Molecular Insights into Fungal Glycosylphosphatidylinositol Transamidase Complex.
Zhengkang Hua, Xuyang Ding, Yanan Wu, Di Zhang, Xinlin Hu, Ping Yang, Jiameng Li, Yi Tan, Junbo Liu, Mingjie Zhang, Min Zhang, Xiaotian Liu, Hongjun Yu
Abstract
Open AccessThe glycosylphosphatidylinositol (GPI) biosynthesis pathway is critical for antifungal drug development. As a key component of this pathway, GPI transamidase (GPIT) catalyzes the attachment of GPI anchors to proteins, a process essential for fungal cell wall integrity and virulence. Despite its biological significance, structural and mechanistic insights into fungal GPIT remain limited. Here, a series of cryo-electron microscopy structures capturing distinct functional states of Saccharomyces cerevisiae GPIT is reported, including GPIT complexed with a GPI anchor, GPIT bound to a substrate-mimetic peptide, and an unprecedented dimeric GPIT assembly. These structures reveal the conserved GPI anchor binding site formed by Gab1 and Gpi16, as well as a key protein substrate recognition site, Gpi16 Y550. Comparative structural analyses uncover fungal-specific adaptations and the dynamic accommodation of catalytic subunit Gpi8. The dimeric GPIT structure exhibits a unique T-shaped organization unexpectedly mediated by transmembrane helices of Gab1 and Gaa1, a configuration unlikely to form in the human counterpart. This study provides a molecular framework for understanding GPIT function and species-specific divergences, providing a molecular basis for antifungal drug development.