FvDFR2 rather than FvDFR1 play key roles for anthocyanin synthesis in strawberry petioles.

The accumulation of anthocyanins can be found in both the fruit and petioles of strawberries, but the fruit appears red while the petioles appear purple-red. Additionally, in the white-fruited diploid strawberries, the petioles can accumulate anthocyanins normally, suggesting a different synthesis pattern between the petioles and fruits. We screened the EMS mutagenized population of a red-fruited diploid strawberry 'Ruegen' and discovered a mutant which showed no anthocyanin accumulation in the petioles but normal accumulation in the fruit. Through BSA sequencing and allelic test, it was found that a mutation in FvDFR2 was responsible for this phenotype. Furthermore, the complex formed by the interaction between the petiole-specific FvMYB10L and FvTT8 only binds the promoter of FvDFR2 but not FvDFR1 , resulting in the expression of only FvDFR2 in the petiole. FvDFR2 can catalyze the conversion of DHQ and eventually the formation of cyanidin and peonidin, giving the petiole a purplish-red color. In the fruit, however, both FvDFR1 and FvDFR2 can be expressed, which can mediate the synthesis of cyanidin and pelargonidin. Our study clearly reveals different regulation of FvDFR1 and FvDFR2 in mediating anthocyanin synthesis in petioles and fruits. • Mutations in FvDFR2 result in a phenotype of green petiole in strawberry. • In petioles, only FvDFR2 expressed while both FvDFR1 and FvDFR2 expressed in fruits. • FvMYB10L and FvTT8 selectively binds to the FvDFR2 promoter instead of FvDFR1. • FvDFR1 compensates for the loss of FvDFR2 function in forming cyanidin in fruits. [ABSTRACT FROM AUTHOR]