1. Structural basis of polyamine transport by human ATP13A2 (PARK9)
- Author
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Sim, Sue Im, von Bülow, Sören, Hummer, Gerhard, and Park, Eunyong
- Subjects
Biochemistry and Cell Biology ,Biological Sciences ,Underpinning research ,1.1 Normal biological development and functioning ,Generic health relevance ,Animals ,Biological Transport ,Catalysis ,Cryoelectron Microscopy ,Cytosol ,Humans ,Lipids ,Lysosomes ,Molecular Dynamics Simulation ,Parkinson Disease ,Phosphorylation ,Polyamines ,Protein Conformation ,Protein Domains ,Proton-Translocating ATPases ,Saccharomyces cerevisiae ,Spodoptera ,P-type ATPase ,P5B-ATPase ,Parkinson's disease ,cryo-EM ,lysosome ,membrane protein ,polyamine ,spermine ,transporter ,Medical and Health Sciences ,Developmental Biology ,Biological sciences ,Biomedical and clinical sciences ,Health sciences - Abstract
Polyamines are small, organic polycations that are ubiquitous and essential to all forms of life. Currently, how polyamines are transported across membranes is not understood. Recent studies have suggested that ATP13A2 and its close homologs, collectively known as P5B-ATPases, are polyamine transporters at endo-/lysosomes. Loss-of-function mutations of ATP13A2 in humans cause hereditary early-onset Parkinson's disease. To understand the polyamine transport mechanism of ATP13A2, we determined high-resolution cryoelectron microscopy (cryo-EM) structures of human ATP13A2 in five distinct conformational intermediates, which together, represent a near-complete transport cycle of ATP13A2. The structural basis of the polyamine specificity was revealed by an endogenous polyamine molecule bound to a narrow, elongated cavity within the transmembrane domain. The structures show an atypical transport path for a water-soluble substrate, in which polyamines may exit within the cytosolic leaflet of the membrane. Our study provides important mechanistic insights into polyamine transport and a framework to understand the functions and mechanisms of P5B-ATPases.
- Published
- 2021