DMXL1 promotes recruitment of V1-ATPase to lysosomes upon TRPML1 activation

Abstract

Lysosomes, central hydrolytic organelles, are regulated by ion flow, including calcium and protons, via transporters and channels to maintain an acidified lumen for hydrolytic activity. TRPML1, a lysosomal ion channel, effluxes cations upon activation, promoting rapid conjugation of ATG8 proteins to the lysosomal membrane in a process known as conjugation of ATG8 to single membranes (CASM). However, our understanding of how TRPML1 activation reorganizes the lysosomal proteome is poorly understood. Here, we identify DMXL1 as a key regulator of lysosomal homeostasis through quantitative proteomics of lysosomes during TRPML1 activation by the agonist MLSA5. DMXL1 is recruited to lysosomes and Salmonella-containing vacuoles, both in a CASM-dependent manner. As the mammalian ortholog of yeast Rav1, DMXL1 assembles with Rav2 ortholog ROGDI and WDR7, and associates with V0 and V1 subunits of the lysosomal V-ATPase. TRPML1 activation drives V1 subunit recruitment to lysosomes in a DMXL1- and DMXL2-dependent manner. DMXL1- and DMXL2-deficient cells display reduced V1-ATPase recruitment, increased lysosomal pH and diminished hydrolytic capacity. Using AlphaFold modeling supported by cross-linking proteomics, we identify interaction interfaces within the DMXL1–ROGDI–WDR7 complex, as well as an ATP6V1A binding interface in DMXL1, whose mutation affects interaction and function. Our findings suggest CASM-dependent DMXL1 recruitment, coupled with V-ATPase assembly, is critical for maintaining lumenal pH and lysosomal function in response to TRPML1 activation.