Abstract
Yeast vacuolar protein sorting 13 (Vps13) is a bridge-like transporter that directs lipid flow between membranes at organelle contact sites. Vps13 targeting relies on organelle-specific adaptors containing proline-X-proline (PxP) motifs, which compete for binding to the Vps13 adaptor-binding (VAB) domain. Though a VAB-PxP interface has been identified for the mitochondrial adaptor Mcp1, whether other adaptors use identical binding mechanisms is unknown. Moreover, not every Vps13 function is connected to a known PxP adaptor, suggesting other adaptors may exist. Here, we validate the significance of the shared VAB-PxP interface by showing that mutations within this region inhibit both adaptor binding and Vps13 membrane targeting in vivo. Using predictive modeling, we demonstrate that while adaptors share a common Vps13-binding interface, slight differences between these interfaces may contribute to preferential binding and adaptor competition. Notably, we find that the VPS pathway functions independently of the PxP motif binding site. Our results indicate that Vps13 likely employs a non-PxP adaptor mechanism in this pathway, yet the structural integrity of the VAB domain remains essential for proper pathway function.