The Transcription Factor VvMYB5b Contributes to the Regulation of Anthocyanin and Proanthocyanidin Biosynthesis in Developing Grape Berries

Deluc, Laurent G.; Bogs, Jochen; Walker, Amanda R.; Ferrier, Thilia; Décendit, Alain; Mérillon, Jean‐Michel; Robinson, Simon P.; Barrieu, François

doi:10.1104/pp.108.118919

Cited by 369 publications

(390 citation statements)

References 64 publications

(99 reference statements)

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“…The current model for the regulation of PA biosynthesis is mainly based on results from Arabidopsis, where TT2, TT8, and TTG1 form a ternary complex to activate PA biosynthesis genes (Baudry et al, 2004). In grape, VvMYB5a and VvMYB5b can activate the VvANR promoter in the presence of AtEGL3, suggesting that MYB5 proteins are also part of a similar ternary complex (Deluc et al, 2008). In our transactivation assays using Arabidopsis protoplasts, we observed that MtMYB5 and MtMYB14 alone can weakly activate both the ANR and LAR promoters, with MYB5 showing somewhat higher activity than MYB14.…”

Section: Downstream Targets Of Myb5 and Myb14 In M Truncatulamentioning

confidence: 99%

“…AtMYB5, a MYB transcription factor regulating trichome branching in leaves and mucilage accumulation in seed coats, plays only a minor role in PA biosynthesis in Arabidopsis (Gonzalez et al, 2009;Li et al, 2009). However, overexpression of VvMYB5a and VvMYB5b (the homologs of AtMYB5 in grape [Vitis vinifera]) in tobacco (Nicotiana tabacum) induces PA accumulation in flowers (Deluc et al, 2006(Deluc et al, , 2008. DkMYB4 (the homolog of AtMYB5 in persimmon [Diospyros kaki]) has been demonstrated to regulate PA accumulation in persimmon fruits, and overexpression or knockdown of DkMYB4 induces or reduces, respectively, PA accumulation in persimmon callus.…”

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MYB5 and MYB14 Play Pivotal Roles in Seed Coat Polymer Biosynthesis in Medicago truncatula

2014

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In Arabidopsis (Arabidopsis thaliana), the major MYB protein regulating proanthocyanidin (PA) biosynthesis is TT2, named for the transparent testa phenotype of tt2 mutant seeds that lack PAs in their coats. In contrast, the MYB5 transcription factor mainly regulates seed mucilage biosynthesis and trichome branching, with only a minor role in PA biosynthesis. We here characterize MYB5 and MYB14 (a TT2 homolog) in the model legume Medicago truncatula. Overexpression of MtMYB5 or MtMYB14 strongly induces PA accumulation in M. truncatula hairy roots, and both myb5 and myb14 mutants of M. truncatula exhibit darker seed coat color than wild-type plants, with myb5 also showing deficiency in mucilage biosynthesis. myb5 mutant seeds have a much stronger seed color phenotype than myb14. The myb5 and myb14 mutants accumulate, respectively, about 30% and 50% of the PA content of wild-type plants, and PA levels are reduced further in myb5 myb14 double mutants. Transcriptome analyses of overexpressing hairy roots and knockout mutants of MtMYB5 and MtMYB14 indicate that MtMYB5 regulates a broader set of genes than MtMYB14. Moreover, we demonstrate that MtMYB5 and MtMYB14 physically interact and synergistically activate the promoters of anthocyanidin reductase and leucoanthocyanidin reductase, the key structural genes leading to PA biosynthesis, in the presence of MtTT8 and MtWD40-1. Our results provide new insights into the complex regulation of PA and mucilage biosynthesis in M. truncatula.

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Section: Downstream Targets Of Myb5 and Myb14 In M Truncatulamentioning

confidence: 99%

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MYB5 and MYB14 Play Pivotal Roles in Seed Coat Polymer Biosynthesis in Medicago truncatula

2014

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“…However, grape was subsequently shown to also use a TT2-like MYB (VvMYBPA2) to regulate PAs in berries, which works in concert with VvMYBPA1 (Terrier et al, 2009). A third type of MYB transcription factor involved in PA synthesis is the MYB5a/b proteins from grapevine (Deluc et al, 2008), but these MYB proteins appear to be less specific than MYBPA1 and MYBPA2. Anthocyanin regulatory MYBs (VvMYBA1/2) have also been characterized in grape (Kobayashi et al, 2002).…”

Section: Vcmybpa1 Phylogeny and Expression Pattern Suggest A Role Inmentioning

confidence: 99%

“…Therefore, in addition to activating PA synthesis early in development, these MYBs may also contribute to anthocyanin synthesis later during ripening via the activation of general flavonoid genes. This would likely necessitate a negative regulator of PA-specific genes during ripening to prevent reactivation of the PA pathway (Deluc et al, 2008). Further work is necessary to unequivocally demonstrate the functionality and specificity of VcMYBPA1 in the context of blueberry fruit development.…”

Section: Vcmybpa1 Phylogeny and Expression Pattern Suggest A Role Inmentioning

confidence: 99%

Gene Expression and Metabolite Profiling of Developing Highbush Blueberry Fruit Indicates Transcriptional Regulation of Flavonoid Metabolism and Activation of Abscisic Acid Metabolism

Zifkin

Jin²,

Ozga³

et al. 2011

Plant Physiology

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Highbush blueberry (Vaccinium corymbosum) fruits contain substantial quantities of flavonoids, which are implicated in a wide range of health benefits. Although the flavonoid constituents of ripe blueberries are known, the molecular genetics underlying their biosynthesis, localization, and changes that occur during development have not been investigated. Two expressed sequence tag libraries from ripening blueberry fruit were constructed as a resource for gene identification and quantitative realtime reverse transcription-polymerase chain reaction primer design. Gene expression profiling by quantitative real-time reverse transcription-polymerase chain reaction showed that flavonoid biosynthetic transcript abundance followed a tightly regulated biphasic pattern, and transcript profiles were consistent with the abundance of the three major classes of flavonoids. Proanthocyanidins (PAs) and corresponding biosynthetic transcripts encoding anthocyanidin reductase and leucoanthocyanidin reductase were most concentrated in young fruit and localized predominantly to the inner fruit tissue containing the seeds and placentae. Mean PA polymer length was seven to 8.5 subunits, linked predominantly via B-type linkages, and was relatively constant throughout development. Flavonol accumulation and localization patterns were similar to those of the PAs, and the B-ring hydroxylation pattern of both was correlated with flavonoid-3#-hydroxylase transcript abundance. By contrast, anthocyanins accumulated late in maturation, which coincided with a peak in flavonoid-3-O-glycosyltransferase and flavonoid-3#5#-hydroxylase transcripts. Transcripts of VcMYBPA1, which likely encodes an R2R3-MYB transcriptional regulator of PA synthesis, were prominent in both phases of development. Furthermore, the initiation of ripening was accompanied by a substantial rise in abscisic acid, a growth regulator that may be an important component of the ripening process and contribute to the regulation of blueberry flavonoid biosynthesis.Highbush blueberry (Vaccinium corymbosum; Ericaceae) is one of the most economically important fruit crops in North America. Blueberry fruit have been the focus of much recent attention due to numerous reports of their positive effects on human health. These benefits are generally attributed to high levels of polyphenolics, in particular the flavonoids (Rasmussen et al., 2005). Highbush blueberries have one of the highest in vitro antioxidant capacities of any fruit or vegetable (Prior and Gu, 2005;Wu et al., 2006). The major health benefits linked to the consumption of blueberries include a reduced risk for cardiovascular (Basu et al., 2010) and neurodegenerative (Neto, 2007) diseases. Furthermore, experiments on rodents suggest that blueberry extracts may also prevent cancer, slow tumor growth, and reverse cognitive and behavioral deficits related to stroke and aging (Lau et al., 2005;Gordillo et al., 2009).The three common types of flavonoids that accumulate in blueberry fruit are the flavonols, anthocya-

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“…The bHLH proteins may have overlapping regulatory targets (Zimmermann et al, 2004), but MYB proteins are believed to be key components by allocation of specific gene expression patterns (Stracke et al, 2001). In grape berries, the MYB proteins MYBA1 and MYBA2 (Kobayashi et al, 2002;Walker et al, 2007), MYB5a (Deluc et al, 2006), MYB5b (Deluc et al, 2008), and MYBPA1 act together with bHLH proteins and probably WDR proteins to control anthocyanin and/or PA synthesis. Most R2R3-MYB factors regulating flavonoid biosynthesis (except flavonol synthesis) depend on cofactors, including WDR proteins but, most importantly, a small subgroup of bHLH proteins that share a common motif in their N termini that interacts with a signature motif in the R3 repeat of the N-terminal R2R3 domain of MYB factors (Grotewold et al, 2000).…”

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The Grapevine R2R3-MYB Transcription Factor VvMYBF1 Regulates Flavonol Synthesis in Developing Grape Berries

et al. 2009

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Flavonols are important ultraviolet light protectants in many plants and contribute substantially to the quality and healthpromoting effects of fruits and derived plant products. To study the regulation of flavonol synthesis in fruit, we isolated and characterized the grapevine (Vitis vinifera 'Shiraz') R2R3-MYB transcription factor VvMYBF1. Transient reporter assays established VvMYBF1 to be a specific activator of flavonol synthase1 (VvFLS1) and several other promoters of grapevine and Arabidopsis (Arabidopsis thaliana) genes involved in flavonol synthesis. Expression of VvMYBF1 in the Arabidopsis mutant myb12 resulted in complementation of its flavonol-deficient phenotype and confirmed the function of VvMYBF1 as a transcriptional regulator of flavonol synthesis. Transcript analysis of VvMYBF1 throughout grape berry development revealed its expression during flowering and in skins of ripening berries, which correlates with the accumulation of flavonols and expression of VvFLS1. In addition to its developmental regulation, VvMYBF1 expression was light inducible, implicating VvMYBF1 in the control of VvFLS1 transcription. Sequence analysis of VvMYBF1 and VvFLS1 indicated conserved putative light regulatory units in promoters of both genes from different cultivars. By analysis of the VvMYBF1 amino acid sequence, we identified the previously described SG7 domain and an additional sequence motif conserved in several plant MYB factors. The described motifs have been used to identify MYB transcription factors from other plant species putatively involved in the regulation of flavonol biosynthesis. To our knowledge, this is the first functional characterization of a light-inducible MYB transcription factor controlling flavonol synthesis in fruit.

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The Transcription Factor VvMYB5b Contributes to the Regulation of Anthocyanin and Proanthocyanidin Biosynthesis in Developing Grape Berries

Cited by 369 publications

References 64 publications

MYB5 and MYB14 Play Pivotal Roles in Seed Coat Polymer Biosynthesis in Medicago truncatula

MYB5 and MYB14 Play Pivotal Roles in Seed Coat Polymer Biosynthesis in Medicago truncatula

Gene Expression and Metabolite Profiling of Developing Highbush Blueberry Fruit Indicates Transcriptional Regulation of Flavonoid Metabolism and Activation of Abscisic Acid Metabolism

The Grapevine R2R3-MYB Transcription Factor VvMYBF1 Regulates Flavonol Synthesis in Developing Grape Berries

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