Felix W. Jaffé scite author profile

Anthocyanins are secondary metabolites found in higher plants that contribute to the colors of flowers and fruits. In apples (Malus domestica Borkh.), several steps of the anthocyanin pathway are coordinately regulated, suggesting control by common transcription factors. A gene encoding an R2R3 MYB transcription factor was isolated from apple (cv Cripps' Pink) and designated MdMYB1. Analysis of the deduced amino acid sequence suggests that this gene encodes an ortholog of anthocyanin regulators in other plants. The expression of MdMYB1 in both Arabidopsis (Arabidopsis thaliana) plants and cultured grape cells induced the ectopic synthesis of anthocyanin. In the grape (Vitis vinifera) cells MdMYB1 stimulated transcription from the promoters of two apple genes encoding anthocyanin biosynthetic enzymes. In ripening apple fruit the transcription of MdMYB1 was correlated with anthocyanin synthesis in red skin sectors of fruit. When dark-grown fruit were exposed to sunlight, MdMYB1 transcript levels increased over several days, correlating with anthocyanin synthesis in the skin. MdMYB1 gene transcripts were more abundant in red skin apple cultivars compared to non-red skin cultivars. Several polymorphisms were identified in the promoter of MdMYB1. A derived cleaved amplified polymorphic sequence marker designed to one of these polymorphisms segregated with the inheritance of skin color in progeny from a cross of an unnamed red skin selection (a sibling of Cripps' Pink) and the non-red skin cultivar Golden Delicious. We conclude that MdMYB1 coordinately regulates genes in the anthocyanin pathway and the expression level of this regulator is the genetic basis for apple skin color.

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The Grapevine Transcription Factor VvMYBPA1 Regulates Proanthocyanidin Synthesis during Fruit Development

Bogs

Jaffé²,

Takos³

et al. 2007

Plant Physiol.

505

469

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Development of three different cell types is associated with the activity of a specific MYB transcription factor in the ventral petal ofAntirrhinum majusflowers

et al. 2005

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Petal tissue comprises several different cell types, which have specialised functions in pollination in different flowering plant species. In Antirrhinum majus, the MIXTA protein directs the formation of conical epidermal cells in petals. Transgenic experiments have indicated that MIXTA activity can also initiate trichome development, dependent on the developmental timing of its expression. MIXTA is normally expressed late in petal development and functions only in conical cell differentiation. However, an R2R3 MYB transcription factor very similar to MIXTA (AmMYBML1), which induces both trichome and conical cell formation in transgenic plants, is expressed very early during the development of the ventral petal. Its cellular expression pattern suggests that it fulfils three functions: trichome production in the corolla tube, conical cell development in the petal hinge epidermis and reinforcement of the hinge through differential mesophyll cell expansion. The DIVARICATA (DIV) gene is required for ventral petal identity. In div mutants, the ventral petal assumes the identity of lateral petals lacking these three specialised cell types, and expression of AmMYBML1 is significantly reduced compared with wild type, supporting the proposed role of AmMYBML1 in petal cell specification. We suggest that AmMYBML1 is regulated by DIV in association with the B-function proteins DEFICIENS and GLOBOSA, and,consequently, controls specification of particular cells within the ventral petal which adapt the corolla to specialised functions in pollination.

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Identification of key amino acids for the evolution of promoter target specificity of anthocyanin and proanthocyanidin regulating MYB factors

et al. 2013

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A complex of R2R3-MYB and bHLH transcription factors, stabilized by WD40 repeat proteins, regulates gene transcription for plant cell pigmentation and epidermal cell morphology. It is the MYB component of this complex which specifies promoter target activation. The Arabidopsis MYB TT2 regulates proanthocyanidin (PA) biosynthesis by activating the expression of ANR (anthocyanidin reductase), the gene product of which catalyzes the first committed step of this pathway. Conversely the closely related MYB PAP4 (AtMYB114) regulates the anthocyanin pathway and specifically activates UFGT (UDP-glucose:flavonoid-3-O-glucosyltransferase), encoding the first enzyme of the anthocyanin pathway. Both at the level of structural and regulatory genes, evolution of PA biosynthesis proceeded anthocyanin biosynthesis and we have identified key residues in these MYB transcription factors for the evolution of target promoter specificity. Using chimeric and point mutated variants of TT2 and PAP4 we found that exchange of a single amino acid, Gly/Arg(39) in the R2 domain combined with an exchange of a four amino acid motif in the R3 domain, could swap the pathway selection of TT2 and PAP4, thereby converting in planta specificity of the PA towards the anthocyanin pathway and vice versa. The general importance of these amino acids for target specificity was also shown for the grapevine transcription factors VvMYBPA2 and VvMYBA2 which regulate PAs and anthocyanins, respectively. These results provide an insight into the evolution of the different flavonoid regulators from a common ancestral gene.

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Felix W. Jaffé

Light-Induced Expression of a MYB Gene Regulates Anthocyanin Biosynthesis in Red Apples

The Grapevine Transcription Factor VvMYBPA1 Regulates Proanthocyanidin Synthesis during Fruit Development

Development of three different cell types is associated with the activity of a specific MYB transcription factor in the ventral petal ofAntirrhinum majusflowers

Identification of key amino acids for the evolution of promoter target specificity of anthocyanin and proanthocyanidin regulating MYB factors

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