Ayako Maeda scite author profile

Ayako Maeda

2Publications

21Citation Statements Received

91Citation Statements Given

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Kyoto University

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DYW deaminase domain has a distinct preference for neighboring nucleotides of the target RNA editing sites

et al. 2022

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C-to-U RNA editing sites in plant organelles show a strong bias for neighboring nucleotides. The nucleotide upstream of the target cytidine is typically C or U, whereas A and G are less common and rare, respectively. In pentatricopeptide repeat (PPR)-type RNA editing factors, the PPR domain specifically binds to the 5 0 sequence of target cytidines, whereas the DYW domain catalyzes the C-to-U deamination. We comprehensively analyzed the effects of neighboring nucleotides of the target cytidines using an Escherichia coli orthogonal system. Physcomitrium PPR56 efficiently edited target cytidines when the nucleotide upstream was U or C, whereas it barely edited when the position was G or the nucleotide downstream was C. This preference pattern, which corresponds well with the observed nucleotide bias for neighboring nucleotides in plant organelles, was altered when the DYW domain of OTP86 or DYW1 was adopted. The PPR56 chimeric proteins edited the target sites even when the À1 position was G. Our results suggest that the DYW domain possesses a distinct preference for the neighboring nucleotides of the target sites, thus contributing to target selection in addition to the existing selection determined by the PPR domain.

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Structural insight into the activation of an Arabidopsis organellar C-to-U RNA editing enzyme by active site complementation

Toma-Fukai

Sawada

Maeda

et al. 2022

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RNA-binding pentatricopeptide repeat (PPR) proteins catalyze hundreds of cytidine to uridine (C-to-U) RNA editing events in plant organelles; these editing events are essential for proper gene expression. More than half of the PPR-type RNA editing factors, however, lack the DYW cytidine deaminase domain. Genetic analyses have suggested their cytidine deaminase activity arises by association with a family of DYW1-like proteins that contain an N-terminally truncated DYW domain, but their molecular mechanism has been unclear. Here, we report the crystal structure of the Arabidopsis thaliana DYW1 deaminase domain at 1.8 Å resolution. DYW1 has a cytidine deaminase fold lacking the PG box. The internal insertion within the deaminase fold shows an α-helical fold instead of the β-finger reported for the gating domain of the Arabidopsis thaliana ORGANELLE TRANSCRIPT PROCESSING 86. The substrate binding pocket is incompletely formed and appears to be complemented in the complex by the E2 domain and the PG box of the interacting PPR protein. In vivo RNA editing assays corroborate the activation model for DYW1 deaminase. Our study demonstrates the common activation mechanism of the DYW1-like proteins by molecular complementation of the DYW domain and reconstitution of the substrate-binding pocket.

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Ayako Maeda

DYW deaminase domain has a distinct preference for neighboring nucleotides of the target RNA editing sites

Structural insight into the activation of an Arabidopsis organellar C-to-U RNA editing enzyme by active site complementation

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