Skip to main content
NCBI home page
Wiley Open Access Collection logoLink to Wiley Open Access Collection
. 2017 Jun 26;215(4):1533–1547. doi: 10.1111/nph.14638

Regulation of growth–defense balance by the JASMONATE ZIM‐DOMAIN (JAZ)‐MYC transcriptional module

Ian T Major 1, Yuki Yoshida 1, Marcelo L Campos 1, George Kapali 1, Xiu‐Fang Xin 1, Koichi Sugimoto 1, Dalton de Oliveira Ferreira 1, Sheng Yang He 1,2,3,4, Gregg A Howe 1,4,5,
PMCID: PMC5542871  NIHMSID: NIHMS874557  PMID: 28649719

Summary

  • The plant hormone jasmonate (JA) promotes the degradation of JASMONATE ZIM‐DOMAIN (JAZ) proteins to relieve repression on diverse transcription factors (TFs) that execute JA responses. However, little is known about how combinatorial complexity among JAZ–TF interactions maintains control over myriad aspects of growth, development, reproduction, and immunity.

  • We used loss‐of‐function mutations to define epistatic interactions within the core JA signaling pathway and to investigate the contribution of MYC TFs to JA responses in Arabidopsis thaliana.

  • Constitutive JA signaling in a jaz quintuple mutant (jazQ) was largely eliminated by mutations that block JA synthesis or perception. Comparison of jazQ and a jazQ myc2 myc3 myc4 octuple mutant validated known functions of MYC2/3/4 in root growth, chlorophyll degradation, and susceptibility to the pathogen Pseudomonas syringae. We found that MYC TFs also control both the enhanced resistance of jazQ leaves to insect herbivory and restricted leaf growth of jazQ. Epistatic transcriptional profiles mirrored these phenotypes and further showed that triterpenoid biosynthetic and glucosinolate catabolic genes are up‐regulated in jazQ independently of MYC TFs.

  • Our study highlights the utility of genetic epistasis to unravel the complexities of JAZ–TF interactions and demonstrates that MYC TFs exert master control over a JAZ‐repressible transcriptional hierarchy that governs growth–defense balance.

Keywords: gene cluster, glucosinolate, growth–defense tradeoffs, jasmonate (JA), plant defense, plant hormone, plant–insect interaction, triterpenoid

Short abstract

See also the Commentary on this article by Wasternack, 215: 1291–1294.

Introduction

Plants continuously integrate information from the environment to tailor their growth, development and defensive capabilities in ways that optimize fitness. Much of this phenotypic plasticity is orchestrated by the concerted action of a small number of plant hormones (Pieterse et al., 2009; Santner et al., 2009). Among the hormones whose biosynthesis and action is exquisitely tuned by changing environmental conditions is the oxylipin jasmonate (JA) (Browse, 2009; Bhosale et al., 2013). JA controls a multitude of transcriptional programs affecting plant growth, development, and responses to biotic and abiotic stress (Howe & Jander, 2008; Baldwin & Wu, 2010; Wasternack & Hause, 2013). In the past decade, tremendous progress has been made in understanding how JA regulates gene expression and also how JA responses are integrated with other signaling pathways (Pauwels & Goossens, 2011; Kazan & Manners, 2012; Campos et al., 2014; Huot et al., 2014; Chini et al., 2016).

When endogenous JA levels are below a threshold concentration, the expression of JA‐responsive genes is switched off through active repression of bHLH‐type MYC transcription factors (TFs) (Chini et al., 2016). This repression is mediated by JASMONATE ZIM‐DOMAIN (JAZ) proteins, which bind directly to MYCs to impede transcription by two distinct mechanisms (Chini et al., 2007; Thines et al., 2007; Yan et al., 2007). First, MYC‐bound JAZs recruit the corepressor TOPLESS (TPL) either directly (Shyu et al., 2012) or indirectly through the NOVEL INTERACTOR OF JAZ (NINJA) adaptor protein (Pauwels et al., 2010). Second, binding of the Jas motif of JAZ to the N terminus of MYC restricts access of MYC to the MED25 coactivator subunit of the mediator complex (Çevik et al., 2012; Chen et al., 2012; Zhang et al., 2015). A subset of JAZ repressors, including alternative splice variants of JAZ10, contain a cryptic MYC‐interaction domain (CMID) that tightly binds MYC and represses target gene expression (Chung & Howe, 2009; Chung et al., 2010; Moreno et al., 2013; Goossens et al., 2015; Zhang et al., 2017). Transcription of JA‐responsive genes is activated upon accumulation of jasmonoyl‐l‐isoleucine (JA‐Ile), the production of which is tightly controlled by environmental and developmental cues (Staswick & Tiryaki, 2004; Suza & Staswick, 2008; Koo & Howe, 2009). JA‐Ile promotes the formation of a nuclear co‐receptor complex consisting of the CORONATINE INSENSITIVE1 (COI1) F‐box protein and JAZ (Xie et al., 1998; Thines et al., 2007; Katsir et al., 2008; Melotto et al., 2008; Fonseca et al., 2009; Koo et al., 2009; Yan et al., 2009; Sheard et al., 2010). JA‐Ile‐dependent recruitment of JAZs to the E3 ubiquitin ligase Skp1‐Cullin‐F‐box protein (SCF)COI1 results in proteolytic destruction of JAZ repressors by the ubiquitin‐proteasome system, resulting in relief of transcriptional repression on MYC TFs (Chini et al., 2007; Thines et al., 2007).

A major gap in our understanding of JA signaling is how receptor activation maintains spatial and temporal control over diverse transcriptional outputs. Several lines of evidence suggest that the size and complexity of the JAZ–TF interactome may account, at least in part, for the diversity of JA responses. First, higher plants produce a large repertoire of JAZ proteins encoded by a family of JAZ genes (e.g. 13 in Arabidopsis), many of which are alternatively spliced to produce multiple JAZ isoforms (Vanholme et al., 2007; Yan et al., 2007; Chung & Howe, 2009; Chung et al., 2010; Bai et al., 2011; Thireault et al., 2015). Second, JAZs repress the transcriptional activity of not only MYCs (bHLH superfamily clade IIIe) but also several other bHLH TFs, as well as transcriptional regulators belonging to other TF families (Wager & Browse, 2012; Chini et al., 2016; Goossens et al., 2016). The combinatorial complexity resulting from interaction of multiple JAZs with multiple TFs could, in theory, explain much of the specificity and diversity of JA responses. Most JAZ–TF interactions, however, have been studied with in vitro approaches that alone are insufficient to delineate the biological consequences of specific JAZ–TF interactions. Among the factors that are likely to influence the biological outputs of JAZ–TF interactions are cell‐ and tissue type‐specific expression pattern, binding affinity of JAZ for TF targets, posttranslational modification, and recruitment of additional regulatory proteins to JAZ–TF complexes. It is therefore necessary to develop experimental approaches that provide insight into the in vivo function of specific JAZ–TF modules. Recent progress in this direction has come from studies showing that JAZ2 regulates a specific MYC‐dependent transcriptional cascade to modulate stomatal dynamics during pathogen infection (Gimenez‐Ibanez et al., 2017).

Here, we employed a genetic approach to define epistatic interactions between components of the core JA pathway and also to assess the contribution of the JAZ‐MYC signaling module to JA responses in Arabidopsis. Our experimental approach leveraged a jaz quintuple mutant (jazQ) that exhibits both enhanced responsiveness to exogenous JA and constitutive growth–defense antagonism as a consequence of mutations in JAZ1/3/4/9/10 (Campos et al., 2016). We show that phenotypes of jazQ are largely dependent on intact pathways for JA biosynthesis and perception. Detailed phenotypic comparison between jazQ and a jazQ myc2/3/4 octuple mutant demonstrated a key role for MYC TFs in restricting leaf growth concomitant with activation of leaf defense pathways, and also revealed JAZ‐repressible processes that do not require MYC TFs. Our collective data provide a genetic framework to understand how specific JAZ–TF transcriptional modules control discrete branches of the JA response.

Materials and Methods

Plant material and growth conditions

Arabidopsis thaliana (L.) Heynh. ecotype Columbia‐0 (Col‐0) was the wild‐type (WT) genetic background for all experiments. Construction of the quintuple jaz mutant (jazQ) and the jazQ suppressor screen has been described previously (Campos et al., 2016). suppressor of jaz quintuple10 (sjq10) and sjq66 suppressor mutants were identified by visual screening for larger rosette size from soil‐grown M2 plants. Phenotype heritability was confirmed in the M3 generation. To generate jazQ allene oxide synthase (aos) and jazQ coi1, jazQ was crossed to aos (Park et al., 2002) or to coi1‐1, respectively. glabrous1 mutations were removed from aos and coi1‐1 lines by backcrossing to Col‐0 (Yoshida et al., 2009). The myc2 myc3 myc4 triple mutant (mycT) was generated by combining the previously described mutants jin1‐7/myc2‐1 (SALK_040500) (Boter et al., 2004), myc3‐1 (GK‐445B11) (Fernandez‐Calvo et al., 2011), and myc4‐1 (GK‐491E10) (Fernandez‐Calvo et al., 2011). The myc5‐1 mutant (SALK_060048) (Figueroa & Browse, 2015; Qi et al., 2015a) was used for construction of the myc2345 quadruple mutant. Pedigrees describing the details of construction of jazQ mycT octuple and myc2345 quadruple mutants are provided in Supporting Information Fig. S1. We note that this breeding scheme was not designed specifically for the construction of jazQ mycT and myc2345. Rather, the pedigrees shown were part of a broad strategy to combine mutations affecting all signaling components of the core JA pathway and to identify, in subsequent segregating populations, specific mutant combinations. PCR‐based genotyping of mutants was performed using primer sets flanking T‐DNA insertion sites, with a third primer specific for the T‐DNA border (Table S1) (Campos et al., 2016). Seeds were stratified for 3–4 d at 4°C before germination. Plants were grown in environmentally controlled chambers with cool‐white fluorescent light for all experiments. Unless stated otherwise, conditions were 21–20°C with a 16 h : 8 h, day (100 μE m−2 s−1) : night photoperiod.

Measurements of shoot and root growth

Root growth inhibition assays (Shyu et al., 2012) were performed with seedlings grown on Petri plates (Thermo Fisher Scientific, Waltham, MA, USA) containing LS medium (0.5× Linsmaier and Skoog (Caisson Labs, Smithfield, UT, USA), 0.7% w/v phytoblend agar (Caisson Labs) and 0.8% w/v sucrose) supplemented with the concentration of methyl‐JA (MeJA; Sigma‐Aldrich) indicated in the legends to Figs 1 and 2. Primary root length of WT and mutant lines (grown on the same plate) was determined in 8‐ to 11‐d‐old seedlings using imagej software (http://imagej.nih.gov/ij/). Growth parameters, including leaf dry weight, leaf area, petiole length, rosette diameter, and flowering time, were determined as described previously (Campos et al., 2016).

Figure 1.

Figure 1

Open in a new tab

Genetic interaction between mutations affecting the core jasmonate (JA) response pathway. (a) Perturbations (shown in red) used in this study to manipulate JA responses included treatment with exogenous JA and loss‐of‐function mutations affecting JA biosynthesis (allene oxide synthase (aos)), the JA co‐receptor (coronatine insensitive1 (coi1)), five JASMONATE ZIM‐DOMAIN (JAZ) repressors (jazQ), or three MYC transcription factors (mycT). (b, e, g) Root growth inhibition assays of Arabidopsis sextuple mutants of jazQ combined with (b) coi1 or (e) aos, and of (g) jaz1, jaz3, jaz4, jaz9 and jaz10 single mutants. Root lengths were determined from seedlings grown on plates supplemented (closed bars) or not supplemented (open bars) with 25 μM methyl jasmonate (MeJA). Bars are means ± SD (= 7–24 seedlings per genotype). Per cent inhibition by MeJA is shown for each genotype in parentheses. Different letters represent significant differences at < 0.05 determined by two‐way ANOVA with Tukey's honest significant difference (HSD) test. Experiments were repeated twice with similar results. (c, d, f) Male sterility of Arabidopsis sextuple mutants of jazQ combined with (c, d) coi1 or (f) aos. Anther filaments elongate and anthers dehisce in Col‐0 and jazQ flowers, but filaments do not elongate fully and anthers fail to dehisce in the sterile coi1 and jazQ coi1 flowers (c). Flowers of (d) coi1 and jazQ coi1 and of (f) aos and jazQ aos are sterile.

Figure 2.

Figure 2

Open in a new tab

Jasmonate (JA) hypersensitivity of the jasmonate zim‐domain quintuple mutant (jazQ) depends on MYC2/3/4 transcription factors. (a) Root length of Arabidopsis seedlings grown on plates supplemented (closed bars) or not supplemented (open bars) with 25 μM methyl jasmonate (MeJA). Bars are means ± SD (= 33–48 seedlings per genotype). Per cent inhibition by MeJA is shown for each genotype in parentheses. (b) Photograph showing genotype‐dependent loss of chlorophyll in detached Arabidopsis leaves treated with 0 μM (mock) or 100 μM MeJA in the dark for 4 d. (c) Measurement of total chlorophyll levels in leaves treated as described in (b). Bars are means ± SD (= 3 leaves per genotype). Different letters represent significant differences at < 0.05 determined by two‐way ANOVA with Tukey's honest significant difference (HSD) test. Experiments were repeated three times with similar results.

JA‐induced chlorophyll degradation assays

JA‐induced chlorophyll degradation assays were performed as previously described (Qi et al., 2015b). Briefly, third and fourth rosette leaves were gently removed from 3‐wk‐old plants and floated on distilled water or 100 μM MeJA, and were kept in the dark at 21°C for 4 d. For chlorophyll extraction, leaves were incubated overnight in methanol in the dark. Absorbance was measured at 652, 665 and 750 nm, and the chlorophyll content was calculated as previously described (Porra et al., 1989). Total chlorophyll was normalized to either leaf area or leaf fresh weight.

Insect and pathogen assays

Insect feeding assays were performed as described previously (Herde et al., 2013; Campos et al., 2016). Plants were grown on soil at 20°C with an 8 h : 16 h, day (120 μE m−2 s−1) : night photoperiod. To each of 12 plants (6 wk old) per genotype, four neonate Trichoplusia ni larvae (Benzon Research, Carlisle, PA, USA) were reared for 10 d, after which larval weights were measured. Pseudomonas syringae (Pst) pv. DC3000 infection assays were performed as described previously (Katagiri et al., 2002). Plants were grown on soil at 22°C with a 12 h : 12 h, light (120 μE m−2 s−1) : dark photoperiod. Five‐week‐old Arabidopsis plants were dip‐inoculated with a Pst DC3000 suspension (1 × 108 colony forming units (CFUs) ml−1) containing 0.025% Silwet L77 (Lehle Seeds, Round Rock, TX, USA). Bacterial population was determined by serial dilution and plating 4 d after inoculation.

mRNA‐sequencing (RNA‐seq) analysis

Global gene expression profiling in 8‐d‐old whole seedlings (Col‐0 WT, jazQ, mycT and jazQ mycT) was assessed by mRNA sequencing (RNA‐seq), as described previously (Campos et al., 2016). mycT and jazQ mycT seedlings were grown and processed, and RNA‐seq analysis was performed in parallel with our previous analysis (Campos et al., 2016) of Col‐0, jazQ, phytochrome B (phyB), and jazQ phyB to facilitate cross‐comparisons; data for Col‐0 and jazQ are from Campos et al. (2016), while data for mycT and jazQ mycT are new here. Seedlings were grown in continuous light on solid medium supplemented with sucrose, and each sample was pooled from c. 200 seedlings, with three independent RNA samples (biological replicates) sequenced per genotype. Single‐end (50‐bp) sequencing was performed on the Illumina (San Diego, CA, USA) HiSeq 2000 platform at the Michigan State University Research Technologies Service Facility (https://rtsf.natsci.msu.edu). Filtered reads (Illumina quality control tools and Fastx toolkit; http://hannonlab.cshl.edu/fastx_toolkit/) were mapped to the arabidopsis information resource, genome release 10 (TAIR10) gene models with Rsem (v.1.2.11; default parameters; Li & Dewey, 2011). deseq (v.1.18.0; Anders & Huber, 2010) was used to normalize expected counts from Rsem and to assess differential gene expression relative to WT. The average transcripts per million (TPM) ± error and P‐values for all Arabidopsis genes are provided in Table S2. Gene onthology (GO) analysis of enriched functional categories was performed using David (v.6.7; Huang et al., 2009). The hypergeometric test with Benjamini & Hochberg's false discovery rate (FDR) correction was used to calculate over‐ and underrepresented GO categories among differentially expressed genes, using a P‐value < 0.05. RNA‐seq data are deposited at the National Center for Biotechnology Information Gene Expression Omnibus (GEO) as series record GSE98389.

Photosynthesis measurements

Plants grown in plastic containers (‘Cone‐tainers’; Steuwe & Sons, Tangent, OR, USA) with an 8 h 19°C : 16 h 16°C, light (120 μE m−2 s−1) : dark period were used for gas exchange measurements (Campos et al., 2016). CO2 and light response curves were obtained from single mature rosette leaves (attached) of 8‐ to 10‐wk‐old plants on an LI‐6400XT system (Li‐Cor Biosciences, Lincoln, NE, USA) outfitted with a standard leaf chamber (chamber area = 6 cm2). Assimilation rates were normalized to projected leaf area as measured by image analysis with the Gimp software (www.gimp.org).

Results

Growth–defense antagonism in jazQ depends on jasmonate biosynthesis and perception

Allocation of metabolic resources to the production of plant defense compounds is often associated with reduced growth and biomass accumulation. These apparent growth–defense tradeoffs are of considerable interest for understanding plant form and function in both natural and agricultural ecosystems (Havko et al., 2016; Karasov et al., 2017; Züst & Agrawal, 2017). In our previous studies, we employed a JAZ‐depleted quintuple mutant (jazQ) to better understand how JA signaling balances growth and defense, and also to identify suppressor mutations that mitigate the antagonistic relationship between leaf growth and anti‐insect defense (Campos et al., 2016). This work showed that phyB mutations resulting in loss of the photoreceptor (phyB) rescue the reduced growth of jazQ rosette leaves but do not compromise the enhanced leaf defense traits of jazQ. Thus, the apparent tradeoff in jazQ between leaf biomass and defense can be effectively uncoupled through loss of phyB activity. The jazQ suppressor screen also identified a distinct class of mutants in which recovery of leaf growth was associated with visible loss of anthocyanin pigment in leaves. Two such sjq lines, sjq10 and sjq66, exhibited features of male sterility that are associated with impaired JA biosynthesis or signaling (Fig. S2) (Thines et al., 2013). DNA sequencing of candidate genes in the JA pathway identified a C→T non‐sense mutation in codon 56 of the AOS gene in sjq10 and a C→T missense mutation in codon 86 of the COI1 gene in sjq66 (Fig. S2). These results suggested that constitutive growth–defense antagonism (i.e. reduced growth and enhanced defense of shoots) resulting from the loss of JAZ1/3/4/9/10 in jazQ depends on intact pathways for JA biosynthesis and signaling.

To further investigate the relationship between jazQ and other components of the JA pathway (Fig. 1a), we reconstructed sextuple mutant lines in which jazQ was combined with mutant alleles of aos or coi1. Root growth inhibition assays showed that jazQ coi1 plants resemble coi1 single mutants in being strongly insensitive to JA treatment (Fig. 1b). We also found that coi1 is epistatic to jazQ with respect to male sterility. Whereas jazQ flowers developed normally, jazQ coi1 flowers had short anther filaments and lacked viable seed production (Fig. 1c,d). jazQ coi1 flowers were also indehiscent at the time when stigmatic papillae are receptive to pollen for fertilization. Reconstructed jazQ aos lines maintained the JA hypersensitivity of jazQ plants and were also male sterile (Fig. 1e,f). These findings demonstrate that coi1 and aos are epistatic to jazQ with respect to leaf growth and fertility traits, and that coi1 abolishes the responsiveness of jazQ roots to exogenous JA.

Constitutive growth repression of jazQ roots is independent of JA signaling

jazQ roots are not only hypersensitive to exogenous JA but also are shorter than WT roots in the absence of JA (Fig. 1b; Campos et al., 2016). To determine whether this constitutive short‐root phenotype results from increased sensitivity to endogenous JA, we compared the root length of jazQ seedlings grown in the absence of applied JA to that of jazQ coi1 and jazQ aos plants. In contrast to our expectation, neither coi1 nor aos rescued the short root of jazQ (Fig. 1b,e). This result indicated that constitutive root shortening in jazQ does not depend on JA signaling, and raised the possibility that one or more of the JAZs (JAZ1/3/4/9/10) affected by jazQ positively regulate root growth when JA concentrations are low. Comparison of jaz single mutants grown side by side on medium lacking JA showed that jaz3 roots were significantly shorter than those of other mutants (Fig. 1g), suggesting that JAZ3 promotes root growth under these conditions. Only jaz10‐1 roots were shorter than WT roots on medium containing JA, as shown in previous studies (Demianski et al., 2012; Moreno et al., 2013).

Enhanced responsiveness of jazQ to exogenous JA requires MYC2/3/4

Among the diverse TFs that physically interact with JAZs are MYC2 and the closely related proteins MYC3 and MYC4, which perform prominent roles in JA signaling (Dombrecht et al., 2007; Fernandez‐Calvo et al., 2011; Schweizer et al., 2013). MYC5, which is also a member of the group IIIe subfamily of bHLH TFs to which MYC2/3/4 belong, plays a role in JA‐mediated stamen development (Figueroa & Browse, 2015; Qi et al., 2015a). We assessed whether MYC5 might contribute to JA signaling in nonfloral tissues by comparing responses of vegetative organs of a myc2 myc3 myc4 triple mutant (referred to hereafter as mycT) to those of a myc2 myc3 myc4 myc5 quadruple mutant (myc2345). No differences in root growth, leaf growth, or leaf anthocyanin concentrations were observed between mycT and myc2345 (Fig. S3). Subsequent studies were thus focused on investigating the genetic interaction between jazQ and mycT.

To investigate the collective role of MYC2/3/4 in jazQ phenotypes, we compared JA responses in jazQ to those in mycT and the corresponding jazQ mycT octuple mutant. Root growth assays performed on JA‐free medium showed that mycT and WT roots were similar in length, whereas jazQ mycT plants displayed the constitutive short‐root trait of jazQ (Fig. 2a). Assays performed on JA‐supplemented media showed that mycT roots were partially insensitive to JA (Fig. 2a), consistent with previous studies (Lorenzo et al., 2004; Fernandez‐Calvo et al., 2011; Gasperini et al., 2015). Moreover, the response of jazQ mycT roots to JA was indistinguishable from that of mycT plants. These data indicate that the hypersensitivity of jazQ roots to JA is mediated by MYC2/3/4 but that the constitutive short‐root phenotype of jazQ does not require these TFs.

We used a dark‐ and JA‐induced chlorophyll degradation assay to investigate how jazQ and mycT interact to mediate shoot responses to exogenous JA. Control experiments showed comparable levels of chlorophyll in WT, jazQ, mycT and jazQ mycT plants, in both intact rosette leaves and in detached leaves incubated in the dark in the absence of exogenous JA (Fig. S4; Table 1). Exogenous JA promoted chlorophyll degradation in detached WT leaves incubated in the dark (Fig. 2b,c), as previously reported (Zhu et al., 2015). JA‐induced leaf degreening was modestly but reproducibly exacerbated in jazQ leaves relative to Col‐0, and this effect was abolished in both mycT and jazQ mycT lines. These results show that the responsiveness of jazQ leaves to exogenous JA is dependent on MYC2/3/4.

Table 1.

Chlorophyll and anthocyanin content in plants with jasmonate zim‐domain quintuple (jazQ) and myc2 myc3 myc4 triple (mycT) mutations

Col‐0 jazQ mycT jazQ mycT
Total chlorophylla 1.37 ± 0.10 1.33 ± 0.09 1.34 ± 0.07 1.41 ± 0.15
A530/g FWb 0.97 ± 0.30 3.75† ± 0.80 0.67 ± 0.25 1.83† ± 0.47
Open in a new tab
a

Total chlorophyll levels (μg chlorophyll per mg fresh tissue) quantified from rosette leaves of 21‐d old plants (n = 10). Plant genotype had no effect at P < 0.05 with an ANOVA. Experiment was repeated three times with similar results.

b

Anthocyanin levels were quantified from rosette leaves of 21‐d old plants (n = 14). Different symbols denote significant differences at P < 0.05 with Tukey's HSD test. Experiment was repeated four times with similar results.

Growth and defense responses in jazQ leaves are largely dependent on MYC TFs

To determine whether MYC2/3/4 activity plays a role in JA‐mediated restriction of shoot growth, we compared leaf growth traits of 21‐d‐old plants grown in soil under our standard conditions. Consistent with previous studies (Campos et al., 2016), the shoot biomass, projected leaf area, petiole length, and leaf number were all decreased in jazQ relative to WT (Fig. 3). Loss of MYC2/3/4 in mycT plants had the opposite effect on shoot growth, such that leaf area, biomass and petiole length of mycT plants were greater than those of WT. Significantly, loss of MYCs in the jazQ genetic background completely recovered the restricted growth of jazQ leaves, and the area and biomass of jazQ mycT leaves also exceeded those of WT (Fig. 3b–e). These data demonstrate that JAZ1/3/4/9/10 and MYC2/3/4 act as positive and negative regulators, respectively, of leaf growth and biomass accumulation.

Figure 3.

Figure 3

Open in a new tab

Growth suppression of jasmonate zim‐domain quintuple mutant (jazQ) rosette leaves is mediated by MYC transcription factors. (a) Photograph of Col‐0, jazQ, mycT and jazQ mycT rosettes of 21‐d‐old Arabidopsis plants. (b–e). Rosette growth at 21 d was assessed by measuring (b) biomass, (c) leaf area, (d) number of leaves, and (e) petiole length. Bars are means ± SD (= 14–15 plants per genotype). Different letters represent significant differences at < 0.05 determined by two‐way ANOVA with Tukey's honest significant difference (HSD) test. The experiment was repeated four times with similar results.

We next determined whether MYC TFs are required for enhanced resistance of jazQ plants to insect herbivory (Campos et al., 2016). Feeding assays performed with Trichoplusia ni (cabbage looper) showed that, as expected, larval growth on jazQ plants was reduced relative to growth of WT‐reared insects. By contrast, the mass of larvae reared on either mycT or jazQ mycT plants exceeded that on WT (Fig. 4a,b). These differences in caterpillar performance were generally reflected by the amount of leaf tissue consumed during the course of the bioassay (Fig. 4c). We conclude that enhanced defense of jazQ to T. ni feeding is dependent on MYC2/3/4 TFs. The finding that the weight gain of caterpillars grown on mycT slightly exceeded that of larvae reared on jazQ mycT plants (Fig. 4b) suggests that other regulatory factors may contribute to jazQ‐mediated anti‐insect defense. We also tested the effect of mycT on leaf anthocyanin concentrations, which are elevated in jazQ (Campos et al., 2016). Anthocyanin concentrations in mycT leaves were modestly but consistently lower than those in WT. Leaf anthocyanin concentrations in jazQ mycT were intermediate between those of jazQ and WT (Table 1). These results indicate that, although MYC2/3/4 positively regulate anthocyanin production, these TFs are not sufficient to account for all anthocyanin accumulation in jazQ.

Figure 4.

Figure 4

Open in a new tab

MYC2/3/4 are required for increased resistance of the jasmonate zim‐domain quintuple mutant (jazQ) to a lepidopteran herbivore. Arabidopsis plants of the indicated genotype were challenged with neonate Trichoplusia ni larvae. Larval weights were measured 10 d later. (a) Photograph of representative T. ni larvae at the end of the feeding trial. (b) Larval weight at the end of the feeding trial. Bars are means ± SD (= 12, where each sample is the mean of four larvae per plant). Different letters represent significant differences at < 0.05 with Tukey's honest significant difference (HSD) test. (c) Photograph of control (Con) and insect‐challenged plants at the end of the feeding trial. The experiment was repeated three times with similar results.

The bacterial pathogen P. syringae pv. tomato DC3000 (Pst DC3000) exploits the host JA signaling pathway to promote virulence. We therefore sought to determine whether the constitutive activation of JA signaling by jazQ is sufficient to alter host susceptibility to this pathogen, which uses the JA‐Ile mimic coronatine as part of its virulence strategy to suppress host defenses (Melotto et al., 2006). Indeed, bacterial infection assays showed that Pst DC3000 multiplies to a higher level on jazQ than on WT leaves (Fig. 5a,b). The enhanced susceptibility of jazQ was particularly evident from strong disease symptoms in young emerging leaves, which in WT plants typically show few disease symptoms after Pst DC3000 infection (Fig. 5c). Consistent with previous reports (Laurie‐Berry et al., 2006; Fernandez‐Calvo et al., 2011), mycT plants were more resistant than WT to Pst DC3000 infection. Moreover, we found that jazQ mycT plants resisted Pst DC3000 infection to a similar level to mycT (Fig. 5a). These results show that MYCs TFs are required for the increased susceptibility of jazQ to Pst DC3000 infection, and are consistent with the idea that this pathogen activates the JA pathway as part of a virulence strategy to suppress salicylate‐based immunity (Zhao et al., 2003; Katsir et al., 2008; Fernandez‐Calvo et al., 2011; Demianski et al., 2012; Zheng et al., 2012).

Figure 5.

Figure 5

Open in a new tab

Enhanced susceptibility of the jasmonate zim‐domain quintuple mutant (jazQ) to bacterial infection requires MYC2/3/4. Five‐week‐old Arabidopsis plants of the indicated genotype were dip‐inoculated with Pseudomonas syringae pv. DC3000 (Pst DC3000) at 1 × 108 colony forming units (CFUs) ml−1. (a) Bacterial populations, represented as CFUs, in fully expanded leaves were determined 3 d after inoculation. Data show the mean ± SD (= 4 technical replicates). Different letters represent significant differences at < 0.05 with Tukey's honest significant difference (HSD) test. The experiment was repeated three times with similar results. (b) Photograph of plants taken 6 d after inoculation with Pst DC3000. (c) Zoom‐in images to show increased symptom development on young leaves of jazQ plants 4 d after inoculation.

MYC TFs do not promote delayed flowering in jazQ

Several studies have reported that JA signaling through the COI1‐JAZ pathway delays the onset of flowering in Arabidopsis (Robson et al., 2010; Yang et al., 2012; Song et al., 2013; Zhai et al., 2015). Consistent with these observations, we found that jazQ plants are developmentally delayed in flowering but have the same number of leaves as WT at the time of bolting (Fig. 6; Campos et al., 2016). Under our standard long‐day growth conditions, mycT alone did not have an obvious effect on flowering time. Unexpectedly, however, the combination of jazQ and mycT retarded flowering time even later than jazQ, and also increased the number of leaves at the time of bolting (Fig. 6). These data indicate that MYC2/3/4 do not mediate the delayed flowering of jazQ.

Figure 6.

Figure 6

Open in a new tab

Delayed flowering of the jasmonate zim‐domain quintuple mutant (jazQ) is not dependent on MYC transcription factors. (a) Photograph of Col‐0, jazQ, mycT and jazQ mycT inflorescence in 45‐d‐old Arabidopsis plants. (b, c) Flowering time was assessed by counting the days required for (b) bolting and (c) flowering. (d) Quantification of the number of leaves at the time of bolting. Bars are means ± SD (= 29–32 plants per genotype). Different letters represent significant differences at < 0.05 with Tukey's honest significant difference (HSD) test. The experiment was repeated four times with similar results.

Global transcript profiling identifies MYC‐dependent and ‐independent sectors of JAZ‐repressible gene expression

To better understand the contribution of MYC TFs to changes in gene expression resulting from loss of JAZ1/3/4/9/10, we used mRNA sequencing (RNA‐seq) to compare transcript profiles of WT, jazQ, mycT, and jazQ mycT seedlings grown in the absence of exogenous JA (Table S2). We used stringent statistical criteria to define a set 99 JAZ1/3/4/9/10‐repressible, MYC2/3/4‐inducible transcripts whose abundance relative to Col‐0 is higher in jazQ but not in jazQ mycT (Figs 7a, S5). Likewise, 159 MYC‐independent genes were identified as being up‐regulated in both jazQ and jazQ mycT (Figs 7a, S5). Based on this analysis, we estimate that MYC2/3/4 activity is required for the increased expression of c. 38% of all genes that are up‐regulated in jazQ seedlings. Among the 258 genes that were up‐regulated in jazQ relative to Col‐0, the MYC‐dependent gene set was associated with gene ontologies for JA biosynthesis and glucosinolate (GLS) metabolism, and also included known wound‐response genes such as vegetative storage protein 2 (VSP2) and tyrosine aminotransferase 1 (TAT1) (Fig. 7b,c). That several of these MYC‐dependent genes, most notably genes involved in GLS biosynthesis, were strongly repressed by mycT relative to Col‐0 (Figs 7c, S6) is consistent with a role for MYC TFs in maintaining basal expression of JA‐responsive genes.

Figure 7.

Figure 7

Open in a new tab

JASMONATE ZIM‐DOMAIN (JAZ) proteins coordinate gene expression through MYC‐dependent and ‐independent mechanisms in Arabidopsis. (a) Conceptual framework of genes up‐regulated in jazQ. Genes controlled by the JAZ‐MYC module are up‐regulated in jazQ but not jazQ mycT, whereas genes controlled by other (MYC‐independent) JAZ‐transcription factor (TF) modules are up‐regulated in both jazQ and jazQ mycT. (b) Gene ontology (GO) terms of genes up‐regulated in jazQ only (top) or in jazQ and jazQ mycT (bottom). (c) MYC‐dependent expression of selected genes associated with jasmonate biosynthesis, glucosinolate biosynthesis, and the wound response. lipoxygenase 2 (LOX2), branched‐chain aminotransferase 4 (BCAT4), isopropyl malate dehydrogenase 1 (IPMD1), CYP79B3 and TAT1 promoters are reported targets of MYC2. (d) MYC‐independent expression of genes associated with triterpenoid metabolism from the marneral and thalianol clusters (shaded genes), with genes flanking these clusters shown for comparison. Errors bars are ± SD of the mean of three biological replicates. Expression levels are transcripts per million (TPM).

Among the genes that were up‐regulated most robustly in jazQ (relative to WT) and independently of MYC2/3/4 were those associated with triterpenoid biosynthesis and GLS catabolism (Fig. 7b). Marneral and thalianol triterpenoids are synthesized in the Arabidopsis root epidermis by enzymes encoded within metabolic gene clusters (Field & Osbourn, 2008). Strikingly, transcript levels for all genes within these clusters were similarly elevated in both jazQ and jazQ mycT, and mycT alone did not affect the basal expression level observed in WT (Fig. 7d). We also found that the expression of genes immediately flanking the marneral and thalianol gene clusters was not altered by jazQ or mycT. Thus, the effect of jazQ in increasing the expression of triterpenoid biosynthetic genes is not only independent of MYC2/3/4, but is also spatially restricted to genes within the clusters.

In intact plant cells, GLSs are stored as inert glycosides physically separated from GLS catabolic enzymes (Halkier & Gershenzon, 2006). Tissue disruption by herbivores allows myrosinases to deglycosylate GLSs, whereas ancillary specifier proteins catalyze the formation of cyanate and nitrile toxins from the corresponding aglycones (Fig. S7a). We found that genes encoding enzymes involved in GLS breakdown were significantly up‐regulated in both jazQ and jazQ mycT (Fig. S7b,c). This expression pattern was highly distinct from that of MYC‐dependent GLS biosynthetic genes (Figs S6, S7), suggesting that specific JAZ–TF modules control different aspects of GLS metabolism. Further analysis of the broader set of 159 genes that are up‐regulated in jazQ independently of MYC2/3/4 (Fig. 7a) revealed a substantial overlap with genes that are up‐regulated in roots of the ninja‐1 mutant (Fig. S5c) (Gasperini et al., 2015). This overlap was significantly greater than the portion of MYC‐dependent genes that overlapped with ninja‐1 (= 0 .0013; Fisher's exact test), suggesting that NINJA cooperates with JAZ1/3/4/9/10 to repress the expression MYC‐independent genes.

Among the 88 genes expressed to higher levels in mycT than Col‐0, there was little overlap with genes misregulated by either jazQ or jazQ mycT (Fig. S5a). We found that the majority of genes (37/72 genes; 51.4%) uniquely up‐regulated in mycT are associated with chloroplast processes and, in particular, photosynthesis (Fig. S8). Gas exchange experiments showed that mycT leaves had higher CO2 assimilation rate per unit leaf area than Col‐0 leaves under our plant growth conditions (Fig. S9). Photosynthetic rates measured in jazQ and jazQ mycT leaves were comparable to those in WT (Fig. S9). These findings suggest a potential role for the MYC2/3/4 TFs as negative regulators of photosynthesis, and further highlight the complex relationship between JA signaling and photosynthetic capacity (Campos et al., 2016).

Discussion

Genetic interactions in the core JA signaling pathway

Genetic epistasis provides a powerful approach to dissect complex interactions between core components of the JA pathway, as exemplified by recent studies of root responses to JA (Acosta et al., 2013; Gasperini et al., 2015). We previously employed a genetic suppressor screen to identify mutations that uncouple growth–defense antagonism in leaves of the jazQ mutant (Campos et al., 2016). Here, we report on a new class of jazQ suppressor mutants in which defects in either JA‐Ile biosynthesis (aos) or perception (coi1) suppress both the slow growth and enhanced defense traits of jazQ leaves. Given that JA‐Ile biosynthesis and perception are both required for turnover of JAZ repressors, the most likely mechanistic explanation for the observed jazQ aos and jazQ coi1 phenotypes is that one or more of the remaining JAZs in jazQ are stabilized by the loss of the JAZ degradation machinery. This model implies that the remaining complement of JAZs in jazQ can strongly repress JA responses in the absence of JAZ1/3/4/9/10, thus providing evidence for functional redundancy among JAZs. The genetic interactions defined in our study are generally consistent with current models of JA‐mediated signal transduction in which JA‐Ile and COI1 work together to degrade JAZs, thereby relieving repression on target TFs (Fig. 1a).

A unique attribute of jazQ in comparison to jaz single mutants is its enhanced sensitivity to exogenous JA. One explanation for this phenotype is that genetic depletion of JAZs increases the capacity of SCFCOI1 to ubiquitylate the remaining pool of JAZ substrates in jazQ, which is consistent with evidence that COI1 dosage modulates sensitivity to JA (Feng et al., 2003). Alternatively, the enhanced responsiveness of jazQ to JA treatment may reflect the loss of JAZ proteins that desensitize JA responses once the signaling pathway is initiated (Campos et al., 2014). JAZ1 and JAZ10 probably contribute to this role. First, JAZ10 alternative splice variants are resistant to JA‐induced degradation, and loss of these isoforms is associated with increased sensitivity to JA (Chung & Howe, 2009; Moreno et al., 2013). Second, the N termini of both JAZ10 and JAZ1 contain a cryptic MYC‐interaction domain (CMID) that may enhance the capacity of these proteins to repress MYCs in JA‐elicited cells (Moreno et al., 2013; Goossens et al., 2015; Zhang et al., 2017). The up‐regulation of JA biosynthetic genes in jazQ raises the additional possibility that changes in endogenous JA/JA‐Ile concentrations contribute to the phenotypes observed in this line. Regardless of the mechanisms that confer enhanced sensitivity of jazQ to JA, it is evident that jazQ mutant phenotypes are relatively subtle in comparison to WT plants subject to chronic JA exposure. This observation supports the notion of genetic redundancy among JAZ genes and provides a strong rationale for further analysis of higher order jaz mutants.

In addition to JA hypersensitivity, jazQ roots are c. 25% shorter than those of WT in the absence of exogenous JA (Campos et al., 2016; this work). The unexpected finding that constitutive root shortening also occurs in jazQ aos, jazQ coi1, and jazQ mycT mutants indicates that this phenotype is not dependent on core components of the JA pathway. Analysis of jaz single mutants further suggested that JAZ3 may serve a role in promoting root growth in the absence of JA, but additional studies are needed to test this hypothesis. We are not aware of other studies suggesting JA‐independent roles for JAZ proteins. However, it was recently reported that overexpression of Arabidopsis TIFY8, a ZIM domain‐containing protein belonging to the TIFY family to which JAZs belong, stunts primary root growth in the absence of exogenous JA (Perez et al., 2014). TIFY8 also represses transcriptional activity through recruitment of the NINJA−TPL corepressor complex, but does not affect the expression of JA‐responsive genes. Acosta et al. (2013) found that null mutations in NINJA led to JA‐independent reduction in root cell elongation to generate a short‐root phenotype similar to that of jazQ. Given that JAZs and NINJA physically interact and negatively regulate JA signaling in roots (Pauwels et al., 2010; Acosta et al., 2013), it is possible that JAZ−NINJA complexes have a role in promoting root growth under specific conditions or in specific cell types. Unlike jazQ, ninja null mutations do not confer hypersensitivity to exogenous JA (Acosta et al., 2013), presumably because loss of NINJA does not impede JA‐Ile‐dependent JAZ degradation via SCFCOI1 and the 26S proteasome. In future studies it will be informative to determine whether jazQ and ninja mutations mediate constitutive root shortening through the same or parallel pathways.

Unraveling physiological roles of multiple JAZ–TF interactions

A current challenge in JA research is to understand how the hormone controls diverse aspects of plant growth, development, and responses to the environment. As summarized in Fig. 8, our genetic data suggest that JAZ‐mediated control over MYC2/3/4 TFs plays a major role in executing the majority of JA‐related phenotypes in jazQ. We found that MYCs are largely responsible for root hypersensitivity to JA, reduced leaf biomass, leaf defense against insect herbivory, and JA‐induced chlorophyll degradation. The latter observation supports previous studies showing that exogenous JA and leaf damage reduce the abundance of photosynthetic proteins in Arabidopsis leaves, perhaps as a strategy to mobilize resources for defense (Gfeller et al., 2011; Shan et al., 2011; Zhu et al., 2015). Consistent with previous work showing that MYCs are critical for the effects of coronatine on virulence of Pst DC3000 (Fernandez‐Calvo et al., 2011; Zheng et al., 2012; Schweizer et al., 2013; Gimenez‐Ibanez et al., 2017), we also found that jazQ‐mediated enhanced susceptibility to this pathogen is eliminated by mycT. These collective data support a dominant role for MYC TFs in mediating JA responses in Arabidopsis and further demonstrate that MYC activity can be enhanced through loss of a specific subset of MYC‐interacting JAZs in vivo.

Figure 8.

Figure 8

Open in a new tab

Conceptual model of how jasmonate (JA) signaling controls multiple JASMONATE ZIM‐DOMAIN (JAZ)‐transcription factor modules to mediate diverse physiological responses. The model depicts specific processes that are either dependent (light purple) or not dependent (blue) on MYC transcription factors (TFs). Some processes, including glucosinolate and anthocyanin metabolism, are controlled by JAZ‐mediated repression of both MYC and non‐MYC TFs. See the Discussion section for details. COI1, coronatine insensitive 1; FT, flowering locus T; TOE, target of eat; TT8, transparent testa 8; GL3, glabrous 3; GL1, glabrous 1; PAP1, production of anthocyanin pigment 1; EGL3, enhancer of glabra 3; TF, transcription factor; PLT1/2, plethora 1 and 2.

Our findings support an increasing number of studies showing that JAZs functionally interact with TFs other than MYCs (Fig. 8) (Wager & Browse, 2012; Chini et al., 2016; Goossens et al., 2016). One example is jazQ‐mediated anthocyanin accumulation, which was reduced but not eliminated by mycT. The role of MYC TFs as positive regulators of anthocyanin biosynthesis is well established (Niu et al., 2011; Nakata et al., 2013). Other JAZ‐interacting TFs, however, including YABBY, MYB, and transparent testa 8/glabrous 3, also contribute to JA‐inducible anthocyanin accumulation (Shan et al., 2009; Qi et al., 2011; Boter et al., 2015). It thus seems likely that these non‐MYC TFs contribute to the anthocyanin accumulation observed in jazQ mycT plants (Fig. 8).

We also demonstrate that MYC2/3/4 activity is not required for delayed flowering of jazQ. This finding agrees with recent models in which a subset of JAZ proteins (i.e. JAZ1/3/4/9) repress TARGET OF EAT1 (TOE1) and TOE2 TFs, which delay flowering time by repressing the expression of FLOWERING LOCUS T (FT) (Zhai et al., 2015). Although additional work is needed to understand how mycT further delays the flowering time of jazQ, inspection of RNA‐seq data (Campos et al., 2016; this work) showed a strong correlation between FT transcript levels and flowering time in various mutant lines. For example, FT mRNA levels were high in the early‐flowering phyB and jazQ phyB lines, whereas FT transcript levels were strongly reduced (relative to Col‐0) in jazQ and even lower in jazQ mycT (Fig. S10).

Control of specialized metabolism by JAZ repressors

Although JA has long been recognized as a potent elicitor of specialized metabolism (Gundlach et al., 1992), the underlying transcriptional mechanisms that control these metabolic pathways in specific cell types and morphological structures are only beginning to be elucidated (De Geyter et al., 2012). Consistent with previous studies (Schweizer et al., 2013; Campos et al., 2016), our results establish a direct link between JAZ1/3/4/9/10 and their interacting MYC TFs in controlling GLS production. Interestingly, however, we also found that genes encoding myrosinases and associated specifier proteins involved in GLS breakdown are up‐regulated in jazQ independently of MYC2/3/4, suggesting that additional JAZ‐interacting TFs govern distinct aspects GLS metabolism (Fig. 8). This interpretation is consistent with recent work showing that GLS accumulation is dependent on a complex transcriptional network in which many TFs optimize metabolite accumulation across multiple tissue types and environmental conditions, thus allowing for tight yet flexible control of the ‘mustard oil bomb’ (Li et al., 2014).

Our results also provide new insight into processes underlying the expression of metabolic gene clusters for triterpenoid biosynthesis. We found that genes within the thalianol and marnerol clusters are coordinately up‐regulated in jazQ seedlings, which is consistent with the ability of JA to elicit triterpenoid production (Hayashi et al., 2003). MYC2‐like TFs are implicated in the control of metabolic gene clusters in several plant species (Shang et al., 2014; Cardenas et al., 2016). However, our finding that mycT does not suppress the elevated expression of the thalianol and marnerol clusters in jazQ argues against a role for MYC2/3/4 in controlling these genes. The observation that genes within these clusters are strongly up‐regulated in roots of ninja mutants (Gasperini et al., 2015) further supports the notion that recruitment of co‐repressors by JAZ‐NINJA complexes (Pauwels et al., 2010) may negatively regulate triterpenoid production. Indeed, recent studies show that chromatin modifications within the thalianol and marnerol clusters are associated with silencing and activation of individual cluster genes (Nützmann et al., 2016; Yu et al., 2016). Mutants affected in NINJA and JAZ function may provide useful tools to delineate the contribution of core JA signaling components to chromatin signatures and TF modules that coordinate the expression of metabolic gene clusters.

MYC TFs mediate repression of leaf growth

JA is a potent inhibitor of leaf growth and biomass accumulation in Arabidopsis (Yan et al., 2007; Zhang & Turner, 2008; Noir et al., 2013; Attaran et al., 2014). Similar effects are observed in monocots (Yang et al., 2012; Hibara et al., 2016), suggesting that the underlying pathways for JA‐mediated restriction of leaf growth are conserved. JA acts primarily to reduce leaf cell number through perturbation of the cell cycle but effects on leaf cell expansion have also been documented (Zhang & Turner, 2008; Noir et al., 2013; Havko et al., 2016). A role for the JAZ‐MYC module in mediating these effects is supported by the observation that myc2 mutation, as well as overexpression of the JAZ10.3 alternative splice variant, partially inhibits JA‐ and wound‐induced growth stunting (Yan et al., 2007; Zhang & Turner, 2008). Our data showing that mycT completely rescues the reduced size and biomass of jazQ are consistent with this view, as is the finding that mycT leaves are larger than Col‐0 leaves under our growth conditions. These collective observations highlight a key role for MYC2/3/4 TFs as negative regulators of leaf growth and biomass accumulation.

The mechanism by which MYC TFs restrict leaf growth remains unknown but several hypotheses can be considered. First, the ability of MYCs to repress the expression of photosynthesis‐associated genes (Yadav et al., 2005; this work) suggests that JA‐induced reduction in photosynthetic efficiency may be linked to reduced leaf growth. The photosynthetic robustness of JA‐elicited Arabidopsis leaves, however, does not support this hypothesis (Attaran et al., 2014; Campos et al., 2016). Second, MYCs may directly repress the activity of positive regulators of leaf cell division or expansion (Pauwels et al., 2008; Zhang & Turner, 2008; Noir et al., 2013). Such a mechanism would be analogous to the role of MYC2 in repressing the activity of PLETHORA TFs, which promote auxin‐dependent control of cell proliferation specifically in the root stem cell niche (Chen et al., 2011). A third possibility is that JA‐induced activation of MYC activity increases the production of GLSs and other defensive compounds whose biosynthesis limits resource allocation to growth (Paul‐Victor et al., 2010). Recent studies, however, show that GLS‐based leaf defenses can be expressed in the absence of a growth penalty, indicating that growth–defense antagonism in this and perhaps other genotypes cannot simply be explained by allocation costs (Campos et al., 2016; Kliebenstein, 2016; Züst & Agrawal, 2017). In this context, uncoupling of growth–defense tradeoffs in jazQ phyB implies that rewiring of phyB−JA crosstalk can override MYC‐mediated growth restriction while leaving MYC‐mediated defenses intact (Campos et al., 2016). Although DELLA proteins have been implicated in JA‐mediated growth inhibition of Arabidopsis roots (Hou et al., 2010) and hypocotyls (Yang et al., 2012), DELLAs are not required for wound‐ and JA‐induced growth stunting of leaves (Zhang & Turner, 2008). Nevertheless, we cannot exclude the possibility that changes in MYC stability (Chico et al., 2014), DELLA protein abundance (Leone et al., 2014), or direct interaction between DELLA and MYC TFs (Hong et al., 2012) contributes to the mechanism by which leaf growth is attenuated by MYC activity. A better understanding of how plants balance leaf growth and defense traits may benefit from research to determine how JA signaling is integrated into regulatory networks that control leaf cell division and expansion (Chitwood & Sinha, 2016; Nelissen et al., 2016; Mao et al., 2017).

Author contributions

I.T.M., Y.Y. and G.A.H. designed the research plans; I.T.M., Y.Y., M.L.C., G.K., D.d.O.F., K.S., and X‐F.X. performed the experiments; I.T.M., Y.Y., G.K., K.S., X‐F.X., S.Y.H., and G.A.H. analyzed the data; I.T.M. and G.A.H. wrote the manuscript.

Supporting information

Please note: Wiley Blackwell are not responsible for the content or functionality of any Supporting Information supplied by the authors. Any queries (other than missing material) should be directed to the New Phytologist Central Office.

Fig. S1 jazQ mycT and myc2345 pedigrees.

Fig. S2 sjq10 and sjq66 carry suppressor mutations in JA biosynthesis and signaling genes.

Fig. S3 JA responsiveness and rosette growth phenotypes of mycT and myc2345.

Fig. S4 Leaf chlorophyll concentrations are comparable among Col‐0, jazQ, mycT and jazQ mycT in the absence of exogenous JA.

Fig. S5 Number of genes up‐ and down‐regulated in jazQ, mycT, and jazQ mycT relative to Col‐0.

Fig. S6 JAZs and MYCs regulate the expression of genes associated with glucosinolate biosynthesis.

Fig. S7 JAZs regulate the expression of genes associated with glucosinolate hydrolysis in manner independent of MYCs.

Fig. S8 Increased accumulation of photosynthesis‐associated mRNAs in mycT.

Fig. S9 Loss of MYC2/3/4 increases photosynthetic rate.

Fig. S10 Transcript levels of FT correspond with flowering time in higher order jazQ mutants.

Table S1 Primers for genotyping jaz and myc mutants

Click here for additional data file. (450.9KB, pdf)

Table S2 RNAseq analysis performed on WT, jazQ, mycT and jazQ mycT seedlings

Click here for additional data file. (6.3MB, xlsx)

Acknowledgements

We thank Tom Sharkey and Sean Wiese for assistance with photosynthesis measurements. This work was primarily funded by the Chemical Sciences, Geosciences and Biosciences Division, Office of Basic Energy Sciences, Office of Science, US Department of Energy through grant DE‐FG02‐91ER20021. Construction of mutant lines was supported by the National Institutes of Health award number GM57795 to G.A.H. K.S. was supported in part by the Japan Society for Promotion of Science Research Fellowship for Young Scientists (24‐824), and D.O.F. was supported by a fellowship from the Brazilian National Council for Scientific and Technological Development (Science Without Borders – CNPq). G.A.H. acknowledges support from the Michigan AgBioResearch Project MICL02278 and the Discretionary Funding Initiative from Michigan State University.

See also the Commentary on this article by Wasternack, 215: 1291–1294.

References

  1. Acosta IF, Gasperini D, Chetelat A, Stolz S, Santuari L, Farmer EE. 2013. Role of NINJA in root jasmonate signaling. Proceedings of the National Academy of Sciences, USA 110: 15473–15478. [DOI] [PMC free article] [PubMed] [Google Scholar]
  2. Anders S, Huber W. 2010. Differential expression analysis for sequence count data. Genome Biology 11: R106. [DOI] [PMC free article] [PubMed] [Google Scholar]
  3. Attaran E, Major IT, Cruz JA, Rosa BA, Koo AJ, Chen J, Kramer DM, He SY, Howe GA. 2014. Temporal dynamics of growth and photosynthesis suppression in response to jasmonate signaling. Plant Physiology 165: 1302–1314. [DOI] [PMC free article] [PubMed] [Google Scholar]
  4. Bai Y, Meng Y, Huang D, Qi Y, Chen M. 2011. Origin and evolutionary analysis of the plant‐specific TIFY transcription factor family. Genomics 98: 128–136. [DOI] [PubMed] [Google Scholar]
  5. Baldwin IT, Wu J. 2010. New insights in plant responses to attack from insect herbivores. Annual Review of Genetics 44: 1–24. [DOI] [PubMed] [Google Scholar]
  6. Bhosale R, Jewell JB, Hollunder J, Koo AJ, Vuylsteke M, Michoel T, Hilson P, Goossens A, Howe GA, Browse J et al 2013. Predicting gene function from uncontrolled expression variation among individual wild‐type Arabidopsis plants. Plant Cell 25: 2865–2877. [DOI] [PMC free article] [PubMed] [Google Scholar]
  7. Boter M, Golz JF, Gimenez‐Ibanez S, Fernandez‐Barbero G, Franco‐Zorrilla JM, Solano R. 2015. FILAMENTOUS FLOWER is a direct target of JAZ3 and modulates responses to jasmonate. Plant Cell 27: 3160–3174. [DOI] [PMC free article] [PubMed] [Google Scholar]
  8. Boter M, Ruiz‐Rivero O, Abdeen A, Prat S. 2004. Conserved MYC transcription factors play a key role in jasmonate signaling both in tomato and Arabidopsis . Genes and Development 18: 1577–1591. [DOI] [PMC free article] [PubMed] [Google Scholar]
  9. Browse J. 2009. Jasmonate passes muster: a receptor and targets for the defense hormone. Annual Review of Plant Biology 60: 183–205. [DOI] [PubMed] [Google Scholar]
  10. Campos ML, Kang JH, Howe GA. 2014. Jasmonate‐triggered plant immunity. Journal of Chemical Ecology 40: 657–675. [DOI] [PMC free article] [PubMed] [Google Scholar]
  11. Campos ML, Yoshida Y, Major IT, de Oliveira Ferreira D, Weraduwage SM, Froehlich JE, Johnson BF, Kramer DM, Jander G, Sharkey TD et al 2016. Rewiring of jasmonate and phytochrome B signalling uncouples plant growth‐defense tradeoffs. Nature Commununication 7: 12570. [DOI] [PMC free article] [PubMed] [Google Scholar]
  12. Cardenas PD, Sonawane PD, Pollier J, Vanden Bossche R, Dewangan V, Weithorn E, Tal L, Meir S, Rogachev I, Malitsky S et al 2016. GAME9 regulates the biosynthesis of steroidal alkaloids and upstream isoprenoids in the plant mevalonate pathway. Nature Communications 7: 10654. [DOI] [PMC free article] [PubMed] [Google Scholar]
  13. Çevik V, Kidd BN, Zhang P, Hill C, Kiddle S, Denby KJ, Holub EB, Cahill DM, Manners JM, Schenk PM et al 2012. MEDIATOR25 acts as an integrative hub for the regulation of jasmonate‐responsive gene expression in Arabidopsis. Plant Physiology 160: 541–555. [DOI] [PMC free article] [PubMed] [Google Scholar]
  14. Chen R, Jiang H, Li L, Zhai Q, Qi L, Zhou W, Liu X, Li H, Zheng W, Sun J 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. [DOI] [PMC free article] [PubMed] [Google Scholar]
  15. Chen Q, Sun JQ, Zhai QZ, Zhou WK, Qi LL, Xu L, Wang B, Chen R, Jiang HL, Qi J et al 2011. The basic helix‐loop‐helix transcription factor MYC2 directly represses PLETHORA expression during jasmonate‐mediated modulation of the root stem cell niche in Arabidopsis . Plant Cell 23: 3335–3352. [DOI] [PMC free article] [PubMed] [Google Scholar]
  16. Chico JM, Fernandez‐Barbero G, Chini A, Fernandez‐Calvo P, Diez‐Diaz M, Solano R. 2014. Repression of jasmonate‐dependent defenses by shade involves differential regulation of protein stability of MYC transcription factors and their JAZ repressors in Arabidopsis . Plant Cell 26: 1967–1980. [DOI] [PMC free article] [PubMed] [Google Scholar]
  17. Chini A, Fonseca S, Fernandez G, Adie B, Chico JM, Lorenzo O, Garcia‐Casado G, Lopez‐Vidriero I, Lozano FM, Ponce MR et al 2007. The JAZ family of repressors is the missing link in jasmonate signalling. Nature 448: 666–671. [DOI] [PubMed] [Google Scholar]
  18. Chini A, Gimenez‐Ibanez S, Goossens A, Solano R. 2016. Redundancy and specificity in jasmonate signalling. Current Opinion in Plant Biology 33: 147–156. [DOI] [PubMed] [Google Scholar]
  19. Chitwood DH, Sinha NR. 2016. Evolutionary and environmental forces sculpting leaf development. Current Biology 26: R297–R306. [DOI] [PubMed] [Google Scholar]
  20. Chung HS, Cooke TF, Depew CL, Patel LC, Ogawa N, Kobayashi Y, Howe GA. 2010. Alternative splicing expands the repertoire of dominant JAZ repressors of jasmonate signaling. Plant Journal 63: 613–622. [DOI] [PMC free article] [PubMed] [Google Scholar]
  21. Chung HS, Howe GA. 2009. A critical role for the TIFY motif in repression of jasmonate signaling by a stabilized splice variant of the JASMONATE ZIM‐domain protein JAZ10 in Arabidopsis . Plant Cell 21: 131–145. [DOI] [PMC free article] [PubMed] [Google Scholar]
  22. De Geyter N, Gholami A, Goossens A. 2012. Transcriptional machineries in jasmonate‐elicited plant secondary metabolism. Trends in Plant Science 17: 349–359. [DOI] [PubMed] [Google Scholar]
  23. Demianski AJ, Chung KM, Kunkel BN. 2012. Analysis of Arabidopsis JAZ gene expression during Pseudomonas syringae pathogenesis. Molecular Plant Pathology 13: 46–57. [DOI] [PMC free article] [PubMed] [Google Scholar]
  24. Dombrecht B, Xue GP, Sprague SJ, Kirkegaard JA, Ross JJ, Reid JB, Fitt GP, Sewelam N, Schenk PM, Manners JM et al 2007. MYC2 differentially modulates diverse jasmonate‐dependent functions in Arabidopsis . Plant Cell 19: 2225–2245. [DOI] [PMC free article] [PubMed] [Google Scholar]
  25. Feng S, Ma L, Wang X, Xie D, Dinesh‐Kumar SP, Wei N, Deng XW. 2003. The COP9 signalosome interacts physically with SCFCOI1 and modulates jasmonate responses. Plant Cell 15: 1083–1094. [DOI] [PMC free article] [PubMed] [Google Scholar]
  26. Fernandez‐Calvo P, Chini A, Fernandez‐Barbero G, Chico J‐M, Gimenez‐Ibanez S, Geerinck J, Eeckhout D, Schweizer F, Godoy M, Manuel Franco‐Zorrilla J 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. [DOI] [PMC free article] [PubMed] [Google Scholar]
  27. Field B, Osbourn AE. 2008. Metabolic diversification – independent assembly of operon‐like gene clusters in different plants. Science 320: 543–547. [DOI] [PubMed] [Google Scholar]
  28. Figueroa P, Browse J. 2015. Male sterility in Arabidopsis induced by overexpression of a MYC5‐SRDX chimeric repressor. Plant Journal 81: 849–860. [DOI] [PubMed] [Google Scholar]
  29. Fonseca S, Chini A, Hamberg M, Adie B, Porzel A, Kramell R, Miersch O, Wasternack C, Solano R. 2009. (+)‐7‐iso‐Jasmonoyl‐L‐isoleucine is the endogenous bioactive jasmonate. Nature Chemical Biology 5: 344–350. [DOI] [PubMed] [Google Scholar]
  30. Gasperini D, Chetelat A, Acosta IF, Goossens J, Pauwels L, Goossens A, Dreos R, Alfonso E, Farmer EE. 2015. Multilayered organization of jasmonate signalling in the regulation of root growth. PLoS Genetics 11: e1005300. [DOI] [PMC free article] [PubMed] [Google Scholar]
  31. Gfeller A, Baerenfaller K, Loscos J, Chételat A, Baginsky S, Farmer EE. 2011. Jasmonate controls polypeptide patterning in undamaged tissue in wounded Arabidopsis leaves. Plant Physiology 156: 1797–1807. [DOI] [PMC free article] [PubMed] [Google Scholar]
  32. Gimenez‐Ibanez S, Boter M, Ortigosa A, García‐Casado G, Chini A, Lewsey MG, Ecker JR, Ntoukakis V, Solano R. 2017. JAZ2 controls stomata dynamics during bacterial invasion. New Phytologist 213: 1378–1392. [DOI] [PubMed] [Google Scholar]
  33. Goossens J, Mertens J, Goossens A. 2016. Role and functioning of bHLH transcription factors in jasmonate signalling. Journal of Experimental Botany 68: 1333–1347. [DOI] [PubMed] [Google Scholar]
  34. Goossens J, Swinnen G, Vanden Bossche R, Pauwels L, Goossens A. 2015. Change of a conserved amino acid in the MYC2 and MYC3 transcription factors leads to release of JAZ repression and increased activity. New Phytologist 206: 1229–1237. [DOI] [PubMed] [Google Scholar]
  35. Gundlach H, Müller MJ, Kutchan TM, Zenk MH. 1992. Jasmonic acid is a signal transducer in elicitor‐induced plant cell cultures. Proceedings of the National Academy of Sciences, USA 89: 2389–2393. [DOI] [PMC free article] [PubMed] [Google Scholar]
  36. Halkier BA, Gershenzon J. 2006. Biology and biochemistry of glucosinolates. Annual Review of Plant Biology 57: 303–333. [DOI] [PubMed] [Google Scholar]
  37. Havko NE, Major IT, Jewell JB, Attaran E, Browse J, Howe GA. 2016. Control of carbon assimilation and partitioning by jasmonate: an accounting of growth‐defense balance. Plants 5: 7. [DOI] [PMC free article] [PubMed] [Google Scholar]
  38. Hayashi H, Huang P, Inoue K. 2003. Up‐regulation of soyasaponin biosynthesis by methyl jasmonate in cultured cells of Glycyrrhiza glabra . Plant and Cell Physiology 44: 404–411. [DOI] [PubMed] [Google Scholar]
  39. Herde M, Koo AJ, Howe GA. 2013. Elicitation of jasmonate‐mediated defense responses by mechanical wounding and insect herbivory. Methods in Molecular Biology 1011: 51–61. [DOI] [PubMed] [Google Scholar]
  40. Hibara K, Isono M, Mimura M, Sentoku N, Kojima M, Sakakibara H, Kitomi Y, Yoshikawa T, Itoh J, Nagato Y. 2016. Jasmonate regulates juvenile‐to‐adult phase transition in rice. Development 143: 3407–3416. [DOI] [PubMed] [Google Scholar]
  41. Hong GJ, Xue XY, Mao YB, Wang LJ, Chen XY. 2012. Arabidopsis MYC2 interacts with DELLA proteins in regulating sesquiterpene synthase gene expression. Plant Cell 24: 2635–2648. [DOI] [PMC free article] [PubMed] [Google Scholar]
  42. Hou X, Lee LY, Xia K, Yan Y, Yu H. 2010. DELLAs modulate jasmonate signaling via competitive binding to JAZs. Developmental Cell 19: 884–894. [DOI] [PubMed] [Google Scholar]
  43. Howe G, Jander G. 2008. Plant immunity to insect herbivores. Annual Review of Plant Biology 59: 41–66. [DOI] [PubMed] [Google Scholar]
  44. Huang DW, Sherman BT, Lempicki RA. 2009. Systematic and integrative analysis of large gene lists using DAVID bioinformatics resources. Nature Protocols 4: 44–57. [DOI] [PubMed] [Google Scholar]
  45. Huot B, Yao J, Montgomery BL, He SY. 2014. Growth‐defense tradeoffs in plants: a balancing act to optimize fitness. Molecular Plant 7: 1267–1287. [DOI] [PMC free article] [PubMed] [Google Scholar]
  46. Karasov TL, Chae E, Herman JJ, Bergelson J. 2017. Mechanisms to mitigate the tradeoff between growth and defense. Plant Cell 29: 666–680. [DOI] [PMC free article] [PubMed] [Google Scholar]
  47. Katagiri F, Thilmony R, He SY. 2002. The Arabidopsis thaliana–Pseudomonas syringae interaction. Arabidopsis Book 1: e0039. [DOI] [PMC free article] [PubMed] [Google Scholar]
  48. Katsir L, Schilmiller AL, Staswick PE, He SY, Howe GA. 2008. COI1 is a critical component of a receptor for jasmonate and the bacterial virulence factor coronatine. Proceedings of the National Academy of Sciences, USA 105: 7100–7105. [DOI] [PMC free article] [PubMed] [Google Scholar]
  49. Kazan K, Manners JM. 2012. JAZ repressors and the orchestration of phytohormone crosstalk. Trends in Plant Science 17: 22–31. [DOI] [PubMed] [Google Scholar]
  50. Kliebenstein DJ. 2016. False idolatry of the mythical growth versus immunity tradeoff in molecular systems plant pathology. Physiological and Molecular Plant Pathology 95: 55–59. [Google Scholar]
  51. Koo AJK, Gao XL, Jones AD, Howe GA. 2009. A rapid wound signal activates the systemic synthesis of bioactive jasmonates in Arabidopsis. Plant Journal 59: 974–986. [DOI] [PubMed] [Google Scholar]
  52. Koo AJK, Howe GA. 2009. The wound hormone jasmonate. Phytochemistry 70: 1571–1580. [DOI] [PMC free article] [PubMed] [Google Scholar]
  53. Laurie‐Berry N, Joardar V, Street IH, Kunkel BN. 2006. The Arabidopsis thaliana JASMONATE INSENSITIVE1 gene is required for suppression of salicylic acid‐dependent defenses during infection by Pseudomonas syringae . Molecular Plant–Microbe Interaction 19: 789–800. [DOI] [PubMed] [Google Scholar]
  54. Leone M, Keller MM, Cerrudo I, Ballare CL. 2014. To grow or defend? Low red: far‐red ratios reduce jasmonate sensitivity in Arabidopsis seedlings by promoting DELLA degradation and increasing JAZ10 stability. New Phytologist 204: 355–367. [DOI] [PubMed] [Google Scholar]
  55. Li B, Dewey CN. 2011. RSEM: accurate transcript quantification from RNA‐Seq data with or without a reference genome. BMC Bioinformatics 12: 323. [DOI] [PMC free article] [PubMed] [Google Scholar]
  56. Li B, Gaudinier A, Tang M, Taylor‐Teeples M, Nham NT, Ghaffari C, Benson DS, Steinmann M, Gray JA, Brady SM et al 2014. Promoter‐based integration in plant defense regulation. Plant Physiology 166: 1803–1820. [DOI] [PMC free article] [PubMed] [Google Scholar]
  57. Lorenzo O, Chico JM, Sanchez‐Serrano JJ, Solano R. 2004. JASMONATE‐INSENSITIVE1 encodes a MYC transcription factor essential to discriminate between different jasmonate‐regulated defense responses in Arabidopsis. Plant Cell 16: 1938–1950. [DOI] [PMC free article] [PubMed] [Google Scholar]
  58. Mao YB, Liu YQ, Chen DY, Chen FY, Fang X, Hong GJ, Wang LJ, Wang JW, Chen XY. 2017. Jasmonate response decay and defense metabolite accumulation contributes to age‐regulated dynamics of plant insect resistance. Nature Communications 8: 13925. [DOI] [PMC free article] [PubMed] [Google Scholar]
  59. Melotto M, Mecey C, Niu Y, Chung HS, Katsir L, Yao J, Zeng W, Thines B, Staswick P, Browse J et al 2008. A critical role of two positively charged amino acids in the Jas motif of Arabidopsis JAZ proteins in mediating coronatine‐ and jasmonoyl isoleucine‐dependent interactions with the COI1 F‐box protein. Plant Journal 55: 979–988. [DOI] [PMC free article] [PubMed] [Google Scholar]
  60. Melotto M, Underwood W, Koczan J, Nomura K, He SY. 2006. Plant stomata function in innate immunity against bacterial invasion. Cell 126: 969–980. [DOI] [PubMed] [Google Scholar]
  61. Moreno JE, Shyu C, Campos ML, Patel LC, Chung HS, Yao J, He SY, Howe GA. 2013. Negative feedback control of jasmonate signaling by an alternative splice variant of JAZ10. Plant Physiology 162: 1006–1017. [DOI] [PMC free article] [PubMed] [Google Scholar]
  62. Nakata M, Mitsuda N, Herde M, Koo AJ, Moreno JE, Suzuki K, Howe GA, Ohme‐Takagi M. 2013. A bHLH‐type transcription factor, ABA‐INDUCIBLE BHLH‐TYPE TRANSCRIPTION FACTOR/JA‐ASSOCIATED MYC2‐LIKE1, acts as a repressor to negatively regulate jasmonate signaling in Arabidopsis . Plant Cell 25: 1641–1656. [DOI] [PMC free article] [PubMed] [Google Scholar]
  63. Nelissen H, Gonzalez N, Inze D. 2016. Leaf growth in dicots and monocots: so different yet so alike. Current Opinion in Plant Biology 33: 72–76. [DOI] [PubMed] [Google Scholar]
  64. Niu YJ, Figueroa P, Browse J. 2011. Characterization of JAZ‐interacting bHLH transcription factors that regulate jasmonate responses in Arabidopsis . Journal of Experimental Botany 62: 2143–2154. [DOI] [PMC free article] [PubMed] [Google Scholar]
  65. Noir S, Bomer M, Takahashi N, Ishida T, Tsui TL, Balbi V, Shanahan H, Sugimoto K, Devoto A. 2013. Jasmonate controls leaf growth by repressing cell proliferation and the onset of endoreduplication while maintaining a potential stand‐by mode. Plant Physiology 161: 1930–1951. [DOI] [PMC free article] [PubMed] [Google Scholar]
  66. Nützmann HW, Huang A, Osbourn A. 2016. Plant metabolic clusters – from genetics to genomics. New Phytologist 211: 771–789. [DOI] [PMC free article] [PubMed] [Google Scholar]
  67. Park JH, Halitschke R, Kim HB, Baldwin IT, Feldmann KA, Feyereisen R. 2002. A knock‐out mutation in allene oxide synthase results in male sterility and defective wound signal transduction in Arabidopsis due to a block in jasmonic acid biosynthesis. Plant Journal 31: 1–12. [DOI] [PubMed] [Google Scholar]
  68. Paul‐Victor C, Züst T, Rees M, Kliebenstein DJ, Turnbull LA. 2010. A new method for measuring relative growth rate can uncover the costs of defensive compounds in Arabidopsis thaliana . New Phytologist 187: 1102–1111. [DOI] [PubMed] [Google Scholar]
  69. Pauwels L, Barbero GF, Geerinck J, Tilleman S, Grunewald W, Perez AC, Chico JM, Bossche RV, Sewell J, Gil E et al 2010. NINJA connects the co‐repressor TOPLESS to jasmonate signalling. Nature 464: 788–791. [DOI] [PMC free article] [PubMed] [Google Scholar]
  70. Pauwels L, Goossens A. 2011. The JAZ proteins: a crucial interface in the jasmonate signaling cascade. Plant Cell 23: 3089–3100. [DOI] [PMC free article] [PubMed] [Google Scholar]
  71. Pauwels L, Morreel K, De Witte E, Lammertyn F, Van Montagu M, Boerjan W, Inze D, Goossens A. 2008. Mapping methyl jasmonate‐mediated transcriptional reprogramming of metabolism and cell cycle progression in cultured Arabidopsis cells. Proceedings of the National Academy of Sciences, USA 105: 1380–1385. [DOI] [PMC free article] [PubMed] [Google Scholar]
  72. Perez AC, Durand AN, Vanden Bossche R, De Clercq R, Persiau G, Van Wees SCM, Pieterse CMJ, Gevaert K, De Jaeger G, Goossens A et al 2014. The non‐JAZ TIFY protein TIFY8 from Arabidopsis thaliana is a transcriptional repressor. PLoS ONE 9: e84891. [DOI] [PMC free article] [PubMed] [Google Scholar]
  73. Pieterse CMJ, Leon‐Reyes A, Van der Ent S, Van Wees SCM. 2009. Networking by small‐molecule hormones in plant immunity. Nature Chemical Biology 5: 308–316. [DOI] [PubMed] [Google Scholar]
  74. Porra RJ, Thompson WA, Kriedemann PE. 1989. Determination of accurate extinction coefficients and simultaneous equations for assaying chlorophyll a and chlorophyll b extracted with four different solvents: verification of the concentration of chlorophyll standards by atomic absorption spectroscopy. Biochimica et Biophysica Acta 975: 384–394. [Google Scholar]
  75. Qi T, Huang H, Song S, Xie D. 2015a. Regulation of jasmonate‐mediated stamen development and seed production by a bHLH‐MYB complex in Arabidopsis. Plant Cell 27: 1620–1633. [DOI] [PMC free article] [PubMed] [Google Scholar]
  76. Qi T, Song S, Ren Q, Wu D, Huang H, Chen Y, Fan M, Peng W, Ren C, Xie D. 2011. The jasmonate‐ZIM‐domain proteins interact with the WD‐repeat/bHLH/MYB complexes to regulate jasmonate‐mediated anthocyanin accumulation and trichome initiation in Arabidopsis thaliana . Plant Cell 23: 1795–1814. [DOI] [PMC free article] [PubMed] [Google Scholar]
  77. Qi T, Wang J, Huang H, Liu B, Gao H, Liu Y, Song S, Xie D. 2015b. Regulation of jasmonate‐induced leaf senescence by antagonism between bHLH subgroup IIIe and IIId factors in Arabidopsis. Plant Cell 27: 1634–1649. [DOI] [PMC free article] [PubMed] [Google Scholar]
  78. Robson F, Okamoto H, Patrick E, Harris SR, Wasternack C, Brearley C, Turner JG. 2010. Jasmonate and phytochrome A signaling in Arabidopsis wound and shade responses are integrated through JAZ1 stability. Plant Cell 22: 1143–1160. [DOI] [PMC free article] [PubMed] [Google Scholar]
  79. Santner A, Calderon‐Villalobos LI, Estelle M. 2009. Plant hormones are versatile chemical regulators of plant growth. Nature Chemical Biology 5: 301–307. [DOI] [PubMed] [Google Scholar]
  80. Schweizer F, Fernández‐Calvo P, Zander M, Diez‐Diaz M, Fonseca S, Glauser G, Lewsey MG, Ecker JR, Solano R, Reymond P. 2013. Arabidopsis basic helix‐loop‐helix transcription factors MYC2, MYC3, and MYC4 regulate glucosinolate biosynthesis, insect performance, and feeding behavior. Plant Cell 25: 3117–3132. [DOI] [PMC free article] [PubMed] [Google Scholar]
  81. Shan X, Wang J, Chua L, Jiang D, Peng W, Xie D. 2011. The role of Arabidopsis Rubisco activase in jasmonate‐induced leaf senescence. Plant Physiology 155: 751–764. [DOI] [PMC free article] [PubMed] [Google Scholar]
  82. Shan XY, Zhang YS, Peng W, Wang ZL, Xie DX. 2009. Molecular mechanism for jasmonate‐induction of anthocyanin accumulation in Arabidopsis . Journal of Experimental Botany 60: 3849–3860. [DOI] [PubMed] [Google Scholar]
  83. Shang Y, Ma Y, Zhou Y, Zhang H, Duan L, Chen H, Zeng J, Zhou Q, Wang S, Gu W et al 2014. Biosynthesis, regulation, and domestication of bitterness in cucumber. Science 346: 1084–1088. [DOI] [PubMed] [Google Scholar]
  84. Sheard LB, Tan X, Mao HB, Withers J, Ben‐Nissan G, Hinds TR, Kobayashi Y, Hsu FF, Sharon M, Browse J et al 2010. Jasmonate perception by inositol‐phosphate‐potentiated COI1‐JAZ co‐receptor. Nature 468: 400–405. [DOI] [PMC free article] [PubMed] [Google Scholar]
  85. Shyu C, Figueroa P, DePew CL, Cooke TF, Sheard LB, Moreno JE, Katsir L, Zheng N, Browse J, Howe GA. 2012. JAZ8 lacks a canonical degron and has an EAR motif that mediates transcriptional repression of jasmonate responses in Arabidopsis . Plant Cell 24: 536–550. [DOI] [PMC free article] [PubMed] [Google Scholar]
  86. Song S, Qi T, Fan M, Zhang X, Gao H, Huang H, Wu D, Guo H, Xie D. 2013. The bHLH subgroup IIId factors negatively regulate jasmonate‐mediated plant defense and development. PLoS Genetics 9: e1003653. [DOI] [PMC free article] [PubMed] [Google Scholar]
  87. Staswick PE, Tiryaki I. 2004. The oxylipin signal jasmonic acid is activated by an enzyme that conjugates it to isoleucine in Arabidopsis. Plant Cell 16: 2117–2127. [DOI] [PMC free article] [PubMed] [Google Scholar]
  88. Suza WP, Staswick PE. 2008. The role of JAR1 in jasmonoyl‐L‐isoleucine production in Arabidopsis wound response. Planta 227: 1221–1232. [DOI] [PubMed] [Google Scholar]
  89. Thines B, Katsir L, Melotto M, Niu Y, Mandaokar A, Liu G, Nomura K, He SY, Howe GA, Browse J. 2007. JAZ repressor proteins are targets of the SCFCOI1 complex during jasmonate signalling. Nature 448: 661–665. [DOI] [PubMed] [Google Scholar]
  90. Thines B, Mandaokar A, Browse J. 2013. Characterizing jasmonate regulation of male fertility in Arabidopsis. Methods in Molecular Biology 1011: 13–23. [DOI] [PubMed] [Google Scholar]
  91. Thireault C, Shyu C, Yoshida Y, St Aubin B, Campos ML, Howe GA. 2015. Repression of jasmonate signaling by a non‐TIFY JAZ protein in Arabidopsis. Plant Journal 82: 669–679. [DOI] [PubMed] [Google Scholar]
  92. Vanholme B, Grunewald W, Bateman A, Kohchi T, Gheysen G. 2007. The tify family previously known as ZIM. Trends in Plant Science 12: 239–244. [DOI] [PubMed] [Google Scholar]
  93. Wager A, Browse J. 2012. Social network: JAZ protein interactions expand our knowledge of jasmonate signaling. Frontiers in Plant Science 3: 41. [DOI] [PMC free article] [PubMed] [Google Scholar]
  94. Wasternack C, Hause B. 2013. Jasmonates: biosynthesis, perception, signal transduction and action in plant stress response, growth and development. An update to the 2007 review in Annals of Botany. Annals of Botany 111: 1021–1058. [DOI] [PMC free article] [PubMed] [Google Scholar]
  95. Xie DX, Feys BF, James S, Nieto‐Rostro M, Turner JG. 1998. COI1: an Arabidopsis gene required for jasmonate‐regulated defense and fertility. Science 280: 1091–1094. [DOI] [PubMed] [Google Scholar]
  96. Yadav V, Mallappa C, Gangappa SN, Bhatia S, Chattopadhyay S. 2005. A basic helix‐loop‐helix transcription factor in Arabidopsis, MYC2, acts as a repressor of blue light‐mediated photomorphogenic growth. Plant Cell 17: 1953–1966. [DOI] [PMC free article] [PubMed] [Google Scholar]
  97. Yan Y, Stolz S, Chetelat A, Reymond P, Pagni M, Dubugnon L, Farmer EE. 2007. A downstream mediator in the growth repression limb of the jasmonate pathway. Plant Cell 19: 2470–2483. [DOI] [PMC free article] [PubMed] [Google Scholar]
  98. Yan J, Zhang C, Gu M, Bai Z, Zhang W, Qi T, Cheng Z, Peng W, Luo H, Nan F et al 2009. The Arabidopsis CORONATINE INSENSITIVE1 protein is a jasmonate receptor. Plant Cell 21: 2220–2236. [DOI] [PMC free article] [PubMed] [Google Scholar]
  99. Yang DL, Yao J, Mei CS, Tong XH, Zeng LJ, Li Q, Xiao LT, Sun TP, Li JG, Deng XW et al 2012. Plant hormone jasmonate prioritizes defense over growth by interfering with gibberellin signaling cascade. Proceedings of the National Academy of Sciences, USA 109: 1192–1200. [DOI] [PMC free article] [PubMed] [Google Scholar]
  100. Yoshida Y, Sano R, Wada T, Takabayashi J, Okada K. 2009. Jasmonic acid control of GLABRA3 links inducible defense and trichome patterning in Arabidopsis . Development 136: 1039–1048. [DOI] [PubMed] [Google Scholar]
  101. Yu N, Nützmann HW, MacDonald JT, Moore B, Field B, Berriri S, Trick M, Rosser SJ, Kumar SV, Freemont PS et al 2016. Delineation of metabolic gene clusters in plant genomes by chromatin signatures. Nucleic Acids Research 44: 2255–2265. [DOI] [PMC free article] [PubMed] [Google Scholar]
  102. Zhai Q, Zhang X, Wu F, Feng H, Deng L, Xu L, Zhang M, Wang Q, Li C. 2015. Transcriptional mechanism of jasmonate receptor COI1‐mediated delay of flowering time in Arabidopsis. Plant Cell 27: 2814–2828. [DOI] [PMC free article] [PubMed] [Google Scholar]
  103. Zhang F, Ke J, Zhang L, Chen R, Sugimoto K, Howe GA, Xu HE, Zhou M, He SY, Melcher K. 2017. Structural insights into alternative splicing‐mediated desensitization of jasmonate signaling. Proceedings of the National Academy of Sciences, USA 114: 1720–1725. [DOI] [PMC free article] [PubMed] [Google Scholar]
  104. Zhang Y, Turner J. 2008. Wound‐induced endogenous jasmonates stunt plant growth by inhibiting mitosis. PLoS ONE 3: e3699. [DOI] [PMC free article] [PubMed] [Google Scholar]
  105. Zhang F, Yao J, Ke J, Zhang L, Lam VQ, Xin X‐F, Zhou XE, Chen J, Brunzelle J, Griffin PR et al 2015. Structural basis of JAZ repression of MYC transcription factors in jasmonate signalling. Nature 525: 269–273. [DOI] [PMC free article] [PubMed] [Google Scholar]
  106. Zhao Y, Thilmony R, Bender CL, Schaller A, He SY, Howe GA. 2003. Virulence systems of Pseudomonas syringae pv. tomato promote bacterial speck disease in tomato by targeting the jasmonate signaling pathway. Plant Journal 36: 485–499. [DOI] [PubMed] [Google Scholar]
  107. Zheng XY, Spivey NW, Zeng W, Liu PP, Fu ZQ, Klessig DF, He SY, Dong X. 2012. Coronatine promotes Pseudomonas syringae virulence in plants by activating a signaling cascade that inhibits salicylic acid accumulation. Cell Host & Microbe 11: 587–596. [DOI] [PMC free article] [PubMed] [Google Scholar]
  108. Zhu X, Chen J, Xie Z, Gao J, Ren G, Gao S, Zhou X, Kuai B. 2015. Jasmonic acid promotes degreening via MYC2/3/4‐ and ANAC019/055/072‐mediated regulation of major chlorophyll catabolic genes. Plant Journal 84: 597–610. [DOI] [PubMed] [Google Scholar]
  109. Züst T, Agrawal AA. 2017. Trade‐offs between plant growth and defense against insect herbivory: an emerging mechnistic synthesis. Annual Review of Plant Biology 68: 513–534. [DOI] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Please note: Wiley Blackwell are not responsible for the content or functionality of any Supporting Information supplied by the authors. Any queries (other than missing material) should be directed to the New Phytologist Central Office.

Fig. S1 jazQ mycT and myc2345 pedigrees.

Fig. S2 sjq10 and sjq66 carry suppressor mutations in JA biosynthesis and signaling genes.

Fig. S3 JA responsiveness and rosette growth phenotypes of mycT and myc2345.

Fig. S4 Leaf chlorophyll concentrations are comparable among Col‐0, jazQ, mycT and jazQ mycT in the absence of exogenous JA.

Fig. S5 Number of genes up‐ and down‐regulated in jazQ, mycT, and jazQ mycT relative to Col‐0.

Fig. S6 JAZs and MYCs regulate the expression of genes associated with glucosinolate biosynthesis.

Fig. S7 JAZs regulate the expression of genes associated with glucosinolate hydrolysis in manner independent of MYCs.

Fig. S8 Increased accumulation of photosynthesis‐associated mRNAs in mycT.

Fig. S9 Loss of MYC2/3/4 increases photosynthetic rate.

Fig. S10 Transcript levels of FT correspond with flowering time in higher order jazQ mutants.

Table S1 Primers for genotyping jaz and myc mutants

Click here for additional data file. (450.9KB, pdf)

Table S2 RNAseq analysis performed on WT, jazQ, mycT and jazQ mycT seedlings

Click here for additional data file. (6.3MB, xlsx)

Articles from The New Phytologist are provided here courtesy of Wiley

RESOURCES