Ultimate paths of least resistance: Intrinsically disordered links as developmental resets in regulatory protein networks

Development and evolution require both stability and adaptability, yet how these opposite properties are reconciled is unclear. Here, we show that intrinsically disordered proteins (IDPs) act as reset mechanisms in conserved regulatory networks facilitating developmental transitions by integrating physical processes with genetic regulation. By tracing the ontogeny of mesenchymal cells in avian beak primordia, we demonstrate that mechanosensitive IDPs mediate shifts between physical cell states via dosage-dependent binding plasticity, converting stochastic protein variation into discreet regulatory networks. The disorder-enabled connectivity in these proteins resets their regulatory specialization and promotes population divergence. Comparative analyses across avian proteomes confirm that binding plasticity in transcriptional IDPs drives their diverse regulatory associations and accelerates their evolution. By resetting specialized states in conserved regulatory networks, IDPs flexibly regulate developmental pathways and reconcile precision with evolvability.