A long-chain heparan sulfate capture mechanism directs paracrine GDNF-GFRα1 signalling through RET

The receptor tyrosine kinase RET is activated by GDNF and GFR1 together as a bipartite ligand, driving receptor activation and signalling in developmental and neuroprotective contexts. Evidence from developmental and cell models has suggested that heparan sulfate (HS) functions as a fourth component in RET signalling by binding to GDNF, but the molecular details remain unclear. Here, we present the cryo-EM structure of the heterohexameric RET:GDNF:GFR1 complex with a fully resolved heparin ligand, revealing an unexpected extended HS binding site spanning all three proteins. The architecture of the complex and binding mode of the HS chain in this complex enables the formation of a higher order 4:4:4 assembly bound to a single 30-saccharide HS chain which bridges two intimately bound complexes. This multi-protein interface selectively binds the highly sulfated domains of HS over other GAG classes, and is essential for RET activation in trans with soluble GFR1, but not in cis when GFR1 is membrane-bound. Our data suggest that HS shapes the dynamics of RET signalling at every stage, from ligand diffusion to signalling complex formation. Thus, GDNF-GFRa1 paracrine signalling reveals a surprising dependence for long-chain GAG function in which the glycan engages in both receptor complex assembly and clustering.