Abstract
Terminal uridylyl transferases (TUTs) catalyze the addition of uridines to the 3' ends of RNAs and are implicated in the regulation of both messenger RNAs and microRNAs. To better understand how TUTs add uridines to RNAs, we focused on a putative TUT from Xenopus laevis, XTUT7. We determined that XTUT7 catalyzed the addition of uridines to RNAs. Mutational analysis revealed that a truncated XTUT7 enzyme, which contained solely the nucleotidyl transferase and poly(A) polymerase-associated domains, was sufficient for catalytic activity. XTUT7 activity decreased upon removal of the CCHC zinc finger domains and a short segment of basic amino acids (the basic region). This basic region bound nucleic acids in vitro. We also demonstrated that XTUT7 repressed translation of a polyadenylated RNA, to which it added a distinct number of uridines. We generated a predicted structure of the XTUT7 catalytic core that indicated histidine 1269 was likely important for uridine specificity. Indeed, mutation of histidine 1269 broadened the nucleotide specificity of XTUT7 and abolished XTUT7-dependent translational repression. Our data reveal key aspects of how XTUT7 adds uridines to RNAs, highlight the role of the basic region, illustrate that XTUT7 can repress translation, and identify an amino acid important for uridine specificity.
Highlights
TUT7 adds uridines to and regulates RNAs
Xenopus TUT7 (XTUT7) Domain Structure—A single XTUT7 ortholog is encoded by the Xenopus genome
Putative XTUT7 cDNAs were cloned from both X. laevis and X. tropicalis oocytes and are collectively referred to as XTUT7
Summary
TUT7 adds uridines to and regulates RNAs. Results: Xenopus TUT7 (XTUT7) uridylates RNAs, possesses a basic region that binds nucleic acids, and represses translation of a polyadenylated RNA. Our data reveal key aspects of how XTUT7 adds uridines to RNAs, highlight the role of the basic region, illustrate that XTUT7 can repress translation, and identify an amino acid important for uridine specificity. TUT7 acts independent of LIN28 and adds a single uridine to a subset of pre-let-7 RNAs [17] Monouridylation of these pre-miRNAs creates an optimal 3Ј end for downstream processing into mature miRNAs. To further understand TUT7-dependent RNA uridylation, we identified and focused on Xenopus TUT7 (XTUT7) as it may have key roles in the oocyte and/or embryo. We utilized Xenopus oocytes because uridylated RNAs are stable, and microinjected mRNAs are efficiently translated With this approach, we identified XTUT7 domains important for catalytic activity, illustrated that XTUT7 can repress translation of a polyadenylated RNA, and pinpointed an important residue for uridine specificity. Our experiments revealed a key role for a small region of basic amino acids that binds nucleic acids
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