Phosphorylation-Coupled Proteolysis of the Transcription Factor MYC2 Is Important for Jasmonate-Signaled Plant Immunity
As a master regulator of jasmonic acid (JA)–signaled plant immune responses, the basic helix-loop-helix (bHLH) Leu zipper transcription factor MYC2 differentially regulates different subsets of JA–responsive genes through distinct mechanisms. However, how MYC2 itself is regulated at the protein level remains unknown. Here, we show that proteolysis of MYC2 plays a positive role in regulating the transcription of its target genes. We discovered a 12-amino-acid element in the transcription activation domain (TAD) of MYC2 that is required for both the proteolysis and the transcriptional activity of MYC2. Interestingly, MYC2 phosphorylation at residue Thr328, which facilitates its turnover, is also required for the MYC2 function to regulate gene transcription. Together, these results reveal that phosphorylation-coupled turnover of MYC2 stimulates its transcription activity. Our results exemplify that, as with animals, plants employ an “activation by destruction” mechanism to fine-tune their transcriptome to adapt to their ever-changing environment.
Published in the journal:
Phosphorylation-Coupled Proteolysis of the Transcription Factor MYC2 Is Important for Jasmonate-Signaled Plant Immunity. PLoS Genet 9(4): e32767. doi:10.1371/journal.pgen.1003422
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1003422
Summary
As a master regulator of jasmonic acid (JA)–signaled plant immune responses, the basic helix-loop-helix (bHLH) Leu zipper transcription factor MYC2 differentially regulates different subsets of JA–responsive genes through distinct mechanisms. However, how MYC2 itself is regulated at the protein level remains unknown. Here, we show that proteolysis of MYC2 plays a positive role in regulating the transcription of its target genes. We discovered a 12-amino-acid element in the transcription activation domain (TAD) of MYC2 that is required for both the proteolysis and the transcriptional activity of MYC2. Interestingly, MYC2 phosphorylation at residue Thr328, which facilitates its turnover, is also required for the MYC2 function to regulate gene transcription. Together, these results reveal that phosphorylation-coupled turnover of MYC2 stimulates its transcription activity. Our results exemplify that, as with animals, plants employ an “activation by destruction” mechanism to fine-tune their transcriptome to adapt to their ever-changing environment.
Introduction
Plants are continuously challenged by various biotic and abiotic stresses with diverse modes of attack. In response to an attack, plant cells undergo dramatic transcriptional reprogramming to efficiently coordinate the activation of attacker-specific immune responses so that the optimal resistance is attained. Equally importantly, when the attacking alarm is relieved, plants cells must effectively suppress their immune responses at the right time to minimize the cost of defense. Therefore, plant cells have involved elaborate regulatory mechanisms to keep defense-related gene transcription tightly in check.
Among the best-characterized molecular signals regulating plant immune responses is the jasmonic acid (JA) family of oxylipins, which orchestrate genome-wide transcriptional reprogramming of plant cells to coordinate defense-related processes. Much of our understanding of the JA signal transduction pathway has come from the recent elucidation of the molecular details of JA-regulated gene transcription through MYC2, a basic helix-loop-helix (bHLH)-type transcription factor that regulates diverse aspects of JA responses [1]–[4]. At low JA levels, the transcriptional activity of MYC2 is repressed by JASMONATE ZIM DOMAIN (JAZ) proteins, which recruit TOPLESS (TPL) to form a transcriptional repressor complex through the adaptor protein NOVEL INTERACTOR OF JAZ (NINJA) [5]–[7]. A battery of stresses, including mechanical wounding, insect attack and pathogen infection, triggers a rapid increase of cellular JA levels. Synthesized JA is conjugated with isoleucine to form the active hormone JA-Ile, which is perceived by its receptor CORONATINE INSENSITIVE1 (COI1), an F-box protein that forms an E3 ubiquitin ligase [6], [8]–[11]. JA-Ile acts as a “molecular glue” to stimulate the interaction between COI1 and JAZs, which bring JAZs for degradation and therefore relieves their repression effect on MYC2 [5], [6]. Two MYC2-like bHLH-type transcription factors, MYC3 and MYC4, were also able to interact with JAZs and act additively with MYC2 in the regulation of JA-signaled immune responses [12]. Although MYC2-mediated transcriptional regulation plays a central role in different aspects of JA-mediated immunity, how MYC2 itself is regulated at the protein level remains elusive.
In mammalian, phosphorylation and the ubiquitin-proteasome system (UPS)-mediated proteolysis are prominent posttranslational mechanisms that control transcription factors [13]. One of the most extensively studied transcription factors whose activity is under the control of UPS-mediated proteolysis is the Myc oncoprotein, which is a bHLH-type transcription factor that shares structural features with MYC2 [14]–[16]. Myc is highly unstable and, surprisingly, the Myc degron–region that signals Myc destruction, is closely overlapped with its transcriptional activation domain (TAD) [17], [18], revealing a functional connection between protein destruction and gene activation. A growing body of evidence demonstrates that this functional overlap between degrons and TADs is not unique to Myc, but reflects a general phenomenon for most unstable transcription factors, leading to the “activation by destruction” hypothesis, in which the UPS-mediated turnover of transcription factors is essential for their ability to activate gene transcription [13], [19], [20]. Whereas “activation by destruction” is a general phenomenon in the mammalian system, evidence that this paradigm is also involved in the regulation of transcription factors in the plant kingdom is lacking.
In this report, we investigated if MYC2 is regulated by posttranscriptional mechanisms. Our findings revealed that UPS-mediated proteolysis is involved directly and mechanistically in the regulation of MYC2 and demonstrate that plants employ proteolysis-coupled transcription as a mechanism to control their responses to various environmental stresses.
Results
Temporal Correlation of MYC2 Protein Accumulation with Its Differential Effects on the Transcription of Wound- and Pathogen-Responsive Genes
To investigate the mechanism by which MYC2 differentially regulates distinct subsets of JA responses, we followed the time-course of MeJA-induced expression of wound- and pathogen-responsive genes in wild type (WT) and the myc2-2 mutant [2]. For this analysis, we select LIPOXYGENASE2 (LOX2) as a representative marker gene for wound response [21] and the plant defensin gene PDF1.2 as a representative marker gene for pathogen response [22]. Quantitative real-time PCR (qRT-PCR) assays indicated that, in MeJA-treated WT seedlings, LOX2 mRNA levels showed a pronounced increase at 3 h and reached to a maximum at 6 h; LOX2 mRNA levels then showed a tendency of reduction and returned to basal levels at 48 h after MeJA treatment (Figure 1A). Parallel experiments indicated that, in MeJA-treated WT seedlings, PDF1.2 mRNA remained at basal levels until 12 h and reached to a maximum at 48 h after treatment (Figure 1B). These results demonstrate that, JA-mediated induction of wound-responsive genes, which are positively regulated by MYC2, occurs relatively early. In contrast, JA-mediated induction of pathogen-responsive genes, which are negatively regulated by MYC2, occurs relatively late.
We then examined JA-induced accumulation of MYC2 at both mRNA and protein levels. As shown in Figure 1C, MYC2 mRNA levels quickly reached to a maximum at 0.5 h after MeJA treatment then showed a tendency of reduction in the duration of the experiment. We then used the MYC2-4myc-15 plants, which express a functional MYC2-4myc fusion protein (Figure S1), to examine the MeJA-induced accumulation kinetics of the MYC2 fusion protein. As shown in Figure 1D, upon MeJA treatment, the MYC2-myc fusion protein showed an obvious induction at 0.5 h, maintained at very high level from 3 h to 12 h, and exhibited a tendency of reduction from 24 h to 48 h (Figure 1D). Therefore, high accumulation of the MYC2 protein correlates with peaked expression of early wound-responsive genes, whereas low accumulation of the MYC2 protein correlates with peaked expression of late pathogen-responsive genes. These results implicate that temporal regulation of MYC2 protein accumulation is important for its function.
The Negative Regulation of PDF1.2 by MYC2 Is Mediated by Direct Suppression of ORA59
Previous studies revealed two mechanisms by which MYC2 activates the expression of early wound-responsive genes including LOX2, TAT1 and VSP1. First, MYC2 activates LOX2 and TAT1 transcription by directly binding to their promoters [23]; Second, MYC2 directly activates the expression of intermediate transcription factors such as ANAC019 and ANAC055 [24], which, in turn, activate the expression of VSP1 [25]. It was reported that the effect of MYC2 on the transcription of pathogen-responsive genes is mainly achieved through direct regulation of a spectrum of intermediate transcription factors [3]. For example, it was shown that the negative regulation of PDF1.2 expression by MYC2 is achieved through directly suppression of EHYLENE RESPONSE FACTOR 1 (ERF1) [3]. We provided several lines of evidence supporting that, in addition to ERF1, the transcription factor OCTADECANOID-RESPONSIVE ARABIDOPSIS AP2/ERF-domain protein 59 (ORA59), which directly binds the promoter of PDF1.2 [26], is also involved in MYC2-mediated suppression of PDF1.2 expression. First, MeJA-induced expression levels of ORA59 was dramatically increased in myc2-2 than those in WT (Figure S2), indicating that MYC2 negatively regulates MeJA-induced expression of ORA59. Second, chromatin immunoprecipitation (ChIP) assays using the previously described 35Spro:MYC2-GFP plants [27] indicated that MYC2 associates with a G-box hexamer ‘CACGTG’ in the ORA59 promoter (Figure 2A and 2B). Third, DNA electrophoretic mobility shift assays (EMSA) indicated that a MYC2-maltose binding protein (MBP) fusion protein binds the ORA59 promoter sequence in a G-box-dependent manner (Figure 2A and 2C). Finally, using the transient expression assay of Nicotiana benthamiana leaves, we verified the repression effect of MYC2 on the expression of a reporter containing the ORA59 promoter fused with the firefly luciferase gene (LUC) (Figure 2D–2F). Together, these results indicate that ORA59 is a member of the intermediate transcription factors involved in MYC2-mediated suppression of PDF1.2 expression.
MYC2 Is Subjected to Proteasome-Mediated Degradation
The existence of a temporal correlation between MYC2 protein accumulation and its function to differentially regulate wound response and pathogen response suggests that protein stability may play a role in MYC2 regulation. To test that MYC2 may be subjected to proteolysis in planta, we generated 35Spro:MYC2-GUS, 35Spro:MYC2-GFP and 35Spro:MYC2-4myc constructs and introduced them into the myc2-2 mutants. The resulting stable transgenic lines including MYC2-GUS-18, MYC2-GFP-12 and MYC2-4myc-15, which expressed comparable transcript levels of the respective transgene and rescued the JA-insensitive phenotype of the myc2-2 mutant (Figure S1), were selected for protein stability and functional analysis. Upon application of cycloheximide (CHX), an inhibitor of de novo protein synthesis, GUS activity of MYC2-GUS-18 seedlings (Figure 3A) or GFP fluorescence of MYC2-GFP-12 seedlings (Figure 3B) were largely reduced. In line with a previous observation that CHX up-regulates MYC2 transcripts [28], we showed that the mRNA levels of the MYC2-GUS or MYC2-GFP transgenes were actually increased in CHX-treated transgenic seedlings (Figure S3). These results eliminate the effect of transcriptional regulation on the protein abundance of the MYC2-GUS or MYC2-GFP fusions and support that the MYC2-reporter fusion proteins are unstable. Addition of the proteasome inhibitor MG132 to the transgenic seedlings, which barely affects the mRNA levels of the transgenes (Figure S3), lead to increased signal intensity of GUS staining (Figure 3A) or GFP fluorescence (Figure 3B). Furthermore, co-treatment with MG132 and CHX largely blocked the effect of CHX (Figure 3A and 3B). These results indicate that degradation of the MYC2-GUS or MYC2-GFP fusions requires the proteasome activity. Similarly, protein gel blot assays using MYC2-4myc-15 seedlings indicated that, whereas addition of CHX led to reduced MYC2-4myc levels, addition of MG132 led to increased MYC2-4myc levels and, the CHX effect was sufficiently suppressed by MG132 (Figure 3C).
As ubiquitination is a prerequisite for protein degradation by the 26S proteasome, we asked whether we could detect the ubiquitinated form of MYC2. For this experiment, the 35Spro:MYC2-4myc construct was transferred into N. benthamiana leaves with the well-established agroinfiltration system [29]. Protein extracts from the agroinfiltrated leaves were immunoprecipitated with an anti-myc antibody and examined via western blotting using an anti-myc antibody. As shown in Figure 3D, in addition to the band of expected size for the MYC2-4myc protein, a smear of bands corresponding to larger molecules, which show the feature of ubiquitinationed forms of the MYC2-4myc fusion protein, were also detected. Indeed, when the same samples were immuno-analyzed with an anti-ubiquitin antibody, the high molecular size bands could be recognized by the anti-ubiquitin antibody, confirming that these additional bands were ubiquitinated forms of the MYC2-4myc protein (Figure 3D). Together, these findings led us to a conclusion that MYC2 is subjected to UPS-dependent proteolysis.
Degradation of MYC2 Is Important for Its Function to Regulate Gene Transcription
To test that MYC2 degradation is a part of the JA signaling, the above-described MYC2-GFP-12 seedlings were treated with MeJA in the absence or presence of CHX. In the absence of CHX, GFP fluorescence showed a marked increase at 6 h following MeJA treatment and, MeJA-induced elevation of GFP fluorescence was dramatically decreased by the addition of CHX (Figure 4A). Similarly, as revealed by western blot assays, treatment of the MYC2-4myc-15 seedlings with MeJA alone led to a strong elevation of the MYC2-4myc fusion protein and MeJA-induced increase of the fusion protein was markedly reduced by CHX (Figure 4B). Considering that addition of CHX actually showed an increasing effect on MeJA-mediated increase of the mRNA levels of the MYC2-GFP or MYC2-myc transgenes (Figure S4), these results support that UPS-mediated degradation of MYC2 occurs during JA signaling.
To substantiate this observation, we monitored the MeJA-mediated change of the MYC2-GFP fluorescence of the MYC2-GFP-12 seedlings in the absence or presence of the UPS inhibitor MG132. Upon treatment with MeJA itself, GFP signal peaked at 6 h and returned to basal levels at 48 h (Figure 4C). In the presence of MG132, however, MeJA-induced increased of GFP signal was strengthened at both 6 h and 48 h, indicating that MeJA-induced fluctuations of the GFP signal were abolished by MG132 (Figure 4C). This MG132 effect on MeJA-induced fluctuations of the MYC2-GFP fluorescence provides us a facile assay to investigate the mechanism underlying MYC2 degradation. Similarly, as revealed by western blot assays, MeJA-induced fluctuations of the MYC2-4myc fusion protein levels were also abolished by MG132 (Figure 4D).
To evaluate the effect of MYC2 degradation on its transcription activity, we examined whether MG132 affects MeJA-induced expression of LOX2 and ORA59, marker genes of JA-induced wound and pathogen responses that were direct targets of MYC2. In line with the notion that MYC2 positively regulates wound response, MeJA-induced expression levels of LOX2 were largely reduced by the myc2-2 mutation (Figure 4E). Whereas treatment with MG132 alone resulted in undetectable MYC2-dependent induction of LOX2 expression, the MeJA-mediated induction of this gene was strongly inhibited in the presence of MG132 (Figure 4E), indicating that MeJA-induced activation of LOX2 expression requires both MYC2 and the proteasome activity. Similarly, MG132 itself showed negligible effect on MYC2-dependent regulation of ORA59 expression and this proteasome inhibitor strongly weakened the MeJA-induced activation of ORA59 expression in WT plants (Figure 4F). Consistent with a negative effect of MYC2 on JA-mediated induction of ORA59 expression, MeJA-induced expression levels of ORA59 were already high in the myc2-2 mutant, and addition of MG132 showed minor, if any, effect on MeJA-induced expression of ORA59 in this mutant (Figure 4F). Collectively, these results demonstrate that proteasome activity is required for the MYC2 function to differentially regulate wound response and pathogen response.
A 12-Amino-Acid Destruction Element of the MYC2 Protein Overlaps with Its TAD
Our findings that the proteasome activity is important for the MYC2 function suggest that MYC2 proteolysis is tightly linked with its transcriptional activity. It is generally considered that the N-terminal part of MYC2 is important for its transcriptional activity [3], [4], [12], but the transcriptional activation domain (TAD) of MYC2 has not been identified based on experimental studies. We used the MATCHMAKER GAL4-based Two-Hybrid System 3 (Clontech) to define the TAD of MYC2. The expressed proteins in yeast strains were analyzed by immunoblot experiments (Figure S5). In these assays, we found that MYC2 has strong transcriptional activation activity whereas MYC2ΔTAD, in which amino acids from 149 to 188 of MYC2 were deleted, dose not (Figure 5A–5B), indicating that the domain from amino acid 149 to 188 could be the TAD of MYC2.
In the mammalian system, it is a general phenomenon that the destruction elements (DE), which are usually acidic, overlap closely with the TADs of unstable transcription factors [18], [28], [30]. Indeed, our sequence analysis of the MYC2 TAD region identified a 12-amino-acid element (MYC2154–165) that is enriched in acidic amino acids (Figure 5A). To test that this acidic domain may function as a degron of MYC2, we generated a DE deletion construct of MYC2 and introduced it into the myc2-2 mutant. Among the resulted transgenic plants, the line MYC2ΔDE-GFP-6 was selected for further analysis. As shown in Figure S6, MYC2ΔDE-GFP-6 plants and the above-described MYC2-GFP-12 plants showed comparable transcript levels of the respective transgenes. Whereas blocking protein synthesis with CHX strongly reduced the MYC2-GFP fusion protein in MYC2-GFP-12 plants, CHX showed minor reduction effect on the MYC2ΔDE-GFP fusion protein in MYC2ΔDE-GFP-6 plants (Figure 5C), indicating that deletion of the DE indeed affects the protein stability of MYC2. Next, through monitoring the MG132 effect on JA-induced fluctuations of GFP fluorescence as an assay, we found that, in the absence or presence of MG132, the MeJA-induced change of GFP fluorescence was largely abolished in MYC2ΔDE-GFP-6 plants (Figure 5D). In summary, deletion of the 12-amino-acid element of MYC2 produces a protein remains stable support a scenario that the DE element we identified functions as a degron of MYC2.
The Destruction Element Is Required for the MYC2 Function to Regulate Gene Transcription
ChIP-PCR assays using MYC2ΔDE-GFP-6 plants indicated that deletion of the DE does not affect the binding capacity of MYC2 to the promoter of ORA59 (Figure S7). To test that the DE may affect MYC2-directed activation of wound responsive genes, we used a transient assay to compare the activation effect of MYC2 or MYC2ΔDE on the expression of LOX2pro:LUC, a reporter containing the LOX2 promoter fused with the LUC gene. Co-expression of LOX2pro:LUC with 35Spro:MYC2 led to an obvious increase of luminescence intensity (Figure 6A–6C), indicating that 35Spro:MYC2 activates the expression of LOX2pro:LUC. In contrast, the 35Spro:MYC2ΔDE construct failed to activate the expression of LOX2pro:LUC (Figure 6A–6C). These results support that the DE is required for the MYC2 function to activate the expression of LOX2.
To confirm this in planta, we examined JA-induced expression of LOX2 in MYC2-GFP-12, MYC2ΔDE-GFP-6, myc2-2 and WT plants. MeJA-induced expression levels of LOX2 in MYC2-GFP-12 plants were much higher than those in the WT (Figure 6D), indicating that the 35Spro:MYC2-GFP construct rescued the JA-insensitive phenotype of myc2-2 in term of JA-induced LOX2 expression. In MYC2ΔDE-GFP-6 plants, however, MeJA-induced expression levels of LOX2 were essentially comparable to those in the myc2-2 mutant (Figure 6D), indicating that the 35Spro:MYC2ΔDE-GFP construct failed to rescue the myc2-2 mutant phenotype. These results support that the DE is important for the MYC2 function to activate the transcription of wound-responsive genes.
Similarly, in a transient assay of N. benthamiana leaves, we showed that DE is also required for the MYC2 function to repress the expression of ORA59pro:LUC, a reporter containing the ORA59 promoter fused with LUC (Figure 6A–6C). Comparison of JA-induced expression levels of ORA59 in MYC2-GFP-12, MYC2ΔDE-GFP-6, myc2-2 and WT plants indicated that, the 35Spro:MYC2-GFP construct, but not the 35Spro:MYC2ΔDE-GFP construct, rescued the myc2-2 mutant phenotype in MeJA-induced ORA59 expression (Figure 6E). Given that MYC2 negatively regulates pathogen response, a featured phenotype of myc2-2 is that this mutant is more resistant than its WT counterpart to the necrotrophic pathogen Botrytis cinerea [4]. Our pathogen response assays revealed that, whereas MYC2-GFP-12 plants showed a similar performance as WT plants, MYC2ΔDE-GFP-6 plants showed a similar performance as myc2-2 plants (Figure 6F). Collectively, these results lead us to a conclusion that the DE and TAD of MYC2 are functionally connected.
MYC2 Phosphorylation at Thr328 Facilitates Its Turnover
Targeting substrates to the proteasome is often regulated by post-translational modifications, such as phosphorylation. To test if MYC2 is phosphorylated, protein extracts from the MYC2-4myc-15 transgenic plants were immunoprecipitated and treated with calf intestinal alkaline phosphatase (CIAP). We found that CIAP treatment led to a slightly faster migration of the MYC2-4myc fusion protein, implying that the slower migrating form of the fusion protein was phosphorylated (Figure 7A). Next, we treated MYC2-4myc-15 plants without or with MeJA, extracted total protein and applied the extracts onto a column that specifically binds phosphorylated proteins. A protein gel blot assay was performed to make sure that the amount of the MYC2-4myc protein in control and MeJA-treated samples was comparable (Figure 7B). Western blot assays indicated that the MYC2-4myc fusion protein could bind to the column and, importantly, MeJA treatment led to a substantial increase of proteins bound to the column (Figure 7B). These results implicate that MYC2 is phosphorylated in vivo and that MYC2 phophorylation is under the regulation of the JA signal.
An examination of MYC2 protein sequence revealed a cluster of four potential phosphorylation residues including Thr328, Ser330, Ser334 and Thr336 (Figure 5A). Mass spectrometric analysis of MYC2 immunoprecipitated from the MYC2-4myc-15 seedlings revealed phosphorylation at Thr328 (Figure 7C). To find out the physiological function of the confirmed and potential phosphorylation sites, phosphorylation defective forms of the MYC2-4myc fusion protein carrying serine/threonine to alanine mutations (i.e., MYC2T328A, MYC2S330A, MYC2S334A, MYC2T336A) were introduced into the myc2-2 mutant under the 35S promoter. Transgenic lines MYC2T328A-4myc-23, MYC2S330A-4myc-13, MYC2S334A-4myc-11 and MYC2T336A-4myc-18, in which the expression levels of the respective transgenes were comparable to those of the MYC2-4myc-10 plants (Figure S8), were selected for further analysis. JA-induced root growth inhibition assays indicated that MYC2T328A-4myc-23, but not the rest of the transgenic lines, showed a JA-insensitive phenotype like myc2-2 (Figure 7D), revealing that the T328A mutation, but not the other three mutations, affects the MYC2 protein function. These results support that Thr328 is an in vivo phosphorylation site of MYC2.
To determine whether Thr328 phophorylation affects MYC2 turnover, MYC2-4myc-10 and MYC2T328A-4myc-23 seedlings were treated with MeJA and the abundance of the fusion proteins were examined. We found that the basal and MeJA-induced accumulation levels of MYC2T328A-4myc were higher than those of the MYC2-4myc and, importantly, that the CHX-mediated reduction of the fusion protein accumulation was abolished in MYC2T328A-4myc-23 seedlings (Figure 7E). Similarly, in the absence or presence of MeJA, MG132-mediated increase of the fusion protein accumulation was also abolished in MYC2T328A-4myc-23 seedlings (Figure 7F). Together, our findings that the MYC2T328A mutation renders the MYC2-4myc fusion more stable support that phosphorylation of Thr328 facilitates the proteolysis of the MYC2 protein.
Phosphorylation of MYC2 at Thr328 Is Coupled with Its Transcription Activity
To test whether the MYC2T328A mutation affects MYC2-dependent gene transcription, we compared MeJA-induced expression of LOX2 and ORA59 in MYC2-4myc-10, MYC2T328A-4myc-23, myc2-2 and WT seedlings. As shown in Figure 8A, whereas MeJA-induced expression levels of LOX2 in MYC2-4myc-10 seedlings were strongly increased than those in WT seedlings, MeJA-induced expression levels of LOX2 in MYC2T328A-4myc-23 seedlings remained comparable to those in myc2-2 seedlings. In parallel experiments, the MeJA-induced expression levels of ORA59 in MYC2-4myc-10 seedlings were substantially reduced compared to those in myc2-2 seedlings, but the MeJA-induced expression levels of ORA59 in MYC2T328A-4myc-23 seedlings were essentially comparable to those in myc2-2 seedlings (Figure 8B). In B. cinerea infection assays, the performance of MYC2-4myc-10 seedlings is similar to that of the WT seedlings, whereas the performance of MYC2T328A-4myc-23 seedlings is similar to that of the myc2-2 seedlings (Figure 8C). Collectively, these results support that MYC2 phosphorylation at Thr328 is functionally coupled with its action to regulate JA-responsive gene transcription.
Discussion
Temporal Regulation of the MYC2 Protein Accumulation Facilitates Its Function to Differentially Regulate Different Aspects of JA–Mediated Immunity
Several lines of evidence hint the existence of protein regulation for the function of MYC2 in regulating JA-dependent plant immunity. For example, it has been shown that MYC2 is upregulated by JA at the transcription level but, transgenic Arabidopsis plants overexpressing MYC2 or its functional homolog in tomato (Solanum lycopsicon) did not show constant expression of defense genes without the JA signal [2], implying that a JA-dependent posttranscriptional modification of MYC2 is required for its function. Indeed, it was recently shown that the circadian-clock component TIME FOR COFFEE (TIC) interacts with and negatively regulates the protein accumulation of MYC2 [31]. A prominent action mode of MYC2 is that this transcription factor differentially regulates different subsets of JA-mediated immune responses. For example, MYC2 positively regulates the expression of early wound-responsive genes, whereas negatively regulates the expression of late pathogen-responsive genes [2]–[4], indicating that MYC2 can act both as a transcriptional activator and repressor. However, whether protein regulation of MYC2 itself is involved in its action to temporally activate or repress specific genes remains largely unknown. Therefore, one of the major challenges in understanding the action mechanisms of MYC2 is to uncover the regulation of this transcription factor at the protein level.
In this study, we found a temporal correlation between the MYC2 protein accumulation and its differential effects on the expression of wound responsive genes and pathogen responsive genes: high accumulation of the MYC2 protein correlates with peaked expression of the branch of early wound-responsive genes that are positively regulated by MYC2, whereas low accumulation of the MYC2 protein correlates with peaked expression of the branch of late pathogen-responsive genes that are negatively regulated by MYC2 (Figure 1). Clearly, the accumulation kinetics of the MYC2 protein during JA signaling facilitates its temporal activation or repression of specific subset of genes. In the context that inducible defense is an energy costly process and that plants have evolved the ability to precisely allocate limited resources in an attacker dependent manner [32], our findings support that MYC2 protein regulation plays an important role in resource management during JA-mediated plant immunity.
Proteolysis of MYC2 Is Coupled with Its Transcription Activity
The existence of a temporal correlation between MYC2 protein accumulation and its function to differentially regulate wound response and pathogen response suggests that protein stability may play a role in MYC2 regulation. Indeed, we describe here that MYC2 is subjected to UPS-dependent proteolysis and demonstrate that UPS-dependent proteolysis of MYC2 is part of the JA signaling. It is well known that UPS-dependent proteolysis plays an important role in nearly every aspect of plant biology, including plant hormone signaling. In these instances UPS either degrades transcription factors to suppress transcription or degrades transcription repressors to activate gene expression [33]–[36]. Surprisingly, we provide here evidence that UPS-dependent proteolysis plays a counterintuitive role in the regulation of MYC2 during JA-mediated immune responses: First, UPS activity is essential for the MYC2 function to temporally activate or repress specific genes; Second, a 12-amino acid element in the TAD of MYC2 plays dual roles to signal proteolysis and to regulate transcription activity of MYC2. These data support that UPS-dependent turnover of MYC2 is coupled with its transcription activity during JA-mediated plant immunity. We further show that phosphorylation at Thr328 is important for both the proteolysis and the transcription activity of MYC2, indicating that UPS-mediated destruction of MYC2 is inherently linked to the way in which it stimulates gene transcription. In the plant kingdom, a similar regulatory mechanism was observed recently for the regulation of NONEXPRESSOR OF PATHOGENESIS-RELATED GENES (NPR1), a transcription coactivator involved in salicylic acid (SA)-mediated plant immunity [37].
Our finding that UPS-mediated proteolysis is involved directly and mechanistically in the regulation of MYC2 fits well with a scenario in the animal and yeast called “activation by destruction”, in which UPS-mediated proteolysis can activate the activity of the transcriptional regulators it destroys [13], [18]–[20], [30], [37]–[41]. This “activation by destruction” phenomenon has only been appreciated in recent years, but it appears to apply to an ever growing number of transcriptional regulators in animal and yeast [13], [19], [20]. Current hypotheses to explain the connection between transcription regulator destruction and function hold three main points: First, destruction of transcription factors is likely to be a direct consequence of their ability to activate transcription; Second, turnover of transcription factors occurs on the chromatin and during the process of gene induction; Third, turnover of transcription factors is often signaled by kinases that are integral parts of the transcriptional machinery [13], [38]. Based on these hypotheses and our findings in this study, we propose a model to explain how the UPS-dependent proteolysis stimulates the transcription activity of MYC2. On the chromatin and during JA-mediated induction process of MYC2 target genes, kinases associated with the transcriptional machinery serve to mark MYC2 as “spent”, trapping it in an inactive state. At the same time, these phosphorylation events bring the UPS machinery in and therefore destroy the “spent” MYC2 in situ, clearing the deck for promoter association with a “fresh” MYC2 molecule. In this model, the initial ‘pioneer round’ of transcription does not involve UPS-dependent proteolysis of MYC2. Proteolysis plays a positive role in transcription by allowing “fresh” MYC2 to access the promoter and therefore stimulates additional rounds of transcription. It will be interesting in future studies to prove that phosphorylation-coupled proteolysis of MYC2 occurs on the chromatin and to identify the kinases and E3 ligases involved in the phophorylation and proteolysis of MYC2. Regardless of these open questions, this study clearly demonstrates that phosphorylation-coupled proteolysis of transcription factors may be a common mechanism by which higher plants regulate gene transcription.
Materials and Methods
Plant Materials and Growth Conditions
Arabidopsis thaliana ecotype Columbia (Col-0) was used as wild type (WT). T-DNA insertion mutant myc2-2 was previously described [1], [27].
Arabidopsis plants were grown in Murashige and Skoog (MS) media at 22°C with a 16-h-light/8-h-dark photoperiod (light intensity 120 µM photons m−2s−1) as previously described [42]. For MeJA-induced gene expression and protein accumulation assays, seedlings of indicated ages grown under 16-h light/8-h dark were treated with 100 µM MeJA. MeJA-treated seedlings were then transferred to continuous light for indicated times.
DNA Constructs and Plant Transformation
The 35Spro:MYC2-GUS was prepared by inserting PCR-amplified coding sequence of MYC2 and Glucuronidase (GUS) into the KpnI-SpeI sites and SalI-PstI sites of the binary vector pCAMBIA2300 under the control of cauliflower mosaic virus 35S promoter. The 35Spro:MYC2-GFP and 35Spro:MYC2-4myc constructs used in this study were previously described [1], [27]. To generate 35Spro:MYC2ΔDE-GFP construct, coding sequence of MYC2 truncated DE domain was amplified with Gateway-compatible primers. The PCR product was cloned by pENTR Directional TOPO cloning kit (Invitrogen) and then recombined with the binary vector pGWB5 (35S promoter, C-GFP) [43]. The codon for Thr328 of MYC2 in pENTR-MYC2 [1] was replaced with the amino acid encoding alanine using the TaKaRa MutanBEST kit. The mutation was confirmed by DNA sequencing. The pENTR-MYC2T328A was then combined with binary vector pGWB17 (35S promoter, C-4myc) [43] to generate 35Spro:MYC2T328A-4myc construct. Similarly, we generated 35Spro:MYC2S330A-4myc, 35Spro:MYC2S334A-4myc, 35Spro:MYC2T336A-4myc constructs. All primers used for DNA construct generation are listed in Table S1.
The above constructs were then transformed into Agrobacterium tumefaciens strain GV3101 (pMP90), which was used for transformation of Arabidopsis plants by vacuum infiltration [44].
Transient Expression Assay in N. benthamiana Leaves
The transient expression assays were performed in N. benthamiana leaves as previously described [1], [45]. The ORA59 promoter was amplified cloned into pENTR using the pENTR Directional TOPO cloning kit (Invirogen). To generate ORA59 promoter with mutations, site-directed mutagenesis was used to delete the CACGTG motif in the P1 region of the ORA59 promoter (Figure 2A) using the TaKaRa MutanBEST kit. Similarly, the LOX2 promoter was amplified and cloned into pENTR vector. Then various promoter versions were fused with the luciferase reporter gene LUC through the Gateway reactions into the plant binary vector pGWB35 [43] to generate the reporter constructs ORA59pro:LUC, ORA59mpro:LUC, LOX2pro:LUC. The MYC2 and MYC2ΔDE effector constructs were the above-described 35Spro:MYC2-GFP (35Spro:MYC2), and 35Spro:MYC2ΔDE-GFP (35Spro:MYC2ΔDE). We used a low-light cooled CCD imaging apparatus (NightOWL II LB983 with indigo software) to capture the LUC image and to count luminescence intensity. The leaves were sprayed with 100 mM luciferin and were placed in darkness for 3 min before luminescence detection.
Transactivation Activity Assay in Yeast
Full-length coding sequence and TAD truncation of MYC2 were amplified with listed primers (see Table S1 online). Enzyme-digested PCR products were cloned into the NdeI and PstI sites of the vector pGBKT7. The resulting constructs were then transformed into the yeast strain Saccharomyces cerevisiae AH109. The MATCHMAKER GAL4-based Two-Hybrid System 3 (Clontech) was used for the transactivation activity assay. Each yeast liquid culture was serially diluted to OD600 = 0.6, and 5 µl of each dilution was inoculated onto SD/-Ade/-His/-Trp synthetic dropout medium. The expressed proteins in yeast strains were analyzed by immunoblot experiments. Proteins fused with the GAL4 DNA binding domain were detected using anti-myc antibody.
Gene Expression Analysis
For qRT-PCR analysis, seedling were harvested and frozen in liquid nitrogen for RNA extraction. RNA extraction and qRT-PCR analysis were performed as previously described [27]. Primers used to quantify gene expression levels are listed in Table S2.
Protein Extraction and Immunoblot Assays
Details for protein extraction and immunoblot assays were described recently [27]. Antibodies and dilutions used in these experiments were as follows: anti-myc antibody (Abmart, 1∶2000), anti-GFP antibody (Abmart, 1∶1000). anti-ubiquitin antibody (Sigma, 1∶1000).
Coimmunoprecipitation
N. benthamiana leaves that transiently expressing MYC2-4myc or MYC2-4myc-15 seedlings were homogenized with ice-cold extraction buffer (50 mM Tris-HCl, pH 7.5, 150 mM NaCl, 0.1% Triton X-100, 0.2% Nonidet P-40, 0.6 mM PMSF, and 20 µM MG132 with Roche protease inhibitor cocktail). After protein extraction, 20 µL protein G plus agarose (Santa Cruz) was added to the 2-mg extracts to reduce nonspecific immunoglobulin binding. After 1 h of incubation, the supernatant was transferred to a new tube. myc antibody-bound agarose beads (Santa Cruz) were then added to each reaction for 4 h at 4°C. The precipitated samples were washed at least four times with the extraction buffer and then eluted by adding 1× SDS protein loading buffer with boiling for 5 min.
A phosphor-portein enrichment kit (Clontech) was used to column-purify phospho-proteins according to the manufacturer's protocol.
ChIP–PCR Assay
ChIP was performed as previously described [46]. 1.5 gram of 10-d-old 35Spro:MYC2-GFP seedlings were used for ChIP experiments. GFP antibody (Abcam) was used to immunoprecipitate the protein-DNA complex. Chromatin precipitated without antibody was used as negative control, while the isolated chromatin before precipitation was used as input control. The enrichment of DNA fragments was determined by semiquantitative PCR. Primers used for ChIP-PCR were listed in Table S2.
Electrophoretic Mobility Shift Assay
Recombinant MYC2 protein in Escheichia coli (E. coli) used in this assay was previously described [1]. Oligonucleotide probes were synthesized and labeled with biotin at the 3′ end (Invitrogen). EMSA was performed using a Lightshift Chemiluminescent EMSA Kit (Thermo Scientific). Briefly, biotin-labeled probes were incubated in 1× binding buffer, 2.5% glycerol, 50 mM KCl, 5 mM MgCl2 and 10 mM EDTA with or without proteins at room temperature for 20 min. For nonlabeled probe competition, nonlabeled probe was added to the reactions. The probe sequences used in MESA were listed in Table S3.
Identification of MYC2 Phosphorylation Site
The anti-myc immunoprecitipitates from MYC2-4myc-15 transgenic plants were resolved on SDS-PAGE and visualized by silver staining. A protein band of approximately 70 KD was cut from the gel and digested with trypsin overnight at 37°C. Peptides were extracted sequentially with 5% formic acid (FA)/50% acetonitrile and 0.1% FA/75% acetonitrile, dried under vacuum, then resuspended in 0.1% FA. LC-MS/MS and data analysis were performed as described previously [47] except that the peptide sample was loaded directly on an analytical reverse-phase column.
Plant Infection
Grow Botrytis cinerea on MEA medium (2% malt extract, 2% glucose, 0.1% peptone, 2% agar) in Petri dishes for 14 days at 24°C with 12 h photoperiod before collection of spores. Spore inoculums were prepared by harvesting spores in water, filtration though nylon mesh to remove hyphae and suspension in potato dextrose broth to a concentration of 105 spores/ml. Detached rosette leaves of 28-d-old plants were placed in Petri dishes containing 0.8% agar, with the petiole embedded in medium. Each leaf was inoculated with a single 5 µl droplet of B. cinerea inoculums. Trays were covered with lids and kept under the same conditions as for plant growth. Photographs were taken after 3 days and mean lesion sizes of 20 leaves from 20 plants of various genotypes were compared using a Student's t-test assuming equal variance.
Supporting Information
Zdroje
1. ChenQ, SunJ, ZhaiQ, ZhouW, QiL, et al. (2011) The basic helix-loop-helix transcription factorMYC2 directly represses PLETHORA expression during jasmonate-mediated modulation of the root stem cell niche in Arabidopsis. Plant Cell 23: 3335–3352.
2. BoterM, Ruiz-RiveroO, AbdeenA, PratS (2004) Conserved MYC transcription factors play a key role in jasmonate signaling both in tomato and Arabidopsis. Genes Dev 18: 1577–1591.
3. DombrechtB, XueGP, SpragueSJ, KirkegaardJA, RossJJ, et al. (2007) MYC2 differentially modulates diverse jasmonate-dependent functions in Arabidopsis. Plant Cell 19: 2225–2245.
4. LorenzoO, ChicoJM, Sanchez-SerranoJJ, SolanoR (2004) JASMONATE-INSENSITIVE1 encodes a MYC transcription factor essential to discriminate between different jasmonate-regulated defense responses in Arabidopsis. Plant Cell 16: 1938–1950.
5. ChiniA, FonsecaS, FernandezG, AdieB, ChicoJM, et al. (2007) The JAZ family of repressors is the missing link in jasmonate signalling. Nature 448: 666–671.
6. ThinesB, KatsirL, MelottoM, NiuY, MandaokarA, et al. (2007) JAZ repressor proteins are targets of the SCFCOI1 complex during jasmonate signalling. Nature 448: 661–665.
7. PauwelsL, BarberoGF, GeerinckJ, TillemanS, GrunewaldW, et al. (2010) NINJA connects the co-repressor TOPLESS to jasmonate signalling. Nature 464: 788–791.
8. XieDX, FeysBF, JamesS, Nieto-RostroM, TurnerJG (1998) COI1: an Arabidopsis gene required for jasmonate-regulated defense and fertility. Science 280: 1091–1094.
9. KatsirL, SchilmillerAL, StaswickPE, HeSY, HoweGA (2008) COI1 is a critical component of a receptor for jasmonate and the bacterial virulence factor coronatine. Proc Natl Acad Sci USA 105: 7100–7105.
10. YanJ, ZhangC, GuM, BaiZ, ZhangW, et al. (2009) The Arabidopsis CORONATINE INSENSITIVE1 protein is a jasmonate receptor. Plant Cell 21: 2220–2236.
11. SheardLB, TanX, MaoH, WithersJ, Ben-NissanG, et al. (2010) Jasmonate perception by inositol-phosphate-potentiated COI1-JAZ co-receptor. Nature 468: 400–405.
12. Fernandez-CalvoP, ChiniA, Fernandez-BarberoG, ChicoJM, Gimenez- IbanezS, et al. (2011) The Arabidopsis bHLH transcription factors MYC3 and MYC4 are targets of JAZ repressors and act additively with MYC2 in the activation of jasmonate responses. Plant Cell 23: 701–715.
13. GengF, WenzelS, TanseyWP (2012) Ubiquitin and proteasomes in transcription. Annu Rev Biochem 81: 177–201.
14. SakamuroD, PrendergastGC (1999) New Myc-interacting proteins: a second Myc network emerges. Oncogene 18: 2942–2954.
15. LuscherB, VervoortsJ (2012) Regulation of gene transcription by the oncoprotein MYC. Gene 494: 145–160.
16. DangCV (2012) MYC on the path to cancer. Cell 149: 22–35.
17. SalghettiSE, KimSY, TanseyWP (1999) Destruction of Myc by ubiquitin-mediated proteolysis: cancer-associated and transforming mutations stabilize Myc. EMBO J 18: 717–726.
18. SalghettiSE, MurataniM, WijnenH, FutcherB, TanseyWP (2000) Functional overlap of sequences that activate transcription and signal ubiquitin-mediated proteolysis. Proc Natl Acad Sci USA 97: 3118–3123.
19. LeungA, GengF, DaulnyA, CollinsG, GuzzardoP, et al. (2008) Transcriptional control and the ubiquitin-proteasome system. Ernst Schering Found Symp Proc 75–97.
20. CollinsGA, TanseyWP (2006) The proteasome: a utility tool for transcription? Curr Opin Genet Dev 16: 197–202.
21. BellE, CreelmanRA, MulletJE (1995) A chloroplast lipoxygenase is required for wound-induced jasmonic acid accumulation in Arabidopsis. Proc Natl Acad Sci USA 92: 8675–8679.
22. PenninckxIA, ThommaBP, BuchalaA, MetrauxJP, BroekaertWF (1998) Concomitant activation of jasmonate and ethylene response pathways is required for induction of a plant defensin gene in Arabidopsis. Plant Cell 10: 2103–2113.
23. HouX, LeeLY, XiaK, YanY, YuH (2010) DELLAs modulate jasmonate signaling via competitive binding to JAZs. Dev Cell 19: 884–894.
24. ZhengXY, SpiveyNW, ZengW, LiuPP, FuZQ, et al. (2012) Coronatine promotes Pseudomonas syringae virulence in plants by activating a signaling cascade that inhibits salicylic acid accumulation. Cell Host Microbe 11: 587–596.
25. BuQ, JiangH, LiCB, ZhaiQ, ZhangJ, et al. (2008) Role of the Arabidopsis thaliana NAC transcription factors ANAC019 and ANAC055 in regulating jasmonic acid-signaled defense responses. Cell Res 18: 756–767.
26. ZareiA, KorbesAP, YounessiP, MontielG, ChampionA, et al. (2010) Two GCC boxes and AP2/ERF-domain transcription factor ORA59 in jasmonate/ethylene-mediated activation of the PDF1.2 promoter in Arabidopsis. Plant Mol Biol 75: 321–331.
27. ChenR, JiangH, LiL, ZhaiQ, QiL, et al. (2012) The Arabidopsis mediator subunit MED25 differentially regulates jasmonate and abscisic acid signaling through interacting with the MYC2 and ABI5 transcription factors. Plant Cell 24: 2898–2916.
28. ChungHS, KooAJ, GaoX, JayantyS, ThinesB, et al. (2008) Regulation and function of Arabidopsis JASMONATE ZIM-domain genes in response to wounding and herbivory. Plant Physiol 146: 952–964.
29. LiuL, ZhangY, TangS, ZhaoQ, ZhangZ, et al. (2010) An efficient system to detect protein ubiquitination by agroinfiltration in Nicotiana benthamiana. Plant J 61: 893–903.
30. KimSY, HerbstA, TworkowskiKA, SalghettiSE, TanseyWP (2003) Skp2 regulates Myc protein stability and activity. Mol Cell 11: 1177–1188.
31. ShinJ, HeidrichK, Sanchez-VillarrealA, ParkerJE, DavisSJ (2012) TIME FOR COFFEE represses accumulation of the MYC2 transcription factor to provide time-of-day regulation of jasmonate signaling in Arabidopsis. Plant Cell 24: 2470–2482.
32. De VosM, Van OostenVR, Van PoeckeRM, Van PeltJA, PozoMJ, et al. (2005) Signal signature and transcriptome changes of Arabidopsis during pathogen and insect attack. Mol Plant Microbe Interact 18: 923–937.
33. VierstraRD (2009) The ubiquitin-26S proteasome system at the nexus of plant biology. Nat Rev Mol Cell Biol 10: 385–397.
34. SpoelSH, TadaY, LoakeGJ (2010) Post-translational protein modification as a tool for transcription reprogramming. New Phytol 186: 333–339.
35. KelleyDR, EstelleM (2012) Ubiquitin-mediated control of plant hormone signaling. Plant Physiol 160: 47–55.
36. SadanandomA, BaileyM, EwanR, LeeJ, NelisS (2012) The ubiquitin-proteasome system: central modifier of plant signalling. New Phytol 196: 13–28.
37. SpoelSH, MouZ, TadaY, SpiveyNW, GenschikP, et al. (2009) Proteasome-mediated turnover of the transcription coactivator NPR1 plays dual roles in regulating plant immunity. Cell 137: 860–872.
38. LipfordJR, SmithGT, ChiY, DeshaiesRJ (2005) A putative stimulatory role for activator turnover in gene expression. Nature 438: 113–116.
39. MurataniM, KungC, ShokatKM, TanseyWP (2005) The F box protein Dsg1/Mdm30 is a transcriptional coactivator that stimulates Gal4 turnover and cotranscriptional mRNA processing. Cell 120: 887–899.
40. ReidG, HubnerMR, MetivierR, BrandH, DengerS, et al. (2003) Cyclic, proteasome-mediated turnover of unliganded and liganded ERalpha on responsive promoters is an integral feature of estrogen signaling. Mol Cell 11: 695–707.
41. von der LehrN, JohanssonS, WuS, BahramF, CastellA, et al. (2003) The F-box protein Skp2 participates in c-Myc proteosomal degradation and acts as a cofactor for c-Myc-regulated transcription. Mol Cell 11: 1189–1200.
42. SunJ, XuY, YeS, JiangH, ChenQ, et al. (2009) Arabidopsis ASA1 is important for jasmonate-mediated regulation of auxin biosynthesis and transport during lateral root formation. Plant Cell 21: 1495–1511.
43. NakagawaT, KuroseT, HinoT, TanakaK, KawamukaiM, et al. (2007) Development of series of gateway binary vectors, pGWBs, for realizing efficient construction of fusion genes for plant transformation. J Biosci Bioeng 104: 34–41.
44. BechtoldN, PelletierG (1998) In planta Agrobacterium-mediated transformation of adult Arabidopsis thaliana plants by vacuum infiltration. Methods Mol Biol 82: 259–266.
45. ShangY, YanL, LiuZQ, CaoZ, MeiC, et al. (2010) The Mg-chelatase H subunit of Arabidopsis antagonizes a group of WRKY transcription repressors to relieve ABA-responsive genes of inhibition. Plant Cell 22: 1909–1935.
46. GendrelAV, LippmanZ, MartienssenR, ColotV (2005) Profiling histone modification patterns in plants using genomic tiling microarrays. Nat Methods 2: 213–218.
47. LiJ, WangJ, HouW, JingZ, TianC, et al. (2011) Phosphorylation of Ataxin-10 by polo-like kinase 1 is required for cytokinesis. Cell Cycle 10: 2946–2958.
Štítky
Genetika Reprodukčná medicínaČlánok vyšiel v časopise
PLOS Genetics
2013 Číslo 4
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