Molecular architecture of human LYCHOS involved in lysosomal cholesterol signaling

Abstract

Lysosomal membrane protein LYCHOS (lysosomal cholesterol signaling) translates cholesterol abundance to mammalian target of rapamycin activation. Here we report the 2.11-Å structure of human LYCHOS, revealing a unique fusion architecture comprising a G-protein-coupled receptor (GPCR)-like domain and a transporter domain that mediates homodimer assembly. The NhaA-fold transporter harbors a previously uncharacterized intramembrane Na+ pocket. The GPCR-like domain is stabilized, by analogy to canonical GPCRs, in an inactive state through ‘tethered antagonism’ by a lumenal loop and strong interactions at the cytosol side preventing the hallmark swing of the sixth transmembrane helix seen in active GPCRs. A cholesterol molecule and an associated docosahexaenoic acid (DHA)-phospholipid are entrapped between the transporter and GPCR-like domains, with the DHA-phospholipid occupying a pocket previously implicated in cholesterol sensing, indicating inter-domain coupling via dynamic lipid–protein interactions. Our work provides a high-resolution framework for functional investigations of the understudied LYCHOS protein. The authors show the dimeric structure of human LYCHOS (lysosomal cholesterol signaling), a fusion of a transporter and a G-protein-coupled receptor-like domain. The study uncovers unique transporter and receptor features and proposes a mechanism to couple cholesterol sensing, transport and signaling.