ATG9A and ARFIP2 cooperate to control PI4P levels for lysosomal repair.

De Tito, Stefano; Almacellas, Eugenia; Yu, Daniel Dai; Millard, Emily; Zhang, Wenxin; de Heus, Cecilia; Queval, Christophe; Hervás, Javier H; Pellegrino, Enrica; Panagi, Ioanna; Fogde, Ditte; Thurston, Teresa LM; Klumperman, Judith; Gutierrez, Maximiliano; Tooze, Sharon A

ATG9A and ARFIP2 cooperate to control PI4P levels for lysosomal repair.

journal contribution

posted on 2025-10-23, 09:31 authored by Stefano De Tito, Eugenia Almacellas, Daniel Dai Yu, Emily Millard, Wenxin Zhang, Cecilia de Heus, Christophe Queval, Javier H Hervás, Enrica Pellegrino, Ioanna Panagi, Ditte Fogde, Teresa LM Thurston, Judith Klumperman, Maximiliano Gutierrez, Sharon A Tooze

Lysosome damage activates multiple pathways to prevent lysosome-dependent cell death, including a repair mechanism involving endoplasmic reticulum (ER)-lysosome membrane contact sites, phosphatidylinositol 4-kinase-2a (PI4K2A), phosphatidylinositol-4 phosphate (PI4P), and oxysterol-binding protein-like proteins (OSBPLs) lipid transfer proteins. PI4K2A localizes to the trans-Golgi network and endosomes, yet how it is delivered to damaged lysosomes remains unknown. During acute sterile damage and damage caused by intracellular bacteria, we show that ATG9A-containing vesicles perform a critical role in delivering PI4K2A to damaged lysosomes. ADP ribosylation factor interacting protein 2 (ARFIP2), a component of ATG9A vesicles, binds and sequesters PI4P on lysosomes, balancing OSBPL-dependent lipid transfer and promoting the retrieval of ATG9A vesicles through the recruitment of the adaptor protein complex-3 (AP-3). Our results identify a role for mobilized ATG9A vesicles and ARFIP2 in lysosome homeostasis after damage and bacterial infection.