes such as lipase and chloroplastic lipoxygenase as well as several genes related to jasmonate and abscisic acid biosynthesis. PR genes, transcription regulators and Aldhs (alcohol dehydrogenases) implicated in abiotic stress and submergence tolerance were also upregulated in transgenic plants. Transgenic plants showed increase in endogenous levels of α-linolenate, several jasmonate derivatives and abscisic acid but not salicylic acid. Soluble modified GFP (SmGFP)-tagged OsEREBP1 was localized to plastid nucleoids. Comparative analysis of non-transgenic and OsEREBP1 overexpressing genotypes revealed that OsEREBP1 attenuates disease caused by Xoo and confers drought and submergence tolerance in transgenic rice. Our results suggest that constitutive expression of OsEREBP1 activates the jasmonate and abscisic acid signalling pathways thereby priming the rice plants for enhanced survival under abiotic or biotic stress conditions. OsEREBP1 is thus, a good candidate gene for engineering plants for multiple stress tolerance.
Citation: Jisha V, Dampanaboina L, Vadassery J, Mithöfer A, Kappara S, Ramanan R (2015) Overexpression of an AP2/ERF Type Transcription Factor OsEREBP1 Confers Biotic and Abiotic Stress Tolerance in Rice. PLoS ONE 10(6): e0127831. https://doi.org/10.1371/journal.pone.0127831
Academic Editor: Girdhar K. Pandey, University of Delhi South Campus, INDIA
Received: January 3, 2015; Accepted: April 21, 2015; Published: June 2, 2015
Copyright: © 2015 Jisha 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
Data Availability: The microarray data has been submitted to the GEO repository and assigned GEO accession number GSE46173 and can be viewed at http://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE46173. Sequence data from this article can be found in the Michigan State University Rice Genome Annotation Project database (http://rice.plantbiology.msu.edu) under the following accession numbers: Jmt (LOC_Os05g01140), PR10 (LOC_Os12g36830), NAC6 (LOC_Os03g60080), PBZ1 (LOC_Os12g36850), Wrky62 (LOC_Os09g25070), OsEREBP1 (LOC_Os02g54160), LOX (LOC_Os12g37320), OsLis (LOC_Os02g02930), Actin (LOC_Os03g50885), Xb22 (LOC_Os07g07540).
Funding: The work was supported by Department of Science and Technology (DST No: SR/SO/PS-68/2008) and Council for Scientific and Industrial Research (CSIR No: 9/1/BS/CCMB (4)/2012-13-PPD), Government of India.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Plants being sessile have evolved adaptive mechanisms to cope with various types of environmental stresses. Transcription factors are important candidates for adapting plants to stress tolerance since they regulate the expression of a number of stress responsive genes (referred to as regulons) by binding to specific cis-elements present in their promoters. A collection of >2000 known and predicted rice (Oryza sativa) transcription factors distributed in 63 families are available in the Database of Rice Transcriptional Factors [1]. Regulons regulated by AP2/ERF (Apetala2/ethylene Responsive factor), ABF/AREB (Abscisic acid binding factor/Abscisic acid responsive element binding) and NAC (NAM, ATAF and CUC domain containing) class of transcription factors are generally involved in abiotic stress responses [2]. Biotic stress responses depend on compatible or incompatible interactions between the pathogen and the host, leading to susceptibility or resistance in the plant via specific induction of transcription factors such as WRKY-type in response to pathogens [3].
The plant specific AP2/ERF (Apetala2/ethylene responsive factor) class of transcription factors are a large family with ~163 members in rice that regulate important functions of responses to environmental stimuli or plant growth and development depending on the presence of one or two highly conserved 60 amino acid AP2 domain in the protein [4, 5]. They regulate the expression of genes having a GCC box in their promoters, which include the DRE/CRT (drought responsive/C-Repeat) elements binding to CBF/DREB factors involved in abiotic stress responses. Overexpression of a tobacco (Nicotiana tabacum) AP2/ EREBP (Apetala2/ethylene responsive element binding protein) type transcription factor was shown to enhance biotic and osmotic stress tolerance in tobacco [6]. Five different DREBs {drought responsive element binding (DREB1A,B,C,D and 2A)} have been cloned from rice and overexpression of rice DREB1A in Arabidopsis thaliana induced the expression of target stress inducible genes, resulting in increased tolerance of transgenic plants to drought, salt and cold tolerance [7]. Arabidopsis and rice constitutively overexpressing DREB1A showed tolerance to drought and cold but were compromised for growth, whereas use of a stress inducible promoter of Rd29 for overexpression led to stress tolerance without stunting plant growth [8]. AthDREB2A full length clone neither affected the growth nor did it confer drought or salt tolerance when overexpressed in Arabidopsis, while a deletion of 135 to 165 residues transformed DREB2A into a constitutive form in the transgenic plants, which showed significant tolerance to drought [9]. Three of the four rice genes [(OsBIERF 1–4){(Oryza sativa benzothiadiazole (BTH)-induced ethylene responsive transcriptional factors (ERF)] with a single conserved ERF domain were found to be upregulated by salt, cold, drought, wounding as well as in an incompatible interaction between rice and fungal pathogen suggesting their role in biotic and abiotic stress [10]. Expression of OsEBP2 (Oryza sativa ethylene-responsive-element binding protein 2) was induced in response to compatible interaction between rice and blast fungus and transiently induced by treatments with MeJA, ABA and ET indicating its possible role in abiotic stress [11]. An AP2/ERF like transcription factor Ath hardy (Hrd), when expressed in rice conferred drought tolerance with improved water-use efficiency and also increased shoot and root biomass [12]. Constitutive expression of OsAP37 enhanced drought tolerance of rice in vegetative stage and increased grain yield under drought conditions [13]. The Sub1A (Submergence1A) gene which encodes for AP2 domain transcription factor enhanced survival in submergence tolerant rice cultivars by inhibiting shoot elongation [14]. Over expression of a tomato (Lycopersicon esculentum) ERF improved osmotic and drought tolerance in rice [15], while overexpression of AthDREB1A improved drought tolerance and OsDREB1B conferred salt tolerance in indica varieties of rice [16].
An AP2/ERF class of transcription factor OsEREBP1 was identified as a downstream component of a signal transduction pathway in a specific interaction between rice and its bacterial pathogen, Xanthomonas oryzae pv. oryzae (Xoo) in yeast two-hybrid screens (unpublished data). The resistance gene Xa21 in rice encodes a LRR- receptor kinase (LRK) protein which specifically recognizes a sulphated peptide Ax21, secreted via the Type I secretion system of Xoo strains [17, 18], resulting in an incompatible interaction between the host and the pathogen [19]. The extracellular LRR domain of Xa21 specifically recognizes the Ax21 ligand from Xoo and results in the autophosphorylation of the serine/threonine residues in the intracellular kinase domain [20] that triggers a signal transduction pathway leading to resistance by the activation of defense genes. The intracellular kinase domain of Xa21 including the JM region (juxtamembrane, a portion of cytoplasmic domain between the transmembrane and kinase region) termed as Xa21K668 [21] interacts with downstream proteins in the signaling pathway. Several proteins interacting with Xa21K668 in vitro were identified using the yeast-two hybrid system and these have been referred to as Xa21-binding proteins (Xbs). One of these Xbs, Xb22 was further used as bait in yeast-two hybrid screens to identify Xb-interacting partners. Two proteins were found to interact with Xb22 and one of them was an AP2-EREBF transcription factor (OsEREBP1), which was shown to be a positive regulator of resistance to Xoo infection in phenotypic assays [22]. This study elucidates the role of OsEREBP1 transcription factor in various stress responses of rice.
Materials and Methods
Plasmid construction for overexpression and rice transformation
The full length coding sequence was PCR-amplified using OsEREBP1FL primers (S1 Table), from a cDNA library of japonica rice cultivar prepared from seedlings inoculated with the blast fungus Magnaporthe griseae and cloned into the pENTR gateway vector (Invitrogen) as per the supplier’s manual, to obtain the AP2/pENTR plasmid. For overexpression in japonica cv. Kitaake, the OsEREBP1 cDNA in pENTR/TOPO was recombined into the Ubi-NC1300-Rfa vector using Gateway LR Clonase (Invitrogen) to obtain AP2/pNC1300 plasmid [23]. Ubi-NC1300-Rfa is a derivative of pC1300 with maize ubiquitin promoter [24] and nopaline synthase to which Gateway cassette has been added. The construct was then mobilized into Agrobacterium strain EHA105 for transformation of rice calli and transformed calli were selected for hygromycin resistance as described [24]. Shoots were regenerated from the hygromycin resistant calli and induced for root formation. The regenerated plants were transferred to soil and allowed to set seeds. The T3 stable transgenic rice plants were obtained.
Microarray analysis
RNA from fully grown third leaf of transgenic and non-transgenic plants at the four-leaf stage were used for hybridization of Rice Affymetrix gene-chip (51K arrays) containing probe sets designed from 48564 japonica and 10260 indica gene sequences according to the Affymetrix GeneChip expression analysis technical manual. Three biological replicates were used for the experiment. Annotation of the differentially expressed probes was done using NetAffyx software of Affymetrix and further validated using BLASTX search through NCBI.
PCR analysis
Total RNA was extracted from fully grown leaf of transgenic (4–3 and 2–4) and non-transformed four week old rice seedlings using trizol reagent (Invitrogen) and treated with RNase-free DNase I (Invitrogen) to prevent genomic DNA contamination. First-strand cDNA was synthesized from 5μg of total RNA from each sample using superscript-III RT-PCR kit (Invitrogen) and oligo–dT 18 mer primer and stored at -20°C for further use.
Regular PCR was performed in a PTC-200 Peltier Thermal cycler (MJ Research) with a 20 μl reaction mixture containing 1 μl template, 5 pmoles of each primer. 200 μM of each of the four deoxynucleotide phosphates and 1 unit Taq polymerase (Bangalore Genie, India). The PCR conditions were 94°C for 5 min for denaturation 30 cycles of 94°C for 30 sec, 55°C for 30 sec and 72°C for 1 min followed by final extension of 72°C for 10 min.
All qRT-PCR was performed on an ABI prism 7900 HT sequence detection system (Applied Biosystems). A typical 10 μl reaction mixture contained 5 μl of 2X SYBR green dye (Invitrogen), 1 pmoles of each primer, 1 μl of template and 2 μl of distilled water. All reactions were set up in triplicates, in a 386-well optical reaction plate. The PCR conditions were as follows: 95°C for 10 min,: 95°C for 15 sec, 60°C for 30 sec and 72°C for 30 sec for 40 cycles. The levels of OsActin1 served to normalize the expression ratio for each gene and the changes in expression were calculated by the ΔΔCt method [25]. To calculate the relative expression of a given gene, all expression values were normalized to that of Kitakee which was taken as calibrator and its expression value was adjusted to one. The values reported are the mean of at least three independent experiments (three biological replicates) with each sample analyzed in triplicate. Primers for real time PCR are listed in S1 Table.
Accession numbers
The microarray data has been submitted to the GEO repository and assigned GEO accession number GSE46173 and can be viewed at http://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE46173. Sequence data from this article can be found in the Michigan State University Rice Genome Annotation Project database (http://rice.plantbiology.msu.edu) under the following accession numbers: Jmt (LOC_Os05g01140), PR10 (LOC_Os12g36830), NAC6 (LOC_Os03g60080), PBZ1 (LOC_Os12g36850), Wrky62 (LOC_Os09g25070), OsEREBP1 (LOC_Os02g54160), LOX (LOC_Os12g37320), OsLis (LOC_Os02g02930), Actin (LOC_Os03g50885), Xb22 (LOC_Os07g07540).
Xb22a-smGFP and OsEREBP1-smGFP plasmid construction and transient expressions in rice protoplast
The coding regions of Xb22a and OsEREBP1 without the stop codon, were PCR amplified using OsEREBP1-smGFP and Xb22a-smGFP forward and reverse primers (S1 Table) and the amplified product was cloned into pENTR/D-TOPO/D vector (Invitrogen). The positive clones were sequence confirmed and the inserts were recombined in-frame into the coding region of soluble-modified green fluorescent protein (smGFP) of pUbi-smGFP binary vector [26] using Gateway LR Clonase (Invitrogen). Protoplasts were isolated from stem and sheath of rice seedlings and transient expressions of smGFP constructs were performed by introducing plasmids into rice protoplasts using the PEG-mediated transformation method [27]. Images were collected through 60x (numerical aperture = 1.40) oil immersion lens of Leica TCS SP5 confocal microscope (Leica Microsystems, Weitlzar, Germany) with argon laser excitation wavelength of 488nm and detection windows of 500–530nm and 640–726nm for GFP and chlorophyll autofluorescence, respectively. All fluorescent experiments were independently performed at least three times.
Estimation of total lipids and phytohormones
Total lipids were extracted from the leaves of 2–3 week old greenhouse grown plants according to Griffiths et al., [28]. Young leaves (~0.2g fresh weight) were homogenized with a pestle and mortar containing 0.15M acetic acid (1ml) and chloroform/methanol (1:2 v/v; 7.5ml) for about 2min and transferred to conical glass centrifuge tubes. Samples were centrifuged at low speed and the lower chloroform phase containing the lipids were removed to glass vials and evaporated under nitrogen. All steps were done in dim light with chilled solvents. Lipids were quantified by GC-MS analysis as their fatty acid methyl ester derivatives after transmethylation with 2.5%v/v H2SO4 in anhydrous methanol (2ml) followed by hexane extractions. Extracts were evaporated under N2 and further redissolved in 200μl of hexane. 3μl of sample is injected in to the column along with the internal standard nonadecanoic acid. GC-MS system used was of Agilent Technologies equipped with thermal conductivity detector (TCD). Method used was GCMS-FAMES M and separation was achieved on a HP-5MS column with helium as the carrier gas at the rate of 1.3ml/min.
For phytohormone analysis, finely ground leaf material was extracted with 1.5 mL of methanol containing 60 ng of 9,10-D2-9,10-dihydrojasmonic acid, 60 ng D4-salicylic acid, 60 ng D6-abscisic acid (Santa Cruz Biotechnology), and 15 ng of jasmonic acid-[13C6]isoleucine conjugate as internal standards according to the method described by Vadassery et al. [29]. Phytohormones were quantified relative to the signal of their corresponding internal standards. The peak of the endogenous bioactive form of JA-Ile, (+)-7-iso-Jasmonoyl-L-isoleucine was used for JA-Ile quantification [30]. The authentic 12-OH-JA-Ile (N-((±)-tuberonoyl)-L-isoleucine was used for the determination of the response factor. 12-OH-JA-Ile was quantified on the MRM m/z 338/130 (DP -50V, CE -30V) using the signal of the internal standard, jasmonic acid-[13C6] isoleucine conjugate applying an experimentally determined response factor of 1.
Inoculations with Xoo and disease scoring
BXO43 strain of Xoo, which is the most prevalent pathotype in India was inoculated in peptone-sucrose medium and incubated for 48 h at 28°C in a shaker incubator adjusted to 180 rpm. The culture was centrifuged at 5000 rpm in refrigerated centrifuge and the bacterial pellet was resuspended in the original volume of sterile distilled water. Two topmost fully expanded leaves in all the tillers of six week old rice seedlings were inoculated by clipping the leaves with a scissor dipped in inoculum [31]. The lesion lengths were measured in centimeters using a ruler at different time intervals from at least ten inoculated leaves for each rice sample and average was plotted as a graph with error bars for each recording. For Xoo colony counts from inoculated leaves, 10 cm of leaf tissue from the top, including lesions and tissue showing no lesions was collected at different time intervals and extracted in 5 ml water to harvest bacteria. The extract was diluted accordingly and plated out on peptone sucrose agar (PSA) plates containing 15 mg/l cyclohexamide (to avoid fungal contamination) to get single colonies. The colonies were counted and the bacterial population per leaf was calculated.
Drought tolerance testing of transgenic plants
Seedlings grown in soil-filled, 15 cm diameter pots were saturated with water (20% W/W) and the soil surface was mulched with a 2 cm thick layer of polythene beads, for minimizing soil evaporation [32]. Eight seedlings per pot with two replicates for drought stress (DS1 and DS2) and one replicate for well watered (WW) control treatment were maintained by uniform watering till the beginning of the experiment in green house conditions. Drought was imposed at four leaf stage (3 weeks after germination) in the first experiment (DS1) and panicle initiation or booting stage (~8 weeks from germination) during second experiment (DS2). Regular watering was done to control WW pot while water was completely withheld in DS1 and DS2 treatments allowing gradual depletion and drying of pots till the plants showed intense drying symptoms and complete rolling of leaves leading to browning of leaf sheaths. Each of the pots was re-watered and the pattern of recovery was closely monitored and plants were scored as viable if new leaves appeared during recovery period.
Submergence treatment
Two week old seedlings grown in soil-filled 15 cm diameter plastic pots were completely submerged in a plastic tub filled with 60 cm water and covered with polythene sheet in greenhouse conditions as described earlier [33]. The plants were removed after 5, 7 or 10 days of submergence, photographed and the leaf length was measured with a scale before and after submergence. Comparisons of the lengths were also made between plants grown under aerobic and submerged conditions. Plants were scored as viable if new leaves appeared upon desubmergence. The leaf tips were collected immediately after de-submergence for histochemical staining to detect reactive oxygen species according to Fitzgerald et al., [34] except that after incubation with DAB or NBT, leaves were cleared by soaking in 95% ethanol at 70°C for 15 minutes.
Results
Constitutive expression OsEREBP1 in rice does not affect normal plant growth
The full length cDNA of OsEREBP1 was cloned in pENTR vector (AP2/pENTR) and was confirmed by sequencing. The OsEREBP1 cDNA is comprised of 1098 bp and codes for 365 amino acid protein of about 40.1 kDa with a predicted pI of 4.89. The protein shows a highly conserved AP2 domain, a highly acidic N-terminal region and a putative nuclear localization signal (NLS). For overexpression of OsEREBP1 in rice, AP2/pNC1300 plasmid was constructed in which the expression of full length cDNA was driven by maize ubiquitin (Ubi) promoter. Transgenic plants were successfully obtained following Agrobacterium mediated transformation of rice cultivar Kitaake. The transgenic plants did not show any undesirable growth phenotypes at seedling stage (Fig 1A) or at reproductive stages and produced fertile seeds (Fig 1B). Two independent transgenic lines were confirmed by Southern analysis to have single insertion of the transgene and were selected for further characterization and the presence of transgene in the progenies of the two stable T3 transformants of Kitaake variety of japonica rice was confirmed by PCR (Fig 1C and 1D). RT-PCR analysis of the transcript levels of OsEREBP1 (also referred to as AP2) revealed that the transgenic lines had higher levels of transcript as compared to the wild type (Fig 1E).
A) Photographs were taken of six week-old seedlings grown under greenhouse conditions. B) Pictures were taken of plants after the panicle initiation stage. C) Southern blot hybridization of BamHI-digested genomic DNA showed single independent insertions in progenies of 2–4 and 4–3 (transgenic lines), whereas no band was observed in non-transformed Kitaake (control) when probed with hygromycin gene obtained by PCR amplification of pC1300 plasmid using HygS/AS primer pair. D) PCR analysis of genomic DNA using a vector-specific (UbiS) and insert-specific (AP2AS) primer pair showed presence of transgene in the progenies of 2–4 and 4–3 and not in Kitaake. Ap2/pNC1300 plasmid DNA was used as positive control. E) RT-PCR of cDNA using OsEREBP1 primers showed increased transcript in 2–4 and 4–3 as compared to Kitaake. EF1a was used to normalize the cDNA. All primer details are given in S1 Table.
Activation of genes involved in jasmonates and abscisic acid biosynthetic pathways and defense responses in OsEREBP1-ox plants
Global gene expression analysis of OsEREBP1-overexpressing (OsEREBP1-ox) transgenic line (4–3) versus non-transgenic control samples was carried out using the Affymetrix gene chip microarrays in order to identify molecular events associated with OsEREBP1 overexpression. The CEL files generated by the Gene Chip Operating System (Affymetrix) were subjected to GeneSpring 12.6—GX—PA (Agilent Technology) for further analysis. The GC-RMA algorithm was used for data normalization. Genes showing differential expression were identified using array data from two of three independent experiments since hierarchical cluster analysis of microarray data from three biological replicates showed that two replicates grouped together while the third replicate formed a different cluster thereby lowering the significance (P value) of the fold-changes. Genes showing >1.5-fold difference with P value <0.05 were selected to obtain higher stringency in selection. The selected genes showed similar regulation between the untransformed Kitaake and 4–3 OsEREBP1-ox line grown under two different growth regimes, thus strengthening the confidence in the data. Among the thirteen genes validated by quantitative real time PCR (qPCR) analysis, all showed the same expression pattern as in microarray results (Fig 2).
Total RNA was extracted from 4 week old non-transformed (Kit) and transgenic (4–3 and 2–4) plants and qPCR was performed with primers for genes which include (A) NAC6, AP59, EREBP1 & WRKY (transcription factors); (B) Jmt, RERJ & OsLis (Jasmonate biosynthesis and regulation); (C) PBZ, PR10, Lox (Pathogenicity related); (D) CatB, HLH148 & Lea5 (ABA pathway). Actin was used as internal standard. Primer details are given in S1 Table. Data representing mean±SE from three independent biological replicates was subjected to further statistical analysis by one way ANOVA using SigmaPlot Version 11.0. The asterix indicate p value of 0.05.
A total of 2395 genes were differentially expressed in the overexpressor line which included 1348 up-regulated and 1047 down-regulated genes. Regulatory genes included transcription factors involved in stress responses such as four NAC-domain containing, fourteen AP2-domain containing including OsEREBP1 and fifteen WRKY-type genes (Table 1).
Biosynthesis of oxylipins like JA is initiated by the coordinated activities of lipases and lipoxygenases resulting in generation of unsaturated fatty acids. Interestingly, six lipases and four plastidic lipoxygenases and several genes involved in Jasmonic acid (JA) metabolism and regulation including OPDA reductase, JA-O methyl transferase (Jmt), CYP94C1, OsJaz1 and linalool synthase (OsLis10-fold increase) and RERJ1 (2.3-fold) were upregulated in transgenic plants. Transcript levels of OsNCED1 coding for 9-cis-epoxycarotenoid dioxygenase, a key gene in abscisic acid (ABA) biosynthesis and AP39 a transcription factor that upregulates OsNECD1 causing increase in endogenous levels of ABA [35] were also elevated. qPCR results showed increased levels of Jmt, RERJ1, OsLis involved in JA metabolism and regulation as well as AP59, CatB, HLH148 and Lea5 involved in ABA pathway in 4–3 and 2–4 transgenic lines as compared to non-transgenic control (Fig 2).
As many as 93 defense response genes showed up-regulation in the OsEREBP1-ox lines compared to the untransformed wild type plants (S2 Table). The transcript levels of WRKY62 (which interacts with Xb10 in the Xa21-mediated resistance pathway), PR1b and PBZ1 genes which are specifically induced following bacterial infection were highly elevated indicating the role of OsEREBP1 in bacterial resistance as confirmed by qPCR analysis (Fig 2). Lox gene, which is induced specifically in response to fungal infection and confers resistance against the fungal pathogen showed higher levels of expression in transgenic plants. Nine genes of the alcohol dehydrogenase family involved in alcohol fermentation during anaerobic conditions showed up-regulation (Table 1). These results suggest a role for OsEREBP1 in bacterial, fungal, anaerobic and abiotic stress pathways by modulating JA and ABA phytohormones.
OsEREBP1 and its interacting protein are localized to chloroplast
Xb22, identified as an interacting partner of Xa21K668 in yeast two hybrid screens [22], when used as a bait in yeast two-hybrid screen interacted with OsEREBP1. Xb22 has two isoforms of which Xb22a is a protein of 335 amino acids containing PDZ domain, a K-box domain and a tetratricopeptide repeat domain, whereas the second isoform Xb22b is alternatively spliced in the first intron resulting in a protein of 220 amino acids with variable N-terminal region (S1 Fig). The interaction of the two isoforms with OsEREBP1 using the Proquest yeast two-hybrid system (Invitrogen, USA) showed that OSEREBP1 interacts with only Xb22a but not Xb22b (S1 Fig). Several differentially regulated genes in the OsEREBP1-ox line that were observed from the microarray data predicted chloroplast/plastid localization. Analysis of the predicted protein sequence of OsEREBP1 showed a DNA binding domain, a putative nuclear localization signal but no clear chloroplast signal, whereas its interacting protein Xb22a showed presence of a characteristic chloroplast signal (S1 Fig). To investigate the subcellular localization of OsEREBP1 and Xb22a, the pUbi:Xb22a-SmGFP (Xb22a) or pUbi:OsEREBP1-SmGFP (OsEREBP1) plasmids were transiently expressed in rice protoplasts by PEG mediated transfections. Confocal microscopy (CLSM) analysis revealed that GFP fluorescence of Xb22a-SmGFP was targeted to chloroplasts and completely overlapped with the red autofluorescence of chlorophyll. The OsEREBP1-SmGFP was localized to chloroplast and GFP fluorescence was seen as distinct punctate patterns in the red background of chlorophyll autofluorescence indicating that the protein is not only chloroplast localized but is associated with chloroplast nucleoids. The control GFP construct alone showed diffused fluorescence (Fig 3).
Confocal micrographs of individual rice protoplast transformed with Ubi:SmGFP (SmGFP), Ubi:Xb22a-SmGFP (Xb22a) or Ubi:OsEREBP1-SmGFP (OsEREBP1) plasmids. The columns from left are: GFP-flourescence in green (false color), chlorophyll fluorescence in red (false color), differential interference contrast transmission (DIC) and the merged image.
OsEREBP1-ox plants show increased levels of α-linolenate and phytohormones
Lipids and lipid metabolites act as important regulators of defense responses. Biologically active lipids and precursors of oxylipins are released from plant membranes by the activity of enzymes such as lipases and lipoxygenases [36]. Since six lipases and four chloroplastic LOX genes were significantly up-regulated in the transgenic plants (Table 1), the fatty acid levels were analyzed in the OsEREBP1-ox lines in comparison to untransformed control plants in three independent experiments by GC/mass spectrometer and values were calculated as mol% ± SD. Lipids in all the rice leaf samples comprised of mainly four kinds of fatty acids namely 16:0, hexadecanoic acid (palmitic acid), 18:0, octadecanoic acid (stearic acid), 18:2, ∆ 9, 12 octadecadienoic acid (linoleic acid) and 18:3, ∆ 9, 12, 15 octadecatrienoic acid (α-linolenic acid). The molar ratios of these fatty acids in Kitaake was 43.9 ± 3.1, 10.1 ± 1.6, 6.5 ± 1 and 37.8 ± 6.2 respectively, with respect to nonadecanoic acid that was used as internal control. The molar ratios of these fatty acids was 33.4 ± 5.4, 9.1 ± 4, 4.6 ± 1.1 and 51.5 ± 11 in 4–3 and 36.7 ± 3.4, 6.6 ± 0.7, 6.2 ± 0.5 and 49.3 ± 3.3 in 2–4 transgenic lines, respectively (Table 2). The nmoles/fresh weight tissue of 18:3 (octadecatrienoic acid) was 36.4% and 30.4% higher in 4–3 and 2–4 transgenic lines, respectively as compared to Kitaake, whereas the levels of other fatty acids were similar in the transgenic and control plants.
Several genes related to jasmonate and ABA metabolism were found to be upregulated in OsEREBP1-ox plants and so we analyzed the levels of phytohormones in transgenic and non-transformed control plants. Overexpression of OsEREBP1 induced accumulation of JA and its derivatives collectively known as jasmonates. There was >2-fold increase in the levels of JA, bioactive 7-iso-jasmonyl isoleucine (JA-Ile), OH-JA-Ile and COOH-JA-Ile in the transgenic lines (Table 3), whereas cis-12-oxo-phytodienoic acid (cis-OPDA) levels were not significantly different. The levels of ABA were ~2-fold increased in the transgenic plants as compared to non-transgenic control whereas salicylic acid (SA) levels which are generally high in rice showed no significant difference. Between the two transgenic lines, considerable variation was observed in 2–4 replicates, which is reflected in the high SD values. However, in spite of this, overall values in 2–4 are still higher as compared to non-transgenic control plants.
OsEREBP1 expressing transgenic rice shows reduced susceptibility to bacterial blight
OsEREBP1 was identified as a downstream component of Xa21-mediated resistance to the bacterial pathogen Xoo and hence, we wanted to assess its role in resistance to the pathogen. Xoo is a vascular pathogen and clip inoculations give rise to lesions whose leading edge advances through the mid-vein, causing drying up of the upper regions of the leaf [31]. Six week old transgenic plants over expressing OsEREBP1 (4–3 and 2–4) and the untransformed control plants (Kit) were inoculated with the BXO43 strain of Xoo. Leaves of Kitaake exhibited typical lesions that extended through the mid-vein along the entire length of the leaf after 14 days of inoculation (DOI), whereas lesions through mid-veins and drying of leaves were distinctly less in the leaves from transgenic lines (Fig 4A). The disease was measured as length of Xoo induced lesions or bacterial population in the inoculated leaves. The transgenic plants showed significant reduction in the lesion lengths (12–15 cm) as compared to the ~22cm in the control after 21 DOI with BXO43 strain (Fig 4B). We quantified the effect of OsEREBP1 overexpression on bacterial growth by monitoring bacterial population in the leaves of transgenic and control rice plants inoculated with BXO43. After seven DOI, Xoo populations in Kitaake reached approximately 1 X 1010 colony forming units per leaf (cfu/leaf) and 1–5 x 108 cfu/leaf in the two transgenic lines (Fig 4C). CFU is a measure of bacterial population within the host and a higher CFU indicates greater susceptibility of the host. A 50–100 fold decrease in the bacterial population was observed in the transgenic lines when compared to the susceptible control Kitaake, indicating a significant difference in the bacterial growth within the plant. These results demonstrate that over expression of OsEREBP1 attenuates the disease caused by Xoo in rice.
(A) Leaf lesion development: Six week old plants of Kitaake (control), 4–3 and 2–4 (T3 progeny of transgenic lines) were inoculated by clipping the leaves with a scissor dipped in the Xoo inoculum. Photos of leaves showing lesions 14 days post inoculation. (B) Leaf lesion length: Lesion lengths (in cms) were measured 7, 14 and 21 days post inoculation from 10 inoculated leaves. Values are means ± SD of three replicates. (C) Bacterial growth curves: Three leaves for each of the cultivars 3, 6, 9 and 12 days post inoculation were individually ground in water and plated at various dilutions to get suitable bacterial counts. Each data point represents average and standard deviation of three independent experiments.
OsEREBP1 confers drought and submergence tolerance
Our microarray and qPCR analysis showed that another transcription regulator OsNAC6 belonging to the NAC family was 1.66-fold up-regulated in the transgenic plants. NAC (NAM, ATAF and CUC) domain containing proteins, another class of plant specific transcription factors form a large family with ~151 predicted members in rice [37] and play important role in biotic as well as abiotic stress responses. Hence, we anticipated that the transgenic plants may endure abiotic stress such as drought. To assess the drought tolerance at the vegetative stage, seedlings of transgenic and non transgenic (NT) control plants grown in a greenhouse were subjected to drought stress at the four leaf stage by withdrawing water for 26 days followed by 1 week of watering. During the course of drought treatment, the transgenic plants showed delay in stress-induced symptoms such as leaf-rolling and wilting as compared to NT plants (Fig 5A). To analyze the drought tolerance at the reproductive stage, plants grown in pots were subjected to continuous water stress at the panicle heading stage till the plants showed complete drying and were subsequently rewatered to allow recovery. The transgenic plants had more number of new tillers, which later formed panicles and grains following rewatering as compared to the control plants (Fig 5B). Transgenic plants over expressing the transcription factor (OsEREBP1-ox) also showed better recovery with 50% recovery for 4–3 and 60% for 2–4 as compared to 10% in the non-transgenic control when water stress was given (DS1, Fig 5C). The recovery from drought stress at reproductive stage was 55% for 4–3, 70% for 2–4 and 16% for Kitaake control (DS2, Fig 5C). These results show that over expression of OsEREBP1 in rice leads to increased drought tolerance at vegetative as well as reproductive stages of growth.
(A) Photos of transgenic rice plants (4–3 and 2–4) and non-transgenic control (Kit) plants subjected to drought stress for 26 days followed by 7 days of watering. (B) Drought tolerance at the reproductive stage. Drought was imposed by withdrawing water at panicle initiation stage till plants were completely brown before they were re-watered. Recovery was indicated by new tillers which formed panicles and grains following rewatering. (C) Percentage recovery of drought stress plants (DS1 and DS2) compared to well-watered ones (WW). Drought was imposed at four leaf stage (DS1) or panicle initiation or booting stage (DS2) till the plants showed complete browning of leaves. Pots were rewatered and percentage recovery was calculated based on the number of plants that produced new leaves out of the total number of plants per pot. Error bars represent mean of three independent experiments.
During anaerobic conditions such as caused by submergence, alcohol fermentation is important for survival of plants. In anaerobic pathway, pyruvate generated by glycolysis is converted to acetaldehyde which is either reduced by alcohol dehydrogenase (ADH) to alcohol or oxidized to acetate by aldehyde dehydrogenase (ALDH). Submergence tolerance in rice is conferred by Sub1A which is another AP2/ERF transcription factor, which positively regulates transcription of Adh1 [14]. Several Adh genes including Adh1 were upregulated in the OsEREBP1-ox plants. In order to assess the role of OsEREBP1 in submergence tolerance, two week old seedlings of 4–3 and 2–4 (transgenic) and Kitaake (untransformed control) were submerged in water for various time intervals. The rolling and yellowing of leaves following 7 days of submergence was more severe in Kitaake upon desubmergence whereas the upper leaves of 2–4 and 4–3 remained flat and green for a longer period (Fig 6A). Submergence causes leaf and internode elongation and decrease in the rate of plant growth is a measure of tolerance to submergence stress. Plant heights of 14 day old seedlings were measured before and after they were submerged in water for 7 days and the difference in their heights was calculated (Fig 6B). An increase of 125% over the 0 day control in plant height was observed in Kitaake as compared to 92.56% in 4–3 and 93.75% in 2–4 indicating that leaf elongation was greater in Kitaake than in OsEREBP1-ox lines after submergence treatment. Similar results were obtained when two week old seedlings were submerged in water for 5 days and their height was compared with plants not subjected to submergence (aerobic conditions). The difference in heights between Kitaake plants subjected to aerobic and submerged conditions was 30% as compared to 12.7% and 11.1% difference in 4–3 and 2–4 respectively (S2 Fig). Upon a more prolonged submergence for 14 days, the withered and dried leaves failed to recover in all the genotypes but there was a significant difference in the emergence and growth of new leaves. More than 80% of plants of 2–4 and ~60% of 4–3 transgenic lines recovered and produced new leaves as compared to 0–28% of Kitaake plants (Fig 6C). These results suggest that constitutive expression of OsEREBP1 increases submergence tolerance and improves recovery from prolonged submerged conditions in rice plants. To assess the injury caused by overproduction of reactive oxygen species (ROS) upon sudden re-exposure to air after submergence, leaves were stained with NBT (nitro-blue tetrazolium) and DAB (3–3’diaminobenzidine tetrahydrochloride) to visualize the accumulation of superoxide O2- and H2O2, respectively immediately following desubmergence. The intensity of blue and brown colors were higher in Kitaake leaves as compared to the transgenic (2–4 and 4–3) leaves (Fig 6D). This suggests that OsEREBP1 enhances submergence recovery and drought tolerance in rice.
(A) Two-week old plants were removed from water after 7 days of submergence and photographed. (B) Plant height after submergence treatment. Two-week old plants were submerged for 7 days and plant height of 10 plants was measured at 0 and 7 days after submergence. The error bars represent means ± SD (n = 3) and asterisk indicates that the differences in length were significant (P<0.01) as analyzed by one way ANOVA using SigmaPlot Version 11.0. (C) Plant viability after submergence treatment. Two-week old seedlings of transgenic lines (4–3, 2–4) and Kitaake control were submerged for 14 days and allowed to recover under normal conditions. The plants were scored as viable if they produced new leaves. (D) Accumulation of reactive oxygen species upon submergence. Two-week old seedlings were submerged for 7 days and immediately after desubmergence, the leaves were stained with DAB or NBT to detect hydrogen peroxide or superoxide radicals, respectively.
Discussion
Innate immune response in plants involves recognition of pathogen associated molecular patterns (PAMPs) by pathogen recognition receptors (PRRs) in the host. In rice, Xa21 is a PRR which confers broad spectrum resistance against strains of Xoo secreting sulphated peptide Ax21 [17]. Our study show that OsEREBP1 interacts with one of the eight unique Xa21-binding protein (Xb22a) in the Xoo-rice resistance pathway (S1 Fig). OsEREBP1 belongs to a large family of AP2-domain containing transcription factors and can be classified as group VIIa class of proteins along with 13 members, which are phosphorylated by MAP kinases [4]. OsEREBP1 is induced in response to the fungal elicitor [38] and is phosphorylated by MAP kinase, OsMPK12 (BWMK1), which upon overexpression in tobacco resulted in expression of PR genes and increased resistance to Pseudomonas syringae and Phytophthora parasitica infection [39]. In this study, we used the transgenic approach to elucidate the role of OsEREBP1 in various stress responses. Earlier studies have shown that expression of transcription factors using constitutive promoters causes growth abnormalities and sterility [40–42], whereas constitutive expression of OsEREBP1 driven by Ubi promoter did not cause any undesirable growth phenotypes in our study. Transgenic rice plants constitutively expressing the transcription factor showed attenuation of the disease symptoms upon infection with the bacterial pathogen and increased tolerance to drought and submergence treatment. OsEREBP1-ox plants also showed reduced lesions upon infection with virulent strain of M. griseae (S3 Fig) following increased expression of chloroplastic Lox and PR genes (Fig 2). Our study reveals that overexpression of transcription factor OsEREBP1 confers biotic and abiotic stress tolerance in rice and could be a good candidate gene for engineering plants for multiple stress tolerance without any growth defects.
Microarray analysis was performed for expression profiling studies to identify genes regulated by OsEREBP1 using three biological replicates and all the data has been deposited in public database. However, while analyzing the data hierachical clustering showed that two replicates of control (Kitaake) formed one cluster and two replicates of sample (transgenic line 4-3-1) formed another cluster whereas the third replicate of control and sample did not group with either cluster (S4 Fig). When data from all three replicates was used for analysis OsEREBP1 did not show upregulation, whereas transcripts levels were shown to be higher in transgenic plants (Fig 1E). Hence, only data from two replicates which showed strong clustering was used for further analysis. We validated the subset of JA and ABA related genes and also OsEREBP1 using qPCR (Fig 2) and the results confirmed the trend in array data thus obtained. Transcriptome analysis showed high expression of several transcription regulators belonging to the WRKY and NAC family in the transgenic plants. WRKY genes included ABA-induced OsWRKY71 involved in rice defence response [43], Xa-21 binding OsWRKY62 [44] in addition to OsWRKY28 and OsWRKY76 and overexpression of all four genes belonging to WRKYIIa family, conferred resistance to Xoo infection by increased expression of PR10 gene [45]. Among the NAC family of transcription factors, OsNAC6, which is induced by ABA and JA and its overexpression confers tolerance to drought and blast infection [42, 46] and two other NAC genes, ONAC122 and ONAC131, which are JA-responsive genes conferring resistance to blast infection [47] were upregulated in the OsEREBP1-ox lines. Immune response is specifically induced in cultured rice cells by another PAMP, flagellin from incompatible strains of bacterial pathogen Acidovorax avenae and OsEREBP1 and OsNAC6 were among the genes that were induced by inoculation with incompatible as well as flagellin-deficient strains of A.avenae [48].
Overexpression of OsEREBP1 results in increased levels of linolenic acid, jasmonates and ABA and corresponding increased expression of the key genes, LOX and NCED involved in the biosynthesis of jasmonic acid and ABA, respectively, in transgenic plants. The initial stage of JA biosynthesis occurs in plastids and involves the conversion of α-linolenic acid by chloroplastic LOX to OPDA, which is transported to peroxisomes for conversion to JA. The bio-active form of jasmonic acid is (3R, 7S)-N-jasmonoyl-L-isoleucine (JA-Ile). It is generated in the cytosol by the conjugation of JA with isoleucine [49]. JA-Ile enters the nucleus, binds to COI1 receptor and activates JA responsive genes. The levels of JA-Ile are controlled by catabolism and deactivation of the hormone. The ω-oxidation pathway catalyzed by the CYP94B3 and CYP93C1, in which JA-Ile is converted to12-hydroxy-JA-Ile (12-OH-JA-Ile) and then further oxidized to dicarboxy-JA-Ile (12-COOH-JA-Ile), is a major route for catabolism of the hormone [50]. Similarly, ABA biosynthesis involves oxidative cleavage of cis-isomers of violaxanthin and neoxanthin by NCED in the plastids to produce the cytoplasmic precursor xanthoxin before final conversion to ABA [51]. Transcription factors may be imported into chloroplast to regulate transcription of chloroplast genes. In silico analysis of Arabidopsis genes encoding putative transcription factors indicate that ~100 TFs are likely to be imported into the chloroplasts which include genes with AP2-, LOB- Zn finger- and TPR- domain containing proteins [52]. Among the several proteins in the proteome analysis of a highly enriched fraction of transcriptionally active chromosomes from chloroplasts of Spinacia oleracea that were identified in structuring of plastid nucleoid core included a member of AP2-EREBP family of transcription factor [53]. Although, OsEREBP1 does not show presence of chloroplast localization signal, it interacts with Xb22a isoform, which shows the presence of a strong chloroplast transit peptide and is localized to chloroplast (Fig 3). We found that OsEREBP1 protein is localized to chloroplast nucleoids where it probably up-regulates the expression of the chloroplastic LOX and NCED thereby triggering the JA and ABA biosynthetic pathways.
ABA biosynthesis is induced during abiotic stress conditions such as drought and serves as chemical signal leading to adaptation to stress conditions. The OsEREBP1-ox plants showed increased expression of ABA-related genes such as OsNCED1, AP39, LEA5 and CatB. Overexpression of AP39 leads to upregulation of NCED1and increase in endogenous levels of ABA [35] and the ABA induced during water stress prevents H2O2 accumulation by upregulating CatB expression in rice [51]. Accumulation of H2O2 was reduced in OsEREBP1-ox leaves during drought-like situation induced by desubmergence with increased expression of Adh1, similar to the increased ABA-responsiveness observed by overexpression of Sub1A in rice [54]. Thus, we surmise that OsEREBP1 confers tolerance to stresses caused during submergence and dehydration during desubmergence by regulating the ABA levels in rice.
Jasmonic acid and its derivatives are fatty acid based oxylipins involved in complex network of jasmonate signaling and hormone cross talk in stress responses and development [55]. Pathogen attack or wounding, increases lipase activity in plants, with the generation of unsaturated fatty acids such as octadecatrienoic acids, which showed elevated levels in the OsEREBP1-ox plants and form the substrate for LOX triggering synthesis of oxylipins such as jasmonates. Four LOX genes found in A. thaliana contribute to JA synthesis in response to wounding with LOX6 being involved in long distance signaling [56]. Suppression of LOX2 resulted in absence of JA accumulation in A. thaliana leaves, while overexpression of TomLOX2 led to elevated JA-biosynthesis in tomato indicating that chloroplastic LOX is involved in wound-induced JA synthesis [57, 58]. Homeostasis of jasmonates involving catabolic turnover of jasmonate derivatives is suggested by increased expression of a wound-inducible CYP94C1, which catalyzes the conversion of JA-Ile to 12COOH-JA-Ile [59]. OsEREBP1-ox plants accumulated higher levels of endogenous jasmonic acid, bioactive JA-Ile, 12OH-JA-Ile and 12COOH-JA-Ile and showed higher expression of the helix-loop-helix transcription regulator RERJ1, linalool synthase, jasmonate-induced protein and other PR genes. JA accumulation has been shown to tightly regulate expression of RERJ1, with localized expression in response to wound stress and in entire leaf during drought [60, 61]. Previous studies show that pathogenic attack increased endogenous levels of JA and application of JA to plants activated expression of PR genes and induced blast resistance in rice [62]. JA has been shown to have a significant role in rice resistance to Xoo [63] with JA application on rice plants inducing expression of OsLiS (Linalool synthase) resulting in accumulation of volatile monoterpene linalool, which induces resistance to Xoo infection [64]. Our gene expression study suggests that activation of jasmonate signaling pathway results in resistance to bacterial and fungal pathogens by the monoterpene linalool and drought tolerance by activation of PR genes mediated by JA-induced RERJ1 transcription regulator. JA and ABA were synergistic for the expression of helix-loop-helix OsHLH148 and its interacting partner OsJAZ1 in rice plants exposed to drought stress, with the overexpression of OsHLH148 leading to upregulation of several AP2/ERF genes including AP59 [65]. A cross-talk between JA and ABA signaling pathways in conferring drought tolerance is evident with the OsEREBP1-ox plants showing increased transcript levels of OsbHLH148, OsJAZ1 and AP59 genes. ABA is one of the phytohormones that also regulate seed dormancy and its concentration in a specific tissue is determined by the process of biosynthesis, catabolism, compartmentation and transport. Among the members of ABA biosynthesis enzymes, NCED is the foremost one which catalyzes the regulating step of this pathway and of the five OsNCED gene family members present in rice, gene expression analysis reveals that the transcript level of OsNCED2 gene is abundant in seed [66] while OsNCED1 is mainly expressed in rice leaves [67] and OsNCED3 may play a role in controlling dormancy and germination [68]. We did not observe any difference in the germination of seeds between the transgenic and control lines and microarray results showed that only OsNCED1 is upregulated in the transgenic plants. Moreover, the levels of ABA were analyzed only in the leaf tissue and not in the seeds.
Based on the transcriptome analysis of OsEREBP1-ox plants and the phenotypes observed, we propose a model for the possible mechanism for OsEREBP1 mediated responses (Fig 7). Increased expression of OsEREBP1 in response to various biotic signals or its overexpression leads to accumulation of jasmonates and ABA and induction of specific subsets of defense genes ultimately resulting in abiotic and biotic stress tolerance in rice. JA confers resistance to bacterial and fungal pathogens and drought stress by regulating the transcription factor RERJ1 which activates its target PR genes. JA and ABA also synergistically regulate another transcription factor OsHLH148 thereby conferring drought tolerance. ABA induces the expression of genes related to oxidative stress that occurs during prolonged submergence in water and dehydration during subsequent desubmergence. Promoter analysis of the differentially regulated genes for transcription factor specific binding motifs would identify the direct targets of the OsEREBP1 and the various transcriptional regulators in the individual signaling pathways.
Increased expression of OsEREBP1 results in accumulation of jasmonates and ABA and induction of specific subsets of defense genes leading to biotic and abiotic stress tolerance. JA regulates transcription factor RERJ1 and induces expression of JA-responsive genes resulting in increased tolerance to pathogen infection and drought stress. A cross talk between ABA and JA signalling mediated by OsHLH148/OsJaz1 interaction results in upregulation of transcripts encoding ERF’s such as AP59 associated with drought acclimation. ABA independently enhances recovery from submergence and provides protection against drought during desubmergence by inducing expression of Lea5 and CatB genes.
Supporting Information
S1 Fig. OsEREBP1 interacts with Xb22a isoform.
X-gal ‘on-plate’ detection for interactions of Xb22a and Xb22b isoforms with OsEREBP1 (AP2). Xb22a and Xb22b baits were expressed in pDEST32 (pDEST32/Xb22a and pDEST32/Xb22b, respectively) and OsEREBP1 prey was expressed in pDEST22 (pDEST22/AP2). Yeast strain MaV203 harboured the following combination of plasmids: 1a-4a) Four transformants of pDEST32/Xb22a + pDEST22/AP2; 1b-4b) Four transformants of pDEST32/Xb22b + pDEST22/AP2; 5) pDEST32 + pDEST22; 6) Positive control vectors pEXP32/Krev1 + pEXP22/RalGDS-wt; 7) pEXP32/Krev1 + pEXP22/RalGDS-m1; 8) pEXP32/Krev1 + pEXP22/RalGDS-m2; 9a) pDEST32/Xb22a + pDEST22; 9b) pDEST32/Xb22b + pDEST22; 10) pDEST32 + pDEST22/AP2. The Xb22a interacted strongly with OsEREBP1 as indicated by blue color in β-galactosidase assays for lacZ reporter gene (1a-4a). However, no color developed when Xb22b/pDEST32 was interacted with AP2/pDEST22 indicating that Xb22b does not interact with OsEREBP1 (1b-4b). The empty vector pDEST22 did not interact with Xb22a/pDEST32, Xb22b/pDEST32 and pDEST32 (9a, 9b) did not interact with and AP2/pDEST22 (10), whereas positive control (supplied with the kit) showed blue color (6,7,8).
https://doi.org/10.1371/journal.pone.0127831.s001
(TIF)
S2 Fig. OsEREBP1 confers submergence tolerance in rice.
Two-week old plants were submerged for 5 days and the height of the plants was measured following submergence treatment. Plants grown under aerobic conditions were used as control. The error bars represent standard deviation of readings from 10 plants and asterisk indicates that the differences in length were significant (P<0.01).
https://doi.org/10.1371/journal.pone.0127831.s002
(TIF)
S3 Fig. OsEREBP1-ox plants show resistance to blast fungus.
The latest fully expanded leaves from 3-week old control (Kit) and transgenic plants (2–4 and 4–3) were spotted with conidial spores (4x 104 conidia/ml) suspended in 0.25% gelatin. The leaves were incubated in growth chamber on moist filter paper with 16h/8h of light/dark regime and were observed for lesion development.
https://doi.org/10.1371/journal.pone.0127831.s003
(TIF)
S4 Fig. Hierarchical clustering of microarray data.
Of the three replicates of control (Kitaki) vs. sample (4-3-1), rep_3 and rep_4 of kitaki form one cluster, rep_3 and rep_4 of 4-3-1 form another cluster, whereas rep_5 of Kitaki and 4-3-1 are distinct.
https://doi.org/10.1371/journal.pone.0127831.s004
(TIF)
S2 Table. List of genes expressed differentially in OsEREBP1 transgenic rice leaves.
https://doi.org/10.1371/journal.pone.0127831.s006
(XLS)
Acknowledgments
We thank Dr. Pamela Ronald’s lab for supplying pC1300, Xb22a/pENTR, Xb22b/pENTR and AP2/pENTR plasmids, Michael Reichelt (Biochemistry Department, Max Planck Institute for Chemical Ecology) for phytohormone sample analysis. We thank N. Deepthi for technical help, M. B. Madhavi and P. Ramesh for help in carrying out microarray experiment, S. Haritha for help with the graphs, J. Shridhar Rao for help with drought experiments and G. Giridharan for his help with the figures. We would like to thank Dr. N. Madhusudan Rao and Ms. A.Vijaylakshmi for their help with the lipid analysis. The authors do not have any conflict of interest.
Author Contributions
Conceived and designed the experiments: RR VJ. Performed the experiments: VJ LD JV AM SK. Analyzed the data: VJ LD JV AM SK. Contributed reagents/materials/analysis tools: RR JV AM. Wrote the paper: RR.
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