Correction
17 Jun 2020: The PLOS ONE Staff (2020) Correction: Identification of a new R3 MYB type repressor and functional characterization of the members of the MBW transcriptional complex involved in anthocyanin biosynthesis in eggplant (S. melongena L.). PLOS ONE 15(6): e0235081. https://doi.org/10.1371/journal.pone.0235081 View correction
Figures
Abstract
Here we focus on the highly conserved MYB-bHLH-WD repeat (MBW) transcriptional complex model in eggplant, which is pivotal in the transcriptional regulation of the anthocyanin biosynthetic pathway. Through a genome-wide approach performed on the recently released Eggplant Genome (cv. 67/3) previously identified, and reconfirmed by us, members belonging to the MBW complex (SmelANT1, SmelAN2, SmelJAF13, SmelAN1) were functionally characterized. Furthermore, a regulatory R3 MYB type repressor (SmelMYBL1), never reported before, was identified and characterized as well.
Through a qPCR approach, we revealed specific transcriptional patterns of candidate genes in different plant tissue/organs at two stages of fruit development. Two strategies were adopted for investigating the interactions of bHLH partners (SmelAN1, SmelJAF13) with MYB counterparts (SmelANT1, SmelAN2 and SmelMYBL1): Yeast Two Hybrid (Y2H) and Bimolecular Fluorescent Complementation (BiFC) in A. thaliana mesophylls protoplast. Agro-infiltration experiments highlighted that N. benthamiana leaves transiently expressing SmelANT1 and SmelAN2 showed an anthocyanin-pigmented phenotype, while their co-expression with SmelMYBL1 prevented anthocyanin accumulation. Our results suggest that SmelMYBL1 may inhibits the MBW complex via the competition with MYB activators for bHLH binding site, although this hypothesis requires further elucidation.
Citation: Andrea M, Francesco EF, Sergio I, Alessandra G, Maria AM, Cinzia C, et al. (2020) Identification of a new R3 MYB type repressor and functional characterization of the members of the MBW transcriptional complex involved in anthocyanin biosynthesis in eggplant (S. melongena L.). PLoS ONE 15(5): e0232986. https://doi.org/10.1371/journal.pone.0232986
Editor: Serena Aceto, University of Naples Federico II, ITALY
Received: February 11, 2020; Accepted: April 24, 2020; Published: May 14, 2020
Copyright: © 2020 Andrea et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: The nucleotide sequence data of SmelMYBL1 (SMEL_010g336390.1) is available at GeneBank Database with accession number MN855525.
Funding: The authors received no specific funding for this work.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Anthocyanins are the major plant flavonoid compounds, which confer appealing colours to flowers and fruits and contribute to stress tolerance [1,2]. In plant vegetative tissues, anthocyanins play key roles in protection against UV radiation, low/high temperatures, drought and pathogen attacks, while in reproductive organs they exert also an eco-physiological role by attracting pollinators and seed dispersers. Anthocyanins also possess widely documented antioxidant, antidiabetic, antihyperlipidemic, anti-inflammatory, anticarcinogenic properties and a preventive activity against cardiovascular diseases in humans [3].
Eggplant purple fruits are a rich source of anthocyanins, being delphinidin-3-p-coumaroylrutinoside-5-glucoside and the delphinidin-3-rutinoside the most abundant [4]. The anthocyanin pathway represents one branch of flavonoid metabolism and it is a very conserved network in many plant species, with most of the genes encoding for enzymes and regulatory transcription factors (TFs) identified in several plant species [5]. The anthocyanin pathway is one of the most finely tuned and it is under the control of Early (EBGs) and Late (LBGs) Biosynthetic Genes in dicotyledonous species [6,7]. Chalcone synthase (CHS), Chalcone-flavonone isomerase (CHI), Flavanone 3-hydroxylase (F3H) and Flavonol synthase (FLS) are common EBGs involved in the biosynthesis of all downstream flavonoids, whose enzymatic steps are controlled by co-activator independent and functionally redundant ‘R2R3-type MYB’ regulatory genes (MYB11, MYB12, MYB111) [8].
Flavonoid 3' hydroxylase (F3՛H), Flavonoid-3',5'-hydroxylase (F3՛5՛H), Dihydroflavonol 4-reductase (DFR), Anthocyanidin synthase (ANS) are LBGs required for anthocyanin synthesis and modification, and their correlation with anthocyanin content has been highlighted in many Solanaceous species including eggplant [6,9–11]. RNAseq analyses showed that most of the eggplant LBGs were up-regulated in flower and young fruit skin tissues at the early stage fruit development of ripening, with a marked decrease at the physiological stage of ripening [12].
It has been reported that the activation of LBGs is mediated by the MYB-bHLH-WD40 (MBW) transcription complexes. MYB proteins, together with bHLH and WD40, can act as positive or negative transcriptional regulators binding to the promoters of structural genes.
The MYB family is one of the largest in flowering plants, with 125 members in A. thaliana [13] sharing common features at amino terminus: the DNA binding domain consists of one to three conserved HLH motifs, referred as R1, R2, R3. The MYB activators mainly belong to the R2R3-MYB family of transcription factors, while repressors consist of both R2R3-MYB and R3-MYB. It has been proposed the involvement of diverse MBW complexes depending on the occurrence of activator or repressor MYBs which directly, and competitively, bind the bHLH via the amino terminus domain, acting in a tissue-specific mode to modulate anthocyanin synthesis [14]. Indeed, the MBW complex is counterbalanced by the amount of MYB repressor(s) which inactivate the complex by recruiting the bHLH partner [5]. The WD40 proteins (e.g. PhAN11) modulate the activity of MYB/bHLH regulators at post-transcriptional level and there are no evidences of a direct interaction with these TFs [15].
In the Solanaceae, the genes encoding R2R3-MYB transcription factors are orthologs of the petunia PhAN2 [16], while those encoding IIIf group of bHLHs are orthologs of the two petunia groups: the AN1 and the JAF13 [17,18]; the physical interaction of PhAN1 and PhAN2 proteins is required to activate the transcription of LBGs (e.g. DFR) [17]. In eggplant, the orthologs of tomato ANT1 and AN2 [19], belonging to R2R3-MYBs, have been identified and found to be preferentially expressed in the early fruit maturation stage as well as in flowers [12]. The transient expression of SmelANT1 in tobacco [12, 20] and the stable expression into a non-anthocyanin accumulating eggplant [9,20, 21] both lead to anthocyanin synthesis, suggesting its role in controlling fruits and flower pigmentation. The orthologs of tomato AN1 and JAF13 belonging to bHLH family have been identified in eggplant as well [12].
The role of MYB repressors has only recently being recognized thanks to the studies in petunia, grapevine, poplar and tomato [22–25]. The R2R3-MYBs can act as both positive and negative transcriptional regulators. Indeed, the petunia R2R3-type PhMYB27 acts as repressor of anthocyanin biosynthetic pathway, since its overexpression leads to a reduced anthocyanin content [5,26]. Recently, a R3-MYB encoding gene with three DNA-binding domain repeats, namely ATROVIOLACEA (ATV), has been characterized in tomato [25]; however, genes encoding MYB repressors have not been yet identified in eggplant, pepper, and potato.
Recently a high quality, annotated and anchored eggplant genome sequence (www.eggplantgenome.org; [12]) has been made available, leading to the identification of genes of MBW complex (SmelANT1, SmelAN2, SmelJAF13 and SmelAN1), in the present paper we confirmed their sequence homology also by functional domain identification and phylogenetic analyses. Furthermore, we identified, for the first time in eggplant, a regulatory R3 MYB repressor according to its high similarity with MYBL1, recently described in the genus Iochroma (Solanaceae) by Gates and co-workers [27]. The expression dynamics of candidate genes were assessed at two stages of fruit development and in flowers. To the best of our knowledge, this is the first report on the establishment of eggplant interaction of MYB proteins with bHLH partners, which we assessed both in a yeast two‐hybrid system and via Bimolecular Fluorescent Complementation (BiFC) in A. thaliana mesophyll protoplasts. At last, we estimated the effect of over-expression of the candidate genes in agro-infiltrated N. benthamiana plants and established their effect on anthocyanin content.
Materials and methods
Plant material and growth conditions
Plants of S. melongena line “67/3” with violet-black round fruits, were grown in pots (30 cm diameter) in glasshouse at CREA (Montanaso Lombardo, Lodi—Italy), under standard conditions, from March to September 2017. For each organ (open flowers, fruits), samples were obtained by pooling tissues collected from at least 3 plants. At least one flower per plant was collected at anthesis (S1A Fig). Skin and flesh of the fruits were collected at the unripe (stage A, S1B Fig) and commercial ripening stage (stage B, S1C Fig) according to Mennella et al. [4]. All fresh tissues were immediately frozen in liquid nitrogen and stored at -80°C.
Phylogenetic analysis and identification of regulatory protein
The deduced amino acid sequences of bHLHs and MYBs were obtained by screening the genome of the eggplant breeding line 67/3 [20] using the pBLAST function tool of Eggplant Genome Browser (http://www.eggplantgenome.org/), with the amino acid sequences of petunia and tomato regulatory anthocyanin proteins as query (S1 and S2 Files).
Sequence alignment of bHLH and MYBs from eggplant as well as from known anthocyanin related bHLH and MYB in other species (from NCBI and Sol Genomic Network (https://solgenomics.net) (S1 and S2 Files) were generated via multiple sequence alignment using the ClustalW algorithm in the MEGA X package [28].
The evolutionary history of both families of TFs was visualized by the Neighbour-Joining method via MEGA X. All ambiguous positions were removed for each sequence pair (pairwise deletion option) resulting in 1301 (for bHLH tree) and 2561 (for MYB tree) positions in the final dataset. The statistical significance of individual nodes was assessed by bootstrap analysis with 1,000 replicates, and the evolutionary distances were calculated using the p-distance method with default parameters. A second round of alignment and phylogenetic analysis was performed, as described above, with a limited number of MYBs belonging to known flavonoids repressor proteins.
MYBL1 structure analysis
The nucleotide sequence data of SmelMYBL1 (SMEL_010g336390.1) is available at GeneBank Database with accession number MN855525. The Intron/Exon organization for SmelMYBL1 gene was determined by aligning the cDNA sequences to their corresponding genomic DNA sequences used as the input for graphical display at the Gene Structure Display Server of Peking University, China (http://gsds.cbi.pku.edu.cn/). Moreover, the protein sequence of SmelMYBL1 was aligned to other similar MYBL1 proteins using ClustalW in MEGA software.
Real-time PCR analysis
Total RNA from eggplant cv. 67/3 tissues was extracted using the TRIzol RNA Isolation Reagents (Thermo Fisher Scientific) combined with the Spectrum Plant Total RNA kit (Sigma Aldrich). The single strand cDNA was synthesized from 1 μg of RNA using a High Capacity RNA-to-cDNA kit (Applied Biosystems, Foster City, USA). Amplifications were performed with primers designed by Primer 3 software (frodo.wi.mit.edu/cgi-bin/primer3/primer3 www.cgi) for eggplant AN2, ANT1, AN11, JAF13, AN1, DFR, MYBL1. All the gene-specific primer sequences are listed in S1 Table. A standard amplification curve was generated for each gene using 2-fold serial dilution of pooled cDNA. PCR efficiency was optimized to be in the range 80–100% with R2-values of 0.996. The PCR reactions were carried out using the Rotor-Gene RG-6000 thermal cycler (Corbett Research) according to the following PCR parameters 95°C for 5 min, followed by incubation for 15s at 95°C and denaturation for 15 s at 95°C, annealing for 60 s at 59°C for 40 cycles, followed by elongation at 72°C for 20 s. Specificity of amplifications was assessed by melt curves analyzed for the presence of a single peak. The analyses were performed on three biological replicates and in technical triplicates. Expression of SmelGAPDH [29] was used as reference gene. Relative expression levels of each individual gene were calculated using GeNorm (https://genorm.cmgg.be/) [30].
Cloning of the MYBs and bHLHs encoding genes
SmelANT1, SmelAN2, SmelMYBL1, SmelJAF13, SmelAN1 were first amplified from cDNA using primers with attB1 and attB2 sites, cloned by Gateway Recombinant Technology in pDONOR 207 vector through a BP recombination and subsequently transferred by LR recombination into the destination vector, as described in the following paragraphs.
Yeast two-hybrid
ProQuest™ Two-Hybrid System (Life Technologies), kindly provided by Dr. Montanini from University of Parma, was used. Each entry vector (pDONOR207 with the CDS of the gene of interest as detailed above) was recombined with the activation domain (AD) vector pDEST22 (for ANT1, AN2 and MYBL1) and/or the binding-domain (BD) vector pDEST32 (for JAF13 and AN1). S. cerevisiae strain Mav203 was transformed with 1μg each of the different combinations of bait, prey and control (non-recombined) vectors using the lithium acetate/polyethylene glycol method. Transformed colonies containing bait and prey plasmids were selected on synthetic dropout medium lacking Tryptophan and Leucine (−W/−L). To test the interaction between bait and prey, an equal number of cells was spotted on medium lacking Tryptophan, Leucine and Uracil (−W/−L/−U). Negative controls using empty vectors were also performed.
Two round-shaped 50 mm Whatman 541 filter papers, saturated with 3.5 ml of 2% X-gal solution, were placed on a 10 cm petri dish. The transformed yeasts from the surface of the YPAD plates were obtained by a 50 mm Whatman 541 filter paper and then completely immersed in liquid nitrogen for 15 seconds and then set them on the top of the soaked Whatman filters. Plates were sealed with a parafilm and incubated at 37°C for overnight. The results were recorded after 1 hours by photography.
Bimolecular Fluorescent Complementation (BiFC) analysis
A. thaliana Columbia-0 ecotype mesophyll protoplasts were isolated and transformed as previously described [31]. AN1 full CDS entry vector was recombined with N9842 vector [32] to generate AN1-nYFP fusion protein. AN2, ANT1 and MYBL1 full CDS were instead recombined with the N9843 vector [32] to generate AN2-cYFP, ANT11-cYFP and MYBL1-cYFP fusion proteins, respectively. Both N9842 and N9843 vectors were kindly provided by Dr. Beatrice Giuntoli (Department of Biology, University of Pisa). As negative control, plasmids containing the expression cassette for nYFP-GUS or cYFP-GUS fusion proteins [33] were used in combination with the previously described vectors. Plasmid DNA was isolated using a DNA Maxi-prep kit. Protoplasts were transformed using 2.5 μg of each plasmid and stained with 2 μg of DAPI (Sigma-Aldrich). Confocal investigation was performed with the Zeiss AiryScan confocal microscope. YFP fluorescent was exited with a 488 nm laser and collected at 490–540 nm. Chlorophyll fluorescent was exited with 640 nm laser and collected at 650–750 nm. DAPI was exited at 405 nm and collected at 410–470 nm. Images were analysed with the ZEN 2010software (Zeiss).
Transient heterologous expression in N. benthamiana
For transient expression, the pEAQ-HT vector kindly provided by Prof. Lomonossoff [34], was used. Each entry vector (pDONOR207 with the CDS of the gene of interest as detailed above) was then recombined with the pEAQ-HT destination vector. The pEAQ-HT destination vectors (containing genes of interest) as well as the empty vector pEAQ-HT, used as a negative control, were inserted in Agrobacterium tumefaciens strain C5801 by the freeze-thaw method. Transformed bacteria were grown overnight at 28°C in 5 mL of L medium (10g L-1 bactotryptone, 5 g L-1 Yeast extract, 5 g L-1 NaCl, 1 g L-1 D-glucose) containing kanamycin (50 mg L-1). The overnight cultures (2 mL) were then transferred into 20 mL of induction medium (L broth containing 10 mM MES and 20 μM acetosyringone) with kanamycin (50 mg L-1),and grown as above. The cells were collected by centrifugation for 10 min at 4,000 g and resuspended in 50 mL of infiltration medium (10 mM MgCl2, 10 mM MES, 200 μM acetosyringone) to an OD600 of 1.0 and kept at room temperature for 3 h before being infiltrated into the abaxial air spaces of 2–4-week-old N. benthamiana plants. After 4 days, the infiltrated leaf material was collected and used for quantitative HPLC/PDA analysis as described below.
Identification and quantification of anthocyanins
Transiently transformed N. benthamiana grinded tissues (1 g) were extracted with 8 mL EtOH/HCl (85/15), pH = 1. After centrifugation (10,000 g for 10 min), supernatants were obtained.
The identification and quantification of delphinidin 3-O-rutinoside was carried out by HPLC on a Shimadzu XR system equipped with a photodiode detector SPD-M20A (Shimadzu, Dusseldorf Germany). HPLC-grade acetonitrile (HPLC plus ≥99.9%) and formic acid (> 98% purity) were purchased from Sigma Aldrich (Bellefonte, USA). De-ionized water (18.2MΩ cm) was obtained from a Milli-Q purification system (Millipore, Bedford, MA, USA). Delphinidin 3-O-rutinoside was obtained from Extrasynthese (Genay Cedex, France).
Each acid extract prepared was filtered with a 13 mm diameter, 0.22 μm pore diameter hydrophilic PTFE syringe filter and then analyzed on an Ascentis Express C18 column (15 cm ×2.1 mm, 2.7 μm, Supelco, Bellefonte, USA) using water/formic acid (99:1, v/v) and acetonitrile/formic acid (99:1, v/v) as mobile phases A and B, respectively. The flow rate was 0.4 mL min-1 and the column temperature was maintained at 30°C. The gradient program was as follows: 5% B for 15 min, 5–20% B in 5 min, 20–100% B in 6 min, 100% B for 2 min. Total pre-running and post-running time was 36 min. UV spectra were acquired over the 220–700 nm wavelength range. The quantification of delphinidin 3-O-rutinoside (Retention Time: 19.155 min) in the extracts was performed through the external calibration method at 520 nm. The calibration curve (S2 Fig) of the authentic commercial standard was prepared with six different concentrations, in the 50–1 μg mL-1 range (curve equation: y = 14200x-13960, R2 = 0.9996). All the data were statistically analyzed using SPSS statistical software.
Results and discussion
Identification of eggplant anthocyanin-related regulatory genes
Based on a genome-wide phylogenetic approach, we identified eggplant putative MYB and bHLH transcription factors as candidates for anthocyanin regulation. The bHLH encoding genes were spotted by screening the genome of S. melongena cv. 67/3 [12] with 13 known plant proteins related to anthocyanin synthesis belonging to the subgroup IIIf [35] (S1 File), whose members are known to be involved in flavonoid regulations.
A total of 84 gene sequences encoding for bHLHs were retrieved in the eggplant genome and manually inspected, while 159 and 124 were previously identified in tomato [36] and potato [37] genomes respectively. The eggplant bHLHs were then used to construct a phylogenetic tree based on the NJ method (Fig 1) together with 13 known plant proteins related to anthocyanin synthesis belonging to the subgroup IIIf.
The optimal NJ tree with the sum of branch length = 31.39844401 is shown. The tree is drawn to scale, with branch lengths in the same units as those of the evolutionary distances used to infer the phylogenetic tree. The percentage of replicate trees in which the associated taxa clustered together in the bootstrap test (1,000 replicates) are shown next to the branches. Branches corresponding to partitions reproduced in less than 50% bootstrap replicates are collapsed. The evolutionary distances were computed using the p-distance method and are in the units of the number of amino acid differences per site. This analysis involved 97 amino acid sequences, 84 from Eggplant genome [12] and 13 from known anthocyanin related bHLH in other species. The AN1 and the JAF13 clade described in the text are marked with orange and purple triangle, respectively.
Among eggplant proteins, two bHLH factors, i.e. SMEL008g319200.1 and the SMEL009g326640.1 showed high homology with the major plant bHLH factors belonging to subgroup IIIf. These sequences were previously identified by Barchi et al. [12] and named SmelJAF13 and SmelAN1 in accordance to their homology with tomato SlJAF13 and SlAN1, respectively. The two proteins fall into distinct evolutionary sub-clades of bHLH involved in anthocyanin regulation of which one comprises members such as JAF13 (tomato, eggplant, petunia and related sequences of other species) and GL3/EGL3 from A. thaliana, while the other includes members such as AN1 (tomato, eggplant, petunia, and related sequences in other species) and TT8 from A. thaliana (Fig 1). The ZmIN1 gene has been considered as a separate group by several authors, due to its unique intron-exon structure [17]. However, no further studies have been performed to elucidate this putative evolutionary divergence. Depending on the species, the two bHLHs are not functionally redundant and they do not complement each other. Indeed, they might regulate anthocyanins synthesis in a specific time and space manner. In tomato and petunia, both JAF13 and AN1 proteins appear to be involved in anthocyanin regulations although in a different manner [17,19].
A similar approach was applied to identify eggplant anthocyanin related MYBs protein encoding genes. The latter were identified by screening the genome of S. melongena breeding line 67/3 [12] with 25 known plant MYBs (S2 File) related to anthocyanin synthesis belonging to subgroup 4–7 according to the classification by Liu et al [38]. Interestingly, an analogous number of MYB proteins, i.e. 127, were identified in tomato [39] while 159, were detected in potato [40].
The identified eggplant MYBs, as well as 25 related MYBs detected in other plant species, were used to construct a phylogenetic tree using the NJ method together (Fig 2). Based on similarity with the R2R3-MYB proteins PhAN2, SlAN2 and SlANT1, which are known to be involved in anthocyanin regulation in petunia and tomato, two homologs were identified in eggplant: SMEL010g351850.1, corresponding to SmelAN2, and SMEL001g120500.1 ortholog to SmelANT1, both of which were previously annotated as putative candidate regulatory MYB in eggplant [12,20]. Moreover, a number of MYB domain encoding proteins were found in evolutionary subgroups closely related to the ones of known anthocyanins regulators. Interestingly, a cluster of 7 R2R3-MYBs, including SMEL007g274170.1 and its paralogous genes SMEL007g274160.1, SMEL001g153180.1, SMEL005g234040.1, SMEL008g299860.1, SMEL008g299200.1 and SMEL008g318650.1, might represent other flavonoids regulatory proteins.
The optimal NJ tree with the sum of branch length = 45.96037176 is shown. The tree is drawn to scale, with branch lengths in the same units as those of the evolutionary distances used to infer the phylogenetic tree. The percentage of replicate trees in which the associated taxa clustered together in the bootstrap test (1,000 replicates) are shown next to the branches. Branches corresponding to partitions reproduced in less than 50% bootstrap replicates are collapsed. The evolutionary distances were computed using the p-distance method and are in the units of the number of amino acid differences per site. This analysis involved 154 amino acid sequences, 129 from Eggplant and 25 from known anthocyanin related MYBs in other plant species. Clades containing MYB proteins involved in positive and negative anthocyanin regulation are marked with purple and blue circles, respectively.
Several putative repressors of anthocyanin biosynthesis were identified in eggplant. As depicted in Figs 2 and 3A, we identified three clades corresponding to different repressor types: (i) a clade including CPC of three repeat binding domain R3 repressors, which comprises A. thaliana TRY and CPC, tomato ATV [25,41] and TRY, the putative S. melongena ortholog of TRY, Smel001g129110.1, and petunia MYBX; (ii) a MYBL1 clade of R3 repressors, including Iochroma MYBL1 and its eggplant ortholog, Smel010g336390.1, A. thaliana MYBL2, and (iii) a clade including R2R3 MYB repressors belonging to subgroup 4, composed by petunia MYB27, A. thaliana MYB4 and its eggplant ortholog Smel001g115870.1.
(A) Phylogenetic tree of MYB transcription factors related to flavonoid synthesis. The optimal NJ tree with the sum of branch length = 8,61587540 is shown. The tree is drawn to scale, with branch lengths in the same units as those of the evolutionary distances used to infer the phylogenetic tree. The percentage of replicate trees in which the associated taxa clustered together in the bootstrap test (1,000 replicates) are shown next to the branches. Branches corresponding to partitions reproduced in less than 50% bootstrap replicates are collapsed. The evolutionary distances were computed using the p-distance method and are in the units of the number of amino acid differences per site. The analysis included 39 amino acid sequences. Positive and negative candidate MYBs analysed in this work are marked with pink and purple square, respectively. (B) Exon/intron structure of S. melongena MYBL1 gene. The exons and introns are represented by purple boxes and black lines, respectively. (C) Domain structure of MYBL1 type repressors.
According to previous works [42,43], in eggplant two anthocyanin related QTLs are located on chromosome 5 and 10, which respectively explain the type and intensity of anthocyanin pigmentation. We focused our attention on the candidate repressor mapping on Chr10, SMEL010G336391.1 (SmelMYBL1), whose intron-exon structure is reported in Fig 3B. Similarly to what observed for Iochroma MYBL1, SmelMYBL1 lost the EAR motif characteristic of the MYB3like genes and petunia MYB27 [5], but acquired a new EAR motif near the end of the R3 domain (Fig 3C). Moreover, the SmelMYBL1 is characterized by the bHLH binding motif in the R3 domain and likely binds with the bHLH transcription factors acting as part of an MBW regulatory complex.
Transcriptional profiling of anthocyanin related genes
To investigate the function of SmelANT1, SmelAN1, SmelAN2, SmelJAF13 in the regulation of anthocyanin synthesis, we performed their qRT-PCR expression analysis in flower at the anthesis and fruit at unripe (stage A) and commercial ripening (stage B) (Fig 4). The SmelAN11 (SMEL003G185640.1), a WD40 encoding gene, previously identified by Barchi and colleagues [12], along with SmelDFR, a structural gene of the biosynthetic pathway, were also included in the analysis.
qRT-PCR based transcription profiling of eggplant MYBL1, AN2, ANT1, AN1, JAF13, DFR, AN11 in two stages of fruit ripening (stage A and B) and in flower organs. Expression levels, measured by qPCR, are shown as relative units using SmelGAPDH as reference gene. Data are means of three biological replicates ± SD.
As highlighted in Fig 4, SmelDFR resulted highly expressed at both stage A and B as well as in flower organs. As previously observed [12], the R2R3 MYB encoding genes ANT1 and AN2 showed a tissue specific expression. AN2 was poorly expressed in all the tissues except flowers, while ANT1 was highly expressed at the fruit stages A and B (Fig 4). These results reinforce the hypothesis of AN2 and ANT1 involvement in the regulation of anthocyanin synthesis in fruits and flowers respectively. Indeed also SlANT1 and SlAN2 in tomato [19] as well as ScAN1 and ScAN2 in S. commersonii [44] were found to be differently involved in anthocyanin regulation. The putative repressor encoding gene, SmelMYBL1, resulted to be expressed in all analysed tissues.
As previously reported [15,19], the WD40 encoding gene AN11 was found to be constitutively expressed in all the tissues analysed.
The two bHLH encoding genes, SmelAN1 and SmelJAF13, were always expressed in tissues containing anthocyanins, with the former more expressed in fruits and the latter in flower organs (Fig 4). This suggests that multiple MYB-bHLH-WD40 complexes exert their regulatory role in different organs as highlighted in other species [45].
All our qPCR analyses in eggplant tissues and organs confirm a clear correlation of DFR and R2R3 MYB TFs transcript levels with anthocyanin content, as previously reported in eggplant (S3 Fig) [12] as well as other species [9,46,47].
Yeast two-hybrid
Interactions between proteins belonging to MYB (SmelANT1, SmelAN2 and SmelMYBL1) and bHLH (SmelJAF13, SmelAN1) families were investigated by means of a yeast two-hybrid assay (Fig 5). Since the fusion of anthocyanin MYB regulators with the GAL4 binding domain led to the auto activation of reported genes, these were associated to GAL4 activation domain. Thus, the coding sequence of SmelJAF13 and SmelAN1 were inserted in the bait vector, while SmelANT1, SmelAN2 and SmelMYBL1 in the prey vector.
ANT1, AN2 and MYBL1 were cloned in the prey plasmid pDEST22 and transformed with the bait plasmid pDEST32 (containing JAF13 and AN1). pDEST22 and pDEST32 were used as a negative control. Yeast cells were grown for three days on (A) synthetic complete medium lacking tryphtophan and leucine (-W/-L), (B) on selective medium lacking tryptophan, leucine and uracil (-W/-L/-U) and (C) on Whatman 541 filter papers, saturated 2% X-gal solution.
Yeast cells co-transformed with SmelANT1, SmelAN2 and SmelMYBL1 in combination with SmelJAF13 or SmelAN1 grew on selective medium lacking leucine, tryptophan and uracil (Fig 5B), demonstrating the ability of different MYB proteins to form a complex with bHLH partners. Negative controls, consisting of yeast cells co-transformed with prey plasmids containing MYB proteins and empty bait plasmid, as well as the opposite combination (i.e. bait plasmids containing bHLH proteins and empty pray plasmid), did not grow on selective medium, indicating the lack of interaction. Our findings were further supported by the formation of blue colonies through β-galactosidase assay (Fig 5C). These results are in accordance with those reported by D’Amelia et al. [48], which highlighted the ability of StAN1 (ortholog of SmelANT1) to interact with StbHLH1 and StJAF13. Besides, the protein interaction assay carried out in tomato protoplasts demonstrated that SlMYB-ATV could actually bind both the endogenous bHLH factors SlAN1 and SlJAF13 [25], in analogy with SmelMYBL1.
Bimolecular Fluorescent Complementation (BiFC)
To confirm the interaction between AN1 and MYBs proteins, we carried out a Bimolecular Fluorescent Complementation experiment using A. thaliana mesophyll protoplasts as model system. The N-terminal domain of the Yellow fluorescent protein (nYFP) was fused in frame with the SmelAN1 CDS missing of the stop codon, while the CDSs of the three investigated MYBs, after removal of the stop codons, where fused upstream the C-terminal domain of the YFP (cYFP). Freshly isolated Arabidopsis protoplasts were then transformed with combinations of plasmids carrying the expression cassette for the fusion proteins and subjected to confocal microscopy the following day. A fluorescent signal, indicating an interaction between the investigated proteins, was reported for all the combinations tested (Fig 6), thus confirming the ability of SmelAN1 to interact with SmelAN2, SmelANT1 and SmelMYBL1. Otherwise, no signal was detected in the control transformations (Fig 6). By means of DAPI staining, we also proved that all complexes localized into the nuclei.
SmelAN1-nYFP fusion proteins was co-expressed transiently with SmelAN2-cYFP, SmelMYBL1-cYFP or SmelANT1-cYFP fusion proteins in freshly isolated Arabidopsis mesophyll protoplasts. GUS protein fused to both nYFP or cYFP was used as negative control. The cellular localization of interactions was investigated through DAPI staining.
Transient heterologous expression in Nicotiana benthamiana
To verify the effect of ectopic expression of the three SmelMYBs and two SmelbHLHs in planta, we carried out a N. benthamiana leaf transient expression assay (Fig 7). Agrobacteria transformed with a pEAQ expression vector containing SmelANT1, SmelAN2, SmelMYBL1, SmelJAF13, SmelAN1 were infiltrated individually or in combination (MYBL1 with ANT1 or AN2) in N. benthamiana leaves. Plants agro-infiltrated with the empty vector were used as negative controls. Four days after infiltration, an anthocyanin-pigmented phenotype was clearly visibly in pEAQ_ANT1 and pEAQ_AN2 agro-infiltrated leaves, while no anthocyanin accumulation was detected upon expression of MYBL1 as well as of JAF13 and AN1 (S4 Fig). Interestingly co-expression of MYBL1 together with ANT1 and AN2 prevented anthocyanin accumulation.
Leaves of N. benthamiana after agroinfiltration with ANT1, AN2 and MYBL1 and a combination of MYBL1 with ANT1 or AN2. Anthocyanin accumulation is indicated by dotted white circles.
HPLC analyses on the transformed leaves were also carried out to provide additional evidence of anthocyanin accumulation (Fig 8). Indeed N. benthamiana leaves transiently expressing SmelANT1 and SmelAN2 were found to accumulate 156.14 and 20.92 μg/g fresh weight (FW) respectively of delphinidin 3-O-rutinosid, which was not detectable in leaves agroinfiltared with the empty vector (Fig 8). In line with the visual observation, no delphinidin 3-O-rutinosid was detected in samples agroinfiltrated with MYBL1, JAF13 and AN1 as well after co-infiltration of MYBL1 together with SmelANT1 and SmelAN2. Our results thus support previously transient expression in tobacco [20] and stable expression in eggplant [9,21], in which anthocyanin accumulation was verified for SmelANT1. Co-expression of MYBL1 together with ANT1 prevented completely the anthocyanin accumulation, acting as a negative regulator of the biosynthetic pathway. Analogous results were found in N. tabacum after the expression of I. loxense MYBL1, resulting in a nearly complete loss of floral anthocyanins in [27]. On the other side, the co-expression of ANT1 together with SmelMYB44/SmelMYB86, proposed as a negative regulators of the anthocyanin pathway, led to a decrease but not to a complete stoppage of anthocyanin production in eggplant [10].
Concentration of delphinidin 3-O-rutinoside in tissue extracts of N. benthamiana control (CTR) and transiently transformed leaves (ANT1, AN2, AN1, JAF13, MYBL1 and a combination of MYBL1 with ANT1 or AN2). Error bars represent SD (n = 3). Asterisk indicates significance based on Tukey’s test (P≤0.05).
Conclusion
A model has been designed to describe the regulation network of anthocyanin biosynthesis in plant [5]. Feedback inhibition of anthocyanin biosynthesis is caused by the interaction of R3 MYB repressors with the core MBW activation complex [25, 41, 49] The replacement of one of the R2R3 MYB partners in the MBW complex with an R3 MYB may transform the complex from an activator to a repressor of anthocyanin gene transcription.
We identified in eggplant the candidate TFs in the anthocyanin related MBW activation complexes. These include two MYB TFs (SmelANT1 and SmelAN2), two bHLH TFs (SmelJAF13 and SmelAN1) and one WDR (SmelAN11). SmelMYBL1, which belongs to R3 MYB, might represent a new component of the eggplant MBW complex. The latter appears to act as inhibitor of MBW complex by competing with MYB activators (SmelANT1 and SmelAN2) for binding to SmelJAF13 and SmelAN1, thus hindering the chances to form new MBW complexes.
In recent years the CRISPR/Cas9 system has emerged as a powerful technology for genome editing and is now widely used to explore gene function. Thanks to the ongoing development of this technology in eggplant [50], our future goal will be to deepen the functional characterization of the isolated genes and validate MBW activation complex in the species. The anthocyanin accumulation in eggplant berries is determined by the balance between biosynthesis and degradation, thus our increase in understanding the genetic mechanisms regulating both processes may open the way for future genetic engineering approaches aimed increase the content of fruit anthocyanins through increasing their production but also through reducing their degradation.
Supporting information
S1 File. Evolutionary relationships of bHLH proteins.
https://doi.org/10.1371/journal.pone.0232986.s001
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S2 File. Evolutionary relationships of MYB proteins.
https://doi.org/10.1371/journal.pone.0232986.s002
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S1 Fig.
Stages of the eggplant flower and fruit employed: A) Open flowers; B) Fruits Ø 2–4 cm at 8–14 DAF (named stage A); C) Fruits at commercial ripening (named stage B) at approximately 38 DAF. Scale bar in each image represents 1cm.
https://doi.org/10.1371/journal.pone.0232986.s003
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S2 Fig. Calibration curve of delphinidin 3-O-rutinoside standard (50, 20, 10, 5, 2, 1 μg/mL).
https://doi.org/10.1371/journal.pone.0232986.s004
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S3 Fig.
Expression value (FPKM) in 5 eggplant tissue samples: root, leaf, flower, fruits stage A (unripe), fruit stage B (commercial ripening) redrawn from data from Barchi et al., 2019 [12]. The average value is sorted by colour, from yellow (low) to blue (high).
https://doi.org/10.1371/journal.pone.0232986.s005
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S4 Fig. The effects of over-expression of JAF13 and AN1 in Nicotiana benthamiana.
Leaves of N. benthamiana after agroinfiltration with JAF13 and AN1.
https://doi.org/10.1371/journal.pone.0232986.s006
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S1 Table. List of primers used in this study.
https://doi.org/10.1371/journal.pone.0232986.s007
(DOCX)
References
- 1. D’Amelia V, Aversano R, Chiaiese P, Carputo D. The antioxidant properties of plant flavonoids: their exploitation by molecular plant breeding. Phytochemistry Reviews. 2018.
- 2. Kovinich N, Kayanja G, Chanoca A, Otegui MS, Grotewold E. Abiotic stresses induce different localizations of anthocyanins in Arabidopsis. Plant Signal Behav. 2015; pmid:26179363
- 3. Putta S, Yarla NS, Peluso I, Tiwari DK, Reddy G V., Giri P V., et al. Anthocyanins: Multi-Target Agents for Prevention and Therapy of Chronic Diseases. Curr Pharm Des. 2017; pmid:28741457
- 4. Mennella G, Lo Scalzo R, Fibiani M, D’Alessandro A, Francese G, Toppino L, et al. Chemical and Bioactive Quality Traits During Fruit Ripening in Eggplant (S. melongena L.) and Allied Species. J Agric Food Chem. American Chemical Society; 2012;60: 11821–11831. pmid:23134376
- 5. Albert NW, Davies KM, Lewis DH, Zhang H, Montefiori M, Brendolise C, et al. A conserved network of transcriptional activators and repressors regulates anthocyanin pigmentation in Eudicots. Plant Cell. 2014; pmid:24642943
- 6. Liu Y, Tikunov Y, Schouten RE, Marcelis LFM, Visser RGF, Bovy A. Anthocyanin biosynthesis and degradation mechanisms in Solanaceous vegetables: A review. Frontiers in Chemistry. 2018. pmid:29594099
- 7. Li S. Transcriptional control of flavonoid biosynthesis: Fine-tuning of the MYB-bHLH-WD40 (MBW) complex. Plant Signaling and Behavior. 2014. pmid:24393776
- 8. Petroni K, Tonelli C. Recent advances on the regulation of anthocyanin synthesis in reproductive organs. Plant Sci. Elsevier; 2011;181: 219–229. pmid:21763532
- 9. Zhang Y, Hu Z, Chu G, Huang C, Tian S, Zhao Z, et al. Anthocyanin accumulation and molecular analysis of anthocyanin biosynthesis-associated genes in eggplant (Solanum melongena L.). J Agric Food Chem. 2014; pmid:24654563
- 10. Li J, Ren L, Gao Z, Jiang M, Liu Y, Zhou L, et al. Combined transcriptomic and proteomic analysis constructs a new model for light-induced anthocyanin biosynthesis in eggplant (Solanum melongena L.). Plant Cell Environ. 2017; pmid:28940206
- 11. Li J, He YJ, Zhou L, Liu Y, Jiang M, Ren L, et al. Transcriptome profiling of genes related to light-induced anthocyanin biosynthesis in eggplant (Solanum melongena L.) before purple color becomes evident. BMC Genomics. 2018; pmid:29554865
- 12. Barchi L, Pietrella M, Venturini L, Minio A, Toppino L, Acquadro A, et al. A chromosome-anchored eggplant genome sequence reveals key events in Solanaceae evolution. Sci Rep. 2019; pmid:31409808
- 13. Stracke R, Werber M, Weisshaar B. The R2R3-MYB gene family in Arabidopsis thaliana. Current Opinion in Plant Biology. 2001.
- 14. Ramsay NA, Glover BJ. MYB-bHLH-WD40 protein complex and the evolution of cellular diversity. Trends in Plant Science. 2005. pmid:15708343
- 15. De Vetten N, Quattrocchio F, Mol J, Koes R. The an11 locus controlling flower pigmentation in petunia encodes a novel WD-repeat protein conserved in yeast, plants, and animals. Genes Dev. 1997; pmid:9192870
- 16. Quattrocchio F, Wing J, Van Der Woude K, Souer E, De Vetten N, Joseph M, et al. Molecular analysis of the anthocyanin2 gene of Petunia and its role in the evolution of flower color. Plant Cell. 1999; pmid:10449578
- 17. Spelt C, Quattrocchio F, Mol JNM, Koes R. Anthocyanin1 of Petunia encodes a basic helix-loop-helix protein that directly activates transcription of structural anthocyanin genes. Plant Cell. 2000; pmid:11006336
- 18. Quattrocchio F, Wing JF, Van der Woude K, Mol JNM, Koes R. Analysis of bHLH and MYB domain proteins: Species-specific regulatory differences are caused by divergent evolution of target anthocyanin genes. Plant J. 1998; pmid:9680994
- 19. Kiferle C, Fantini E, Bassolino L, Povero G, Spelt C, Buti S, et al. Tomato R2R3-MYB proteins SlANT1 and SlAN2: Same protein activity, different roles. PLoS One. 2015; pmid:26308527
- 20. Docimo T, Francese G, Ruggiero A, Batelli G, De Palma M, Bassolino L, et al. Phenylpropanoids accumulation in eggplant fruit: Characterization of biosynthetic genes and regulation by a MYB transcription factor. Front Plant Sci. 2016; pmid:26858726
- 21. Zhang Y, Chu G, Hu Z, Gao Q, Cui B, Tian S, et al. Genetically engineered anthocyanin pathway for high health-promoting pigment production in eggplant. Mol Breed. 2016;
- 22. Cavallini E, Matus JT, Finezzo L, Zenoni S, Loyola R, Guzzo F, et al. The phenylpropanoid pathway is controlled at different branches by a set of R2R3-MYB C2 repressors in grapevine. Plant Physiol. 2015; pmid:25659381
- 23. Yoshida K, Ma D, Constabel CP. The MYB182 protein down-regulates proanthocyanidin and anthocyanin biosynthesis in poplar by repressing both structural and regulatory flavonoid genes. Plant Physiol. 2015; pmid:25624398
- 24. Jun JH, Liu C, Xiao X, Dixon RA. The transcriptional repressor MYB2 regulates both spatial and temporal patterns of proanthocyandin and anthocyanin pigmentation in Medicago truncatula. Plant Cell. 2015; pmid:26410301
- 25. Colanero S, Perata P, Gonzali S. The atroviolacea gene encodes an R3-MYB protein repressing anthocyanin synthesis in tomato plants. Front Plant Sci. 2018; pmid:29971083
- 26. Ma D, Constabel CP. MYB Repressors as Regulators of Phenylpropanoid Metabolism in Plants. Trends in Plant Science. 2019. pmid:30704824
- 27. Gates DJ, Olson BJSC, Clemente TE, Smith SD. A novel R3 MYB transcriptional repressor associated with the loss of floral pigmentation in Iochroma. New Phytol. 2018; pmid:29023752
- 28. Kumar S, Stecher G, Li M, Knyaz C, Tamura K. MEGA X: Molecular evolutionary genetics analysis across computing platforms. Mol Biol Evol. 2018; pmid:29722887
- 29. Barbierato V, Sala T, Rinaldi P, Bassolino L, Barchi L, Rotino GL, et al. A spiking strategy facilitates housekeeping selection for RT-qPCR analysis under different biotic stresses in eggplant. Protoplasma. 2017; pmid:28429149
- 30. Vandesompele J, De Preter K, Pattyn F, Poppe B, Van Roy N, De Paepe A, et al. Accurate normalization of real-time quantitative RT-PCR data by geometric averaging of multiple internal control genes. Genome Biol. 2002; pmid:12184808
- 31. Iacopino S, Jurinovich S, Cupellini L, Piccinini L, Cardarelli F, Perata P, et al. A synthetic oxygen sensor for plants based on animal hypoxia signaling. Plant Physiol. 2019; pmid:30459266
- 32. Zhong S, Lin Z, Fray RG, Grierson D. Improved plant transformation vectors for fluorescent protein tagging. Transgenic Res. 2008; pmid:18594998
- 33. Shukla V, Lombardi L, Iacopino S, Pencik A, Novak O, Perata P, et al. Endogenous Hypoxia in Lateral Root Primordia Controls Root Architecture by Antagonizing Auxin Signaling in Arabidopsis. Mol Plant. 2019; pmid:30641154
- 34. Sainsbury F, Thuenemann EC, Lomonossoff GP. PEAQ: Versatile expression vectors for easy and quick transient expression of heterologous proteins in plants. Plant Biotechnol J. 2009; pmid:19627561
- 35. Davies KM, Albert NW, Schwinn KE. From landing lights to mimicry: The molecular regulation of flower colouration and mechanisms for pigmentation patterning. Functional Plant Biology. 2012.
- 36. Sun H, Fan HJ, Ling HQ. Genome-wide identification and characterization of the the bHLH gene family in tomato. BMC Genomics. 2015; pmid:25612924
- 37. Wang R, Zhao P, Kong N, Lu R, Pei Y, Huang C, et al. Genome-wide identification and characterization of the Potato bHLH Transcription factor family. Genes (Basel). 2018; pmid:29361801
- 38. Liu J, Osbourn A, Ma P. MYB transcription factors as regulators of phenylpropanoid metabolism in plants. Molecular Plant. 2015. pmid:25840349
- 39. Li Z, Peng R, Tian Y, Han H, Xu J, Yao Q. Genome-wide identification and analysis of the MYB transcription factor superfamily in solanum lycopersicum. Plant Cell Physiol. 2016; pmid:27279646
- 40. Sun Wenjun, Ma Zhaotang Chen, Hui Liu M. MYB Gene Family in Potato (Solanum tuberosum L.): Genome-Wide Identification of Hormone-Responsive Reveals Their Potential Functions in Growth and Development. Int J Mol Sci. 2019;20: 4847.
- 41. Cao X, Qiu Z, Wang X, Van Giang T, Liu X, Wang J, et al. A putative R3 MYB repressor is the candidate gene underlying atroviolacium, a locus for anthocyanin pigmentation in tomato fruit. J Exp Bot. 2017; pmid:29186488
- 42. Barchi L, Lanteri S, Portis E, Valè G, Volante A, Pulcini L, et al. A RAD tag derived marker based eggplant linkage map and the location of QTLs determining anthocyanin pigmentation. PLoS One. 2012; pmid:22912903
- 43. Toppino L, Barchi L, Lo Scalzo R, Palazzolo E, Francese G, Fibiani M, et al. Mapping quantitative trait loci affecting biochemical and morphological fruit properties in eggplant (Solanum melongena L.). Front Plant Sci. 2016; pmid:26973692
- 44. D’Amelia V, Aversano R, Ruggiero A, Batelli G, Appelhagen I, Dinacci C, et al. Subfunctionalization of duplicate MYB genes in Solanum commersonii generated the cold-induced ScAN2 and the anthocyanin regulator ScAN1. Plant Cell Environ. 2018; pmid:28386931
- 45. Allan AC, Espley R V. MYBs Drive Novel Consumer Traits in Fruits and Vegetables. Trends in Plant Science. 2018. pmid:30033210
- 46. Jiang M, Ren L, Lian H, Liu Y, Chen H. Novel insight into the mechanism underlying light-controlled anthocyanin accumulation in eggplant (Solanum melongena L.). Plant Sci. 2016; pmid:27297989
- 47. Gisbert C, Dumm JM, Prohens J, Vilanova S, Stommel JR. A spontaneous eggplant (Solanum melongena L.) color mutant conditions anthocyanin-free fruit pigmentation. HortScience. 2016;
- 48. D’Amelia V, Aversano R, Batelli G, Caruso I, Moreno MC, Castro-Sanz AB, et al. High AN1 variability and interaction with basic helix-loop-helix co-factors related to anthocyanin biosynthesis in potato leaves. Plant J. 2014; pmid:25159050
- 49. Chen L, Hu B, Qin Y, Hu G, Zhao J. (2019) Advance of the negative regulation of anthocyanin biosynthesis by MYB transcription factors. Plant Physiol Biochem.136:178–187 pmid:30685697
- 50. Moglia A, Gianoglio S, Acquadro A, Maioli A, Valentino D, Milani A, et al. CRISPR/Cas9 mediated mutagenesis of Polyphenol Oxidase Genes in eggplant for the improvement of the berry quality. LXIII SIGA ANNUAL CONGRESS. 2019. p. 8.03.