Abstract
Steroidal glycoalkaloids (SGAs) are cholesterol-derived molecules produced by solanaceous species. They contribute to pathogen defence but are toxic to humans and considered as anti-nutritional compounds. Here we show that GLYCOALKALOID METABOLISM 9 (GAME9), an APETALA2/Ethylene Response Factor, related to regulators of alkaloid production in tobacco and Catharanthus roseus, controls SGA biosynthesis. GAME9 knockdown and overexpression in tomato and potato alters expression of SGAs and upstream mevalonate pathway genes including the cholesterol biosynthesis gene STEROL SIDE CHAIN REDUCTASE 2 (SSR2). Levels of SGAs, C24-alkylsterols and the upstream mevalonate and cholesterol pathways intermediates are modified in these plants. Δ(7)-STEROL-C5(6)-DESATURASE (C5-SD) in the hitherto unresolved cholesterol pathway is a direct target of GAME9. Transactivation and promoter-binding assays show that GAME9 exerts its activity either directly or cooperatively with the SlMYC2 transcription factor as in the case of the C5-SD gene promoter. Our findings provide insight into the regulation of SGA biosynthesis and means for manipulating these metabolites in crops.
Steroidal glycoalkaloids (SGAs) accumulate in solanaceous plants and contribute to plant defence but are toxic to humans. Here the authors show that the GAME9 transcription factor is a regulator of the SGA biosynthetic pathways providing a potential way to manipulate SGA levels in crops.
Steroidal alkaloids (SAs) and their glycosylated forms (steroidal glycoalkaloids; SGAs) are nitrogen-containing toxic compounds occurring primarily in the Solanaceae and Liliaceae plant families1. This class of metabolites is produced in Solanaceae vegetable crops such as potato, tomato and eggplant. Although SGAs contribute to plant resistance to a wide range of pathogens and predators, including bacteria, fungi, oomycetes, viruses, insects and animals2, some are considered as anti-nutritional compounds to humans due to their toxic effects3,4.
In potato, α-chaconine and α-solanine comprise >90% of the total SGA content in the tubers. Nevertheless over 50 different SAs have been identified in a variety of potato wild species and commercial cultivars5,6. In tomato, α-tomatine and dehydrotomatine are the major SGAs in green tissues, while esculeosides are predominant in the red ripe fruit7,8,9. About 100 SAs have been reported in different tissues and developmental stages of tomato8,10,11,12. Explored to a lesser extent, α-solasonine and α-solamargine are the two major SGAs found in eggplant13,14. Early studies of SGA biosynthesis in potato reported on the characterization of three glycosyltransferases (SGT1, SGT2 and SGT3) that are involved in the addition of sugar moieties on the aglycone solanidine, leading to specific synthesis of either α-solanine or α-chaconine15,16,17,18. In tomato, the first gene reported in the synthesis of SGAs was the potato SGT1 homolog, GLYCOALAKLOID METABOLISM 1 (GAME1), which adds a galactose to the aglycone tomatidine8.
Recently, Itkin et al.5 reported a set of GLYCOALKALOID METABOLISM (GAME) genes that participate in the core pathway producing SGAs in both potato and tomato. Consequently, an elaborated pathway for SGA biosynthesis in the Solanaceae family, starting from the precursor cholesterol up to the SGAs, was proposed5. Extensive functional characterization suggested that cholesterol undergoes several hydroxylation, oxidation, transamination and glycosylation steps to generate SGAs. The GAME genes were found to be located physically close to each other in the genome and thus organized in a form of metabolic gene clusters. In tomato six GAME genes are positioned in a cluster on chromosome 7, whereas two other neighboring genes on chromosome 12. Furthermore, three additional genes, encoding cytochrome P450s (P450s), not belonging to these clusters, were also associated with SGA biosynthesis (GAME7, GAME8a and GAME8b). In potato, four SGA-related genes are located on chromosome 7 and two on chromosome 12. In tomato, the GAME genes include P450s [GAME7, GAME8a, GAME8b, GAME6 (chromosome 7 cluster) and GAME4 (chr. 12)], a dioxygenase (GAME11; chr. 7) involved in the hydroxylation and oxidation of the cholesterol skeleton and a transaminase protein (GAME12; chr. 12) required for the incorporation of the nitrogen atom into the SA aglycone. Finally, glycosyltransferases (GAME1, GAME17, GAME18 and GAME2; chr. 7) required for generating the sugar moieties that decorate the SA aglycone were also among the clustered genes.
Cholesterol, produced through the cytosolic isoprenoid mevalonate pathway is a key precursor in the biosynthesis of SGAs. In sharp contrast to other kingdoms, the pathway leading to cholesterol biosynthesis in plants is only partially understood. Very recently, research related to SGA biosynthesis advanced our knowledge regarding the pathway to cholesterol formation in SGA-producing Solanaceae species. Sawai et al.19 demonstrated that STEROL SIDE CHAIN REDUCTASE 2 (SSR2) exhibits Δ24(25) reductase activity that converts cycloartenol to cycloartanol in the first committed step towards cholesterol formation. Hence, SSR2 directs the pathway towards cholesterol and SAs instead of alkylated sterol biosynthesis19. On the other hand, STEROL METHYLTRANSFERASE1 (SMT1) directs the pathway towards C-24 alkylsterols by adding a methyl group at the C-24 position of the cycloartenol side chain20. Overexpression of a soybean SMT1 in potato plants therefore increased the metabolic flux of cycloartenol into alkylated sterols at the expense of cholesterol21.
In contrast to the intense research related to structural genes of the pathway, the transcriptional regulation of SGA biosynthesis and its cholesterol precursor pathway is utterly unclear. Some transcription factors have been identified that regulate the biosynthesis of other classes of alkaloids in different plant species22,23,24,25,26,27,28,29 such as the one represented by the APETALA2/Ethylene Response Factors (AP2/ERF) family members. The AP2/ERF transcription factor ORCA3 regulates the biosynthesis of terpenoid indole alkaloids (TIAs) in Catharanthus roseus22. ORCA3 gene expression is induced by jasmonate and is regulated by direct binding of the basic helix-loop-helix (bHLH) transcription factor CrMYC2 to the ORCA3 gene promoter30. Close homologs of ORCA3 in Nicotiana tabacum present in the NIC2 locus were associated with nicotine levels in the tobacco leaf and have been used extensively in breeding of low-nicotine tobacco lines31. Specifically, the NIC2 locus comprises at least seven ERF transcription factors that regulate the expression of structural genes in the biosynthesis of nicotine. In the nic2 mutant, this ERF gene cluster is deleted, resulting in a low-nicotine phenotype24. Genes present in the NIC2 locus include ERF189 and ERF221 (also known as ORC1 (ref. 23)). Overexpression of ERF189 and ERF221/ORC1 was sufficient to stimulate nicotine biosynthesis in tobacco plants24,26. Members of the ERF family of transcription factors can recognize different GC-rich boxes in the promoters of target genes activating their transcription32,33.
In this study, we identified GLYCOALKALOID METABOLISM 9 (GAME9), an AP2/ERF transcription factor that regulates the biosynthesis of steroidal alkaloids in Solanaceae plants. We found that GAME9 is part of an ERF-gene cluster existing in potato and tomato. Transactivation and promoter binding assays as well as transgenic tomato and potato plants revealed that GAME9 controls SGA biosynthesis as well as several upstream mevalonate and cholesterol precursor pathway genes. Furthermore, GAME9 exerts its activity either directly or through co-binding with the SlMYC2 transcription factor to promoters of downstream target genes. These findings provide insight into the transcriptional regulation of SGAs in Solanaceae plants as well as a base for engineering these anti-nutritional compounds in plants.
Results
Initial evidence of GAME9 association with SGA biosynthesis
In a previous study, we discovered an AP2/ERF type transcription factor displaying a similar expression pattern to the GAME1 and GAME4 genes of the tomato and potato SGA biosynthetic pathway (both GAME genes used as baits in co-expression analysis)5. To examine the possible association of this regulator (termed GLYCOALKALOID METABOLISM 9; GAME9) in the control of SGA biosynthesis, we carried out combined co-expression analysis using potato and tomato transcriptome data (see Methods for details on co-expression analysis). A total of 1,260 and 168 genes were co-expressed with GAME9 in tomato (SlGAME9) and potato (StGAME9), respectively (Fig. 1; Supplementary Data 1). Thirty seven homologous genes were co-expressed with GAME9 in both potato and tomato (Fig. 1a; Supplementary Table 1). Among the co-expressed genes, we found all those previously associated with SGA biosynthesis in potato (i.e., GAME2, GAME11, GAME6, GAME1, GAME12 and GAME4) and tomato (GAME11, GAME6, GAME17, GAME1, GAME18, GAME12 and GAME4) (Fig. 1a). Genes encoding HMGR and SQS34,35, involved in the synthesis of isoprenoid precursors in the mevalonate pathway, were not co-expressed with GAME9 in either species (Supplementary Data 1). Interestingly, the phytosterols and cholesterol biosynthesis related genes CYCLOARTENOL SYNTHASE (CAS) and SSR2 were co-expressed with GAME9 in tomato (r-value≥0.73) while only SSR2 was co-expressed with the potato GAME9 gene (Supplementary Data 1). When examined across 19 different tomato tissue types, SlGAME9 was highly expressed in leaf and flower buds. In fruit tissues, it was expressed early, predominantly in the immature stages of development (Fig. 1b) while displaying some, albeit relatively low level of expression in petals and root tissues. The expression pattern of SlGAME9 was analyzed using RNA in situ hybridization. In 13-day-old tomato shoots, SlGAME9 was expressed in both young leaves and throughout the vascular system. SlGAME9 expression was also detected in mature leaves, mostly in the outer epidermis layer of the blade (Fig. 1c).
GAME9 lies within a QTL previously linked to SGA content
Identification of QTLs linked to total SGA content in potato tubers has been of high interest in breeding of new potato cultivars. Sørensen et al.36 reported a highly significant QTL on chromosome 1 that explained a major proportion of the SGA content in potato tubers (both in dark and light exposed tubers). Considering that GAME9 is located on chromosome 1 (Solyc01g090340 and PGSC0003DMG400025989, in tomato and potato, respectively), we suspected that it might be associated with this earlier reported QTL region. The potato QTL was flanked by the simple sequence repeat (SSR) markers STM5136 and STM2030 (ref. 36). Using these markers and the Comparative Map Viewer and Genome Browser tools available in The Sol Genomics Network (SGN, http://solgenomics.net), we identified the corresponding chromosomal region spanning 6.6 Mbp on chromosome 1 of tomato [between markers TG21 and TG59 (Fig. 2a)]. In both species, GAME9 was located inside these QTL regions, and moreover, as part of a cluster of AP2/ERF transcription factors. In potato, a cluster spanning ∼230 kilobase pair (kbp) genomic region includes GAME9 together with seven GAME9-like transcription factors, whereas in tomato, a region of ∼104 kbp contains GAME9 and additionally four GAME9-like genes (Fig. 2b).
Phylogenetic analysis showed that GAME9 and GAME9-like proteins are part of the ERF IXa subfamily37 divided earlier by Shoji et al.24 into two separate clades. GAME9 and the GAME9-like proteins are part of clade 2 that includes the tobacco NIC2 locus protein ERF189 involved in the synthesis of the pyridine alkaloid nicotine. The same clade also includes ORCA3 and ORCA2, both transcription factors involved in the synthesis of TIAs in C. roseus22,38 (Fig. 2c). Two other members of the ERF IXa subfamily clade 2 are also involved in the control of nicotine biosynthesis, namely, the tobacco ERF221 (ORC1)23 and the Nicotiana benthamiana ERF125. Thus, GAME9 represents a potential third case in which proteins of this clade control the biosynthesis of different classes of alkaloids.
Altering GAME9 expression impacts the levels of major SGAs
To provide additional evidence regarding the role of GAME9 in SGA biosynthesis, we generated transgenic tomato lines in which GAME9 was silenced (GAME9-RNAi) or overexpressed (GAME9-Ox). Transgenic potato lines overexpressing GAME9 were also generated. Real-Time PCR analysis in leaves showed GAME9 expression was significantly higher in GAME9-Ox lines from potato and tomato, and was decreased in the GAME9-RNAi tomato lines (Fig. 3a,b). SGAs profiling was carried out on extracts of tomato and potato leaves, skin of potato tubers and tomato fruits by Liquid Chromatography Mass Spectrometry (LC-MS). In leaves of potato GAME9-Ox lines, the levels of α-solanine and α-chaconine increased between 3.5–4.6 fold and 2.8–4.2 fold, respectively as compared to leaves of wild-type plants (Fig. 3c). Likewise, in tuber skin isolated from the same potato lines, we detected an increase in α-solanine levels (up to 1.2–2.6 fold) and α-chaconine (up to 1.2–2.1 fold) (Fig. 3e). In tomato leaves, the levels of α-tomatine and dehydrotomatine were significantly increased (2.4–3 fold and 2.1–2.7 fold, respectively) in GAME9-Ox lines, whereas in GAME9-RNAi lines there was a reduction in the levels of α-tomatine (21–32 fold) and dehydrotomatine (13–21 fold) as compared to wild-type plants (Fig. 3d). Similarly, in green fruit from the same tomato lines, there was an increase in α-tomatine (2.1–5.7 fold) and dehydrotomatine (2.2–6.1 fold) in GAME9-Ox lines and a reduction in α-tomatine (45–47 fold) and dehydrotomatine (37–50 fold) in GAME9-RNAi lines compared to wild-type tomato plants (Fig. 3f).
Impact on the mevalonate pathway and its branches
We envisaged that regulation of SGA content by GAME9 is achieved, at least partially, by regulating the flux through the mevalonate pathway and its branches. These include C-24 alkylated phytosterols (e.g., campesterol and β-sitosterol), non-alkylated sterols (primarily cholesterol, which is the precursor for SGA biosynthesis), and the triterpenoid branch. Gas Chromatography Mass Spectrometry (GC–MS) was employed to profile the various metabolic intermediates in leaves of the four potato GAME9-Ox lines. Overexpression of GAME9 in potato resulted in a significant decrease in levels of cycloartenol and cycloartanol, early intermediates in cholesterol biosynthesis (Fig. 4). Cholesterol itself showed a slight, but significant increase in leaves of the GAME9-Ox lines (Fig. 4). Interestingly, β-amyrin and campesterol contents were also increased, yet, β-sitosterol was detected in levels similar to those in leaves of wild-type plants (Fig. 4). These observations point to increased flux to cholesterol, the triterpene β-amyrin as well as to a certain part of phytosterol biosynthesis (i.e., campesterol) due to GAME9 overexpression.
Similarly, in tomato we detected altered sterol composition when GAME9 was either overexpressed or downregulated (Fig. 5). For instance, in GAME9-Ox lines there was a significant increase in β-amyrin level. On the other hand, GAME9-RNAi lines had an increase in cycloartenol, cholesterol and β-sitosterol content (Fig. 5). Campesterol did not show any significant differences in GAME9-altered plants compared to wild-type.
Gene expression analysis in plants misexpressing GAME9
We used quantitative Real-Time PCR (qRT-PCR) to examine the expression level of SGA biosynthetic genes and those in the mevalonate and downstream pathways (towards triterpenoids, phytosterol and cholesterol biosynthesis) in the GAME9 altered plants. In potato, GAME9 overexpression did not change the expression of genes involved in the upper mevalonate pathway (i.e., HMGR, SQS)34,35, β-amyrin (the potato homolog of TRITERPENOID SYNTHASE 1, TTS1 (ref. 39)) and campesterol/β-sitosterol (SMT1) (Fig. 6; Supplementary Table 2). However, genes acting downstream to 2,3-oxidosqualene, towards the formation of sterols, including CAS, SSR2 and C5-SD, were upregulated in the GAME9-Ox potato lines. Similarly, in the same lines, the GAME genes responsible for the synthesis of the solanidine aglycone (GAME11, GAME6, GAME4 and GAME12) and the subsequent glycosylation (GAME1, GAME2 and SGT2) were all significantly upregulated (Fig. 6; Supplementary Table 2).
In tomato, we found that when GAME9 was either silenced or overexpressed, expression of HMGR, CAS, SSR2 and C5-SD was significantly altered. However, expression of TTS1 and TTS2 (ref. 39) involved in the triterpene β-amyrin formation was not affected. Altered expression of GAME9 did not affect SQS but upregulated SMT1 expression (Fig. 7; Supplementary Table 3). Finally, 7 out of 8 examined GAME genes involved in the synthesis of the SGA aglycone tomatidine and its glycosylation were altered in expression, at all times correlating with the GAME9 transcript levels in tomato leaf tissues (Fig. 7).
Transcriptome changes in GAME9-Ox and GAME9-RNAi lines
To obtain a more global picture of genes that are downstream of GAME9 and to understand more precisely the metabolic pathways under its control, we performed RNA-sequencing (RNA-Seq) in leaf tissue of GAME9-RNAi and GAME9-Ox tomato lines and wild-type. Transcriptome analysis was also conducted on leaves of potato lines overexpressing GAME9 and wild-type ones. Silencing of GAME9 in tomato resulted in 931 genes that were downregulated [fold change log2 (RNAi/WT)<−0.5; Supplementary Data 2]. When GAME9 was overexpressed, 1,002 genes were upregulated in tomato [fold change log2 (Ox/WT)>0.5]. GAME9 overexpression in potato, led to upregulation of 1,829 genes [fold change log2 (Ox/WT) >0.5; Supplementary Data 2].
A concise set of 27 genes (including GAME9) was found in common between the down- and upregulated genes in the GAME9-RNAi and GAME9-Ox tomato lines, respectively (Supplementary Table 4). Among these, we found a significant representation of SGA biosynthetic genes (GAMEs), explicitly those located in the metabolic gene cluster in tomato chromosome 7 (GAMEs 1, 6, 11, 17 and 18; Supplementary Fig. 1). This gene set also contained an additional gene in the SGAs cluster on chromosome 7, a sequence with homology to cellulose synthase family proteins (Solyc07g043390). The CELLULOSE SYNTHASE LIKE transcript was also found to be significantly co-expressed with GAME9 in both tomato and potato (Fig. 1; Supplementary Table 1). Four genes out of the 27 could be associated with sterol metabolism, possibly phytosterol or cholesterol biosynthesis20 (Supplementary Table 4). Recent work reported one of the four genes, namely SSR2, a sterol side chain reductase catalyzing the first committed step towards cholesterol formation in the Solanaceae19 (the conversion of cycloartenol to cycloartanol; Fig. 6). The three additional genes include homologs of a Δ(7)-STEROL-C5(6)-DESATURASE (C5-SD), METHYLSTEROL MONOOXYGENASE 2-2-LIKE (SMO1) and a 3-β-HYDROXYSTEROID DEHYDROGENASE (OXR) (Supplementary Table 4). Out of these 4 sterol metabolism associated genes, SSR2 was co-expressed with GAME9 in both potato and tomato, while the other three (i.e., C5-SD, SMO1 and OXR) were significantly co-expressed with the GAME9 transcript in tomato (Fig. 1). Finally, among the 27 genes set we found a homolog of the E3 UBIQUITIN-PROTEIN LIGASE RMA1H1-LIKE. Apart from being significantly co-expressed with GAME9 (Supplementary Data 1), this gene is related to an ERAD-type RING membrane-anchor E3 ubiquitin ligase reported to control the activity of 3-hydroxy-3-methylglutaryl-CoA reductase (HMGR)40, the rate-limiting enzyme in the mevalonate pathway leading to cholesterol and subsequently SGAs formation.
A set of 466 genes was found in common between the upregulated genes in the GAME9-Ox tomato and potato lines (Supplementary Data 2). Among them, we found represented GAME genes located on chromosome 7 both in potato and tomato (GAMEs 1, 6 and 11 and CELLULOSE SYNTHASE LIKE). The SSR2, C5-SD, SMO1 and the E3 UBIQUITIN-PROTEIN LIGASE RMA1H1-LIKE were also among the genes upregulated in both the potato and tomato overexpression lines (Supplementary Data 2).
GAME9 and SlMYC2 act synergistically in gene transactivation
To study the GAME9 transactivation capacity of putative target genes upstream regions, we performed transient luciferase expression assays in tobacco protoplasts. Altogether, we assayed a total of 12 different putative promoter regions (ranging in size from 1200 to 2700, bp) of known tomato SGA genes and those involved in the mevalonate and cholesterol precursor pathways (Supplementary Table 5). In this assay GAME9 did not transactivate the putative promoter regions of any of the core SGA pathway GAME genes acting in between cholesterol and α-tomatine (Fig. 8a). Nevertheless, transactivation was clearly detected for the promoter of the gene C5-SD, putatively involved in the synthesis of cholesterol (Fig. 8a; Supplementary Fig. 2). These experiments indicated that GAME9 likely requires additional factors to control SGA production.
In tobacco, both MYC2 and ERF transcription factors are involved in the regulation of nicotine biosynthesis genes24,26,41,42. MYC2 was shown to directly bind G-box sequences in the promoters of several nicotine biosynthesis genes and to activate these genes additively with ERF189 (ref. 41). In Catharanthus roseus, CrMYC2 was shown to regulate TIA biosynthesis by directly binding to the ORCA3 promoter30. Since G-box or G-box-like motifs could be detected in the putative promoters of several of the GAME and putative cholesterol genes, we investigated the potential additive role of SlMYC2 in the regulation of SGA biosynthesis. To this end, we cloned the tomato MYC2 (Solyc08g076930) homolog and performed additional transfection assays in tobacco protoplasts, in which SlMYC2 and GAME9 were combined to assess transactivation of a subset of five SGA biosynthesis gene promoters containing or lacking G- and/or GCC-box sequences, required for the binding of the SlMYC2 and GAME9 proteins, respectively (Supplementary Figs 3 and 4).
These assays demonstrated that SlMYC2 alone was capable to transactivate the C5-SD gene promoter (ProC5-SD) (Fig. 8b). More importantly however, a synergistic effect was observed when GAME9 was combined with SlMYC2, observed with the promoters of C5-SD, GAME4, GAME7 and HMGR1 pointing to a cooperative action of these two transcription factors in the regulation of SGA biosynthesis. This was further supported by the observation that SlMYC2 alone, in contrast to GAME9, could also mildly transactivate ProGAME4, and that with the combination of the two transcription factors, again a synergistic transactivation of ProGAME4 was achieved (Fig. 8b). The promoters of HMGR1 and GAME7 were not transactivated by GAME9 or SlMYC2 alone, whereas a significant but slight (less than 1.5-fold) synergistic transactivation effect of the combination of GAME9 and SlMYC2 could be observed (Fig. 8b). The promoter of SSR2 was not transactivated by either transcription factor alone or the combination thereof (Fig. 8b).
Analysis of the 1,550 bp promoter sequence of C5-SD revealed the presence of a G-box and three GCC-rich motifs (Fig. 8c, Supplementary Fig. 3). To determine if these boxes are important for the transactivation of ProC5-SD, we generated a series of promoter deletion constructs and assessed their transactivation by GAME9 and/or SlMYC2 in tobacco protoplasts (Fig. 8c, Supplementary Fig. 3 and Supplementary Table 6). Thereby we could pinpoint a 97-nt promoter region (C5-SD d9) sufficient for transactivation by GAME9 and SlMYC2 that contains both the G-box and a putative GCC-box. To further substantiate the importance of the G- and GCC-boxes, we created ProC5-SD constructs in which either one or both boxes were mutated. As expected, mutation of the 6-bp CACGTG motif of the G-box into ATGTGA was sufficient to impede promoter transactivation (Fig. 8c). Unexpectedly however, mutation of the 10-bp AGCCTGCCAC motif of the putative GCC-box into GATTACAGTC did not interfere with transactivation by GAME9 and SlMYC2. This observation indirectly correlates with the apparent absence of a GCC-motif in the ProGAME4 sequence (Supplementary Fig. 4), which could nonetheless be transactivated by combining SlMYC2 and GAME9.
Electrophoretic mobility shift assays (EMSA) were further performed to determine the in vitro binding of GAME9 to its putative binding sites in C5-SD and SSR2 promoters. We tested the GCC-boxes found in both promoters and compared to the binding of probes where these boxes were mutated (Fig. 8d, Supplementary Table 7). When incubated with the GAME9 protein, probes derived from both promoters (containing GCC-boxes) showed retarded bands, suggesting the formation of GAME9—DNA complexes (Fig. 8d). Furthermore, SlMYC2 protein bound to the G-box present in the promoter of C5-SD. When this G-box was mutated the binding was impaired (Fig. 8d, Supplementary Table 7).
Characterization of the C5-STEROL DESATURASE
Virus induced gene silencing (VIGS) was subsequently employed for functional characterization of one of the four candidate cholesterol biosynthesis genes (C5-SD). Real-Time PCR analysis in leaves and fruit showed C5-SD expression was significantly reduced in VIGS-silenced plants (Fig. 9). Analysis of the C5-SD-silenced leaf and green fruit tissues of tomato showed a significant decrease in levels of α-tomatine. We anticipated that C5-SD could be catalyzing the conversion of cholesta-7-enol to 7-dehydrocholesterol in the cholesterol pathway20. Indeed, C5-SD silenced leaves showed accumulation of the predicted C5-SD cholesta-7-enol substrate while cholesterol and α-tomatine content was significantly reduced (Fig. 9). Levels of cycloartenol and the C-24 alkylated phytosterols intermediates, 24-methylenecycloartanol and isofucosterol were increased, whereas β-amyrin content was decreased in leaves. The decrease in β-amyrin levels in C5-SD silenced leaves is difficult to explain and might be through yet undescribed post-transcriptional control mechanism in triterpenoid biosynthesis.
In order to provide further evidence for C5-SD enzymatic activity, we performed yeast complementation assays. In Saccharomyces cerevisiae, the desaturase enzymatic activity is carried out by ERG3, which catalyzes the C5(6) desaturation of episterol to ergosta-5,7,24(28)-trienol in the synthesis of ergosterol, the main yeast sterol43. As cholesterol contains a C5-C6 double bond, a C5(6) desaturase would be required for its biosynthesis. To assess whether the tomato C5-SD was able to carry out this enzymatic reaction, we introduced the gene in a yeast erg3 null strain, in which a kanamycin cassette replaced the native ERG3 gene. S. cerevisiae erg3 null mutants are viable, but are unable to synthesize ergosterol43. GC–MS analysis of organic extracts of the yeast erg3 null strain confirmed its inability to accumulate ergosterol (Supplementary Fig. 5a). However, when expressing the tomato C5-SD, the ergosterol synthesis capacity of the erg3 null strain was repaired (Supplementary Fig. 5a and b); indicating that C5-SD like ERG3, has the capacity to introduce a C5-C6 double bond into episterol (Supplementary Fig. 5c).
Discussion
Alkaloids represent one of the three major classes of plants specialized (or secondary) metabolites with more than 20,000 reported in thousands of species to date44. The steroidal alkaloids produced by most members of the Solanum genus in the Solanaceae family are known primarily due to the toxicity of the major potato metabolites α-chaconine and α-solanine to mammals. To date, the research of SGAs was focused on structure elucidation, composition in different species and unraveling their biosynthetic pathway5,6,8,10,16,17,18,45. In this study, we identified an AP2/ERF-type transcription factor, which regulates the biosynthesis of steroidal alkaloids in tomato and potato, and likely in other Solanaceae plants producing SGAs (e.g., eggplant). It appears that GAME9 belongs to a separate clade of AP2/ERF transcription factors together with proteins regulating the biosynthesis of distinct alkaloid classes in other species namely, the pyridine alkaloid nicotine in tobacco and TIAs in C. roseus. This raises thought-provoking questions regarding the specificity of transcriptional regulation of alkaloids in plants and its molecular evolution (discussed below).
As in the case of its homolog ERF189 located in the NIC2-locus in Nicotiana tabacum, the potato and tomato GAME9 genes are positioned inside a cluster of similar, GAME9-like genes. In the tobacco NIC2 locus, seven highly similar ERF genes were shown to regulate the expression of structural genes involved in nicotine biosynthesis24. When these ERFs genes were used to rescue nicotine content in a nic2 background, they showed some functional redundancy. However, ERF189 was able to recover nicotine content to the wild-type levels24. Similarly, it appears that ORCA3, involved in regulation of the TIA biosynthesis, is also positioned inside a cluster of similar genes46. As we did not investigate the GAME9-like proteins, we cannot exclude functional redundancy between cluster members. Yet, GAME9 was the only gene in this cluster that was co-expressed with other SGA genes and is thus likely to play a key role in the regulation of SGAs in both tomato and potato. Noticeably, in both species, only GAME9 and not the GAME9-like proteins have a serine-rich C-terminal domain (Supplementary Fig. 6). This domain was found to have a regulatory function in the Catharanthus roseus ORCA3 protein47 and could therefore serve to locate GAME9 primary homologs in different species. Nevertheless, while the Catharanthus roseus47 ORCA2 does not possess the serine-rich domain it was demonstrated to have an overlapping role with ORCA3. This suggests that the lack of the serine-rich domain in the potato and tomato GAME9-like genes does not exclude their possible function in the control of SGA biosynthesis.
The precursor for SGA biosynthesis is cholesterol, which undergoes several hydroxylation, oxidation, transamination and glycosylation steps to generate the SGA chemical diversity3,5,48. While still far from being resolved, cholesterol biosynthesis in plants is predicted to be a multi-step branch from cycloartenol. Recently, the first committed enzyme in the cholesterol pathway, SSR2, was described in potato and tomato19. Several studies demonstrated the tight crosstalk between the cholesterol and C-24 alkylsterol pathways in SGA-producing plants19,21,35. The SSR2 reaction is therefore a junction for controlling fluxes towards cholesterol and downstream to SGA biosynthesis. The enzyme SMT1, catalyzing the alternate branching reaction in which cycloartenol is trans-methylated to 24-methylenecycloartanol, is not less important in maintaining the balance between the two pathways21. Apart from SSR2, three additional genes including homologs of those encoding a C5-SD, SMO1 and an OXR could be associated with cholesterol biosynthesis as their expression was affected very significantly in the tomato GAME9-altered transgenic lines. Our results showed that GAME9 is most likely involved in regulating C5-SD but is not associated with SMT1 expression. Although we detected a significant increase in levels of the triterpenoid β-amyrin in potato leaves overexpressing GAME9, the transcript level of TTS1 was not altered. This suggests either a different gene associated with β-amyrin biosynthesis in potato or a post-transcriptional mechanism for TTS1 activation.
Functional characterization by VIGS and yeast complementation assays, showed that C5-SD is an additional, currently the second enzyme reported to be involved in the cholesterol biosynthetic pathway. The desaturation reaction catalyzed by C5-SD is specific for the non-alkylated sterols branch, as shown by the accumulation of the cholesta-7-enol intermediate and decrease of cholesterol and α-tomatine. We speculate that there might be a different C5-SD paralog catalyzing the desaturation of C-24 alkylsterol intermediates leading to the biosynthesis of campesterol and β-sitosterol. Similarly Sawai et al.19 reported two paralogs, SSR2 and SSR1 involved in the biosynthesis of cholesterol and C-24 alkylsterols, respectively.
It appears that genes encoding enzymes in the mevalonate pathway, upstream of the SSR2-SMT1 branch point, are also under some level of control by the GAME9 transcription factor. This was evidenced in the tomato GAME9-Ox that showed a significant change in HMGR35 expression and significant decrease in CAS expression levels in the GAME9-RNAi lines. In potato GAME9-Ox lines, a significant increase in CAS but not in HMGR expression was observed. Additionally, when combined with SlMYC2, GAME9 could significantly transactivate the HMGR1 promoter. Expression of the gene encoding SQS, an enzyme downstream HMGR in the mevalonate pathway, was not altered in either the tomato or potato transgenic plants. Yet, it cannot be ruled out that altered expression of the mevalonate pathway genes (e.g., CAS and HMGR) may have been a result of a feedback mechanism (e.g., by SGA or cholesterol pathway metabolite intermediates) and not a direct regulatory effect of the GAME9 transcription factor.
It is hence apparent that GAME9 control of SGA biosynthesis is not restricted to the GAME genes of the core pathway between cholesterol and α-tomatine, but it includes the upstream biosynthetic genes of the cholesterol pathway and possibly upper in the pathway. This is likely crucial for ensuring the flux of precursors in times of SGA production and to maintain the homeostasis in the interface between the cholesterol pathway and essential phytosterol biosynthesis. Likewise, the Catharanthus ORCA3 was shown to activate several TIA biosynthetic genes as well as some primary metabolism genes involved in the synthesis of TIA precursors22.
It was previously reported that group IXa ERFs proteins from several plant species possess similar but diverse DNA-binding specificities and that each can differentially bind to multiple GC-rich sequences32. At least three different GC-rich boxes can be recognized in promoters of these transcription factors target genes: a P-box, a CS1 box and a GCC box. We performed transactivation assays by testing combinations of GAME9 and upstream regions of core SGA biosynthetic genes, mevalonate and cholesterol pathway genes as well as of some other genes altered in both GAME9-Ox and GAME9-RNAi tomato plants. The results suggested that GAME9 slightly activated the C5-SD gene upstream region containing a GCC-box.
Apart from acting directly on the C5-SD promoter, GAME9 might be acting indirectly through an intermediate transcription factor that by itself directly activates the promoters of core SGA genes (Fig. 10). In a different scenario, GAME9 requires an interacting factor and co-binding of both regulators to the promoter region of target genes in order to permit target gene activation. Such an interacting factor might be the SlMYC2 protein, a jasmonate signaling component shown to take part in activating the tobacco nicotine and Catharanthus TIA biosynthetic pathways together with the NIC2 locus protein ERF189 and the ORCA3 protein, respectively. Our results support the control of tomato cholesterol (i.e., C5-SD), mevalonate (i.e., HMGR1) and SGA- related (i.e., GAME7 and GAME4) genes promoters through co-transactivation by the GAME9 and SlMYC2 proteins. In the current model of transcriptional regulation of tobacco nicotine biosynthesis, when the bioactive jasmonate is perceived (i.e., JA-Ile) an active MYC2 is liberated41. The NIC2 locus ERF proteins recognize the GCC-box and activate structural genes in cooperation with NtMYC2 that recognizes the G-box element in the same promoter. NtMYC2 also induces, directly or indirectly, the NIC2 locus ERF genes (e.g., ERF189). In Catharanthus, MYC2 and ORCA3 factors likely act in a transcriptional cascade to regulate TIA biosynthetic genes and no evidence is available suggesting direct interaction of both proteins on the promoters of biosynthesis genes in a cooperative manner30. Similarly to the NIC2 locus ERF proteins, the EMSA assays performed in our study showed that both GAME9 and SlMYC2 can recognize and bind specifically to GCC- and G-boxes present in their target genes.
The major potato SGAs are considered anti-nutritional factors for humans and their levels in tubers of commercial potato varieties are limited by law3,4. One approach to select low alkaloid potato lines is the identification of associated QTLs and carrying out marker-assisted selection. GAME9 is likely the gene underlying the major QTL on chromosome 1, reported by Sørensen et al.36 to explain 75% of the variance in SGA content among tubers in the population examined in the study. Hence, the identification of GAME9 provides a platform for the generation of Solanaceae crops with modified levels of SGAs. Furthermore, GAME9 provides a starting point for the elucidation of signaling and transcriptional regulatory networks that mediate constitutive and pathogen induced SGA biosynthesis in the Solanaceae.
Methods
Plant material and generation of transgenic plants
Tomato plants (Solanum lycopersicum) cv. MicroTom and potato (Solanum tuberosum) cv. Desiree were grown in a climate-controlled greenhouse at 24 °C during the day and 18 °C during night, with natural light. The GAME9-RNAi construct was created by introducing a GAME9 fragment to pENTR/D-TOPO (Invitrogen) (by NotI and AscI) and further transfer of the resulting plasmid to the pK7GWIWG2 (II) binary vector49 using Gateway LR Clonase II enzyme mix (Invitrogen). The GAME9-Ox constructs were generated by introducing the corresponding tomato and potato GAME9 coding sequences into pDONR221 using the Gateway BP Clonase II enzyme mix (Invitrogen) and then transferred to the pJCV52 binary vector using Gateway LR Clonase II enzyme mix. Constructs were transformed into tomato and potato as described previously5,8. Primers used in this work are listed in Supplementary Table 6.
Co-expression analyses
Co-expression analyses were done as described by Itkin et al.5 Briefly, the tomato GAME9 (Solyc01g090340) and its potato ortholog (Sotub01g029510) were used as 'baits' in co-expression analyses, resulting in lists of co-expressed genes (r-value ≥0.8) for each bait, separately and shared homologs between the two species. The analyses were performed using tomato RNA-Seq transcriptome data from different tissues and organs (flesh, peel, seeds, roots, leaves, buds and flowers) and developmental stages (19 experiments in total)8 and potato RNA-Seq transcriptome data from different tissues and organs (40 experiments in total)50. The co-expression network was visualized with the Cytoscape program51.
In situ RNA hybridization
In situ hybridization was performed as described by Hendelman et al.52 with minor modifications. The sense and anti-sense cRNA probes were produced by in vitro transcription with digoxigenin-11-UTP (Roche) using AmpliScribe T7 High Yield Transcription Kit (Epicentre Biotechnologies) from PCR fragments templates containing a T7 promoter sequence (tttgcggtaatacgactcactatagggcgaattgggtacc) flanking the sense/anti-sense GAME9 full-length cDNA. Shoot apices from 13 days old tomato plants were fixed in PFA (3.8% PFA in 1xPBS, pH 7.0 by H2SO4), gradually transferred to ethanol and then to K-clear plus (Kaltek), and embedded in Paraplast Plus (Laica). Eight-micrometer-thick tissue sections were produced and mounted on Superfroset Plus slides (Thermo Scientific). Slides were treated successively with K-clear plus, an ethanol series, Diethylpyrocarbonate treated double distilled water, 2 × SSC, Proteinase K (1 μg/ml) in 100 mM Tris-HCl, pH 8.0, and 50 mM EDTA at 37 °C, Glycine (2 mg/ml) in PBS, two times with PBS, 4% paraformaldehyde in PBS, two times with PBS, triethanolamine (0.1 M, with stirring), two times with PBS, and increasing ethanol series up to 100% ethanol. For hybridization, slides were incubated with sense or antisense cRNA probes in hybridization buffer (0.3 M NaCl, 10 mM Tris-HCl, pH 8.0, 10 mM sodium phosphate buffer pH 6.8, 5 mM EDTA, 50% v/v deionized formamide, 10% w/v dextran sulfate, 1 × Denhardt's solution, 200 μg tRNA) overnight at 55 °C. Following hybridization, slides were washed successively twice with 0.2 × SSC at 55 °C. Then, slides were blocked with 1% fresh Boehringer block (Roche) in 100 mM Tris-HCl, pH 7.5, and 150 mM NaCl, and then with 1% BSA solution (1% BSA, 100 mM Tris-HCl, pH 7.5, 150 mM NaCl, and 0.3% Triton X-100). Blocked slides were incubated with antidigoxigenin antibodies (Roche) for 2 h at room temperature and then washed three times with 1% BSA solution and three times with detection buffer (100 mM Tris-HCl, pH 9.5, and 100 mM NaCl). Then the slides were incubated with NBT/BCIP color development substrate (Promega) for 24 h and then washed with double distilled water followed by increasing ethanol series and then mounted and analyzed. The expression pattern detected by the GAME9 antisense probe was compared with a control GAME9 sense probe, which showed only background signal.
Phylogenetic analysis
A literature search was performed to identify functionally characterized proteins belonging to the ERF family of transcription factors. Amino acid sequences were aligned using ClustalW2 (ref. 53). A phylogenetic tree was built using the neighbor-joining method54 implemented in MEGA6 (ref. 55). The analysis involved 50 amino acid sequences and evolutionary distances are in units of number of amino acid substitutions per site. All positions containing gaps and missing data were eliminated. Accession numbers for sequence data used in this tree can be found in Supplementary Table 8.
Preparation of plant extracts and metabolite analysis
Profiling of phytosterols was performed with three biological replicates (i.e., three plants for each genotype, n=3) with each plant being one independent extraction and was carried out as described previously8. Briefly, 100 mg frozen leaf powder was extracted at 75 °C for 60 min with 4 ml chloroform/methanol (2:1 v/v) containing epicholesterol as an internal standard. Extracts were kept at room temperature for 1 h, solvents were evaporated to dryness, and the residues were saponified at 90 °C for 60 min in 2 ml 6% (w/v) KOH in methanol. Upon cooling to room temperature, 1 ml n-hexane and 1 ml water were added, and the mixture was shaken vigorously. Following centrifugation to separate the phases, the hexane phase was transferred and evaporated to dryness. Subsequently, 50 μl of N-methyl-N-(trimethylsilyl) trifluoroacetamide (MSTFA) was added, the sample was shaken vigorously, and the mixture was transferred to an autosampler glass vial with a 100 μl conical glass insert and analyzed by GC–MS according to Itkin et al.8 Compounds were identified by comparison of their retention time and mass spectrum to those generated for authentic standards analyzed on the same instrument. Preparation of extracts for SGAs analysis was performed as in Itkin et al.8 with three biological replicates (n=3) and the following modifications: potato and tomato extracts were diluted 80 and 50-fold, respectively, before injection. Compounds were analyzed in MRM positive mode using a UPLC-TQ-MS (Waters), equipped with Acquity BEH C18 column and Triple Quadrupole MS detector. Mobile phases A and B, column temperature and flow rate were set as described previously9. For potato samples, α-solanine and α-chaconine were isocratically eluted at 20% B for 10.5 min, the column washed with 100%B for 3.5 min and re-equilibrated at 20% B for 1 min. The following MS parameters were applied: capillary voltage 2.7 kV, cone—61 V, collision—65 eV. Relative quantification was done using the TargetLynx program (Waters), using the sum of two MRM transitions for α-solanine (868.5>398.4, 868.5>706.5) and α-chaconine (852.5>398.4, 852.5>706.5). For tomato samples, the following linear gradient was applied for α-tomatine analysis: 15 to 30% B over 5 min, 30 to 50% B over 10.5 min, 50 to 100% B over 0.5 min, held at 100% B for a further 1.5 min, then returned to the initial conditions (15% B) in 0.2 min and conditioning at 15% B for 1.3 min. MS parameters: capillary—2.72 kV, cone—60 V, collision energy—40 eV. MRM transitions were set as 1034.5>416.3 and 1034.5>578.3. The first transition trace was used for α-tomatine quantification.
Quantitative real-time PCR
Gene expression analysis was performed with three biological replicates (n=3) for each genotype. RNA isolation was performed by the Trizol method (Sigma-Aldrich). DNase I (Sigma-Aldrich)-treated RNA was reverse transcribed using a high-capacity cDNA reverse transcription kit (Applied Biosystems). Gene-specific oligonucleotides were designed with Primer Express 2 software (Applied Biosystems). The TIP41 gene56 was used as an endogenous control for tomato samples and the NAC gene21 was used for potato. Oligonucleotides used are listed in Supplementary Table 6.
RNA-Seq library preparation and sequencing
RNA-Seq libraries were prepared as described by Zhong et al.57 with minor modifications. Briefly, 5 μg of total RNA was used for poly(A) RNA capture using Dynabeads Oligo (dT)25 (Invitrogen), fragmented at 94 °C for 5 minutes and eluted. The first-strand cDNA was synthesized using reverse transcriptase SuperScript III (Invitrogen) with random primers and dNTP, whereas the second-strand cDNA was generated using DNA polymerase I (Enzymatics) using dUTP. After end-repair (Enzymatics), dA-tailing with Klenow 3′-5′ (Enzymatics) and adapter ligation (Quick T4 DNA Ligase, NEB), the dUTP-containing second-strand was digested by uracil DNA glycosylase (Enzymatics). The resulting first-strand adaptor-ligated cDNA was used for PCR enrichment (NEBNext High-Fidelity PCR Master Mix, NEB) for 14 cycles. Indexed libraries were pooled and sequenced.
Transient expression assays
Transient expression assays in Nicotiana tabacum protoplasts were performed as described previously23,58. Briefly, protoplasts prepared from tobacco Bright Yellow-2 (BY-2) cells were transfected with three different plasmids. The first plasmid (reporter plasmid) contained the firefly luciferase (fLUC) gene under control of the investigated promoter; the second plasmid (effector plasmid) contained the ERF transcription factor GAME9 or SlMYC2 driven by the cauliflower mosaic virus 35S promoter (pCaMV35S) and the third plasmid (normalizer plasmid) contained the renilla luciferase (rLUC) under pCaMV35S control. After transfection and overnight incubation, the protoplasts were lyzed and both fLUC and rLUC activities were measured with the Dual-Luciferase Reporter Assay System (Promega). The fLUC activity is a measure of the activity of the investigated promoter, whereas the rLUC activity reflects the transfection efficiency. For normalization, the fLUC value of each independent transfection was divided by the corresponding rLUC value. For screening and confirmation experiments, 4 and 8 transfections were performed for each promoter-GAME9/SlMYC2 combination, respectively, and the obtained normalized fLUC values were averaged and compared relative to the values obtained from transfections with an effector plasmid containing the GUS gene.
C5-SD promoter cloning
C5-SD promoter deletion constructs were PCR-amplified from the original full-length C5-SD promoter construct using the primers listed in Supplementary Table 6. Promoter fragments in which the CACGTG motif of the G-box and the AGCCTGCCAC motif of the putative GCC-box were mutated into ATGTGA and GATTACAGTC, respectively, were generated by overlap extension PCR using the primers listed in Supplementary Table 6. The obtained PCR products were directly recombined into pGWL7 using single step BP/LR combined Gateway reactions and the resulting reporter constructs were sequence verified before being used for transient expression assays.
Electrophoretic mobility shift assays
The coding sequence of GAME9 (amino acid 40–219) and SlMYC2 were cloned in pET28 vectors. The recombinant proteins with a His-tag were expressed in E. coli BL21 Star (DE3) (Invitrogen) and affinity purified. Unlabeled oligonucleotides containing GCC-, G-boxes and their mutated versions (shown in Supplementary Table 7) were used to determine in vitro binding. Annealing of the probes was performed by boiling equimolar concentration of sense and antisense oligonucleotides to 95 °C for 5 min and cooling to room temperature. Electrophoretic mobility shift assay was performed as described previously59 with 200 ng of protein and equimolar concentration of probes. The probes were separated in 1% agarose gel. The uncropped gel image is shown in Supplementary Fig. 7.
Virus induced gene silencing
Vector containing a fragment of C5-SD gene was generated and VIGS experiments were conducted as described previously5. The infection was performed in the background of a transgenic tomato line expressing the Antirrhinum majus DELILA and ROSEA1 (DEL/ROS) transcription factors, that convey a purple anthocyanin-rich phenotype to the fruit60. The VIGS vector includes the candidate gene as well as the DEL/ROS sequences in a way that allows locating leaf or fruit green patches in which the candidate gene was likely silenced. Plants infected with Agrobacterium, containing empty vector and helper vector pTRV1, were used as control. Leaves and green fruits were collected after 4 and 6 weeks post-infection respectively, and analyzed by LC-MS and GC–MS as described before. Oligonucleotides used to prepare the pTRV2 vector are listed in Supplementary Table 6.
Yeast complementation assay
C5-SD was amplified with primers listed in Supplementary Table 6 and cloned into pDONR221 by Gateway recombination. For expression in yeast, the entry clone was recombined with the destination vector pAG423GPD-ccdB (Addgene plasmid 14150)61 yielding the pAG423GPD-(C5-SD) expression clone. S. cerevisiae erg3 null strain was obtained from EUROSCARF (accession number Y12667; genotype: BY4742; MATα; his3Δ1; leu2Δ0; ura3Δ0; YMR056w::kanMX4)62 and cultivated on yeast extract peptone dextrose medium (Clontech) supplemented with 200 μg/ml of G-418 disulfate (Duchefa). This yeast strain was transformed with the pAG423GPD-(C5-SD) expression clone for complementation or with the unrecombined destination vector pAG423GPD-ccdB as a control. Transformants were selected on plates containing synthetic-defined (SD) medium with the -His dropout supplement (Clontech). For each strain, 5 individual colonies were used to inoculate 5 ml of liquid SD-His medium. The cultures were grown for 2 days at 30 °C with shaking at 250 rpm after which the yeast cells were collected by centrifugation. The yeast cells were lyzed by adding equal amounts of 40% (w/v) KOH and 50% (v/v) ethanol to a final volume of 1 ml, followed by boiling for 2 h. Sterols were extracted from the lyzed cells by liquid-liquid extraction using three times 500 μl of hexane. The organic phases were pooled, vaporized to dryness and trimethylsilylated with 10 μl of pyridine and 50 μl of N-Methyl-N-(trimethylsilyl) trifluoroacetamide (Sigma-Aldrich) for GC–MS analysis. GC–MS analysis was carried out as previously described63.
Additional information
Accession codes: Tomato RNA-seq data associated with this manuscript have been deposited into the NCBI Sequence Read Archive with BioProject ID PRJNA307656.
How to cite this article: Cárdenas, P. D. et al. GAME9 regulates the biosynthesis of steroidal alkaloids and upstream isoprenoids in the plant mevalonate pathway. Nat. Commun. 7:10654 doi: 10.1038/ncomms10654 (2016).
Supplementary Material
Acknowledgments
This work was supported by the European Union Seventh Framework Program FP7/2007–2013 under grant agreement number 613692-TRIFORC (A.G. and A.A. partners) and the Israel Ministry of Agriculture cooperation with Italy grant (for A.A.; agency reference number: 261-0929-13). We thank the Adelis Foundation, Leona M. and Harry B. Helmsley Charitable Trust, Jeanne and Joseph Nissim Foundation for Life Sciences, Tom and Sondra Rykoff Family Foundation Research and the Raymond Burton Plant Genome Research Fund for supporting the A.A. lab activity. P.D.C. thanks Becas Chile Program (CONICYT, Chile) for PhD financial support. A.A. is the incumbent of the Peter J. Cohn Professorial Chair. J.P. is a postdoctoral fellow of the Research Foundation Flanders (FWO). Project funding under the Council of Scientific and Industrial Research network program to CSIR-National Chemical Laboratory (A.P.G.) is greatly acknowledged (BSC0107). We thank Olga Davydov for assistance with protein purification.
Footnotes
Author contributions P.D.C. designed and performed the research and wrote the article. P.D.S. performed the promoter cloning, VIGS and assisted in the RNA-sequencing and metabolomics. J.P., R.V.B. and A.G. performed, analyzed the promoter transactivation and yeast complementation assays and wrote the article. V.D. performed the protein expression and EMSA assays. E.W. assisted in the co-expression and RNA-sequencing data analysis. L.T. performed the in situ hybridization experiments. S.Ma., I.R. and S.Me. assisted with metabolomics data analysis and operated the LC-MS and GC–MS. S.B. and A.P.G. designed part of the research and wrote the article. A.A. designed the research and wrote the article.
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