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Transport mechanism of P4 ATPase phosphatidylcholine flippases

Lin Bai, Qinglong You, Bhawik K. Jain, H. Diessel Duan, Amanda Kovach, Todd R. Graham, Huilin Li

2020eLife62 citationsDOIOpen Access PDF

Abstract

The P4 ATPases use ATP hydrolysis to transport large lipid substrates across lipid bilayers. The structures of the endosome- and Golgi-localized phosphatidylserine flippases—such as the yeast Drs2 and human ATP8A1—have recently been reported. However, a substrate-binding site on the cytosolic side has not been found, and the transport mechanisms of P4 ATPases with other substrates are unknown. Here, we report structures of the S. cerevisiae Dnf1–Lem3 and Dnf2–Lem3 complexes. We captured substrate phosphatidylcholine molecules on both the exoplasmic and cytosolic sides and found that they have similar structures. Unexpectedly, Lem3 contributes to substrate binding. The conformational transitions of these phosphatidylcholine transporters match those of the phosphatidylserine transporters, suggesting a conserved mechanism among P4 ATPases. Dnf1/Dnf2 have a unique P domain helix-turn-helix insertion that is important for function. Therefore, P4 ATPases may have retained an overall transport mechanism while evolving distinct features for different lipid substrates.

Topics & Concepts

FlippaseATPasePhospholipid scramblasePhosphatidylserineATP hydrolysisPhosphatidylcholineBiophysicsP-type ATPaseATP-binding cassette transporterChemistryTransmembrane domainBiochemistryCytosolCell biologyEndosomeBiologyTransporterEnzymeMembranePhospholipidReceptorGeneCellular transport and secretionLipid Membrane Structure and BehaviorEndoplasmic Reticulum Stress and Disease
Transport mechanism of P4 ATPase phosphatidylcholine flippases | Litcius