Abstract
Poly(A)-specific ribonuclease (PARN), a multifunctional multi-domain deadenylase, is crucial to the regulation of mRNA turnover and the maturation of various non-coding RNAs. Despite extensive studies of the well-folding domains responsible for PARN catalysis, the structure and function of the C-terminal domain (CTD) remains elusive. PARN is a cytoplasm–nucleus shuttle protein with concentrated nucleolar distribution. Here, we identify the nuclear and nucleolar localization signals in the CTD of PARN. Spectroscopic studies indicated that PARN-CTD is intrinsically disordered with loosely packed local structures/tertiary structure. Phosphorylation-mimic mutation S557D disrupted the local structure and facilitated the binding of the CTD with the well-folded domains, with no impact on PARN deadenylase activity. Under normal conditions, the nucleolus-residing PARN recruited CBP80 into the nucleoli to repress its deadenylase activity, while DNA damage-induced phosphorylation of PARN-S557 expelled CBP80 from the nucleoli to discharge activity inhibition and attracted nucleoplasm-located CstF-50 into the nucleoli to activate deadenylation. The structure switch-induced function switch of PARN reshaped the profile of small nuclear non-coding RNAs to respond to DNA damage. Our findings highlight that the structure switch of the CTD induced by posttranslational modifications redefines the subset of binding partners, and thereby the RNA targets in the nucleoli.
Highlights
In eukaryotic cells, the length of the non-templated oligo(A) or poly(A) tail at the 30 -end of RNAs is regulated by the opposing actions of polyadenylation and deadenylation [1]
Despite the extensive structural studies of the nuclease domain, R3H domain and RNA recognition motif (RRM) [44,45,46,47], little is known about the structural properties of Poly(A)-specific ribonuclease (PARN)-C-terminal domain (CTD)
PARN is a cytoplasm–nucleus shuttling multifunctional deadenylase that participates in diverse cellular processes [21]
Summary
The length of the non-templated oligo(A) or poly(A) tail at the 30 -end of RNAs is regulated by the opposing actions of polyadenylation and deadenylation [1]. Poly(A) tail length is crucial to almost all RNA turnover processes including processing, maturation, transportation, localization, function and degradation [2,3,4,5,6]. Removal of the poly(A) tail is the rate-limiting step of the decay of most mRNAs via the deadenylation-dependent degradation pathway [7]. Deadenylation is achieved by deadenylases, which are a group of Mg2+ -dependent 30 –50 exonucleases with high substrate preference of oligo(A) or poly(A) [2,4].
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