Phosphorylation tunes electrostatically driven protein-RNA interactions

Phosphorylation of intrinsically disordered proteins (IDPs) is essential for regulating biomolecular interactions in many cellular processes. However, a quantitative understanding of how phosphorylation tunes the affinity between highly charged IDPs and nucleic acids is lacking. Here, we show that multi-site phosphorylation of the disordered arginine/serine-rich (RS) domain of the splicing factor SRSF1 acts as an electrostatic rheostat that governs RNA binding. By combining enzymatic phosphorylation, phosphomimetic variants, and chemically synthesised phosphopeptides with single-molecule Förster resonance energy transfer measurements, we reveal the RS domain to be a potent driver of protein–RNA association. Increasing phosphorylation progressively reduces this interaction, and extensive phosphorylation eliminates detectable RNA binding. Remarkably, the binding free energy depends linearly on RS-domain net charge, regardless of whether the charge arises from phosphorylation or acidic residues introduced as phosphomimetics. Together, our findings uncover a quantitative framework for how phosphorylation tunes the interactions of charged IDPs and rationalize why two acidic residues are required to mimic a single phosphorylation event.