The wheat R2R3-MYB transcription factor TaRIM1 participates in resistance response against the pathogen Rhizoctonia cerealis infection through regulating defense genes

The necrotrophic fungus Rhizoctonia cerealis is a major pathogen of sharp eyespot that is a devastating disease of wheat (Triticum aestivum). Little is known about roles of MYB genes in wheat defense response to R. cerealis. In this study, TaRIM1, a R. cerealis-induced wheat MYB gene, was identified by transcriptome analysis, then cloned from resistant wheat CI12633, and its function and preliminary mechanism were studied. Sequence analysis showed that TaRIM1 encodes a R2R3-MYB transcription factor with transcription-activation activity. The molecular-biological assays revealed that the TaRIM1 protein localizes to nuclear and can bind to five MYB-binding site cis-elements. Functional dissection results showed that following R. cerealis inoculation, TaRIM1 silencing impaired the resistance of wheat CI12633, whereas TaRIM1 overexpression significantly increased resistance of transgenic wheat compared with susceptible recipient. TaRIM1 positively regulated the expression of five defense genes (Defensin, PR10, PR17c, nsLTP1, and chitinase1) possibly through binding to MYB-binding sites in their promoters. These results suggest that the R2R3-MYB transcription factor TaRIM1 positively regulates resistance response to R. cerealis infection through modulating the expression of a range of defense genes, and that TaRIM1 is a candidate gene to improve sharp eyespot resistance in wheat.

into the major groove of DNA [5][6] . Since the first plant MYB gene COLORED1 (C1) being involved in anthocyanin biosynthesis was identified in maize 7 , a large number of MYB proteins have been identified in different plant species. Based on the number of adjacent MYB repeats, MYB proteins can be divided into 4 classes: 1R-MYB, 2R-MYB (R2R3-MYB), 3R-MYB and 4R-MYB 6 . Numerous MYB proteins have been implicated in diverse biological processes, including cell cycle regulation, cell wall biosynthesis, development and reproduction, and defense responses to abiotic and biotic stresses 6,[8][9][10][11][12][13][14] . To date, most of the identified MYB genes belong to R2R3-MYB subfamily, and a number of R2R3-MYB transcriptional factors have been evidenced to play different important roles in various plant species 6,[15][16][17][18][19][20][21] . For example, in Arabidopsis, BOS1 (BOTRYTIS-SUSCEPTIBLE1), an R2R3-MYB gene (AtMYB108), is required for restricting the spread of 2 necrotrophic pathogens Botrytis cinerea and Alternaria brassicicola, and involved in the tolerance to osmotic and oxidative stresses 22 . Overexpression of an Arabidopsis R2R3-MYB AtMYB96 could enhance tolerance to drought stress 23 and increase resistance to bacteria pathogens 24 . In barley, the MYB transcription factor HvMYB6 functions as positive regulator of basal and MLA-mediated immunity responses to Blumeria graminis 25 . Ectopic expression of the wheat MYB gene TaMYB33 that was induced by NaCl and PEG stresses increased salt and drought tolerance in Arabidopsis plants 17 . The ectopic expression of TaMYB73 improved salt tolerance of transgenic Arabidopsis plants 15 . Overexpression of the wheat pathogen-induced MYB gene TaPIMP1 in transgenic wheat could significantly enhance resistance to the fungal pathogen Bipolaris sorokiniana and drought stresses 26 . Ectopic expression of a Thinopyrum intermedium MYB gene TiMYB2R-1 could significantly increase resistance of transgenic wheat lines to take-all caused by Gaeumannomyces graminis 27 . Silencing of a wheat R2R3-MYB gene TaMYB4 in wheat impaired the resistance to Puccinia striiformis f. sp. tritici 5 . However, none of MYB genes being involved in defense response to R. cerealis infection has been reported yet.
In this study, we identified and functional characterized a R. cerealis-induced MYB gene in wheat, named TaRIM1. Toward R. cerealis infection, the gene expression goes higher level. The sequence analysis and bio-molecular assays proved that TaRIM1 protein is a R2R3-type MYB transcription factor. It is localized in the nucleus and can bind to MYB binding site cis-elements. Through generation of TaRIM1-silencing and overexpression wheat plants and assessment of their defense responses following R. cerealis inoculation, the functional dissection results indicated that TaRIM1 positively modulated wheat defense response to R. cerealis. Further investigation suggested that TaRIM1 might activate the expression of a range of defense-related genes, resulting in enhanced resistance to R. cerealis infection.

Results
Identification and cloned sequence of TaRIM1 induced by R. cerealis infection. To identify wheat genes being involved in defense response to R. cerealis, we performed transcriptomic analysis through Deep RNA-seq on 3 resistance lines of the recombinant inbred lines (RILs, being derived from the cross of sharp eyespot-resistant wheat line Shanhongmai and sharp eyespot-susceptible wheat cultivar Wenmai 6) at 4 and 10 d post inoculation (dpi) with R. cerealis high-virulence strain WK207 (Unpublished). Among the up-regulated sequences, the expression of the sequence with no. Traes_6BL_E5A9546C9, being homologous to the wheat MYB gene TaMYB33 sequence, was up-regulated in the resistant wheat lines after R. cerealis inoculation. It showed a 4.18-fold at 4 dpi or a 10.23-fold at 10 dpi transcriptional increase than the mocked (Fig. 1a). Quantitative RT-PCR (qRT-PCR) analysis showed that the transcriptional levels of this gene were induced after R. cerealis inoculation (Fig. 1b), and the expression tendency by experimental qRT-PCR was in agreement with the RNA-Seq data. This gene was designated as TaRIM1 and was suggested to be involved in wheat defense response to R. cerealis infection.
The full-length cDNA sequence (with 1028 bp, Fig. 2a, NCBI accession no. KU864997) of TaRIM1 was obtained from R. cerealis-infected stem cDNA of the resistance wheat line CI12633 by RACE and nest RT-PCR. It includes the complete ORF with 732-bp, 5′ -untranslated region (UTR) with 98-bp, and 3′ -UTR with 198-bp. The genomic DNA sequence of TaRIM1 was amplified from CI12633 genomic DNA. The comparison of the genomic and cDNA sequences indicated that no intron existed in genomic transcription unit of TaRIM1, at least in the amplification region. The deduced protein TaRIM1 contains 243 amino acids with a predicted molecular weight of 26.61 KD and predicted PI of 6.09. As shown in Fig. 2a, the TaRIM1 protein sequence possesses two conserved MYB DNA-binding domains [one (R2) located at amino acids 13-63 and another (R3) at amino acids 66-114], a putative nuclear localization signal (NLS, located at amino acids110-136), and an acidic region (amino acids 138-191) possibly acting as a transcription activation domain 28 . The reconstructed phylogenetic tree analysis showed that this protein TaRIM1 was clustered into the R2R3-MYB subfamily (Fig. 2b). Thus, TaRIM1 most likely is a R2R3-MYB transcription factor with transcription-activation activity.
TaRIM1 localizes to the nucleus and binds to MYB-binding site cis-elements. As the TaRIM1 protein sequence contains the NLS sequence (Fig. 2a), the p35S:TaRIM1-GFP (green fluorescent protein) fusion expressing-vector was prepared for investigating the subcellular localization of TaRIM1. The p35S:TaRIM1-GFP and control p35S:GFP construct DNAs were separately introduced into and transiently expressed in both wheat mesophyll protoplasts and onion epidermal cells. Confocal imaging of the transient expression showed that TaRIM1-GFP localized in the nucleus in both the wheat mesophyll protoplasts and onion epidermal cells (Fig. 3a,b), whereas the fluorescence of the control GFP was distributed throughout the cell (Fig. 3a,b). These results indicated that the expressing TaRIM1 protein localizes in the nuclear.
The amino acid sequence of TaRIM1 contains R2 and R3 DNA-binding domains. To investigate if TaRIM1 binds to MYB-binding site (MBS) cis-elements, the glutathione S-transferase (GST)-TaRIM1 recombinant protein was prepared, expressed, and purified. Electrophoretic mobility shift assay (EMSA) was used to examine the DNA binding ability of TaRIM1 with MBS. Here, the tested 5 MBS cis-elements include ACI, MBS1-Bz, MBS1-w, RT1, and St1R that were bound by known functional R2R3-MYB, StMYB1R-1 and OsMYB3R-2 transcription factors 26 (Fig. 4a, Table S1). The EMSA results showed that the GST-TaRIM1 protein could bind to all the tested 5 MBS probes, especially showing the strongest binding to ACI, but not bind to the GCC-box cis-element that is specifically bound by ERF transcription factors, whereas GST failed to bind with the MBS cis-element ACI and the GCC-box cis-element (Fig. 4b). These data proved that the protein TaRIM1 can bind to these five MBS elements.

Silencing of TaRIM1 impairs wheat resistance to R. cerealis. Virus-induced gene silencing (VIGS)
is an efficient reverse-genetic tool for rapidly analyzing functions of genes in plants. Barley stripe mosaic virus (BSMV)-based VIGS is extensively used for investigating functions of interest genes in barley and wheat [29][30][31] . To explore whether TaRIM1 plays an important role in wheat resistance response against R. cerealis, we used BSMV-based VIGS method to down-regulate transcriptional levels of TaRIM1 in the resistant wheat line CI12633. At 15 dpi with the virus, the transcript of BSMV coat protein (cp) gene was readily detected (Fig. 5a), suggesting that BSMV successfully infected these wheat plants. Importantly, the transcript levels of TaRIM1 were significantly reduced in CI12633 plants infected by BSMV:TaRIM1 compared to BSMV:GFP infected CI12633 plants (control plants) (Fig. 5a,b), suggesting that TaRIM1 transcript was successfully down-regulated in BSMV:TaRIM1 infected plants, hereafter TaRIM1-silenced plants represented BSMV:TaRIM1 infected ones. The TaRIM1-silenced and BSMV:GFP infected CI12633 plants were further inoculated with R. cerealis. Subsequently, the infection types (ITs) by the fungus were evaluated. At 45 dpi with R. cerealis, TaRIM1-silenced CI12633 plants showed more susceptible to the sharp eyespot disease caused by R. cerealis (ITs: ~2.8-3.8; Fig. 5c), whereas BSMV:GFP infected CI12633 plants showed more resistance of sharp eyespot (IT: 1.2, Fig. 5c). These results suggested the down-regulation of TaRIM1 compromised the resistance to R. cerealis in CI12633, and that TaRIM1 is required for host resistance response to R. cerealis.
Overexpression of TaRIM1 enhances wheat resistance to R. cerealis. To further investigate the defense role of TaRIM1 in wheat, we constructed the TaRIM1 overexpression vector pUbi:myc-TaRIM1 (Fig. 6a), in which the expression of the fused protein gene myc-TaRIM1 of a c-myc epitope tag and TaRIM1 was driven by a maize ubiquitin (Ubi) promoter and terminated by the terminator of the Agrobacterium tumefaciens nopaline synthase gene (Tnos) in a modified monocot transformation vector pAHC25 [31][32] . The pUbi:myc-TaRIM1 vector DNA was bombarded by gene gun into immature embryos of the spring wheat cultivar Yangmai 16 for generating transgenic wheat plants. The presence of TaRIM1 transgene cassette was detected by the desired PCR product (374 bp) using the primer pairs specific to TaRIM1-Tnos transgene (Fig. 6b). Based on results of PCR detection in 3 successive generations of T 0 -T 2 , five stably transgenic lines (MO1-MO5) containing Ubi:myc-TaRIM1 transgene were selected. qRT-PCR assays showed that the transcriptional levels of TaRIM1 in these five TaRIM1-overexpressing transgenic lines were significantly elevated compared with non-transformed (wild type, WT) recipient wheat Yangmai 16 (Fig. 6c). Western blotting analysis indicated that the introduced myc-TaRIM1 gene was translated into the myc-TaRIM1 protein in these 5 overexpressing transgenic lines (MO1-MO5), but not in WT Yangmai 16 (Fig. 6d). Following inoculation with R. cerealis for ~47 d, all the 5 TaRIM1-overexpressing wheat lines in successive two (T 1 -T 2 ) generations showed significantly enhanced-resistance to sharp eyespot compared with susceptible WT wheat Yangmai 16 (Table 1). These results indicated that TaRIM1 positively contributed to wheat defense response to R. cerealis infection.

TaRIM1 positively regulates the expression of defense genes in wheat.
To explore the putative mechanism of TaRIM1 in the resistance response to R. cerealis infection, we analyzed the transcript levels of 5 wheat defense genes by qRT-PCR in TaRIM1-silencing and overexpression wheat plants as well their controls after the pathogen inoculation. The examined genes include Defensin (NCBI accession no. CA630387), PR10 (NCBI accession no. CA613496), PR17c (NCBI accession no. TA65181), nsLTP1 (NCBI accession no. TC411506), and chitinase1 (Chit1, NCBI accession no. CA665185). As shown in Fig. 7, the transcription levels of all the 5 defense genes were significantly decreased in susceptible TaRIM1-silenced wheat plants than that in BSMV:GFP infected control plants. These results suggested that the expression level of TaRIM1 was correlated with the transcriptional levels of these defense genes. As expected, the transcription levels of these 5 defense genes were significantly elevated in resistant TaRIM1-overexpressing transgenic wheat lines compared to those in susceptible WT wheat Yangmai 16 plants (Fig. 8). These results indicated that TaRIM1 positively regulated, most likely activated, the expression of these defense genes in wheat.
MYB proteins can regulate the expression of defense-and stress-related genes following by interaction with MBS cis-elements. Our above EMSA results showed that the TaRIM1 protein could bind to 5 MBS motif sequences (Fig. 4). Furthermore, to address how TaRIM1 activates the afore-tested 5 defense genes, we obtained the promoters' sequences of these 5 defense genes from International Wheat Genome Sequencing Consortium (http://www.wheatgenome.org/), and then searched MBS cis-elements in − 2000 to − 1 bp promoter sequences upstream of ATG of all of these genes using PLACE (https://sogo.dna.affrc.go.jp/cgi-bin/sogo.cgi?lang= en&pj= 640&action=page&page= newplace) and the tested 5 MBS motif sequences. As shown in Table 2, the promoters of Defensin and PR10 contain 4 MBS motif sequences, including ACI, MBS1, RT1, and St1R, respectively. The promoter of Chit1 contains 3 MBS motif sequences, including ACI, MBS1, and RT1. The promoter of PR17c and nsLTP1 contain 2 MBS cis-elements, including MBS1 and St1R. These data implied that TaRIM1 may interact with these MBS cis-elements in the promoters of these defense genes.

Discussion
The sharp eyespot disease, caused primarily by the necrotrophic fungal pathogen R. cerealis, seriously limits the wheat production worldwide. The wheat defense response to R. cerealis is complicated and involves expression changes of a series of defense-related genes 31,33 . Identification of important genes in wheat defense response to R. cerealis is critical for developing wheat varieties with resistance to sharp eyespot. In plants, MYB transcription factors play important roles in development and defense responses against abiotic and biotic stresses. Many MYB genes are induced after various stress stimuli. For example, the Arabidopsis R2R3-MYB gene BOS1 showed significant induction after B. cinerea, bos1 mutant displayed more sensitivity to 2 necrotrophic pathogens, osmotic and oxidative stresses than WT plants 22 . In wheat, the R2R3-MYB gene TaPIMP1 was induced after B. sorokiniana infection and drought stress, and positively regulated resistance responses to B. sorokiniana and drought stresses 26 . TaLHY, a wheat 1R-MYB gene, was induced by the infection of stripe rust pathogen strain CYR32. VIGS-based functional analysis suggest that TaLHY may positively participate in wheat defense response to the biotrophic fungal pathogen CYR32 13 . However, no MYB gene being involved in resistance to the necrotrophic pathogen R. cerealis has been identified yet.
In this study, through RNA-Seq-based transcriptomic analyses, TaRIM1, a wheat MYB gene induced by R. cerealis in wheat, was identified, and cloned from R. cerealis-resistant wheat CI12633. In fact, some stress-induced genes play important roles in defense responses to the stresses, whereas other stress-induced genes do not. To explore the functional role of TaRIM1 in wheat defense response to R. cerealis, we generated the TaRIM1-silencing and overexpression wheat plants. Through molecular characterization and assessment of resistance responses of TaRIM1-silencing and overexpression as well their control wheat plants after inoculation with the fungal pathogen, the functional dissection results displayed that silencing of TaRIM1 did obviously impair resistance to R. cerealis in CI12633, TaRIM1-overexpression wheat lines exhibited significantly enhanced-resistance compared with susceptible WT recipient Yangmai16. These data suggest that TaRIM1 is required for defense response against R. cerealis in wheat, at least for the resistant wheat line CI12633, and positively contributes to wheat defense response to R. cerealis infection. Moreover, the transgenic wheat produced in this study will provide potential wheat germplasm for enhancing resistance to sharp eyespot disease. To our knowledge, TaRIM1 is the first reported member of MYB family positively participating in resistance response to R. cerealis.
In this report, Blast and phylogenetic analyses showed that the deduced protein TaRIM1 is a member of the R2R3-MYB subfamily. The sequence of the TaRIM1 protein possesses R2 and R3 MYB DNA-binding domains, a NLS and a putative transcription-activation domain, implying that the TaRIM1 protein is an activator-type R2R3-MYB transcription factor. Our biochemical and molecular-biological experiment results reveal that TaRIM1 is localized in the nuclear and can bind to all the test 5 MBS cis-elements. These biochemical properties In plants, activator-type transcription factors have been implicated in defense responses through activating the expression of defense-related genes 10,26-28,33-35 . Defense genes positively contribute to resistance to pathogens in plants 24,26 . For example, transgenic wheat plants overexpressing a barley chitinase gene or a radish defensin gene RsAFP2 or a wheat LTP gene showed enhanced-resistance to fungal pathogens [36][37][38] . To explore the putative mechanism of TaRIM1 in wheat resistance response, we analyzed the transcriptional levels of 5 wheat defense genes, including Defensin, PR10, PR17c, nsLTP1, and Chit1, in TaRIM1-silencing and TaRIM1-overexpression wheat plants and their control plants. The results showed that the expression levels of these 5 defense genes were lower in TaRIM1-silenced wheat than in the control plants, whereas the transcriptional levels of the 5 genes in  TaRIM1-overexpression wheat plants were elevated compared with non-transformed recipient wheat, suggesting that TaRIM1 positively regulates the transcriptional levels of the above-tested 5 defense genes. These results suggest that overexpression of TaRIM1 up-regulates, most likely activates, the expression of a subset of, at least the above-tested 5, defense-related genes. Many papers document that transcription factors firstly bind to specific DNA sequences (cis-acting elements) in target genes, and then modulate the transcription levels of these genes 10,[26][27][28][33][34][35]39 . To address how TaRIM1 up-regulates the expression of the 5 afore-tested defense genes, we analyzed the promoter sequences of the examined 5 defense genes in wheat. The promoter sequences of these 5 defense genes, including Defensin, PR10, PR17c, nsLTP1, and Chit1, contain 2-4 kinds of MBS cis-acting elements. Our EMSA results prove that TaRIM1 indeed binds to these MBS cis-acting elements (Fig. 4). Thus, we deduce that the TaRIM1 transcription factor interacts with the promoters of these defense genes and then activates the expression of these genes. Consequently, the expression change of a range of wheat defense-related genes regulated by TaRIM1 probably results in enhanced resistance in transgenic wheat to sharp eyespot caused by R. cerealis infection.
In conclusion, TaRIM1, a wheat MYB gene induced by R. cerealis infection, was identified and its functional role was dissected. TaRIM1 encodes an activator-type R2R3-MYB transcription factor TaRIM1. TaRIM1 positively contributes to wheat resistance response to R. cerealis infection through regulation of the expression of a range of defense-related genes. TaRIM1 is a candidate gene for breeding wheat varieties with resistance to sharp eyespot caused by R. cerealis infection. This study provides novel insight into characteristics and functional roles of the MYB members in plants' defense responses.

Plant and fungal materials, and treatments. R. cerealis-resistant wheat line CI12633 was used in clon-
ing and VIGS analysis. The spring wheat cultivar Yangmai16 displaying susceptible was used as transformation recipient. Three resistant lines of RILs (cross of resistant wheat cultivar Shanhongmai and highly-susceptible wheat cultivar Wenmai 6), provided by Prof. Jizeng Jia in our Institute, were used in RNA-Sequencing.
The fungus R. cerealis Jiangsu-prevailing strain R0301 and North-China high-virulence strain WK207 were provided by Profs Huaigu Chen and Shibin Cai (Jiangsu Academy of Agricultural Sciences, China,) and Prof. Jinfen Yu (Shandong Agricultural University), respectively.
Wheat plants were grown in a 15 h light (~22 °C)/9 h dark (~10 °C) regime. The treatments were conducted according to the protocol by Zhu et al. 31 . and subjected to DNase I (Takara, Japan) digestion and purification. The first-strand cDNA was synthesized using 2-μ g purified RNA, AMV reverse transcriptase and AP primer (5′ -GGCCACGCGTCGACTAGTACTT TTTTTTTTTTTTTTT-3′ ) and Oligo dT primer according to the manual (Takara, Japan).

Cloning of cDNA and genomic DNA full-length sequences of TaRIM1. After inoculation with
R. cerealis WK207 for 4 or 10 d, RNAs extracted from the infected base stems and sheaths of three resistant lines of the RILs were deeply sequenced. The further transcriptiomic analyses were performed by Bioinformatics to identify up-regulated genes (Data unpublished). Among them, one with no. Traes_6BL_E5A9546C9 is homologous to the TaMYB33 sequence, thus this corresponding gene was named TaRIM1.
The p35S:TaRIM1-GFP or p35S:GFP alone construct was separately introduced into wheat leaf protoplasts via the PEG-mediated transfection method following the protocol of Yoo et al. 40 or transformed into onion epidermal cell by particle bombardment following Zhang et al. 41 . After incubation at 25 °C for 12 h, GFP signals were then observed and photographed using Confocal Laser Scanning Microscopy (Zeiss LSM 700, Germany).
BSMV:TaRIM1 and control virus BSMV:GFP viruses were used to inoculate the CI12633 using protocol following Zhu et al. 31 . At 14 d after infection, the fourth leaves of the inoculated seedlings were collected to monitor BSMV infection, the transcription of the BSMV coat protein (CP) gene with the specific primers (BSMV-CPF: 5′ -TGACTGCTAAGGGTGGAGGA-3′ , BSMV-CPR: 5′ -CGGTTGAACATCACGAAG AGT-3′ ) and RT-PCR was used to evaluate if BSMV inoculates wheat plants. At   were inoculated with the small toothpick fragments harboring the well-developed mycelia of R. cerealis WK 207 34 . At 45 dpi with R. cerealis, ITs were scored, and sharp eyespot symptoms were photographed. TaRIM1 with EcoR I and Xho I restriction sites was amplified with the primers (GF: 5′ -GATGAATTCAAGAGGGGGCCGTGGACG-3′ , underline represents EcoR I restriction site. GR: 5′ -CTACTCGAGCTGGCCGGACGTCTTGGA -3′ underline represents Xho I restriction site) and then sub-cloned in-frame into 3′ -terminus of GST in pGEX-4T-1 vector. The resulting GST-TaRIM1 recombinant protein was expressed in Escherichia coli BL21 cells after induction with 0.3 mM isopropyl-β -D-thiogalactopyranose, and purified using MicroSpin module (GE Amersham). The primers of 6 cis-element probes including 5 MBS and GCC-box were synthesized as the sequences in Table S1 26 .

EMSA on TaRIM1 binding activity to MBS Cis-elements. The coding sequence of
Following a modified EMSA protocol 42 , each probe was mixed with ~2 μ g of recombinant GST-TaRIM1 or GST in a binding buffer. Each reaction mixture was incubated on ice for 6 h and loaded onto 8% polyacrylamide gel. After electrophoresis was performed at 100 V for 30 min, the gels were stained with ethidium bromide for visualization of the DNA bands.
Generation and PCR detection of TaRIM1-overexpressing transgenic wheat. ORF of TaRIM1 was amplified with the primers (TVF: 5′ -CAAACTAGTATGGGGAGG TCTCCTTGC-3′ , underline represents Spe I restriction site, TVR: 5′ -CGTGAGCTCCT AAATCTGAGACAAACT-3′ , underline represents Sac I restriction site) to sub-clone in-frame with a c-myc epitope tag in a modified pAHC25-myc vector 31,32 , resulting in TaRIM1-overexpression transformation vector pUbi:myc-TaRIM1 (Fig. 6a). In predicted transformed plants, the expression of the fused protein gene myc-TaRIM1 of a c-myc epitope tag and TaRIM1 was driven by a maize ubiquitin (Ubi) promoter and terminated by the terminator of the Agrobacterium tumefaciens nopaline synthase gene (Tnos).
The resulting transformation vector pUbi:myc-TaRIM1 plasmid was transformed into 1,200 immature embryos of wheat Yangmai 16 by biolistic bombardment following Chen et al. 34 .
Western blot analysis of myc-TaRIM1 protein in transgenic wheat. The protein expression of introduced c-myc-TaRIM1 was evaluated by Western blotting. Total proteins were extracted from 0.4 g of ground base stem powders. About 10 μ g of total soluble proteins were separated on 12% sodium dodecyl sulfate polyacrylamide gels and transferred to PVDF membrane. The Western blots were incubated with a 2000-fold dilution of c-myc antibody (TransGen Biotech, China) at 4 °C for 12 h, and then with 1000-fold dilution of secondary antibody conjugated to horseradish peroxidase (TransGen Biotech, China) at ~25 °C for 1 h. The expressing myc-TaRIM1 proteins were visualized using the Pro-light HRP Chemiluminescent Kit (TIANGEN Biotech, China).
qRT-PCR analyses of TaRIM1 and defense genes. qRT-PCR technique was used to examine the