A Phosphorylation Switch Modulates Configurational Codes in the Oncofetal IGF2BP RNA Binding Paralogs

The insulin-like growth factor 2 mRNA-binding proteins (IGF2BP1-3) are oncofetal RNA regulators that control translation, stability, and localization of several transcripts, yet display paralog-specific functions despite high structural similarity. Each paralog contains six RNA-binding domains (two RRMs and four KH domains) linked by intrinsically disordered segments. mTORC2 phosphorylates IGF2BP1 and IGF2BP3 at a single conserved serine within the disordered linker between the RRM2 and KH1 domains, a modification required for proper regulation of mRNA translational fate. Pairing site-specific phosphoserine incorporation with structural and biophysical interrogations, we show that this phosphorylation acts as a configurational switch that reorganizes long-range arrangements of RNA-binding domains and linkers without altering the secondary structure, and with only modest effects on RNA-binding affinity. Critically, pSer-driven rearrangements occur both in the RNA-free state and upon RNA engagement, and the resulting architectures differ markedly between IGF2BP1 and IGF2BP3 despite >70% sequence identity. These paralog-specific, phosphorylation-dependent configurational landscapes likely underlie differences in mRNA recognition modes and functional outcomes. Our work identifies a post-translational mechanism that tunes IGF2BP paralog dynamics across free and RNA-bound states to program target mRNA selection, processing, and translational fate.