Structural basis for the ATP-dependence of omegasome biogenesis by DFCP1

Autophagosome formation begins at phosphatidylinositol 3-phosphate-enriched endoplasmic reticulum (ER) subdomains termed omegasomes. DFCP1/ZFYVE1 is recruited to omegasomes through its FYVE domains and has recently been shown to function as an ATPase involved in omegasome constriction and autophagosome biogenesis. However, the structural basis of DFCP1 ATPase activity and how nucleotide-dependent conformational states regulate omegasome dynamics remain unknown. Here, we determined the crystal structures of the DFCP1 ATPase domain in complex with either ADP or the non-hydrolyzable ATP analogue, AppNHp at near atomic resolution. We employed structure-guided mutagenesis to define residues required for DFCP1 function in cells. The structures reveal that the active site contains a trans-acting Arg271 finger coordinating the ψ-phosphate and trans-acting His323 that stacks on the ATP adenine ring. ATP hydrolysis results in a conformational switch in the vicinity of Arg271, while contacts with His323 persist in the presence of ADP. Biochemical analyses of DFCP1 and its mutants show that DFCP1 forms ATP-dependent microdomains on membranes. Disruption of His323 and Arg271 uncouples nucleotide binding from ATP hydrolysis and alters the oligomeric state of the protein. Live-cell imaging of DFCP1 knockout cells reconstituted with wild-type or mutant DFCP1 further demonstrates that these biochemical defects translate into distinct omegasome phenotypes. Together, our data provides a structural-function framework for DFCP1 ATPase activity and reveals how distinct catalytic elements control omegasome dynamics in vivo . We propose that nucleotide-dependent assembly and hydrolysis-driven conformational changes enable DFCP1 to regulate omegasome formation and its progression toward autophagosome closure.