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Molecular basis of the inositol deacylase PGAP1 involved in quality control of GPI-AP biogenesis

Jingjing Hong, Tingting Li, Yulin Chao, Yidan Xu, Zhini Zhu, Zixuan Zhou, Weijie Gu, Qianhui Qu, Dianfan Li

2024Nature Communications18 citationsDOIOpen Access PDF

Abstract

The secretion and quality control of glycosylphosphatidylinositol-anchored proteins (GPI-APs) necessitates post-attachment remodeling initiated by the evolutionarily conserved PGAP1, which deacylates the inositol in nascent GPI-APs. Impairment of PGAP1 activity leads to developmental diseases in humans and fatality and infertility in animals. Here, we present three PGAP1 structures (2.66-2.84 Å), revealing its 10-transmembrane architecture and product-enzyme interaction details. PGAP1 holds GPI-AP acyl chains in an optimally organized, guitar-shaped cavity with apparent energetic penalties from hydrophobic-hydrophilic mismatches. However, abundant glycan-mediated interactions in the lumen counterbalance these repulsions, likely conferring substrate fidelity and preventing off-target hydrolysis of bulk membrane lipids. Structural and biochemical analyses uncover a serine hydrolase-type catalysis with atypical features and imply mechanisms for substrate entrance and product release involving a drawing compass movement of GPI-APs. Our findings advance the mechanistic understanding of GPI-AP remodeling.

Topics & Concepts

BiogenesisHydrolaseCell biologySerineSecretionTransmembrane proteinChemistrySubstrate (aquarium)BiochemistryInositolEnzymeBiologyEcologyReceptorGeneCellular transport and secretionLysosomal Storage Disorders ResearchStudies on Chitinases and Chitosanases
Molecular basis of the inositol deacylase PGAP1 involved in quality control of GPI-AP biogenesis | Litcius