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Gene Pyramiding of Peptidase Inhibitors Enhances Plant Resistance to the Spider Mite Tetranychus urticae

  • Maria Estrella Santamaria,

    Affiliations Centro de Biotecnología y Genómica de Plantas (UPM-INIA). Campus Montegancedo Universidad Politécnica de Madrid, Autopista M40 (km 38), Madrid, Spain, Department of Biology Western University, Ontario, Canada, Dpto. Biologia Medioambiental, Centro de Investigaciones Biológicas, CSIC, Madrid, Spain

  • Inés Cambra,
  • Manuel Martinez,

    Affiliation Centro de Biotecnología y Genómica de Plantas (UPM-INIA). Campus Montegancedo Universidad Politécnica de Madrid, Autopista M40 (km 38), Madrid, Spain

  • Clara Pozancos,

    Affiliation Centro de Biotecnología y Genómica de Plantas (UPM-INIA). Campus Montegancedo Universidad Politécnica de Madrid, Autopista M40 (km 38), Madrid, Spain

  • Pablo González-Melendi,

    Affiliation Centro de Biotecnología y Genómica de Plantas (UPM-INIA). Campus Montegancedo Universidad Politécnica de Madrid, Autopista M40 (km 38), Madrid, Spain

  • Vojislava Grbic,

    Affiliation Department of Biology Western University, Ontario, Canada

  • Pedro Castañera,

    Affiliation Dpto. Biologia Medioambiental, Centro de Investigaciones Biológicas, CSIC, Madrid, Spain

  • Felix Ortego,

    Affiliation Dpto. Biologia Medioambiental, Centro de Investigaciones Biológicas, CSIC, Madrid, Spain

  • Isabel Diaz

    i.diaz@upm.es

    Affiliation Centro de Biotecnología y Genómica de Plantas (UPM-INIA). Campus Montegancedo Universidad Politécnica de Madrid, Autopista M40 (km 38), Madrid, Spain

Abstract

The two-spotted spider mite Tetranychus urticae is a damaging pest worldwide with a wide range of host plants and an extreme record of pesticide resistance. Recently, the complete T. urticae genome has been published and showed a proliferation of gene families associated with digestion and detoxification of plant secondary compounds which supports its polyphagous behaviour. To overcome spider mite adaptability a gene pyramiding approach has been developed by co-expressing two barley proteases inhibitors, the cystatin Icy6 and the trypsin inhibitor Itr1 genes in Arabidopsis plants by Agrobacterium-mediated transformation. The presence and expression of both transgenes was studied by conventional and quantitative real time RT-PCR assays and by indirect ELISA assays. The inhibitory activity of cystatin and trypsin inhibitor was in vitro analysed using specific substrates. Single and double transformants were used to assess the effects of spider mite infestation. Double transformed lines showed the lowest damaged leaf area in comparison to single transformants and non-transformed controls and different accumulation of H2O2 as defence response in the leaf feeding site, detected by diaminobenzidine staining. Additionally, an impact on endogenous mite cathepsin B- and L-like activities was observed after feeding on Arabidopsis lines, which correlates with a significant increase in the mortality of mites fed on transformed plants. These effects were analysed in view of the expression levels of the target mite protease genes, C1A cysteine peptidase and S1 serine peptidase, identified in the four developmental mite stages (embryo, larvae, nymphs and adults) performed using the RNA-seq information available at the BOGAS T. urticae database. The potential of pyramiding different classes of plant protease inhibitors to prevent plant damage caused by mites as a new tool to prevent pest resistance and to improve pest control is discussed.

Introduction

The two-spotted spider mite Tetranychus urticae Koch (Acari: Techanychidae) is one of the most damaging agriculture pests worldwide. It is a polyphagous species that feeds on more than 1,100 host plants, 150 of them of economic interest, including a wide range of ornamentals, greenhouse crops and annual and perennial field cultivars [1]. The spider mite sucks the plant cell content of leaf mesophyll and in consequence chloroplasts are gradually destroyed, plant photosynthesis declines, stomata closes, and transpiration decreases leading to a reduction in crop yield. Pesticides have played a central role in spider mite control. However, because of its short generation time and high population rate, T. urticae has a particular ability to develop a rapid resistance to the major pesticide groups and presents a great record of pesticide resistance [2], [3]. In addition, few resistant plant cultivars are currently available and mites are not affected by Bt toxins expressed in transgenic plants [4], [5].

Recently, the complete sequence and annotation of T. urticae genome have been published [6]. Among other important features of spider mite genome, a large proliferation of gene families associated with digestion and detoxification of plant secondary compounds have been identified. A parallel transcriptomic analysis of spider mites feeding on different hosts has shown that expression of members of these gene families vary depending on the host, correlating with mite’s adaptability to change host environment and to its polyphagous behaviour. Mites use both extracellular and intracellular digestion, with the latter occurring in gut wall-derived epithelial cells that digest food particles that can be free floating [7], [8]. Processed food and cells pass into the posterior midgut, are subsequently compacted in the hindgut and excreted as faecal pellets [7]. The midgut is the site for synthesis and secretion of digestive enzymes and absorption of nutrients. The proteolytic digestion on mite species that feed on plants is based mostly on cysteine peptidase activities [9], [10]. This is consistent with the three-fold proliferation of cysteine peptidase gene family, mainly of C1A papain and C13 legumain classes, found in the T. urticae genome in comparison to other sequenced arthropod species [6]. However, serine and aspartic peptidase gene families have also been identified as important peptidases in the spider mite genome, though they are most probably involved in other physiological processes.

Peptidase activity is modulated by specific inhibitors that are grouped according to the peptidase type they inhibited [11]. Two of the most abundant plant protease inhibitors are the cystatins (family I25), which inhibit cysteine peptidases C1A and C13, and cereal trypsin/α-amylase inhibitors (family I6). Plant protease inhibitors from these two classes have been used as defence proteins against pathogens and pests due to their capability to inhibit heterologous enzymes. However, besides a defence role, they are also involved in the regulation of the plant protein turn-over required in multiple physiological processes. In barley, the complete family of cystatins, which comprises 13 genes, has been characterised and some of their members transgenically expressed in plants have conferred resistance against coleopteran, aphids and mites [10], [12], [13]. The best characterized trypsin inhibitor in barley is the Itr1 gene encoding the BTI-CMe protein which is specifically accumulated in the developing endosperm of the grain [14]. It has been also used as a defence transgene in wheat and rice against stored grain pests such as the lepidopteran Sitotroga cerealella and the coleopteran Sitophilus oryzae, respectively [15], [16].

A number of genes with anti-mite properties have been transgenically expressed in plants to interfere with mite performance and to develop alternative strategies of plant protection. McCafferty et al. [17] reported a significant reduction in the multiplication of carmine spider mites (Tetranychus cinnabarinus) after feeding on papayas expressing a chitinase gene from Manduca sexta. The transformed papayas showed an increased tolerance both under laboratory and field trials where natural mite infestation occurred. Similarly, in papayas expressing the snowdrop GNA lectin gene affected the performance of the carmine spider mite that displayed a reduction in the feeding time and delay in egg laying [18]. Although chitinase mode of action is still not well known, it was suggested that it targeted the peritrophic membrane that encloses food in the mid and hingut, while the anti-mite activity of lectins was probably mediated by binding to chitin in the peritrophic matrix or by interacting with glycoproteins on the epithelial cells of the mite midgut [17], [18]. More recently, Carrillo et al. [10] have shown that the expression of the barley cystatin HvCPI-6 in maize impaired development and reproductive performance of T. urticae by inhibiting their cysteine protease activities. In contrast, experiments developed with tomato plants expressing a glucose oxidase or the soybean Kunitz inhibitor gene enhanced the T. urticae growth under greenhouse conditions [19].

Pyramiding (stacking) multiple defence genes in one plant has been developed as a method to prevent pest resistance and to improve pest control. Plants co-expressing a combination of enzyme inhibitors or combining them with transgenically expressed Bt toxins, lectins and thionins have enhanced plant resistance against insects when compared to plants that expressed the individual genes [20][24]. Based on this approach, rice lines expressing Cry1Ac and the cowpea trypsin inhibitor CpTI are awaiting approval of biosafety certificates for their release/exploitation as commercial resistant plants in China [25]. Enhancement of insecticidal activity of hydrolytic inhibitors has also been obtained by combining them with transgenically expressed lectins and thionins [22], [23], [26].

In the present study, we described a multigene approach targeted to control T. urticae infestation by co-expressing two barley proteases inhibitors (cystatin Icy6 and trypsin inhibitor Itr1 genes) in Arabidopsis plants. Single transformed lines independently expressing each transgene and double transformants have been challenged to spider mite infestation. Impact on mite survival and on endogenous mite peptidase activities have also been determined after feeding on transformed and non-transformed Arabidopsis lines. The potential of pyramiding different classes of plant protease inhibitors to prevent plant damage caused by mites is discussed.

Results

Molecular Characterization of Arabidopsis Plants Expressing the Icy6 and Itr1 Barley Genes from Barley

CMe-plants (lines 3.4 and 8.9) and CPI6-plants (lines 5.4 and 9.8) expressing trypsin and cystatin inhibitors (Itr1 and Icy6 genes), respectively, were used in this study [10], [27]. Additionally, double transgenic Arabidopsis plants (CPI6-CMe-plants) were generated after Agrotransformation of the single transgenic CPI-6, line 5.4 with the Itr1 gene. Double T1 seedlings were assessed for the presence of transgene mRNAs of both genes. The T1 lines that expressed Itr1 and Icy6 genes were self-fertilized and progeny from the T2 generation was recovered and screened by genomic PCR to identify the presence of Icy6 and Itr1 genes. No phenotypic differences were observed in transformed lines in comparison to the control Columbia plants. Lines CPI6-CMe 6.4 and CPI6-CMe 8.2 were selected for further studies based on their inhibitory activity against papain and trypsin (data not shown). Independent plants of these T2 double transgenic lines exhibited the expected 321 and 534 bp bands after electrophoresis of amplified products, which were absent in the non transformed plant and in the water control (Fig. S1).

The expression of the cystatin and trypsin inhibitor genes in Arabidopsis transformed and non-transformed control (Col) plants was analysed by real-time quantitative PCR (qRT-PCR) using specific primers and the content of cystatin/trypsin inhibitor mRNAs was normalized to Arabidopsis ubiquitin transcript levels. Strong differences in the expression of transgenes among different transgenic lines were observed (Fig. 1). While cystatin messengers were highly expressed in the CPI6-CMe 6.4 line, Icy6 mRNA expression levels were much lower in the CPI6-CMe 8.2, and expression of the trypsin inhibitor Itr1 gene was comparatively lower in both double transgenic lines. In addition, qRT-PCR analyses were performed in single transgenic lines independently expressing the Itr1 or the Icy6 genes, selected for this study. Again, strong differences on the mRNA expression levels among transgenic lines were observed for CPI6-plants (lines 5.4 and 9.8) and CMe-plants (lines 3.4 and 8.9). As expected, no Icy6 transcripts were detected in the RNA isolated from CMe-plants (lines 3.4 and 8.9) neither was Itr1 mRNA was found in the CPI6-plants (lines 5.4 and 9.8). Similarly, Icy6 and Itr1 messengers did not appear in the non-transformed Col plants.

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Figure 1. Analysis of the mRNA expression of the barley transgenes in the single (CPI6-plants, lines 5.4 and 9.8; CMe-plants, lines 3.4 and 8.9) and double (CPI6-CMe-plants, lines 6.4 and 8.2) T2 transgenic plants and non transformed control (Col), by real time quantitative PCR.

A. Expression of barley Icy6 gene. B. Expression of barley Itr1 gene. Values expressed as the relative mRNA contents of the protease inhibitor genes were normalized to the Arabidopsis ubiquitin gene expression.

https://doi.org/10.1371/journal.pone.0043011.g001

Transformed and control Arabidopsis lines were also used to analyse the presence of the cystatin protein in leaf extracts by indirect ELISA (iELISA) assays to analyse variations in protein and mRNA expression levels. As shown in Fig. S2, the barley cystatin protein immobilized on a plastic substrate was detected with the anti-cystatin peptide antibody and subsequently quantified by a secondary alkaline phosphatase-conjugated antibody. Protein was accumulated at higher concentration in plants expressing the Icy6 as a single transgene (CPI-6) than in plants expressing both inhibitors (CPI6-CMe). Additionally, in vitro inhibitory activity was performed with protein extracts derived from all Arabidopsis lines against commercial papain, trypsin and T. urticae extracts. Results, quantified by the decreased amount of substrates hydrolyzed by the papain and trypsin, were expressed as percentage of inhibitory enzyme activity (Fig. 2A). Transgenic lines over-expressing the Icy6 gene (CPI6-CMe-plants: lines 6.4 and 8.2 and CPI6-plants: lines 5.4 and 9.8) showed significant inhibitory activity against papain over the values obtained with the protein extracts from the non-transformed control plants Similarly, transformed CPI6-CMe- and CMe-lines presented a greater ability to inhibit commercial trypsin than did extracts from the control plants. Interestingly, the double transformed lines showed higher inhibitory capability against both commercial proteases. As expected, no papain inhibition was detected in CMe-plants neither trypsin inhibition was observed in the CPI6-plants.

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Figure 2. Inhibitory activity of protein extracts from transformed lines and non-transformed control against commercial proteases and T. urticae extracts.

A. Inhibitory activity of commercial papain and trypsin using Z-FR-AMC and ZLA-AMC as substrates. B. Inhibitory activity of spider mite protein extracts using Z-RR-AMC and Z-FR-AMC as substrates. Data are mean ± SE of triplicate measurements of each sample. Different letters indicate significant differences (P<0.05, Student-Newman-Keuls test).

https://doi.org/10.1371/journal.pone.0043011.g002

To know if these inhibitors affect protease activity in mite extracts, Arabidopsis protein were tested using Z-FR-AMC and Z-RR-AMC substrates susceptible to be hydrolysed by cathepsin L- and B-like activities, respectively. As is shown in Fig. 2B, single or double transformed lines over-expressing the Icy6 gene showed an inhibitory capability against cathepsin B- and L-like activities slightly lower to that obtained against commercial papain, which was not detected in control plants nor in the transformed CMe-plants. Trypsin inhibition could not be determined on mite protein samples because the activity was too low to be accurately measured (data not shown), which was congruent with the absence of trypsin activity in mite extracts reported by Carrillo et al. [10].

Spider Mite Feeding Damage on Arabidopsis Lines

To investigate the effect produced by T. urticae on transformed and non-transformed lines, leaf damage was quantified after 4 days of mite feeding on entire Arabidopsis plants. All T2 transgenic lines, independently of single or double transgene integration, showed significant less damaged leaf area than leaves from non-transformed control (Fig. 3). Interestingly, double transgenic lines CPI6-CMe 6.4 and 8.2 showed the highest resistance to mite damage: 3.2 and 2.1 mm2 of damaged leaf area, respectively, in comparison to the 10.91 mm2 of damage area detected in the control plant. Lines over-expressing the cystatin gene resulted significantly more resistant (about 4–5 mm2 of total leaf damage) than lines over-expressing the trypsin inhibitor (about 7 mm2).

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Figure 3. Leaf damage on single and double Arabidopsis transformed lines and non-transformed control 4 days after T. urticae infestation.

Data are mean ± SE of twelve measurements divided in two experimental blocks. Different letters indicate significant differences (P<0.05, Student-Newman-Keuls test).

https://doi.org/10.1371/journal.pone.0043011.g003

Upon feeding, mites induced the accumulation of H2O2 at the leaf-feeding site which can be detected by the brown colour of the oxidized diaminobenzidine (DAB) used as substrate in the histochemical assays. To further corroborate the leaf damage results, DAB-H2O2 reaction product was determined in the transformed and no-transformed lines after mite feeding. Control plants stained more intensely than any of the transformed lines (Fig. S3). Double transgenic leaves resulted more resistant to spider mites, showed less damage leaf area and in consequence should produce less H2O2. No H2O2 was detected in non-infested Arabidopsis leaves.

Effects of Arabidopsis Transgenic Plants on Mites

T2 plants of the transformed and non-transformed lines were used to analyse the transgene effect on T. urticae survival. As it is shown in Fig. 4, mite mortality quantified after 10 days of infestation reached values between 50 and 90% when mites fed on transformed lines compared to the 23% on non-transformed plants. Developing time from newborn larvae to nymph lasted 6.7±3 days for mites fed on control plants, whereas ranged from 7.4 to 9.7 when fed on transformed lines (Table S1). However, these differences were only statistically significant between CMe 8.9 and the control group, because of the high variability due to the low rate of mite survival on all transgenic lines.

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Figure 4. Effects of barley protease inhibitors expressed in single and double transformed plants and in non-transformed controls on T. urticae mortality, 10 days after infestation with neonate larvae.

Different letters indicate significant differences (P<0.05, Student-Newman-Keuls test).

https://doi.org/10.1371/journal.pone.0043011.g004

Biochemical analyses were carried out on mites after feeding on transformed and control plants for 7 days. The specific activity of cathepsin L-like peptidase detected in mite protein extracts was higher than the cathepsin B-like specific activity when mites were reared on the control Arabidopsis plants. After feeding on transgenic lines, these proteolytic activities were significantly reduced when compared to those of mites fed on non-transformed control (Fig. 5). Exceptionally, a significant increase in the specific activity of both cathepsin L- and B-like was observed in extracts from mites reared on the transgenic line CPI6 9.8. Specific trypsin activity was also tested but no activity was detected (data not shown).

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Figure 5. Specific proteolytic activities of cathepsin B- and L-like in T. urticae after feeding for 7 days on single and double transformed lines and non-transformed control using specific substrates.

Data, expressed as nmoles/min/mg, are mean ± SE of triplicate measurements of each sample. Different letters indicate significant differences (P<0.05, Student-Newman-Keuls test).

https://doi.org/10.1371/journal.pone.0043011.g005

Expression Profiling of C1A Cysteine Peptidases and S1 Serine Peptidases in T. urticae

The expression levels of potential mite targets for cystatin Icy6 and trypsin inhibitor Itr1 genes were analyzed by an in silico assays using the RNA-seq information available at the BOGAS T. urticae database [28]. Transcriptomic information was available for the 57 genes of C1A cysteine peptidase and for 125 genes of S1 serine peptidase. Figure 6A shows the sum of the normalized mean values of gene expression for both families of enzymes at different mite developmental stages. Genes with an expression value lower than five (14 and 51 genes of C1A and S1, respectively) were discarded from further analysis. Figure 6B shows the distribution of numbers of C1A cysteine and S1 serine peptidases that reach maximum expression over mite developmental stages. Genes belonging to the C1A family are reaching maximum expression at later stages, mainly in the adult phase, while most genes of the S1 family were expressed in similar pattern throughout the mite life cycle, although an important set of genes had their maximum expression values at the embryo and larvae stages.

Discussion

The two-spotted spider mite, T. urticae, is one of the most striking examples of polyphagy among herbivores. The recent sequencing and annotation of the spider mite genome has discovered a high number of detoxification gene families associated with plant feeding and a proliferation of peptidase genes putatively involved in digestion that may support the expression of the spider host range [6]. The abundance of cysteine peptidase genes, particularly C1A papain, is consistent with its proteolytic digestion based mostly on cysteine peptidase activity [9], [29]. Previous findings on the characterization of protease activities of T. urticae corroborated the presence of these enzymes and have shown their susceptibility as targets of cystatins. Additionally, in vitro inhibitory assays have demonstrated that the HvCPI-6 cystatin (gene Icy6) purified as recombinant protein was the strongest inhibitor against spider mite cathepsin B- and L-like activities [10]. Besides the proliferation of cysteine proteases found in the spider mite genome, a large serine-protease gene family was also identified [6]. Thus, serine proteases including trypsin- and chymotrypsin-like proteases have to be essential in the spider mite physiology although they are probably not directly involved in the hydrolytic digestion of dietary proteins. These genomic features show the presence of putative mite targets for Itr1 and Icy6 transgenes encoding trypsin and cystatin inhibitors from barley. Transformed plants containing either one or both of these transgenes were used to analyse the putative acaricide effects on T. urticae and to test their ability to protect plants against the spider mite infestation.

The accumulation of Itr1 or/and Icy1 transcripts detected in Arabidopsis lines was associated with the inhibition of commercial papain and trypsin detected by in vitro assays using plant extracts. However, Arabidopsis lines with high mRNA levels do not always correspond to the lines with the greater protein accumulation or the maximum inhibition activity. This may be due to differences on the gene copy number inserted into the plant genome or on the protein expression levels, as is exemplified by the cystatin accumulation detected by iELISA assays. These differences on mRNA and protein expression are a general characteristic previously described in transgenic plants [13], [17]. Feeding trials conducted with the spider mite resulted in a significant reduction of leaf damage and an increase in mite mortality, observed in all the transformed lines analysed in comparison to non-transformed control. In this context, the most interesting observation was that the double transgenic lines, and in particular the line 8.2, had the greatest inhibitory properties not only against commercial proteases but also against cathepsin L- and B-like cysteine proteases from T. urticae extracts. These results are strongly correlated with the reduction in the leaf damage detected in the Arabidopsis lines expressing both inhibitors after 4 days of mite feeding. Moreover, the retardation tendency in the larvae development, after feeding on transformed Arabidopsis leaves, particularly detected in lines expressing the trypsin inhibitor, corroborate the role of the serine proteases in the spider mite growth.

The effect of the two transgenes may be additive or synergistic depending on the gene combination, although here it is difficult to ascertain the transgene relationship since the trypsin inhibitor protein levels have not been determined. Nevertheless, it is clearly shown that double transgenic lines presented a significant reduction in leaf damage either quantified as total chlorotic area or detected by DAB staining in comparison to the independent single transformants. These results were clarified by an in silico analysis of transcriptome expression that was performed using the RNA-seq information available at the BOGAS T. urticae database, where most genes for C1A cysteine and S1 serine peptidase genes have transcriptomic information. The sum of all normalized C1A peptidase genes in the four developmental mite stages (embryo, larvae, nymphs and adults) resulted much higher than the total expressed S1 serine peptidase genes, which did not show a clear specific developmental pattern of expression. Furthermore, the most expressed genes belonging to the C1A peptidase group were highly abundant in the last stages of mite development, mainly in the adult phase, while S1 serine peptidase genes did not show a clear specific developmental pattern of expression. These results are in agreement with a primarily digestive role of cysteine protease in mites [6], [10]. In contrast, the presence of highly expressed S1 serine peptidase genes in embryo and larvae suggest that they may have other putative roles, probably associated with the regulation of growth and development. These physiological processes can potentially be targeted if the protease inhibitors may get access through the mite gut to endogenous targets, as have been already reported in insects [30], [31].

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Figure 6. Expression profiling of C1A cysteine and S1 serine peptidase families in T. urticae.

A. Sum of the normalized expression values for all C1A and S1 family members in each developmental stage analyzed. B. Number of genes for the C1A cysteine and S1 serine peptidase groups assigned to the developmental stage (embryo, larvae, nymph and adult) in which their highest expression was detected.

https://doi.org/10.1371/journal.pone.0043011.g006

The characterization of specific cathepsin B- and L-like protease activities of T. urticae after feeding on transgenic lines substantiated the impact of the barley cystatin on mite target peptidases. The clear decrease on both cathepsin-like specific activities confirmed the potential for direct interference of HvCPI-6 cystatin on T. urticae digestion. The inhibition of proteolysis through PIs may decrease access to essential amino acids and consequently protein functions can be impaired disrupting crucial physiological events of T. urticae such as nutrition, redox status, development, reproductive performance, etc., which finally increase their mortality, as it is demonstrated in this work. However, mites possess a remarkable ability to adapt their metabolism to the dietary material ingested and can show different compensatory responses to host plants expressing distinct sets of defence proteins [2], [6], [19]. Arthropods can also employ a battery of tactics to avoid the effects of plant defences (PIs in this case) by compensating or by adjusting their proteases through modulation of transcripts and/pr protein products. In addition, they can even modify the efficiency of posttranslational features, particularly under inhibitor challenges, which directly correlates with varied proteolytic activity of different protein isoforms [32], 33. The over-expression of target proteases is a common strategy to counteract the inhibitory activity [34], [35], which could explain the increases of cathepsin L- and B-like specific activities observed on line 9.8 of the transformed CPI6-plants. Similarly, the induction of novel insensitive proteases and the physiological complementation by non-target proteases of other mechanistic classes have also been described as pest adaptive processes [12], [35], [36]. It could explain the non-expected reduction of cathepsin L-like specific activity found in T. urticae reared with single transformed lines 3.4 and 8.9, expressing the CMe trypsin inhibitor. Besides, we can not discard the possibility that some serine proteases may be involved in the cysteine protease processing needed for this peptidase to become active [37]. In this scenario, the transgene pyramiding targeting different physiological process in mites will make more difficult to the spider mite to overcome defences and to create counter defences.

In conclusion, pyramiding two barley protease inhibitor genes in Arabidopsis genome have resulted more effective to enhance T. urticae control than a single transgene expression by conferring leaf protection against spider mite damage. An additional advantage is that this approach may prevent the development of spider mite adaptive mechanisms directed to overcome the expression of single miticidal proteins and in consequence, makes it more difficult to overcome plant resistance. Our approach also highlights the benefits of the access to genomic and other ‘omic information for the identification of candidate target sites that may have a positive impact in pest control.

Materials and Methods

Plant Material

Arabidopsis plants independently expressing the barley Icy6 gene encoding the HvCPI-6 cystatin without its signal peptide (35S-Icy6-plant, in this article CPI6-plants) and the barley Itr1 gene encoding the BTI-CMe trypsin inhibitor (35S-Itr1-plants, in this article CMe-plants), previously described by Carrillo et al. [13], [27], were used in this study. Additionally, double transgenic plants (CPI6-CMe-plants) were generated by the Agrobacterium-mediated floral dip method [38]. The construct containing the Itr1 gene under the CaMV35S promoter and the NptII selective gene previously used by Carrillo et al. [13] was integrated into the genome of the transgenic line 5.4 of CPI6-plants. Seeds from double transformed plants were harvested and plated on MS-medium containing 50 µg/ml Kanamycin and the resultant seedlings were transplanted to soil and allowed to set seeds. T2 seeds were harvested and tested for the presence of the two transgenes by PCR before further characterization and mite bioassays.

Arabidopsis thaliana transgenic and non-transformed Col plants were grown under control conditions (23°C, 70% relative humidity and a 16 h/8 h day/night photoperiod).

Spider Mites

A colony of T. urticae, London strain (Acari: Tetranychidae), provided by Dr. Miodrag Grbic (UWO, Canada), was reared on beans (Phaseolus vulgaris) and maintained on growth chambers (Sanyo MLR-350-H, Sanyo, Japan) at 23°C±1°C, >70% relative humidity and a 16 h/8 h day/night photoperiod.

Nucleic Acid Analysis

Total DNA was isolated from control and T2 transgenic Arabidopsis lines (CPI6-CMe: lines 6.4 and 8.2; CPI6: lines 5.4 and 9.8; CMe: lines 3.4 and 8.9) essentially as described by Sambrook and Russell [39] and tested for the presence of cystatin and/or serine protease inhibitors genes by PCR using the following primers:

35S-F: 5′-CACTATCCTTCGCAAGACC-3′,

CPI6-R: 5′-CGAGGTACCTTAGCCGCCGGCAGCCGG-3′ and

CMe-R: 5′-CGAGGTACCTTACAAGACCAC-3′.

The PCR conditions were 40 cycles with 30 sec at 92°C, 30 sec at 55°C and 1.30 min at 72°C. The reaction products were separated on 1% agarose electrophoresis gels.

For quantitative real time PCR (qRT-PCR) studies, Arabidopsis rosettes from transformed and control lines were collected, frozen into liquid N2 and stored at −80°C until used for RNA isolation. Total RNA was extracted by the phenol/chloroform method, followed by precipitation with 8 M LiCl [40]. cDNAs were synthesized from 2 µg of RNA using the Revert Aid™ H Minus First Strand cDNA Synthesis Kit (Fermentas) following manufacturer’s instructions. The qRT-PCR conditions were 40 cycles with 15 sec at 95°C, 1 min at 55°C and 5 sec at 65°C. FastStart Universal SYBR Green Master (Rox) (Roche) using a total volume of 20 µl. PCR reactions were performed in multiplate PCR plates (BioRad). The reactions were carried out in a C1000™ thermal cycler with CFX96™ optical reaction module (BioRad) and results were analysed using CFX Manager Software 2.0 (BioRad). For negative controls, 1 µl of water was used instead of cDNA, as well as an RNA sample without reverse transcription (no-RT). Primer efficiency was tested using a standard curve for each gene. After amplification, a melting curve analysis was performed to verify gene specificity. The absence of genomic DNA was confirmed by the no-RT control. Reactions were performed for triplicate samples. Gene expression values were referred as relative expression or . After testing that ubiquitin gene was not differentially expressed, values were normalized to Arabidopsis ubiquitin mRNA levels. The primers used for qRT-PCR amplification were:

qRT-CPI6-F: 5′-GCGGACGGCTCCGGCAAGAG-3′;

qRT-CPI6-R: 5′-AAGGACGTGAGCTTGCGGGT-3′;

qRT-CMe-F: 5′- TCCTCACCTCGGACATGAAGA-3′;

qRT-CMe-R: 5′- CCCTGCCAAGTTACTACCCCTT-3′;

qRT-Ubi-F: 5′-GAGCCTTACAACGCTACTCTGTCTGTC-3′;

qRT-Ubi-R: 5′-ACACCAGACATAGTAGCAGAAATCAAG-3′.

Protein Detection by Indirect ELISA

Plant protein extracts were prepared from frozen transgenic and control Arabidopsis leaves. Samples were ground and resuspended in a sodium carbonate-bicarbonate extraction buffer pH 9.6, containing 15 mM sodium carbonate, 28.4 mM sodium bicarbonate and 1% polyvynilpyrrolidone-40 (PVP-40) following Hnasko et al. [41]. After quantification of protein concentration as described Bradford [38], 100 µg of total protein were applied to flat-bottom 96-well plates and incubated for 1 h at 37°C. Wells were washed with phosphate-buffered saline with 0.05% Tween-20 (PBST). 100 µl of primary anti-cystatin antibody at the optimal dilution 1∶200 (v/v) in PBST and 2% (w/v) PVP-40 were incubated overnight at 4°C. The HvCPI-6 cystatin antibody was a specific polyclonal antibody against 16 amino acids (G36 to L51 from the initial Met) of the HvCPI-6 protein, produced in rabbits by Pineda Antibody Services (Berlin, Germany). Plates were washed with PBST and incubated with 100 µl of secondary Alkaline Phosphatase-conjugated antibody (Chemicon Internationals, USA) diluted to 1∶1500 (v/v) in PBST and 2% (w/v) PVP-40 for 1 h at room temperature. One mg/ml of phosphatase substrate (Sigma Aldrich, USA) was added and absorbance was measured using a 405 nm wavelength filter. Triplicate assays were performed for determination of each value and the average was calculated. Blanks were used to account for the spontaneous breakdown of substrates. Data were normalized to the Columbia non-transformed control.

Inhibitory Activity of Protein Extracts of Transgenic and Control Arabidopsis Lines Against Papain and Trypsin

Total protein extracts from the selected T2 transgenic and non-transformed Arabidopsis rosettes were ground and resuspended in 0.15 M NaCl sodium phosphate pH 6.0, 2 mM EDTA for 1 hour at 4°C and treated as described in Alvarez-Alfageme et al. [12]. Total protein content was determined according to the method of Bradford [42].

Inhibitory activity of plant protein extracts was in vitro tested against commercial papain (EC 3.4.22.2) and trypsin (EC 3.4.21.4) from Sigma. The Z-FR-AMC (N-carbobenzoxyloxy-Phe-Arg-7-amido-4-methylcoumarin) substrate was used for papain, trypsin-like activity was assayed using ZLA-AMC (z-L-Arg-7-amido-4-methyl coumarin). Basically, 20 µg of protein extracts were preincubated for 10 min with 100 ng of papain in a buffer 100 mM sodium phosphate pH 6.0, L-cysteine, 10 mM EDTA, and 0.01% (v/v) Brij35 or with 100 ng of trypsin in the buffer Tris-HCl 0.1 M, pH 7.5. Subsequently, substrates were added at a final concentration of 0.2 mM and incubated 1 h at 28°C.

Fluorescence was measured using an excitation filter of 365 nm and an emission filter of 465 nm (Tecan GeniusPro). The system was calibrated with known amounts of AMC hydrolysis product in a standard reaction mixture. Results were expressed as a percentage of protease activity relative to that in the absence of the inhibitor. All assays were carried out in triplicate and blanks were used to account for spontaneous breakdown of substrates.

Inhibitory Activities of Protein Extracts of Transgenic and Control Arabidopsis Lines Against Mites

Spider mites reared on control Arabidopsis plants were homogenized in 0.15 M NaCl (600 mg/ml), centrifuged at 10,000 rpm for 5 min and the supernatants pooled to obtain soluble protein extracts for enzymatic activity assays. Total protein content was determined according to the method of Bradford [42]. Inhibitory activity of plant protein extracts from control and transgenic lines prepared as indicated above was in vitro tested using 10 µg of mite protein extracts. Inhibitory assays were performed using Z-FR-AMC and Z-RR-AMC (N-carbobenzoxy-loxy-Arg-Arg-7-amido-4-methylcoumarin) substrates for cathepsin L- and B-like activities, respectively, and the Z-LA-AMC substrate for trypsin assays, following buffers and conditions mentioned above.

Leaf Damage Quantification on Arabidopsis Plants after Mite Feeding Assays

Damage quantification analysis were done on Arabidopsis entire T2 plants from selected transgenic lines (CPI6-CMe: lines 6.4 and 8.2; CPI6: lines 5.4 and 9.8; CMe: lines 3.5 and 8.9) and from the non-transformed control. Three week old plants were infected with 20 adults of T. urticae per plant. After 4 days of infestation, the leaf damage was assessed by scanning the entire rosette using a hp scanjet (HP Scanjet 5590 Digital Flatbed Scanner series), according to Navarro et al. [43]. Leaf damage was calculated in mm2 using Adobe Photoshop CS software. Twelve measurements divided in two experimental blocks were used for each genotype.

The detection of H2O2 accumulation in response to mite damage was analysed using 3,3-diaminobenzidine tetrachloride hydrate (DAB) substrate which produces a brown precipitate after oxidation in the presence of H2O2 [44]. The staining procedure used was reported by Rodríguez-Herva et al. [45] and observed under a Zeiss Axiophot microscope.

Mite Bioassays on Arabidopsis Plants Expressing the Barley Cystatin and/or Serine Protease Inhibitors

Mite bioassays were conducted on Arabidopsis entire detached leaves derived from T2 plants of the selected transgenic lines (CPI6-CMe: lines 6.4 and 8.2; CPI6: lines 5.4 and 9.8; CMe: lines 3.5 and 8.9) and from the plant control. Entire leaves were placed onto wet cotton, surrounded by wet filter paper to avoid mite escapes in confined Petri dishes. Samples were maintained under controlled conditions at 23°C±1°C, >70% relative humidity and a 16 h/8 h day/night photoperiod. Fifteen neonate larvae (<24 h) of T. urticae were placed on each leaf and mortality recorded after 10 days. Six replicates (from different plants) of every transgenic line and non-transformed control were done.

Protease Activity of T. urticae Protein Extracts after Feeding on Arabidopsis Lines

Protease activity of T. urticae was analysed after 7 days of feeding on control and transgenic Arabidopsis lines. Mites were collected and stored frozen (−20°C) until needed. Mites were homogenized in 0.15 M NaCl (600 mg/ml), centrifuged at 10,000 rpm for 5 min and the supernatants pooled to obtain soluble protein extracts for enzymatic activity assays. Total protein content was determined according to the method of Bradford [42].

The standard assay volume was 100 µl, using 5 µg of mite protein extract and the corresponding substrate added to a final concentration of 0.2 mM. Cathepsin B- and L-like and trypsin activities were assayed as described above using Z-RR-AMC, Z-FR-AMC and ZLA-AMC substrates, respectively. The reaction was incubated 2 hours at 28°C and emitted fluorescence measured and calibrated as indicated above. Specific enzymatic activity was calculated as nmoles of substrate hydrolyzed/min/mg protein. All assays were carried out in triplicate and blanks were used to account for spontaneous breakdown of substrates.

Statistic Analysis

Differences in inhibitory activity, leaf damage, mortality, development and proteolytic activities were compared by on-way ANOVA, followed by Student-Newman-Keuls multiple comparison tests. Percentage data (inhibitory activity and mortality) were transformed using arcsin square root transformation to normalize distributions and stabilize the variance before statistical analysis.

In Silico Transcriptome Expression

The transcriptomic information available at the BOGAS T. urticae website (Bogas;http://bioinformaticspsbugentbe/webtools/bogas/overview/Tetur]. ) was used to the developmental expression analyses. The protocol to normalized read counts of RNA-seq Illumina reads has been previously described [6]. T. urticae C1A genes were previously reported in [6]. 120 spider mite S1 genes were automatically selected from the GO annotation of the transcriptome. When their S1 features were manually checked 114 of these genes belonged to the S1 family. Eleven additional S1 genes with transcriptomic data were obtained by recurrent BLAST searches in the T. urticae database using spider mite S1 sequences.

Supporting Information

Figure S1.

PCR analysis of T2 Arabidopsis double transformed with Icy6 and Itr1 barley genes, encoding the cystatin HvCPI-6 (CPI6) and the trypsin inhibitor (CMe), respectively. Genomic PCR was performed using the forward and reverse primers derived from the CaMV35S promoter and the 3′region of the Icy6 or Itr1 genes, respectively. Plants are: double transgenic CPI6-CMe plants (lines 6.4 and 8.2) and non transformed control (Col). H20: water control. M: molecular size marker.

https://doi.org/10.1371/journal.pone.0043011.s001

(PDF)

Figure S2.

Detection of HvCPI-6 barley cystatin in transgenic Arabidopsis lines by iELISA assays. Leaf protein extracts (100 µg) were immobilized by adsorption into 96-well microplates and HvCPI-6 protein detected with the cystatin peptide antibody and subsequently quantified by a secondary alkaline phosphatase-conjugated antibody. Data are mean ± SE of triplicate measurements of each protein extract sample. Different letters indicate significant differences (P<0.05, Student-Newman-Keuls test).

https://doi.org/10.1371/journal.pone.0043011.s002

(PDF)

Figure S3.

Histochemical detection of reactive oxygen species (ROS) in leaves of control uninfected plants (a) and leaves in response to 24 hours spider mite feeding: b) control Arabidopsis; c) CMe 3.4 line; d) CPI6 6.4 line and e) CPI6-CMe 8.4 line.

https://doi.org/10.1371/journal.pone.0043011.s003

(PDF)

Table S1.

Effects of the transgenic Arabidopsis lines on T. urticae development after feeding assay.

https://doi.org/10.1371/journal.pone.0043011.s004

(PDF)

Acknowledgments

We thank the advices and help of Dr. Laura Carrillo, Dr. Carmen Mansilla, Lucia Zurita (CBGP-UPM-INIA, Madrid, Spain) and Pedro Hernández-Crespo (CIB-CSIC, Madrid, Spain).

Author Contributions

Conceived and designed the experiments: ID FO. Performed the experiments: MES IC CP PGM MM. Analyzed the data: ID FO. Contributed reagents/materials/analysis tools: ID FO PC VG. Wrote the paper: ID.

References

  1. 1. Migeon A, Dorkeld F (2011) Spider Mites Web: a comprehensive database for the Tetranychidae. http://www.montpellier.inra.fr/CBGP/spmweb.
  2. 2. Khajehali J, Van Nieuwenhuyse P, Demaeght P, Tirry L, Van Leeuwen T (2011) Acaricide resistance and resistance mechanisms in Tetranychus urticae populations from rose greenhouses in the Netherlands. Pest Manag Sci. 67: 1424–33.
  3. 3. Van Leeuwen T, Demaeght P, Osborne EJ, Dermauw W, Gohlke S, et al. (2012) Population bulk segregant mapping uncovers resistance mutations and the mode of action of a chitin synthesis inhibitor in arthropods. Proc Natl Acad Sci USA 105: 598–5985.
  4. 4. Rovenska GZ, Zemek R, Schmidt JEU, Hilbeck A (2005) Altered host plant preference of Tetranychus urticae and prey preference of its predator Phytoseiulus persimilis (Acari: Tetranychidae, Phytoseiidae) on transgenic Cry3Bb-eggplants. Biol Control 33: 293–300.
  5. 5. Esteves-Filho AB, de Oliveira JV, Torres JB, Gondim MG Jr (2010) Compared biology and behaviour of Tetranychus urticae Koch (Acari: Tetranychidae) and Phytoseiulus macropilis (Banks) (Acari: Phytoseiidae) on Bollgard and non-transgenic isoline cotton. Neotrop Entomol 39: 338–44.
  6. 6. Grbic M, Van Leeuwen T, Clark R, Rombauts S, Rouzé P, et al. (2011) The genome of Tetranychus urticae reveals herbivorous pest adaptations. Nature 479: 487–492.
  7. 7. Hamilton KA, Nisbet AJ, Lehane MJ, Taylor MA, Billingsley PF (2003) A physiological and biochemical model for digestion in the ectoparasitic mite, Psoroptes ovis (Acari: Psoroptidae). Int J Parasitol 33: 773–785.
  8. 8. Filimonova SA (2009) The ultrastructural investigation of the midgut in the quill mite Syringophilopsis fringilla (Acari, Trombidiformes: Syringophilidae). Arthropod Struct Dev 38: 303–313.
  9. 9. Nisbet AJ, Billingsley PF (2000) A comparative survey of the hydrolytic enzymes of ectoparasitic and free-living mites. Int J Parasitol 30: 19–27.
  10. 10. Carrillo L, Martinez M, Ramessar K, Cambra I, Castañera P, et al. (2011a) Expression of a barley cystatin gene in maize enhances resistance against phytophagous mites by altering their cysteine-proteases. Plant Cell Rep 30: 101–112.
  11. 11. Rawlings ND, Barrett AJ, Bateman A (2012) MEROPS: the database of proteolytic enzymes, their substrates and inhibitors. Nucleic Acids Res 40: D343–350.
  12. 12. Alvarez-Alfageme F, Martinez M, Pascual-Ruiz S, Castanera P, Diaz I, et al. (2007) Effects of potato plants expressing a barley cystatin on the predatory bug Podisus maculiventris via herbivorous prey feeding on the plant. Transgenic Res 16: 1–13.
  13. 13. Carrillo L, Martinez M, Alvarez-Alfageme F, Castanera P, Smagghe G, et al. (2011b) A barley cysteine-proteinase inhibitor reduces the performance of two aphid species in artificial diets and transgenic arabidopsis plants, Transgenic Res. 20: 305–319.
  14. 14. Royo J, Diaz I, Rodriguez-Palenzuela P, Carbonero P (1996) Isolation and promoter characterization of barley gene Itr1 encoding trypsin inhibitor BTI-CMe: differential activity in wild-type and mutant lys3a endosperm. Plant Mol Biol 31: 1051–1059.
  15. 15. Altpeter F, Diaz I, McAuslane H, Gaddour K, Carbonero P, et al. (1999) Increased insect resistance in transgenic wheat stably expressing trypsin inhibitor CMe. Mol Breeding 5: 53–63.
  16. 16. Alfonso-Rubi J, Ortego F, Castañera P, Carbonero P, Diaz I (2003) Transgenic expression of trypsin inhibitor CMe from barley in indica and japonica rice, confers resistance to the weevil Sitophilus oryzae. Transgenic Res 12: 23–31.
  17. 17. McCafferty HRK, Moore PH, Zhu Y (2006) Improved Carica papaya tolerance to carmine spider mite by the expression of Manduca sexta chitinase transgene. Transgenic Res 15 337–347.
  18. 18. McCafferty HRK, Moore PH, Zhu Y (2008) Papaya transformed with the Galanthus nivalis GNA gene produces a biologically active lectin with spider mite control activity. Plant Sci 175: 385–393.
  19. 19. Castagnoli M, Caccia R, Liguori M, Simoni S, Marinari S, et al. (2003) Tomato transgenic lines and Tetranychus urticae: changes in plant suitability and susceptibility. Exp Appl Acarol 31: 177–189.
  20. 20. Senthilkumar R, Cheng CP, Yeh KW (2010) Genetically pyramiding protease-inhibitor genes for dual broad-spectrum resistance against insect and phytopathogens in transgenic tobacco. Plant Biotech J 8: 65–75.
  21. 21. Dunse KM, Stevens JA, Lay FT, Gaspar YM, Heath RL, et al. (2010) Coexpression of potato type I and II proteinase inhibitors gives cotton plants protection against insect damage in the field. Proc Natl Acad Sci USA 107: 15011–15015.
  22. 22. Golmirizaie A, Zhang DP, Nopo L, Newell CA, Vera A, et al. (1997) Enhanced resistance to West Indian sweet potato weevil (Euscepes postfaciatus) in transgenic ‘Jewel’ sweet potato with cowpea trypsin inhibitor and snowdrop lectin. Hort Sci 32: 435.
  23. 23. Charity JA, Hughes P, Anderson MA, Bittisnich DJ, Whitecross M, et al. (2005) Pest and disease protection conferred by expression of barley beta-hordothionin and Nicotiana alata proteinase inhibitor genes in transgenic tobacco. Funct Plant Biol 32: 35–44.
  24. 24. Cui J, Luo J, van der Werf W, Ma Y, Xia J (2011) Effect of pyramiding Bt and CpTI genes on resistance of cotton to Helicoverpa armigera (Lepidoptera: Noctuidae) under laboratory and field conditions. J Econ Entomol 104: 673–684.
  25. 25. Chen M, Shelton A, Ye G (2010) Insect-resistant genetically modified rice in China: from research to commercialization. Annu Rev Entomol 56: 81–101.
  26. 26. Li G, Xu X, Xing H, Zhu H, Fan Q (2005) Insect resistance to Nilaparvata lugens and Cnaphalocrocis medinalis in transgenic indica rice and the inheritance of gna+sbti transgenes. Pest Manag Sci 61: 390–396.
  27. 27. Carrillo L, Herrero I, Cambra I, Sanchez-Monge R, Diaz I, et al. (2011c) Differential in vitro and in vivo effect of barley cysteine and serine protease inhibitors on phytopathogenic microorganisms. Plant Physiol Biochem 49: 1191–1200.
  28. 28. BOGAS (Bioinformatics Online Genome Annotation System) Tetranychus urticae website [http://bioinformaticspsbugentbe/webtools/bogas/overview/Tetur].
  29. 29. Michaud D, Cantin L, Raworth DA, Varin TC (1996) Assessing the stability of cystatin/cysteine proteinase complexes using mildy-denaturing gelatine-polyacrylamide gel electrophoresis. Electrophoresis 17: 74–79.
  30. 30. Down REe, Ford L, Mosson HI, Fitches E, Gatehouse JA, et al. (1999) Protease activity in the larval stage of the parasitoid wasp, Eulophus pennicornis (Nees) (Hymenoptera: Eulophidae); effects of protease inhibitors. Parasitology 119: 157–166.
  31. 31. Azzouz A, Cherqui A, Campan EDM, Rahbe Y, Duport G, et al. (2005) Effects of plant protease inhibitors, oryzacystatin I and soybean Bowman-Birk inhibitor, on the aphid Macrosiphum euphorbiae (Homoptera, Aphididae) and its parasitoid Aphelinus abdominalis (Hymenoptera, Aphididae). J Insect Physiol 51: 75–86.
  32. 32. Zhu-Salzman K, Luthe DS, Felton GW (2008) Arthropod-inducible proteins: broad spectrum defenses against multiple herbivores. Plant Physiol 146: 852–858.
  33. 33. Ahn JE, Guarino LA, Zhu-Salzman K (2007) Seven-up facilities insect counter-defense by suppressing cathepsin B expression. FEBS J 274: 2800–2814.
  34. 34. Ortego F, Novillo C, Sanchez-Serrano JJ, Castañera P (2001) Physiological response of Colorado potato beetle and beet armyworm larvae on depletion of wound-inducible proteinase inhibitors in transgenic potato plants. J Insect Physiol 47: 1291–1300.
  35. 35. Novillo C, Castañera P, Ortego F (1997) Characterization and distribution of chymotrypsin-like and other digestive proteases in Colorado potato beetle larvae. Arch Insect Biochem Physiol 36: 181–201.
  36. 36. Lara P, Ortego F, Gonzalez-Hidalgo E, Castañera P, Carbonero P, et al. (2000) Adaptation of Spodoptera exigua (Lepidoptera: Noctuidae) to barley trypsin inhibitor BTI-CMe expressed in transgenic tobacco. Transgenic Res 9: 169–178.
  37. 37. Grudkowska M, Zagdanska B (2004) Multifunctional role of plant cysteine proteinases. Acta Biochim Pol 51 609–624.
  38. 38. Clough SJ, Bent AF (1998) Floral dip: a simplified method for Agrobacterium-mediated transformation of Arabidopsis thaliana. Plant J 16: 735–743.
  39. 39. Sambrook J, Russell DW (2001) Molecular cloning: a laboratory manual, 3rd edn. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, New York.
  40. 40. Oñate-Sánchez L, Vicente-Carbajosa J (2008) DNA-free RNA isolation protocols for Arabidopsis thaliana, including seeds and siliques. BMC Res Notes 1: 93.
  41. 41. Hnasko R, Lin A, McGarvey JA, Stanker LH (2011) A rapid method to improve protein detection by indirect ELISA. Biochem Biophys Res Comm 410: 726–731.
  42. 42. Bradford MM (1976) A rapid and sensitive method for the quantification of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem 72: 248–254.
  43. 43. Navarro M, Acevedo G, Cazaux M, Mathieu J, Schmid M, et al. (2011) Genomic dissection of the plant/pest interaction: transcriptome analysis of arabidopsis response to Tetranychus urticae (Two spotted spider mite) feeding. ICAR (22nd International Conference on Arabidopsis Research) Madison USA.
  44. 44. Martinez de Ilarduya O, Xie Q, Kaloshian I (2003) Aphid-induced defense responses in Mi-1-mediated compatible and incompatible tomato interactions. Mol Plant-Microbe Interact 8: 699–708.
  45. 45. Rodriguez-Herva JJ, Gonzalez-Melendi P, Cuartas-Lanza R, Antunez-Lamas M, Río-Alvarez I, et al. (2012) A bacterial cysteine protease effector protein interferes with photosynthesis to suppress plant innate immune responses. Cell Microbiol 14: 669–681.