Phosphorylation-dependent tuning of mRNA deadenylation rates

mRNA decay is a major determinant of gene regulation that is controlled through shortening of mRNA poly(A) tails by the Ccr4-Not complex. The specificity of deadenylation can be mediated through RNA adaptors – RNA-binding proteins that tether substrate mRNAs to Ccr4-Not in a regulated and context-specific manner. Interaction with Ccr4-Not is mediated by intrinsically disordered regions (IDRs) within the RNA adaptors. Due to the difficulty in studying large IDR-containing complexes, the determinants of specificity and their regulation remain unclear. Here we use structural biology and biochemical reconstitution to show that dispersed segments within IDRs of RNA adaptors bind to several distinct binding sites on Ccr4-Not through multivalent interactions. We further demonstrate that binding can be modulated by phosphorylation, altering the consequent deadenylation rate in a continuously tunable manner. This mechanism is broadly applicable in evolutionarily divergent IDRs from multiple RNA adaptors including fission yeast Puf3, and human Pumilio/PUM1 and Tristetraprolin/TTP. Together, our work suggests that multivalent interactions and phosphorylation represent conserved strategies for regulating gene expression. Thus, in response to cellular cues, mRNA decay can be regulated by a graded mechanism, rather than a bistable on/off switch, rationalizing how post-transcriptional gene expression is fine-tuned.